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THREATS TO NATIVE AQUATIC INSECT BIODIVERSITY IN HAWAI'I AND THE PACIFIC,
AND CHALLENGES IN THEIR CONSERVATION
A DISSERTATION SUBMITTED TO THE GRADUATE DIVISION OF THEUNIVERSITY OF HAWAI 'I IN PARTIAL FULFILLMENT OF THE
REQUIREMENTS FOR THE DEGREE OF
DOCTOR OF PHILOSOPHY
IN
ENTOMOLOGY
AUGUST 2005
ByRonald A. Englund
Dissertation Committee:
Mark Wright, ChairpersonDan RubinoffNeal EvenhuisDan PolhemusAndrew Taylor
TABLE OF CONTENTS
ACKNOWLEDGEMENTS , ii
ABSTRACT iii
LIST OF TABLES vi
LIST OF FIGURES viii
CHAPTER 1. THE IMPACTS OF INTRODUCED POECILIID FISH AND ODONATA ON THE
ENDEMIC MEGALAGRION (ODONATA) DAMSELFLIES OF 0'AHU ISLAND, HAWAI'I 1
CHAPTER 2: EVALUATING THE EFFECTS OF INTRODUCED RAINBOW TROUT (Oncorhynchus
mykiss) ON NATIVE STREAM INSECTS ON KAUA'I ISLAND, HAWAI'I 40
CHAPTER 3. LONG-TERM MONITORING OF ONE OF THE MOST RESTRICTED INSECT
POPULATIONS IN THE UNITED STATES, Megalagrion xanthomelas Selys-Longchamps, 1876, AT
TRIPLERARMY MEDICAL CENTER, O'AHU, HAWAI'I... 76
CHAPTER 4. THE LOSS OF NATIVE BIODIVERSITY AND CONTINUING NONINDIGENOUS
SPECIES INTRODUCTIONS IN FRESHWATER, ESTUARINE, AND WETLAND COMMUNITIES
OF PEARL HARBOR, O'AHU, HAWAIIAN ISLANDS 91
CHAPTER 5. FLOW RESTORATION AND PERSISTENCE OF INTRODUCED SPECIES IN
WAlKELE STREAM, 0'AHU 125
CHAPTER 6: INVASIVE SPECIES THREATS TO NATIVE AQUATIC INSECT AND ARTHROPOD
BIODIVERSITY IN HAWAI'I, THE PACIFIC AND OTHER RELEVANT AREAS WITH DISCUSSION
OF CONSERVATION MEASURES 143
ACKNOWLEDGEMENTS
I would like to thank the many people that have made this dissertation possible. I especially would like to
extend my thanks and warmest gratitude to my advisor Mark Wright, whose sense of humor and keen
intellect made this process as enjoyable as it can be. My committee, consisting of Dan Rubinoff, Neal
Evenhuis, Dan Polhemus and Andrew Taylor provided valuable insights and advice throughout. I sincerely
acknowledge and appreciate the efforts of my entire committee throughout my time at the University of
Hawai'i at Manoa. I am also deeply appreciative of Neal Evenhuis and Allen Allison for their
encouragement, and allowing me the flexibility to pursue a Doctorate while being employed at the Bishop
Museum. I have greatly enjoyed the scientific and cultural 'ohana at the Bishop Museum that always
provided an ideal research and working atmosphere. Rob Cowie and Frank Howarth of the Bishop Museum
also provided valuable reviews and advice for many of these chapters. Bishop Museum librarians Patti
Belcher and B.J. Short were always helpful in tracking down the many obscure references. Several key
organizations provided the support that allowed my research to take place, and I thank the following
organizations that funded this research: Bishop Museum, Hawaii Division of Aquatic Resources, Nature
Conservancy, Smithsonian Institution, and the Delegation ala Recherche Polynesie fran<;aise.
People too numerous to mention assisted me in various aspects of the fieldwork required for this wide
ranging dissertation, and I greatly appreciate help from David Preston, Betsy Gagne, Dan Polhemus, Jean
Yves Meyer, BenoIT Fontaine, Olivier Gargominy, Tina Lau, Stephanie Loo, Brian Naeole, Alison
Sherwood, and Steve Jordan. Special thanks goes to the Hawaii Division of Aquatic Resources crew
including Bob Nishimoto, Glenn Higashi, Darrell Kuamo'o, John Kahiapo, Skippy Hau, Bill Puleloa, and
Mike Yamamoto. Bill Devick and Bob Nishimoto were also instrumental in encouraging and funding much
of this research as well. La Vonne Furtado provided consistent moral support during the crucial final stages
of this journey. I am also privileged to have incredibly supportive parents and a wonderful family, without
whom I would have never attempted this work. I would like to dedicate this dissertation to my wonderful
parents, Stanley and Marjorie Englund.
11
ABSTRACT
Although the decline in numbers and diversity and threat to native insects in the Hawaiian Islands is widely
recognized by field scientists there has been little progress in either documenting the real decline of native
species, or in demonstrating specific causes of the overall decline of these species. Additionally, few
conservation actions to either restore populations or mitigate actual threats to native arthropods have been
mentioned in the literature. The following chapters examine several assessments of relevant aquatic systems
and the native aquatic insects dwelling within, where there has either been a perceived or real decline of these
native Hawaiian aquatic arthropods because of threats from invasive or introduced species.
The large adaptive radiation of the endemic native damselflies (Coenagrionidae: Megalagrion) in Hawai'i has
received considerable attention and study since at least the 1880s. Endemic Megalagrion are in many ways
reflective of a great loss because they are largely now found in remote upper headwater areas of streams, yet
they also represent the hope of preserving highly diverse freshwater ecosystems found throughout the
Hawaiian archipelago. The first two chapters of this dissertation examine the impacts of two differing taxa
of introduced fish on Hawaiian Megalagrion, Poeciliidae (livebearers or mosquitofish family) and
Salmonidae (trout). The effects of each fish species on native aquatic insects depended mainly on the
invasive status of each group; for example, Chapter 1 (Englund 1999) examines the impacts of introduced
poeciliids on native damselflies. Damselflies were completely eliminated on the island of 0' ahu wherever
species in the highly invasive mosquitofish family were found, and only remnant populations were found in
high elevations lacking introduced fish. Chapter 2 (Englund and Polhemus 2001) examines the impacts of
the non-invasive rainbow trout (Oncorhynchus clarkI) on Megalagrion damselflies. Damselflies and all other
native aquatic insects were not found to be harmed by trout in the uppermost elevations of Kaua'i streams
where trout reproduce naturally, and even had more robust populations than in some nearby non-trout
containing streams. The lack of impacts on native damselflies by a large, generalist predator such as
rainbow trout pointed out a seeming paradox. Whereas the small but ubiquitous mosquitofish appears to
have completely devastated native aquatic fauna wherever it has been introduced outside of its natural range,
iii
trout, because of their restricted range and smaller population sizes have had minimal, if any impacts on
native invertebrates in Hawai'i.
Because introduced fish species have caused either the extinction or severe range contractions of Megalagrion
damselflies in Hawai'i, long-term monitoring of the remnant populations has become necessary to preserve
these remaining populations. Chapter 3 (Englund 2001) provides a case study in both the monitoring and
preservation of a remnant O'ahu damselfly population now found in only 95 m of fishless stream at the
TripIer Army Medical Center. Chapter 3 also provides several harrowing examples of how this species was
nearly been eliminated in the past 10 years through accidents and mismanagement. Not only are the endemic
Megalagrion now missing from all lowland areas of O'ahu (with the exception of the TripIer population),
lowland aquatic insect diversity throughout O'ahu is at a remnant status, and biodiversity surveys for native
aquatic insects in the Pearl Harbor watersheds in Chapter 4 (Englund 2002) indicated a near absence of
native aquatic insects in these freshwater habitats. Lower Pearl Harbor watersheds were documented to have
lost many native aquatic insect taxa such as all native Heteroptera, damselflies, Coleoptera, and many
Diptera species, while introduced insect species were abundant.
A variety of conservation measures have been suggested to either restore or maintain the current levels of
freshwater biodiversity in Hawai'i. In Chapter 5 (Englund and Filbert 1999), the case of significantly
increasing and restoring stream flow in a formerly diverted stream was examined to determine whether this
factor alone would lead to a restoration of native aquatic species. It was found that merely increasing stream
flow by itself was not enough to rid the stream of any alien aquatic species, in fact, several new
nonindigenous aquatic species became established after stream flows were increased. The results of Chapter
5 confirm that an integrated, balanced and possibly drastic approach will be required to maintain and preserve
Hawai'i's native aquatic insect fauna. A wide-variety of conservation measures in the Hawaiian archipelago
will be needed to maintain current biodiversity levels, and also hopefully restore native freshwater
biodiversity in selected areas.
iv
To put the Hawai'i problem into perspective, a brief review of the impacts of invasive species on native
insects in other tropical areas is provided in Chapter 6. This review chapter also provides a synthesis of the
problem facing Hawaiian freshwater insects and other terrestrial arthropods in Hawai'i and elsewhere due to
invasive species, and how the Hawaiian case study of invasive species impacts has many parallels to other
vulnerable biotas. Finally, drawing on a mixed record of past mistakes and successes in Hawai'i and
elsewhere, some potential practical conservation measures intended to preserve and restore endemic island
aquatic insects are provided in Chapter 6.
v
LIST OF TABLES
Table 1.1. Extinctions of Megalagrion species in surveyed 0'ahu aquatic habitats since 1936 8
Table 1.2. Remnant native Megalagrion species found in O'ahu streams, tributaries in parentheses, and
relative abundance in stream areas containing native damselflies, (rare (R) = < 3 individuals collected or
observed); (moderately common (C) = <: 3 individuals collected or observed) 9
Table 1.3. Biogeographic status and Hawaiian Island distribution of aquatic Megalagrion and introduced
Odonata species found on O'ahu 11
Table 2.1. Aquatic insect species and native or introduced status collected at each Kaua'i stream 50
Table 2.2. Total number of aquatic species collected during benthic, drift, and aerial (general) collections
during this study 51
Table 2.3 Presence or absence in surveyed K6ke'e State Park streams of naturally reproducing and stOcked
rainbow trout and native Megalagrion damselflies 57
Table 2.4. Geographic origin and terrestrial or aquatic status of prey items found in 80 K6ke'e trout
stomachs, 1997-1999 60
Table 2.5. Summary numbers and percent frequency of native prey items of special concern collected in
rainbow trout stomachs during this study, compared to the number of taxa collected per stream 61
Table 4.1. Summary of the native or nonindigenous status and total number (percent) of aquatic species
found in Pearl Harbor estuarine habitats 98
Table 4.2. Geographic source (year of introduction) and known (or probably known) mode of introduction of
nonindigenous species of aquatic macrofauna found in Pearl Harbor streams and estuaries 107
Table 5.1. The range and mean water velocities (± standard error) recorded in transects downstream of
Waikele Springs 131
Table 5.2. Introduced and native species found in Waikele Stream, Oahu in 1993 and 1997-1998 from 250
m above Waikele Springs downstream to concrete weir. Oahu introduction dates from Beardsley
(1980), Devick (1991a), Cowie (1995), Polhemus & Asquith (1996), Randall (1996), Cowie (1998).
.................................................................................................................................... 132
vi
Table 6.1. Extinction status of native insect taxa in the Hawaiian Islands that have recently had their
conservation status examined, to lowest taxonomic resolution 149
Table 6.2. Successfully eradicated invasive animal species in the Hawaiian Islands 161
vii
LIST OF FIGURES
Figure 1.1. Limnological divisions on O'ahu defined for the purposes of this study 5
Figure 1.2. Status of stream and wetland dwelling damselflies on the island of 0'ahu. E = Extinct on 0'ahu
....................................................................................................................................... 8
Figure 1.3. Elevational distribution for Hawaiian Megalagrion damselflies and introduced poeciliid fish for
streams entering Kane'ohe Bay, O'ahu 12
Figure 1.4. Elevational distribution for Hawaiian Megalagrion damselflies and introduced poeciliid fish for
streams entering northern windward O'ahu 13
Figure 1.5. Elevational distribution for the Hawaiian Megalagrion damselflies and introduced poeciliid fish
for streams entering Pearl Harbor and leeward O'ahu 14
Figure 1.6. Elevational distribution for introduced Ischnura ramburii and Ischnura posita damselflies and
introduced poeciliid fish for selected Kane'ohe Bay and Pearl Harbor streams, O'ahu 18
Figure 2.1. Study area of sampled K6ke'e State Park Streams, Kaua'i Island, Hawai'i 45
Figure 2.2 Summary of aquatic species collected in K6ke'e State Park streams from all sampling methods
combined (general sampling, Malaise traps, drift, benthic samples) 52
Figure 2.3. Summary of all insect species collected from rainbow trout stomachs (n = 80) and their
terrestrial or aquatic, and native or introduced status in K6ke'e State Park Streams 52
Figure 2.4. Mean density by stream for the two most important constituents of benthic (Surber) samples,
the caddisfly C. pettiti and midge C. bicinctus 53
Figure 2.5. Summary graph of number of aquatic species in Kaua'i Streams and the presence or absence of
naturally reproducing trout in each stream; Lumaha'i and Hanalei have never been stocked with trout.
..................................................................................................................................... 53
Figure 2.6. The six numerically most abundant aquatic insect taxa captured in drift samples taken in K6ke'e
state park streams 58
Figure 3.1. Map of O'ahu, Hawai'i showing locations of current and historic records for Megalagrion
xanthomelas (from Evenhuis et a1., 1995) 78
viii
Figure 3.2. TAMC Mitigation ponds prior to drainage, February 2000 79
Figure 3.3. Megalagrion xanthomelas captures at TAMC stream, May 1997-June 2000 82
Figure 3.4. Megalagrion xanthomelas captures at TAMC mitigation ponds from May 1997-February 2000.
..................................................................................................................................... 83
Figure 3.5. Oviposition scars on water lilies at the TAMC mitigation ponds July 1997-February 2000.. 84
Figure 4.1. Map of Pearl Harbor with sampling locations 95
Figure 4.2. Number of species by stream and native or nonindigenous status for combined aquatic fauna
found in estuarine regions of Pearl Harbor 98
Figure 4.3. Native or nonindigenous status of fish species and total numbers found at different salinity
levels in Pearl Harbor estuaries 101
Figure 4.4. Native or nonindigenous status of aquatic insects at varying elevations on O'ahu: upper Halawa
data from Polhemus (1994), upper Waikele data from Englund (1993) 112
Figure 5.1. Waikele Stream study area 128
ix
CHAPTER 1. THE IMPACTS OF INTRODUCED POECILIID FISH AND ODONATA ON THE
ENDEMIC MEGALAGRION (ODONATA) DAMSELFLIES OF 0'AHU ISLAND, HAWAI'I
1
ABSTRACT
Since the beginning of this century there have been substantial declines in the distribution and abundance of
native Megalagrion damselflies on the Hawaiian Island of O'ahu. Native damselflies have also vanished
from most low elevation areas on other Hawaiian Islands, although historically, lotic and wetland dwelling
damselfly species were once common throughout the archipelago. It is hypothesized that poeciliid fish
introduced for biological control have caused the decline of four stream-breeding damselfly species on O'ahu,
and the extinction or near-extinction of two other species statewide. This study documents the presence of
remnant Megalagrion populations in O'ahu streams, wetlands, and estuaries, and records the elevational
distributions of introduced fish in each waterbody surveyed. The distributions of introduced Odonata are also
recorded, because the eight species ofdamselflies and dragonflies introduced to O'ahu since 1936 present
another potential threat to native Hawaiian damselflies. Native damselfly and introduced poeciliid fish
distributions were mutually exclusive on O'ahu, and it is concluded that this is probably due to predation by
these introduced fish. By contrast, even the rarest native Megalagrion damselflies were found in areas
containing introduced damselflies and dragonflies.
INTRODUCTION
The Hawaiian Islands have a rich native damselfly fauna with 26 recognized species and subspecies in the
endemic genus Megalagrion (Polhemus and Asquith 1996). Hawaiian damselflies have radiated into a wide
range of aquatic and terrestrial habitats, including streams and wetlands, coastal anchialine ponds, and upland
bogs. Certain species also breed in upland terrestrial habitats, such as in the leaf litter of the native fern
Dicranopteris linearis, and in waterpockets formed in the base of climbing plants such as Freycinetia arborea
(Williams 1937a; Polhemus and Asquith 1996).
Although native damselflies were formerly one of the most conspicuous elements of Hawaiian stream and
wetland communities, many species appear to be increasingly rare or have disappeared altogether. Because of
efforts by early collectors, historic damselfly distributions and abundances prior to introductions of alien
2
aquatic species are relatively well known, particularly on O'ahu. Extensive collections by R.C.L. Perkins
from 1892 to the early 1900s documented the presence of native damselfly populations prior to many
environmental changes (Perkins 1899; Perkins 1910; Polhemus 1993; Liebherr and Polhemus 1997). These
early surveys were followed by almost a century of subsequent damselfly collecting. Liebherr and Polhemus
(1997), assessing Megalagrion relative abundances over time, found a substantial decline in stream species
on O'abu since 1892, even though terrestrial species were as widespread and abundant as they were in the
1890s.
By 1935, native damselflies on O'abu, such as Megalagrion xanthomelas (Selys-Longchamps, 1876), were
becoming uncommon, and fish introduced for mosquito control were suspected to be involved in their
decline (Williams 1937a). Subsequent researchers also implicated introduced fish as a cause of decline
(Zimmerman, 1948; Polhemus 1993; 1997; Polhemus and Asquith 1996). However, these observations
were anecdotal, and definitive distributional data for introduced fish and endemic damselflies have not been
published.
Hawai 'i has a long history of purposeful and accidental introduction of aquatic species (Funasaki et aI.,
1988; Devick 1991). Among these were three species of fish imported from southern Texas in 1905 for
mosquito control (Van Dine 1907; 1908). At least two of these species, Gambusia affinis (Baird & Girard,
1853) (western mosquitofish) and Poecilia latipinna (Leseur, 1821) (sailfin molly), both in the family
Poeciliidae, eventually established naturally reproducing populations in Hawai'i. In 1922, more poeciliid
species such as Poecilia reticulata Peters, 1859, Xiphophorus helleri (Heckel, 1848) and Xiphophorus
maculatus (Gunther, 1866) were introduced for mosquito control (Brock 1960). Since these initial biological
control introductions there have been additional intentional and accidental introductions of fresh and brackish
water fish species. By 1991, at least 44 species of introduced freshwater fish had become established in
Hawaiian waters (Devick 1991). These introductions have resulted from deliberate release by government
agencies, or by casual release of domestic aquarium fish. The poeciliid fish suspected of having the greatest
3
impact on Oahu's Megalagrion damselflies, however, were those introduced for biological control of
mosquitoes prior to 1923.
Another potential concern for native Megalagrion damselflies has been the introduction of alien Odonata
species. Three damselfly and five dragonfly species have been accidentally introduced to O'ahu since 1936
(Zimmerman 1948; Harwood 1974; Nishida 1997). It is possible that introduced Odonata could have
negative impacts on native Megalagrion species through competition or predation, and may be an additional
or alternate reason that native damselflies are absent from lowland areas. Thus, in conjunction with surveys
of native damselflies and introduced fish, distributions of introduced Odonata were also recorded.
Three species of amphibians have become successfully established on O'ahu since the 1800s (Devick 1991).
Two frog (Rana rugosa Schlegel, 1838, Rana catesbeiana Shaw, 1802) and one toad (Bufo marinus
(Linneaus, 1758)) species were common from sea level to even the highest elevations of O'ahu.
Distributions of introduced amphibians in stream and wetland areas were also recorded.
STUDY AREA
The study area covers lentic, lotic, coastal wetland and estuarine habitats on the island of 0'ahu, with 0'ahu
freshwater habitat types classified according to Polhemus and Asquith (1996). One of the high islands in the
Hawaiian archipelago, O'ahu has 57 recognized perennial streams (Hawaii Stream Assessment 1990), with
the longest, Kaukonahua, being 50 km long, although most are much shorter. The headwaters or sources of
these streams vary in elevation from 1219 m on Mt. Ka'ala (Makaha and Hale'au'au Streams) to large
springs emerging only 1.0-2.5 m above sea level in the Pearl Harbor area (Kapakahi Stream, Waiawa
Springs, Waiau Springs).
For this study, we divided O'ahu into three major geographic units (Figure 1.1). The wetter windward areas
of O'ahu, which contain the majority of the island's perennial streams, were separated into Kane'ohe Bay
4
21°30'
Leeward & I'earl HarborStreams
158°00'
OAHU
r-··· ---110km
Northern Windward Shaded areas indicate reliefStreams above 600 m. elevation
21°30'
Figure 1.1. Limnological divisions on O'ahu defined for the purposes ofthis study.
Bold line indicates hydrological boundary between leeward and windward (northeastern) O'ahu, crosshatching indicates surveyed northern windward and Kane'ohe Bay streams. Streams containing Megalagrionpopulations are numbered on this map as follows:
Kahalu'u = 1Waihe'e=2Ka'alaea= 3Waiahole =4Waikane= 5Kahana = 6
Kaluanui = 7Ma'akua=8Kaipapa'u = 9Koloa = 10Wailele = 11Kahawainui = 12
Dillingham = 13Hale'au'au (Mt. Ka'ala) = 14Makaha (Mt. Ka'ala) = 15Kaupuni = 16Helemano = 17Poamoho = 18
5
Kaukonahua = 19Waiawa=20Halawa=21Moanalua = 22Kalihi = 23
and northern windward drainages, while the drier leeward Ko'olau, Pearl Harbor, and Wai'anae Mountain
watersheds were combined into a third major hydrological unit. Most streams on O'ahu are naturally
interrupted, with perennial flow only in the mountain headwaters and in low-elevation areas near the ocean
(Polhemus et ill. 1992). This is a natural condition caused by percolation of water into the alluvium in the
mid-reaches. Such streams exhibit surface flow throughout their length only during periods of extended
precipitation, and streamflow is characteristically flashy, with high flood peaks and low baseflows (Nichols
et a1. 1997).
METHODS
Damselfly sampling commenced in 1992 and continued through 1998; whenever possible, streams were
sampled more than once to confirm aquatic species composition. As O'ahu streams are short, it was often
possible to completely survey a stream from the ocean to the headwaters, especially those originating at
low elevations. Sampling sites were also dependent on local terrain and access to private property. Altitude
at each sampling station was determined by using a combination of topographic maps and a hand-held
altimeter. Fish and damselfly species composition was recorded at each sampling site. A summary of
sampling sites, capture locations, stream type (permanent or intermittent), elevations surveyed, and
elevations where introduced fish and damselflies were found is provided in Appendix 1.
Damselfly Sampling
Sampling focused solely on stream-dwelling damselflies on O'ahu, and did not include terrestrial damselfly
species such as Megalagrion oahuense (Blackburn, 1884) or Megalagrion koelense (Blackburn, 1884). Adult
Odonata were collected mainly with aerial nets. Immature damselflies were collected by benthic sampling
with aquatic dip nets. Most damselfly collections were of adults, as it was usually difficult to locate
immature individuals. Voucher specimens have been deposited in the Bishop Museum and Smithsonian
Institution collections. Aquatic habitat type, such as riffle, run, pool, wetland or estuary (mixed fresh and
6
saltwater), was recorded at each site to ascertain habitat preferences for native Megalagrion damselflies.
Immature damselflies were identified according to Polhemus and Asquith (1996).
Immature Damselfly Behavior
Inferences obtained from immature damselfly response to the threat of fish predation could lead to a
behavioral explanation as to why native damselflies have become so rare. To observe behavioral interactions
with introduced fish, ten immature O'ahu Megalagrion xanthome1as larvae were placed in a 40 liter
aquarium containing ten Gambusia affinis and ten Poecilia mexicana Steindachner, 1863. Additionally,
several species of introduced Odonata such as Ischnura ramburii (Selys-Longchamps, 1850) and Orthemis
ferruginea (Fabricius, 1775) were also placed in this same aquarium. The response ofthe immature Odonata
(such as swimming away, keeping still, or hiding) to predation attempts by the introduced poeciliid fish
was observed.
Fish Sampling
Fish species composition was assessed through seining, netting, snorkeling, and above-water observations.
Fish species composition and number of individuals captured were also recorded during seining. Underwater
visual observations using mask and snorkel were made at sites with sufficient water depth and clarity. The
stomach contents of eight Gambusia affinis and four Poecilia mexicana were examined for immature
damselflies.
RESULTS
Native Damselflies
There has clearly been a significant island-wide decline in the distribution of O'ahu Megalagrion species
when compared to historical records. Resurveys during this study in the 1990s found that almost none of
the original collecting sites of early collectors such as R.C.L. Perkins, FX. Williams, and others contained
native damselfly populations (Table 1.1). Appendix 2 contains specific O'ahu site locality information for
7
Table 1.1. Extinctions of Megalagrion species in surveyed O'ahu aquatic habitats since 1936.
M. hawaiiense M. leptodemas M. n. nigrolineatum M. oceanicum
Collector (Years) Original Currentl Original Current' Original Current! Original Current!
Perkins (1892-1912) 5 1 5 0 8 0 11 0
Williams (1925-1936) 1 0 3 0 1 0 2 0
Timberlake (1919-1923) 1 0
Others (1901-1926) 7 3 0
Total: 6 1 8 0 16 0 17 0
M. pacificum
Original Current'
3 0
3 0
M. xanthomelas
Original Currentl
4 0
3 0
2 0
0
10 0
lCurrent number of extant damselfly populations in exactly or approximately the same aquatic habitats where collected prior to 1936, see Appendix 2 forsites collected by R.C.L. Perkins and F'x. Williams.
Eo
60 i I
50
10
enE 40til~
en'030
Qi.0E::J 20Z
00
Oahu Streams hawaiiense leptodemas nigrolineatum pacificum oceanicum xanthomelas
Figure 1.2. Status of stream and wetland dwelling damselflies on the island of O'ahu. E = Extinct on O'ahu
Table 1.2. Remnant native Megalagrion species found in O'ahu streams, tributaries in parentheses, and relative abundance in stream areas containing nativedamselflies, (rare (R) = < 3 individuals collected or observed); (moderately common (C) = ~ 3 individuals collected or observed).
'"
Kane'ohe BayKahalu'uWaihe'eKa'alaeaWaiahole (Waianu tributary)Waiahole (Uwau tributary)Waikane
WindwardKahanaKaluanuiMa'akuaKaipapa'uKoloaWaileleKahawainui
Native Damselfly Species and Relative AbundanceM. hawaiiense (R), M. nigrohamatum nigrolineatum (C), M oceanicum (R)M. nigrohamatum nigrolineatum (C), M. oceanicum (R)M. nigrohamatum nigrolineatum (C)M hawaiiense (R)M. nigrohamatum nigrolineatum (R)M. hawaiiense (C), M. nigrohamatum nigrolineatum (C)
M. hawaiiense (C), M. nigrohamatum nigrolineatum (C), M. leptodemasM. nigrohamatum nigrolineatum (C), M. oceanicum (C)M. leptodemas (C), M oceanicum (R)M hawaiiense (C), M oceanicum (R)M. hawaiiense (R), M. nigrohamatum nigrolineatum (C), M. oceanicum (R)M. oceanicum (R)M. oceanicum (C)
LeewardlPearl HarborHale'au'au (Mt. Ka'ala) M. hawaiiense (C)Miikaha (Mt. Ka'ala) M. hawaiiense (C)Dillingham (unnamed) M hawaiiense (C)Kaupuni (Honua tributary) M hawaiiense (R)Helemano M. hawaiiense (R), M. nigrohamatum nigrolineatum (C)Poamoho M. nigrohamatum nigrolineatum (C)Kaukonahua M. nigrohamatum nigrolineatum (C)Waiawa M. nigrohamatum nigrolineatum (C), M.leptodemas (C)Halawa M hawaiiense (C), M. leptodemas (C), M nigrohamatum nigrolineatum (C),Moanalua (TAMC) M. xanthomelas (C)'Kalihi M. nigrohamatum nigrolineatum (C)
'Found in only 95 m of artificial stream habitat on O'ahu
Megalagrion damselflies collected by Perkins and Williams. Most of the remaining native damselfly
populations on O'ahu were instead found in remote upper elevation areas that were not surveyed by early
collectors.
Fifty-five of fifty-seven O'ahu streams and most coastal wetland areas were surveyed in whole or part.
Highly fragmented damselfly populations remained in only twenty-two streams (Figure 1.2); these streams
are listed in Table 1.2. Due to rugged terrain, the upper elevation sections of many streams were difficult to
access, and some headwater reaches in the Ko'olau Mountains above 350 m have not yet been surveyed.
These areas are likely to harbor a few additional remnant populations.
Five of the six native stream or wetland dwelling damselflies still persisted on O'ahu (Table 1.3), with one
species, Megalagrion pacificum (McLachlan, 1883), now apparently extinct on O'ahu, and another,
Megalagrion xanthomelas, near extinction. Three species (Megalagrion hawaiiense (McLachlan, 1883),
Megalagrion oceanicum McLachlan, 1883, and Megalagrion leptodemas (Perkins, 1899) were rare and found
in twelve or fewer streams. Two of these species are O'ahu endemics (M oceanicum and M.leptodemas),
and were found in six or fewer small streams. Populations of M. hawaiiense, currently still common on all
the main Hawaiian Islands except O'ahu, were found in low numbers in 12 stream and wetland areas.
Megalagrion nigrohamatum nigrolineatum (Perkins, 1899) was the most common native stream damselfly
collected, and was found in high elevation sections of 15 streams, mainly in windward areas.
Kane'ohe Bay Streams
Only three of the six remaining O'ahu Megalagrion species were observed in Kane'ohe Bay streams. Of
these species, fragmented colonies of Megalagrion nigrohamatum nigrolineatum were found in upper
elevation reaches of six catchments (Figure 1.3), all above barriers that precluded the upstream movement of
poeciliids. Megalagrion nigrohamatum nigrolineatum, a side-channel and calm water dweller in its larval
stages, was the most common species in these Kane'ohe Bay streams (Table 1.2). With the exception of
10
Table 1.3. Biogeographic status and Hawaiian Island distribution of aquatic Megalagrion and introducedOdonata species found on O'ahu.
Biogeographic Current Known Island Historical IslandSpecies Status! Distribution Distribution
Megalagrion hawaiiense Hawaiian Endemic All Major Hawaiian All Major HawaiianIslands Islands
Megalagrion leptodemas O'ahu Endemic O'ahu O'ahuMegalagrion nigrohamatum O'ahu Endemic O'ahu O'ahunigrolineatumMegalagrion oceanicum O'ahu Endemic O'ahu O'ahuMegalagrion pacificum Hawaiian Endemic Maui, Moloka'i, All Major Hawaiian
Hawai'i IslandsMegalagrion xanthomelas Hawaiian Endemic O'ahu, Maui, All Major Hawaiian
Moloka'i, Hawai'i IslandsEnallagma civile Introduction (1936) All Major Hawaiian
IslandsIschnura posita Introduction (1936) All Major Hawaiian
IslandsIschnura ramburii Introduction (1973) All Major Hawaiian
IslandsCrocothemis servilia Introduction (1994) O'ahuOrthemis ferruginea Introduction (1976) All Major Hawaiian
IslandsPantala hymenaea Introduction (1989) O'ahuTramea abdominalis Introduction (1977) O'ahuTramea lacerata Introduction (1874) All Major Hawaiian
IslandsIprom Polhemus and Asquith (1996)
Waikane Stream, M. hawaiiense was uncommon throughout the Kane'ohe Bay watershed. For instance,
only a single M. hawaiiense was found in Waiahole Stream at 244 m elevation, well above the range of
introduced fish. Megalagrion oceanicum were found in restricted areas of only two Kane'ohe Bay streams.
Megalagrion damselflies were completely missing from the lower reaches of all Kane'ohe Bay streams, and
associated low elevation coastal wetland areas. In addition, all taro (Colocasia esculenta) wetland areas in the
Kane'ohe Bay drainage were surveyed. Although historically found in taro fields and lowland areas (Moore
and Gagne 1982), Megalagrion damselflies were never observed in any O'ahu taro field during this study,
despite some areas being intensively sampled, e.g., fifty sampling trips made between 1994 and 1998 to the
Waiahole Stream watershed and adjacent taro fields.
11
o••
Poeciliids =
Megalagrion =
300 .,.---------------------------.....,275250225
E 200-; 175i5 150<tla; 125jjj 100
755025O+--+'+-.,..-t-'-t--t-rr-t--+'-t---+---+''-t----+'--l~__Ir_+'_I-+_-+'+__;
Kawa Kaneohe Heeia Kahaluu Waihee Kaalaea Waiahole Waikane
Figure 1.3. Elevational distribution for Hawaiian Megalagrion damselflies and introduced poeciliid fish forstreams entering Kane'ohe Bay, O'ahu.
Northern Windward Streams
Four Megalagrion species were observed in northern windward streams. Megalagrion oceanicum was found
in five northern windward streams, while M. hawaiiense and Megalagrion nigrohamatum nigrolineatum
were each found in three streams (Table 1.2). Megalagrion leptodemas was found in two catchments:
Kahana Stream and a short section of Ma'akua Stream. Although native damselflies were generally found in
the upper elevations of northern windward streams (Figure 1.4), an exception occurred at Kahana Stream,
where damselflies were found in relatively low-elevation areas (30 m). The Kahana watershed has numerous,
small high-gradient tributaries and seeps lining the steep valley walls, and this was the lowest elevation site
at which any Megalagrion damselflies were found on O'ahu.
12
+
PoecilUds ::::
Megalagrion =
o
700
800 ,----------------------------,
Iffi600
§: 500c:~ 400
~iIi 300
100
200
Kahana Kaluanui Maakua Kaipapau Koloa Wailele Kahawainui
Figure 1.4. Elevational distribution for Hawaiian Megalagrion damselflies and introduced poeciliid fish forstreams entering northern windward O'ahu.
Megalagrion damselflies were completely missing from all stream estuary and coastal wetland areas
surveyed in and near northern windward streams. By contrast, relatively large populations of some species
were found in the upper reaches of most of the same catchments. Malaekahana Stream was the exception;
although this stream maintained perennial flow from 43-244 m elevation, neither introduced fish nor
Megalagrion damselflies were found there.
Pearl HarborlLeeward Streams
Native damselflies were completely absent from the lower sections of Pearl Harbor and leeward streams, and
from the large set of emergent basal springs in the Pearl Harbor region. Four of the six stream-dwelling
Megalagrion species were observed in other leeward O'ahu streams, mainly in upper elevation areas (Figure
1.5). One exception was the presence of M. xanthomelas at the relatively low elevation of 79 m in a
tributary of Moanalua Stream at the TripIer Army Medical Center (TAMC). Megalagrion nigrohamatum
13
nigrolineatum was the most common native species in leeward streams, with other damselflies relatively
more rare (Table 1.2). Three species of stream-dwelling Megalagrion damselflies were found in North
Halawa Stream, which contained the most diverse assemblage of native lotic damselflies of any leeward
O'ahu stream. Two damselfly species were found in Waiawa Stream (from 213 to 335 m), M.
nigrohamatum nigrolineatum and M.leptodemas. Between them, North Halawa and Waiawa Stream
550 .,...--------------------------::::-----------,
500 cIJ Megalagrion =I~ Q400 Poeciliids = CJ
350 0300
250 l. ...200
150
100
50
0+------t.J+--+--44--f---+-+--+--f-i-+----+-+4--+--t::::t--+--1-'+--l--t-'+---jHelemano Waikele Kapakahi Waiawa Waimalu Kalauao Halawa Moanalua
Figure 1.5. Elevational distribution for the Hawaiian Megalagrion damselflies and introduced poeciliid fishfor streams entering Pearl Harbor and leeward O'abu.
accounted for two of the four known remaining M. leptodemas populations. Megalagrion hawaiiense was
found in six widely separated leeward and Pearl Harbor watersheds, but was only common in the Mt. Ka'ala
(elevation 1150 m) bog area, and in a small stream (near Dillingham Airfield) draining Mt. Ka' ala.
Damselfly Behavioral Observations
To observe the behavior of immature Megalagrion in the presence of poeciliids, larvae were placed in an
aquarium with Poecilia mexicana and Gambusia affinis. In these aquarium observations, all 10 Megalagrion
xanthomelas larvae swam to the water's surface, and smaller individuals were eaten whole and larger
individuals were picked apart by Gambusia affinis and Poecilia mexicana. This resulted in 100% mortality
14
of M. xanthomelas larvae within 10 minutes of them being placed in the aquarium. This contrasts with the
diving-to-the-bottom and hiding-in-the-substrate behavior of the introduced Odonata Ischnura ramburii and
Orthemis ferruginea larvae in the same aquarium. Neither of these introduced species exhibited mortality
from poeciliids after remaining in the aquarium for one day. The behavior of Megalagrion paciflcum larvae
(from Moloka'i) was similar to that exhibited by O'ahu M. xanthomelas, as these larvae always swam to
the aquarium surface when disturbed. Swimming to the surface by Megalagrion larvae appeared to be a
completely ineffective escape response behavior against the surface-oriented poeciliid predators, since the
native damselfly larvae were immediately consumed. By contrast, the lack of movement and hiding behavior
by immature Ischnura rambuni appeared to reduce or eliminate successful attacks by poeciliids in
aquariums.
Introduced Fishes
The introduced poeciliids Poecilia mexicana, Xiphophorus helleri, Poecilia reticulata, and Gambusia affinis
were common, and were found in every low-elevation and coastal aquatic habitat surveyed on O'ahu.
Introduced poeciliids such as Poecilia mexicana, Xiphophorus hellen, Poecilia reticulata, and Gambusia
affinis were abundant in all 0' ahu streams, with some species occurring to an elevation of nearly 400 m.
There were also three relatively uncommon poeciliid species mainly restricted to still water habitats such as
springs, marsh areas, and estuarine or brackish water areas. These are the Cuban limia (Limia cf. vittata),
platy (Xiphophorus maculatus), and sailfin molly (Poecilia latipinna). The following ~ection summarizes
the distributional range and impacts of the most common poeciliid species found on 0'ahu.
Poecilia mexicana
This species apparently resulted from hybridization, possibly in the wild in its native range prior to its
Hawaiian introduction (R.R. Miller and W. Fink, personal communication). However, Poecilia mexicana
(shortfin molly) now exhibits stable morphological characters readily distinguishing it from other poeciliids
found in Hawai'i. This species was the largest of the introduced poeciliids, up to 115 mm in length.
15
Poecilia mexicana inhabited waters with a wide range of salinities, from 0 ppt to 40 ppt (ocean water in
Hawai'i has a salinity of 36-37 ppt). Because of this salinity tolerance, these fish were found in every
coastal estuary and low-elevation wetland.
In general, Poecilia mexicana was found in estuaries, coastal wetlands, and in the lower «70 m elevation)
reaches of streams. One notable exception was the collection of Poecilia mexicana at the source (elevation
400 m) of Kipapa Stream, a tributary of Waikele Stream. The Waikele Stream system has a gentle gradient
with no barrier waterfalls below 400 m elevation. As in other O'ahu streams, Waikele Stream water flow
disappears into the alluvium and dries up in its mid-reaches during periods of low precipitation. A water
connection (combined with a low stream gradient) through the often dry mid-reaches (120 to 240 m
elevation) of the Waikele Stream system was clearly maintained long enough to enable P. mexicana to
colonize the uppermost headwaters of this stream.
Xiphophorus helleri
Xiphophorus helleri (green swordtail) was found only in freshwater and was always found above areas of
tidal influence. Xiphophorus helleri was generally (with the exception ofWaikele Stream) found higher than
P. mexicana, and was found upstream as far as the fIrst barrier falls or rapids. Xiphophorus helleri were
abundant in pools and also in relatively high water velocity habitats, including runs and slower sections of
riffles. The largest Xiphophorus helleri measured was 105 mm long, attaining a size nearly double that of
other common poeciliids such as Poecilia reticulata and Gambusia affinis. The highest elevation at which
this fish was found during this study was 204 m at Poliwai Gulch, a leeward drainage with a gradual stream
profIle.
Gambusia affinis
Gambusia affinis (western mosquitofish) was recorded at a maximum length of 56 mm, and was always
found in high densities in the lower stream reaches, usually in the presence of Poecilia mexicana. The
16
highest elevation at which Gambusia affinis was found was at 185 m in Poliwai Gulch, near the Waiahole
Ditch. Gambusia afflnis also exhibited a wide salinity tolerance of 0 to 40 ppt, but was usually found in
areas having salinities of 16 ppt or less. Ten Gambusia affinis stomachs from Pearl Harbor streams were
examined and found to contain various aquatic fauna such as chironomids, shrimp, and ants. Native
damselflies were not found in these stomachs. It was not surprising because of the complete lack of native
damselflies in all areas where Gambusia afflnis was found.
Poecilia reticulata
Poecilia reticulata (guppy) and Gambusia afflnis are similar in size and ecological requirements, and these
were also the smallest of the introduced poeciliids found on 0'ahu. In comparison with Gambusia affinis,
Poecilia reticulata were restricted to water of s 4 ppt salinity. Poecilia reticulata were also generally found
at the highest elevations of all the introduced fish. This species penetrated the headwater source areas of
Hakipu'u, Kawa, and Kane'ohe Streams, none of which were observed to contain native Megalagrion in
their uppermost reaches. Poecilia reticulata was found up to 400 m elevation, and was sympatric with
Poecilia mexicana in the Waikele Stream system (a Kipapa tributary). This species was generally more
common than Gambusia affinis in the upper reaches of streams, but absent from estuarine areas.
Tilapia
Introduced into Hawai'i in 1951, tilapia (Sarotherodon melanotheron Ruppell, 1852) is considered to be a
harmful and dominant introduced fish in low-elevation Hawaiian streams, wetlands, and estuaries (Nelson
and Eldredge, 1991). We found high densities of tilapia in both limnetic and estuarine habitats, in water
ranging from 0 to 40 ppt salinity. In contrast to poeciliids, tilapia have little ability to colonize areas of
high stream gradient, but were found in high numbers in still-waters of low elevation streams, estuaries,
and wetlands.
17
Introduced Odonata
The introduced damselflies Ischnura posita (Hagen, 1862), Ischnura ramburii, and Enallagma civile (Hagen,
1862) were common in low elevation areas containing high densities of introduced poeciliid fish and tilapia;
these same areas were devoid of native Megalagrion damselflies (Figure 1.6). For example, extensive
250
225
200
E 175"-"
c: 150.9- 125ella;ill 100
75
50
25
0
Ischnura =
Poeciliids =
Kawa Kaneohe Kahaluu Waihee Kaalaea Waiahole Moanalua Waikele
Figure 1.6. Elevational distribution for introduced Ischnura ramburii and Ischnura posita damselflies andintroduced poeciliid fish for selected Kane'ohe Bay and Pearl Harbor streams, O'ahu.
surveys of Pearl Harbor and Kane'ohe Bay wetland habitats found only these introduced damselflies with
corresponding high densities of Poecilia mexicana, Gambusia afflnis, and Poecilia reticulata.
In some cases, the distribution of introduced damselfly species did overlap with that of Megalagrion
damselflies. For example, Megalagrion nigrohamatum nigrolineatum, M. oceanicum, and Ischnura ramburii
exhibited a near-identical elevational distribution in Waihe'e Stream. Four introduced species of Odonata
(Ischnura posita, Tramea abdominalis (Rambur, 1842), Orthemis ferruginea, and Crocothemis servilia
(Drury, 1770)) also co-existed with adults and larvae of the last Megalagrion xanthomelas population on
18
0'ahu at the TAMC Stream, a tributary of Moanalua Stream. Introduced fish were absent at the TAMC
stream.
Relative Distributions of Damselflies and Introduced Fish
Little overlap in the distribution of adult Megalagrion damselflies and other introduced fish was found in
streams entering Kane'ohe Bay (Figure 1.3). For example, poeciliids were found in Kahalu'u Stream up to
an impassable 2 m high concrete barrier encountered at 80 m elevation; above this barrier Megalagrion
nigrohamatum nigrolineatum was present. In Kahana Stream, a few adult Megalagrion nigrohamatum
nigrolineatum were recorded down to the maximum limit of introduced Xiphophorus helleri at
approximately 33 m elevation, although they may have strayed temporarily from higher elevations. A small
amount of overlap from the 52-61 m elevation level was also found between these two species in Waihe'e
Stream. Only adult Megalagrion damselflies were captured from lower elevation areas of Kahana and
Waihe'e Streams, and immature Megalagrion were not found in this small area of overlapping distribution.
Thus, distributional overlaps in both streams of introduced fish and native damselflies may be explained by
downstream adult damselfly flight.
In upper Kahalu 'u Stream, Megalagrion oceanicum, Megalagrion nigrohamatum nigrolineatum. and
Megalagrion hawaiiense were found above two forks of the stream, with one fork containing a 2 m high
concrete barrier and the other a series of high gradient cascades 2-3 m in height. A slight overlap in the
distribution of Poecilia reticulata and adult Megalagrion nigrohamatum nigrolineatum was observed for 70
100 meters in the Waihe'e Stream channel. This was most likely caused by downstream flight of adult
Megalagrion nigrohamatum nigrolineatum, which were common in upper Waihe'e Stream. Poecilia
mexicana and Megalagrion distributions were always mutually exclusive.
Northern windward O'ahu streams also had a dissimilar elevational distribution of introduced fish and
Megalagrion damselflies (Figure 1.4). As with most Kane'ohe Bay streams (with the exception of Kahana),
19
the surveyed northern windward O'ahu streams were naturally interrupted with water flow sinking into the
alluvium in the lower to mid-reaches (Polhemus et a1. 1992). This gap in water flow explains the lack of
both damselflies and introduced fish shown in Figure 1.4 in the lower to mid-reaches of most of these
streams. Stream flow in the interrupted sections occurs only for short times during periods of intense
precipitation. Despite this, native stream biota such as fish, crustaceans, and mollusks were still found in
the upper reaches of surveyed northern windward streams. By contrast, the relatively long dry sections and
high gradient of these streams apparently preclude poeciliid colonization of their upper reaches (areas above
ca. 210 m elevation). Kaipapa'u, Koloa, Ma'akua, Wailele, and Kahawainui were all dry in the lower to
mid-reaches, but the upper reaches of these streams contained robust native damselfly populations, with
Megalagrion oceanicum occurring in all five streams. By comparison, the terminal reaches, estuaries, and
adjacent wetland areas of all northern windward O'ahu streams were found to have high densities of
introduced poeciliid fish, and lacked native damselflies. The upper reaches of Punalu 'u Stream, the only
continuously flowing northern windward drainage, were not assessed, since access was denied by the
landowner. In lower Punalu'u Stream, however, high densities of tilapia and Poecilia mexicana, were found,
and native damselflies were not observed.
Pearl Harbor drainages and leeward streams were found to be the most affected by introduced fish, possibly
due to low stream gradients and general lack of waterfall barriers, which allow such fish to access the entire
lengths of many of these streams. Introduced fish were not observed in the surveyed upper reaches surveyed
(490 m) of Helemano Stream, but Megalagrion nigrohamatum nigrolineatum was common there. The most
dramatic example of non-overlapping distribution of alien fish and native damselflies on O'ahu was the
presence of a remnant population of Megalagrion xanthomelas in a small (35-70/1 min flow) unnamed
artificial tributary of Moanalua Stream at !he TripIer Army Medical Center (TAMC). Poeciliids have been
unable to access this tributary because of a 7 m high culvert at the downstream end of this section of
stream. Megalagrion xanthomelas was not found during surveys of adjacent streams or in downstream
sections of Moanalua Stream, all of which had high densities of introduced fish.
20
Pearl Harbor streams are also among the shortest on O'ahu, and this is reflected in the elevational
distribution of introduced fish for some of the streams (Figure 1.5). Many of these streams flow in their
mid- and headwater reaches only during periods of extended precipitation, and maintain a perennial flow only
downstream of emergent springs in an area of caprock around Pearl Harbor (Stearns and Vaksvik 1935).
Kapakahi, Honouliuli, Kalauao, and the Waiawa Springs outlet, are short, spring fed streams that flow for
distances of 50-350 m before entering Pearl Harbor. These limnocrenes contain high densities of introduced
poeciliids, and three species of introduced damselflies are common in this area. Native damselflies were not
found in any of these wetland areas surrounding Pearl Harbor.
Discussion
Introduced Fishes
Predator-prey relationships between fish and Odonata have been extensively studied in temperate regions,
and fish have been shown to affect the distribution of many species of Odonata (Nilsson 1981; Pierce 1988;
Henrikson 1988; McPeek 1989; 1990a; 1990b). In Sweden, experiments found that dragonfly larvae
inhabiting only fishless lakes and acid bog" ponds attempted to actively escape from fish predators, while
species from lakes containing fish feigned death and remained still when attacked (Nilsson 1981; Henrikson
1988). This naIve larval escape response to the threat of predation was similar to that observed for Hawaiian
Megalagrion larvae both in the field and in aquarium observations conducted during this study. McPeek
(l990b) identified similar naIve behaviors in Enallagma damselflies from fishless lakes, which attempted to
swim away from predators. While this behavior was successful against attacks by immature dragonflies, it
failed to deter fish predation.
Poeciliid predation was also correlated with the elimination of native Odonata species in Australian lakes;
lakes containing Gambusia affinis had only 3-4 species of Odonata, while nearby lakes without introduced
fish contained 11 species (Davis et a1. 1987). In the presence of mosquitofish, declines in Odonata
21
populations were also found in California rice fields (Farley and Younce 1977). Although most research on
the negative effects of poeciliids on native species has involved Gambusia affinis and Xiphophorus helleri,
Arthington and Lloyd (1989) believed the carnivorous Poecilia reticulata might have impacts similar to that
of Gambusia affinis on native aquatic biota.
Megalagrion xanthomelas and Megalagrion pacificum, two low-elevation stream and wetland damselflies,
are the species that appear to have been most adversely affected by introduced poeciliids. These damselflies
are obligate coastal and low-elevation species, and poeciliids have invaded all of these habitats on O'ahu,
with the exception of the artificial stream at TAMC. Although Megalagrion xanthomelas is still found on
other islands, the O'ahu population maintains a precarious existence. Only 100-160 adults can be observed
at anyone time in the 95 m (long) artificial TAMC stream (Englund 1998). Similarly, an analysis of
Megalagrion pacificum collection records by Liebherr and Polhemus (1997) indicated this species was likely
extirpated on O'ahu by 1920.
The current absence of native damselflies in lowland coastal areas of O'ahu is clearly not due to a lack of
suitable aquatic habitats. For example, large amounts of formerly suitable native damselfly habitat are still
found adjoining springs in the Pearl Harbor region, with watercress (Nasturtium microphyllum) and taro
cultivated here in large quantities. These spring areas also feed an extensive fresh and brackish water coastal
wetland system that is now completely devoid of native damselfly species. Native damselflies such as
Megalagrion xanthomelas that formerly were found in lowland stream areas, coastal wetlands, and brackish
estuarine waters on O'ahu in areas of up to 8-15 ppt salinity (Polhemus 1996; Nishida 1997) are now
completely extirpated, while introduced Odonata are abundant. All taro fields in the Kane'ohe Bay watershed
were surveyed and were found to contain high densities of not only Poecilia mexicana, but also Poecilia
reticulata, and Xiphophorus helleri. Neither Megalagrion pacificum or Megalagrion xanthomelas were found
in any O'ahu taro fields, although both ofthese species were recently found in Moloka'i taro fields lacking
introduced fish (R.A. Englund and W. Puleloa, unpublished). Thus, lowland native damselfly species appear
22
to be adaptable to artificial wetlands created by taro cultivation, but are not found in taro fields containing
introduced fish species.
Another endemic O'ahu species, Megalagrion oceanicum, has also disappeared from most streams, occurring
only in high-elevation stream areas lacking introduced poeciliids. However, it is known that M. oceanicum
formerly occurred in low-elevation stream habitats and was originally collected by Perkins in 1892 near sea
level (Perkins 1899). This species also appears to be at high risk of extinction, and was usually only
observed in low numbers. Additionally, the larval preference of M oceanicum for fast-water habitats has
made it vulnerable to loss of habitat through water diversions and channelization.
With the exception of the bogs and small rivulets of Mt. Ka' ala, the highest mountain on the island,
Megalagrion hawaiiense was also uncommon on O'ahu, and few individuals were observed in the streams
where this species was found. This contrasts to its status as one of the most abundant native damselflies on
other Hawaiian Islands, in habitats lacking introduced fish. On O'ahu, poeciliids were found in high
densities in some of the habitats preferred by Megalagrion hawaiiense larvae, including springs, cut-off
stream channel areas, and seep areas. Similarly to Megalagrion oceanicum, Megalagrion hawaiiense was
originally collected by Perkins on O'ahu in 1896 at "no great elevation above the sea" (Nishida, 1997), and
is still found near sea level on other islands, e.g. Moloka'i (R.A. Englund and W. Puleloa, unpublished).
The lowest elevation this species was found at during the present study was 137 m on Kahalu'u Stream,
which was above the range of introduced poeciliids for that stream.
Megalagrion leptodemas, another O'ahu endemic, is known from scattered colonies in the upper elevation
sections offour widely separated windward and leeward streams. Due to its overall scarcity, Megalagrion
leptodemas may be the stream-dwelling damselfly species at greatest risk of extinction in the Hawaiian
Islands. No populations of Megalagrion leptodemas exist at sites where this species was collected prior to
1936 by Perkins and Williams (see Table 1.1), and these stream areas are now heavily infested with
23
poeciliids. Immature M. leptodemas favor areas of standing pools and slow water (Polhemus and Asquith,
1996) that are also favored by introduced poeciliids.
This study found that native damselflies adapted to higher elevations have fared better than species restricted
to lower elevations. For example, Megalagrion nigrohamatum nigrolineatum was found in the upper
elevation sections of fifteen O'ahu streams, and was usually common in these areas. This species may have
remained more abundant than other Megalagrion species on O'abu because of its broader habitat preferences.
Megalagrion nigrohamatum nigrolineatum was locally common in high-elevation habitats in both leeward
and windward drainages, unlike Megalagrion xanthomelas or Megalagrion pacificum, species preferring low
elevation habitats. This may be due to the preference of Megalagrion nigrohamatum nigrolineatum larvae
for side pools and slow-water channels in high elevation areas that are usually wetter and more shaded.
Because no Megalagrion damselflies were found in poeciliid stomachs, this study did not establish a direct
causal relationship between poeciliid predation and the island-wide decline of native stream damselflies on
O'abu. However, the effects of introduced poeciliids on invertebrates have been widely documented, and
predation by Gambusia affinis and other poeciliids is believed to be the primary cause of native species
extirpation or reduction in other locations (Courtenay and Meffe 1989). On Hawai'i Island, an endemic
hypogeal shrimp species was found in high densities in 187 pools lacking introduced poeciliids, but co
occurred with poeciliids in only five of thirty-three pools, and then in very low numbers (Maciolek 1984).
On Kaua'i, Megalagrion damselflies are no longer found within the Hanalei River National Wildlife Refuge,
another area with high densities of introduced tilapia and poeciliids (Polhemus and Asquith 1996).
The apparent susceptibility of immature Megalagrion species to poeciliid predation may be due to a
combination of naive behavior and evolution to avoid benthic feeding by native Hawaiian stream fish in the
families Gobiidae and Eleotridae. Way and Burky (1991), for instance, found that Odonata (dragonflies and
damselflies combined) comprised 13% of the diet of the native stream goby Lentipes concolor. Furthermore,
24
most larval Megalagrion are not found in the benthic habitats most preferred by native insect-eating gobies,
but instead live in habitats such as shallow side-channels, isolated side-pools, the highest velocity areas of
riffles, or seeps, rheocrenes, and waterfalls (Polhemus 1997). These habitat preferences may in part be due
to evolutionary predation pressure from native stream fish. Currently, introduced poeciliids are found in
high densities in many of these preferred larval Megalagrion habitats throughout the Hawaiian Islands.
Isolated Hawaiian streams, such as those on the north shore of Moloka'i, have healthy populations of
native gobies and lack introduced fish; these areas also contain the greatest number of native damselfly
species (R.A. Englund and W. Puleloa, unpublished). At the TAMC stream, immature M xanthomelas
were frequently observed on the top of the stream substrate and free swimming at surface of shallow, small
pools (Englund 1998), habitats unlikely to have native, benthic gobies.
Introduced Odonata
In the past century, five species of dragonflies and three species of damselflies have been accidentally
introduced into Hawai'i (Nishida, 1997). It has been hypothesized that negative interactions could occur
between these newly arrived species and native damselfly species. We found overlapping distributions of
Megalagrion xanthomelas, one introduced damselfly, and three introduced dragonfly species in the 95 m
section of the TAMC stream. Megalagrion xanthomelas also co-exists with other introduced dragonflies and
damselflies on Lana'i and Hawai'i Islands (Polhemus, 1996). On Liina'i, for instance, Polhemus (1996)
could not correlate the presence of introduced or native Odonata with the absence Megalagrion xanthomelas.
Similarly, in lowland coastal wetland and riverine habitats of Moloka'i, the introduced Orthemis ferruginea,
Ischnura ramburii, and Ischnura posita were found sympatrlcally with Megalagrion pacificum and
Megalagrion xanthomelas (Englund 1999). This study found little or no evidence that introduced Odonata
impact native damselfly distributions.
25
Introduced Amphibians
Liebherr and Polhemus (1997) indicated that introduced amphibians might be one of the reasons for the
decline of Megalagrion, and at least three species of amphibians have become successfully established on
O'ahu since 1896 (Devick 1991). This study found no evidence of introduced amphibians impacting native
Megalagrion. The effects of the two frog (Rana rugosa, Rana catesbeiana) and one toad (Bufo marinus)
species on Megalagrion damselflies are unknown; however, frogs and toads are common even in the most
isolated and pristine aquatic habitats of the Hawaiian archipelago. For example, all six species of stream
Megalagrion are abundant in areas of Moloka'i containing introduced amphibians, but lacking introduced
fish (Englund and Puleloa unpublished). Toads were commonly observed in the 95 m reach of stream at
TAMC, and during the present study both frogs and toads were found to co-occur with Megalagrion
damselflies throughout O'ahu. Thus, although it is possible that these introduced amphibians have some
detrimental impacts on both immature and adult damselflies, no clear adverse impacts were ascertained.
Conclusions
Introduced poeciliids present potential threats to the biodiversity of aquatic ecosystems throughout the
Hawai'i. Megalagrion damselflies are now absent from virtually all lowland areas where early collections
occurred prior to poeciliid introductions. Protective measures will be necessary to prevent the decline of
remaining upland populations, as translocations of fish by people to areas above waterfall barriers has
already occurred in a number of Hawaiian streams. To preserve native aquatic invertebrate biodiversity in
Hawai'i, research on the elimination ofthese introduced fishes should have high priority.
Chemical or rotenone treatment in selected stream, spring or wetland areas could eliminate alien fish species
and allow establishment of additional populations of now rare endemic damselflies, such as Megalagrion
leptodemas, Megalagrion oceanicum, and Megalagrion xanthomelas. Chemical treatment to eliminate
introduced fish has already been selectively used mainly for tilapia (and poeciliid) elimination by the U.S.
Fish and Wildlife Service in Hawai'i, in areas such as Hanalei National Wildlife Refuge on Kaua'i (A.
26
Asquith, personal communication). Once poeciliids are removed from a reach of stream, it would also be
feasible to construct fish barriers that could prevent poeciliids from recolonizing upstream areas, as most
O'ahu streams are small in volume and size. Since native stream gobiids and crustaceans are accomplished
waterfall climbers (Englund and Filbert, 1997), small fish barriers in restored streams would not hinder
recolonization after chemical treatment by native species. Additionally, a high priority should be placed by
management agencies on educating the public to the harmful effects of releasing aquarium fish into
Hawaiian waters.
This study has shown a negative correlation between the distribution of introduced fish and native damselfly
species. While this does not prove cause and effect, it is highly suggestive that introduced fish are one of
the key mechanisms in the reduction in Megalagrion damselfly populations. Further behavioral and
experimental studies can build upon the findings of this study, perhaps ultimately allowing the restoration
of endemic Megalagrion populations on O'ahu.
27
Appendix 1. Summary of O'ahu streams surveyed, elevations (above sea level) assessed, stream type according to Polhemus and Asquith (1996), anddamselfly species present.Stream Elevations
surveyedStream Type Damselfly species present (elevation above sea level) Poeciliid species present (elevation above
sea level)
N00
Kane'ohe BaytributariesKawa
Kane'ohe
He'eia
Kahalu'u
Waihe'e
Ka'alaea
Waiahole
Waikane
Hakipuu
WindwardTributariesKaelepuluMaunawili
MakauaKahana
0-74 m
0-80 m
0-134 m
0-152 m
0-243 m
0-91 m
0-244 m
0-244 m
0-91 m
0-2 m0-50 m,220-240 m335-520 m0-300 m
Permanent
Permanent
Permanent
Interrupted bychannelization
Permanent
Permanent
Permanent
Permanent
Permanent
PermanentPermanent
IntermittentPermanent
1. ramburii (0-74 m), 1. posita (0-74 m)
1. rambudi (0-30 m)
1. posita (134 m), M. n. nigrolineatum (134 m)
1. rambudi (0-12 m), M. n. nigrolineatum (85-152 m),M. hawaiiense (137-152 m), M. oceanicum (137-152m)1. posita (31-210 m), M. n. nigrolineatum (52-243 m),M. oceanicum (243 m)1. ramburii (0-37 m), 1. posita (28-37 m), M. n.nigrolineatum (67-91 m)1. ramburii (0-25 m), 1. posita (0-152 m), M.hawaiiense (244 m), M. n. nigrolineatum (244 m)M. n. nigrolineatum (150-244 m), M hawaiiense (200244 m)1. ramburii (0 m)
1. ramburii (0-2 m)1. rambudi (0-50 m)
M. oceanicum (335 m )1. posita (0-30 m), 1. ramburii (0-20 m), M n.nigrolineatum (30-300m), M. hawaiiense (240-300 m),M. leptodemas (60-70 m)
P. mexicana, P. reticulata, G. affinis, X.helled (all 0-30 m)P. mexicana, P. reticulata, G. affinis, X.helled (all 0-61 m)P. mexicana (0-23 m), G. affinis (0-15 m),x. helleri (0-61 m)P. mexicana (0-37 m), P. reticulata (37-80m), x. helled (25-55 m)
G. affinis (0-12 m), P. mexicana (0-12 m),P. reticulata (0-61 m), X. helleri (0-61 m)P. mexicana (0-37 m), P. reticulata (0-37m), x. helled (0-37 m)P. mexicana (0-25 m), P. reticulata (0-97m), x. helled (0-97 m), G. affinis (0-10 m)P. mexicana (0-15 m), P. reticulata (0-67m), X. helled (0-67 m), G. affinis (0-15 m)P. mexicana (0-4 m), P. reticulata (0-31 m),X. helleri (0-31 m)
P. mexicana (0-2 m), G. affinis (0-2 m)P. mexicana (0-50 m), G. affinis (0-50 m),x. helleri (0-50 m), P. reticulata (0-50 m)NoneP. mexicana (0-20 m), P. reticulata (0-30m), x. helleri (0-30 m)
Appendix 1 (cont.). Summary of O'ahu streams surveyed, elevations (above sea level) assessed, stream type according to Polhemus and Asquith (1996), anddamselfly species present.Stream Elevations
surveyedStream Type Damselfly species present (elevation above sea level) Poeciliid species present (elevation above
sea level)
Kaluanui 0-107 m, Intermittent M. n. nigrolineatum (671-762 m), M. oceanicum (671-671-762 m 762 m)
Ma'akua 0-245 m Intermittent M. oceanicum (220-305 m), M. leptodemas (220-305m)
Kaipapa'u 0-305 m Intermittent M. hawaiiense (220 m), M. oceanicum (220-305)Koloa 0-366 m Intermittent M. hawaiiense (244-274 m), M. n. nigrolineatum (274-
366 m), M. oceanicum (244-366 m)Wailele 0-396 m Intermittent 1. ramburii (0-3 m), M. oceanicum (388-396 m)
Kahawainui 0-590 m Intermittent M. oceanicum (396-488 m)
tv\0 Malaekahana 0-244 m Intermittent 1. posita (61-244 m)
LeewardWaimea 0-76 m Permanent noneAnahulu 180-317 m Permanent none
'Opae'ula 260 m Permanent noneHelemano 0-260 m, Permanent 1. posita (480-520 m), M. hawaiiense (480-520 m), M.
480-520 m n. nigrolineatum (480-520 m)Poamoho 480-570 m Permanent M. n. nigrolineatum (480-570 m)lKaukonahua 430-490 m Permanent M. n. nigrolineatum (430-490 m)Dillingham 30-122 m Intermittent M. hawaiiense (30-122 m)Makua 0-3 m Intermittent noneHale'au'au 1130-1160 Intermittent M. hawaiiense (1130-1160 m)
mMakaha 0-2 m, Intermittent M. hawaiiense (1130-1160 m)
1130-1160m
Punaluu 0-1 m Permanent none P. mexicana (0-1 m), P. reticulata (0-1 m),X. helleri (0-1 m)P. reticulata (0-107 m), X. helleri (0-107m)P. mexicana (0-2 m)
NoneP. mexicana (0-6 m), P. reticulata (0-6 m),X. helleri (0-6 m)P. mexicana (0-6 m), P. reticulata (0-6 m),X. helleri (0-6 m)P. reticulata (0-122 m), X. helleri (0-122m)none
P. reticulata (0-76 m), X. helleri (0-76 m)P. reticulata (180-317 m), X. helleri (180317 m)P. reticulata (260 m)P. reticulata (0-260 m), X. helleri (0-260m)P. reticulata (480-570 m)nonenonenone (dry stream)none
G. affinis (0-2 m), P. mexicana (0-2 m)
Appendix 1 (cont.). Summary ofO'ahu streams surveyed, elevations (above sea level) assessed, stream type according to Polhemus and Asquith (1996), anddamselfly species present.Stream Elevations
surveyedStream Type Damselfly species present (elevation above sea level) Poeciliid species present (elevation above
sea level)
Kaupuni
MailiiliUlehawaNanakuliPearl Harbor andsouth shoretributaries
0-2 m,365-487 m0-1 m0-2 m0-2 m
Intermittent
IntermittentIntermittentIntermittent
I. ramburii (0-2 m), M. hawaiiense (400-430 m)
nonenonenone
G. affinis (0-2 m), P. mexicana (0-2 m)
none (dry stream)G. affinis (0-2 m), P. mexicana (0-2 m)G. affinis (0-2 m), P. mexicana (0-2 m)
Honouliuli 0-3 m Intermittent Enallagma civile (0-3 m) G. affinis (0-3 m), P. mexicana (0-3 m)Waikele 0-487 m Intermittent Enallagma civile (0-10 m), I. posita (0-10), I. ramburii G. affinis (0-40 m), P. mexicana (0-381 mY,
(0-381 m), P. reticulata (1-381 m), X. helleri (1-381m)
Kapakahi 0-2 m Permanent I. posita (0-2 m), I. ramburii (0-2 m) G. affinis (0-2 m), Limia cf. vittata (0-2 m)P. mexicana (0-2 mY, P. reticulata (0-2 m),
w X. maculatus (0-2 m)0 Waiawa 0-2 m, 189- Intermittent I. posita (0-2 m), I. ramburii (0-2 m), M. n. G. affinis (0-2 m), P. mexicana (0-2 m), P.
336 m nigrolineatum (213-365 m), M. leptodemas (213-365 reticulata (0-213 m)m)
Waimalu 0-3 m Intermittent I. ramburii (0-3 m) G. affinis (0-3 m), P. mexicana (0-3 mY, P.reticulata (1-122 m), x. helleri (1-122 m)
Kalauao 0-3 m Intermittent I. posita (0-3 m), I. ramburii (0-3 m) G. affinis (0-3 m), P. mexicana (0-3 m)Aiea 0-11 m Intermittent I. ramburii (0 m) P. mexicana (0-11 m)Halawa 0-3 m, 240- Intermittent I. ramburii (0-3 m), M. hawaiiensis (240-305 m), M. n. G. affinis (0-3 m), P. mexicana (0-3 m), P.
305 m nigrolineatum (240-305 m), M. leptodemas (240-305 reticulata (1-183 m)m)
Moanalua 0-365 m Intermittent I. posita ( 0-79 m), I. ramburii (0-79 m), M. G. affinis (0-122 m), P. mexicana (0-122xanthomelas (79 m-in an unnamed tributary)2 m), P. reticulata (0-122 m), X. helleri (0-
122 m)Kalihi 0-2 m, 305- Interrupted I. ramburii (0-2 m), M. n. nigrolineatum (305-366 m) G. affinis (0-2 m), P. mexicana (0-2 m)
366 mKapalama 0-1 m Intermittent none P. mexicana (0-1 m)
Appendix 1 (cont.). Summary of O'ahu streams surveyed, elevations (above sea level) assessed, stream type according to Polhemus and Asquith (1996), anddamselfly species present.Stream Elevations Stream Type Damselfly species present (elevation above sea level) Poeciliid species present (elevation above
surveyed sea level)
Nuuanu 0-3 m, 230- Permanent 1. ramburii (0-240 m) P. mexicana (0-3 m), P. reticulata (0-240378 m m)
Makiki 0-300 m Interrupted none G. affinis (O-lO m), P. mexicana (O-lO m),P. reticulata (0-300 m)
Manoa/palolo 0-360 m Permanent 1. ramburii (0-100 m) G. affinis (0-70 m), P. mexicana (O-lOO m),P. reticulata (0-360 m), X. helleri (0-300m)
Wai'alaenui 0-2 m Intermittent none P. mexicana (0-2 m)Wailupe 0-2 m Intermittent none none (dry stream)Pia 0-2 m, 61- Intermittent none none (dry stream)
400 mKuliouou 0-1 m Intermittent none P. mexicana (0-1 m)Kuapa Pond 0-2 m Intermittent 1. ramburii (0-2 m) G. affinis (0-2 m), P. mexicana (0-2 m),tributaries Limia cf. vittata (0-2 m)Awawamalu 0-2 m Intermittent 1. ramburii (0-2 m) G. affinis (0-2 m), P. mexicana (0-2 m)
~ 1 M. n. nigrolineatumcaptured in small side tributaries lacking P. reticulata entering Poamoho Stream. 2See text for explanation of M. xanthomelas distribution.
Appendix 2. Collection sites of O'ahu Megalagrion species by R.c.L. Perkins (1892-1912) and F.x. Williams (1925-1936).Colllector Collection Site Elevation Dates SpeciesR.C.L. Perkins? O'ahu sea level none given M. hawaiienseR.C.L. Perkins Wai'anae Mountains none given February 1896 M. hawaiienseR.C.L. Perkins Honolulu Mountains 550 m March 1901 M. hawaiienseR.C.L. Perkins Honolulu 366 m 1910 M. hawaiienseR.C.L. Perkins Palolo Valley none given May 1912 M. hawaiienseF.X. Williams Herring Valley (Makiki) none given February 1930 M. hawaiienseR.C.L. Perkins Helemano Stream 610 m February 1893 M. leptodemasR.C.L. Perkins Kawailoa Gulch 550 m April 1901 M. leptodemasR.C.L. Perkins Kawailoa Gulch none given August 1901 M. leptodemasR.C.L. Perkins Kawailoa Gulch 550 m August 1901 M. leptodemasR.C.L. Perkins Palolo Valley none given 1912 M. leptodemasF.X. Williams Mt. Ka'ala, Hale'au'au Stream 610 m April 1931 M. leptodemasF.X. Williams Herring Valley (Makiki) none given June 1931 M. leptodemasF.X. Williams Herring Valley (Makiki) none given November 1933 M. leptodemasR.C.L. Perkins Wai'anae Mountains 610 m April 1892 M. n. nigrolineatumR.C.L. Perkins Honolulu none given November 1892 M. n. nigrolineatum
wR.C.L. Perkins Wai'anae Mountains 610 m February 1896 M. n. nigrolineatumtv
R.C.L. Perkins Honolulu none given 1901 M. n. nigrolineatumR.C.L. Perkins Waialua none given March 1901 M. n. nigrolineatumRC.L. Perkins Waialua none given April 1901 M. n. nigrolineatumRC.L. Perkins Palolo Valley none given May 1902 M. n. nigrolineatumR.C.L. Perkins Maunawili 244m 1912 M. n. nigrolineatumF.X. Williams Ha1e'au'au Stream (Wai'anae Mountains) 610 m January 1932 M. n. nigrolineatumR.C.L. Perkins? O'ahu sea level no date M. oceanicumR.C.L. Perkins Wai'anae Mountains 610 m April 1892 M. oceanicumR.C.L. Perkins Honolulu none given May 1892 M oceanicumR.C.L. Perkins Wai'anae Mountains 610 m February 1896 M. oceanicumR.C.L. Perkins Kawailoa Stream none given March 1901 M. oceanicumR.C.L. Perkins Kawailoa Stream none given April 1901 M.oceanicumR.C.L. Perkins Kawailoa Stream none given July 1901 M.oceanicumR.C.L. Perkins Kawailoa Stream none given August 1901 M. oceanicumRC.L. Perkins Wai'anae Mountains 610 m July 1901 M. oceanicumRC.L. Perkins Honolulu Mountains 550 m 1903 M.oceanicumR.C.L. Perkins Palolo Valley none given May 1912 M. oceanicum
Appendix 2 (cont.). Collection sites of O'ahu Megalagrion species by R.C.L. Perkins (1892-1912) and F.X. Williams (1925-1936).
lJ.)lJ.)
Colliector Collection SiteF.X. Williams Hale'au'au Stream (Wai'anae Mountains)F.X. Williams Hale'au'au Stream (Wai'anae Mountains)R.C.L. Perkins HonoluluR.C.L. Perkins Kawailoa StreamR.C.L. Perkins Kawailoa StreamR.C.L. Perkins Waialua, Ko'olau RangeR.C.L. Perkins Wai'anae MountainsR.C.L. Perkins HonoluluR.C.L. Perkins HonoluluF.X. Williams WaipahuF.X. Williams Wai'anaeF.X. Williams Wai'anae - lowland reservoir!
IFrom Williams (1937b)
Elevation Datesnone given February 1930none given May 1935none given February 1892457 m September 1900457 m April 1901near sea level March 1892610 m April 1892none given September 1892none given November 1900none given April 1925none given March 1935none given July 1936
SpeciesM. oceanicumM. oceanicumM. pacificumM. pacificumM. pacificumM. xanthomelasM. xanthomelasM. xanthomelasM. xanthomelasM. xanthomelasM. xanthomelasM. xanthomelas
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Courtenay, W. R. and Meffe, G. K. 1989. Small fishes in strange places: a review of introduced poeciliids. In
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34
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38
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Odonata or dragonflies. Proceedings of the Hawaiian Entomological Society 9: 235-345.
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39
CHAPTER 2: EVALUATING THE EFFECTS OF INTRODUCED RAINBOW TROUT (Oncorhynchus
mykiss) ON NATIVE STREAM INSECTS ON KAUA'I ISLAND, HAWAI'I
40
ABSTRACT
Rainbow trout (Oncorhynchus mykiss) and other salmonids have been widely stocked into upland streams
throughout the world to provide a basis for sport fisheries, but the effects of such introductions on
indigenous and endemic aquatic insect assemblages are poorly documented. In this study, we examine the
impact of rainbow trout on the indigenous and endemic entomofauna of upland streams in K6ke'e State
Park, Kaua'i, Hawai'i, with particular emphasis on the potential threat trout pose to populations of endemic
damselflies in the genus Megalagrion. Rainbow trout were introduced into the upland streams of Kaua'i
beginning in the 1920s, with over 60 years of subsequent restocking. This study indicates, however, that
streams in this area still maintain diverse populations of Megalagrion damselflies and other indigenous and
endemic aquatic insects, both in catchments containing naturally reproducing trout populations and in
catchments lacking rainbow trout. Our results indicate that the indigenous and endemic aquatic insect
communities in the streams under study compare favorably in terms of density and taxonomic richness with
other isolated and unimpacted streams elsewhere in Hawai'i, containing high densities and relative
percentages of indigenous and endemic aquatic insect taxa. Our results demonstrate that the threats posed by
conspicuous introduced species such as trout should not simply be assumed a priori on the basis of
postulated negative interactions, because this may divert limited resources from programs aimed at control
of other, potentially more destructive introduced taxa such as inconspicuous poeciliid fishes.
INTRODUCTION
Conservation biologists working with the faunas of isolated oceanic islands, such as Hawai'i, have long
recognized that introduced species represent perhaps the most pervasive and persistent threat to the survival
of insular biotas. At the same time, the effects of such introduced species are often simply presumed to
occur, without rigorous scientific evaluation as to the actual impacts; this paper provides an example. This
could lead to unnecessary expenditures of time and money in attempts to control introduced species that,
though conspicuous, may be having relatively low impacts on endemic taxa, diverting resources that could
be better utilized to deal with other, more pressing threats. In this paper we examine such a case, that of
41
introduced rainbow trout (Oncorhynchus mykiss) on the island of Kaua'i in the Hawaiian Islands, and their
impact on Megalagrion damselflies and other endemic aquatic insects.
Salmonids were first stocked on Kaua'i in 1894, with an unsuccessful attempt to establish brook trout
(Salvelinus fontinalis) into the Waimea River (Needham and Welsh 1953). Rainbow trout (Oncorhynchus
mykiss) were subsequently introduced starting in 1920, and in 1935, brown trout (Salmo trutta) were
stocked in the Wainiha River and certain other Kaua'i streams, although the latter never became successfully
established (Needham and Welsh 1953). Stocking ofrainbow trout into streams in the upland Koke'e State
Park was perfonned on an annual basis after World War II (Needham and Welsh 1953), but was discontinued
in 1992 because of concerns regarding the impacts of rainbow trout on populations of endemic Megalagrion
damselflies, certain species of which had by that time been proposed for listing under the U. S. Endangered
Species Act.
The introduction of trout to Kaua'i led in tum to the deliberate introduction of several alien mayfly species
to Koke'e State Park streams in an attempt to supplement the naturally limited benthic invertebrate
communities of these systems. Two mayfly species were introduced from Waddell Creek in the Santa Cruz
Mountains of California to K6ke'e in 1961 (Needham and Usinger 1962; Usinger 1972): Nixe rosea (at that
time called Heptagenia rubroventris) and Epeorus lagunitas (fonnerly Iron lagunitas). Although over
200,000 mayfly eggs were planted into various habitats in Koke'e and Kawaikoi Streams, this attempted
introduction of herbivorous mayflies failed completely, with no adults of either species ever recovered from
any Kaua'i stream, probably because these temperate zone species require an obligate cold diapause in order
to complete their life cycles, a stimulus that was not provided under Hawaiian conditions (G. F. Edmunds,
Jr., pers. comm.). In Hawai'i as a whole, the only mayfly species known to be successfully established is
Caenis nigropunctata, a tropical mayfly indigenous to Indonesia, the Philippines, and southern China
(Dudgeon 1999), which is found in lowland, disturbed and silted streams on O'ahu (Smith 2000), and does
not require a seasonal diapause. In addition, by 1965 several species of alien caddisflies, including the large
42
Cheumatopsyche pettiti, had become accidentally established in Hawaiian streams (Denning and Beardsley
1967), providing additional food sources for introduced gamefish, including rainbow trout. The mode of
introduction for these latter species into Hawai'i remains unknown, but probably involved the arrival of
eggs in aquatic plants or plant substrates imported in association with the aquarium trade (l.W. Beardsley,
pers.comm.). Whatever the means of establishment, by the early 1970s introduced Trichoptera had become
abundant in the benthos of most Hawaiian streams, thereby inadvertently accomplishing what the earlier
unsuccessful mayfly introductions had set out to do.
In their natural condition, Hawaiian streams have poorly developed benthic insect communities in
comparison to similar continental ecosystems. The largest endemic benthic insects are larvae of the
secondarily freshwater chironomid genus Telmatogeton, and various Odonata species in the genera Anax,
Nesogonia, and Megalagrion. Although recent studies have indicated Megalagrion damselflies with stream
dwelling immatures are sensitive to the presence of introduced poeciliid fishes such as the Western
mosquitofish (Gambusia affinis), green swordtails (Xiphophorus hellen) and shortfin mollies (Poecilia
mexicana) (Polhemus and Asquith, 1996; Englund 1999), the impact of rainbow trout predation on
indigenous and endemic damselfly populations has remained equivocal prior to the current study. In recent
papers, different authors have alternately claimed that rainbow trout significantly impact endemic damselfly
populations on Kaua'i (Kido et al. 1999), or conversely that trout in Hawai'i are an example of a failed
invasion and therefore have little impact (Brown et al. 1999). The prevailing assumption among local
conservationists is that because introduced trout are known to adversely impact indigenous and endemic
species in other regions, they must also be having a significant impact on endemic aquatic species in
Hawai'i. One of the primary aims of this study was therefore to objectively assess the relative threat posed
by trout to Megalagrion damselfly populations and other endemic Hawaiian aquatic invertebrates in the
context of the overalllimnological setting occupied by these organisms.
43
METHODS
STUDY AREA
Koke'e State Park is located in northwestern Kaua'i, the northernmost of the major high Hawaiian islands,
and encompasses most of the Alaka'i Swamp. The park contains numerous streams draining from the flanks
of Mt. Waialeale, lying near the highest summit on Kaua'i and putatively the wettest area on earth (Hazlett
and Hyndman 1996). The Alaka'i Plateau surrounding Mt. Waialeale is a swampy tableland, heavily
dissected by deep, erosion-formed canyons that cut into its relatively flat surface, and thickly covered by
predominantly native Hawaiian upland rain forest.
The five streams examined in this study, Wai'alae, Koai'e, Kauaikinanii, Kawaikoi, and Waiakoali, are
situated relatively close to each other in the western section of the Alaka'i Plateau, lying at elevations
ranging from 1035-1160 m (Figure 2.1). Because all five streams lie at relatively similar elevations, and
exhibited low and stable streamflows throughout both phases of this study, it was possible to conduct
uniform aquatic insect sampling protocols at each, resulting in comparable data for all watersheds. The
stations sampled were as follows:
Station 1: HAWAI'I, Kaua'i, Wai'alae Stream in vicinity of Wai'alae Cabin, 1095 m, water temp.
15°C, January 1999. 22°04.964'N, 159°35.170'W.
Station 2: HAWAI'I, Kaua'i, Koai'e Stream in vicinity of USGS gaging station, near
Mohihi-Wai'alae Trail crossing, 1125 m, water temp. 15°C, August 1997, January 1999. 22°06.778'N,
159°33.723 'W.
Station 3: HAWAI'I, Kaua'i, Waiakoali Stream above Camp 10 Road, 1035 m, water temp. 13°C,
August 1997, August 1998, January 1999. 22°07.586'N, 159°37.225'W.
Station 4: HAWAI'I, Kaua'i, Kawaikoi Stream above Camp 10 Road, 1035 m, water temp. 15°C,
August 1997, August 1998, January 1999. 22°07.892'N, 159°37.280'W.
44
Station 5: HAWAI'I, Kaua'i, Kauaikinana Stream at Camp 10 Road, 1035 m, water temp. 14°C,
August 1997, August 1998, January 1999. 22°07.974'N, 159°37.840'W.
tN
Figure 2.1. Study area of sampled K6ke'e State Park Streams, Kaua'i Island, Hawai'i
45
In addition, aquatic insect richness data from two other nearby trout-free Kaua'i streams, the Lumaha'i and
Hanalei rivers, were incorporated into the current analysis based on studies by Polhemus (1995).
General Methods
This study was conducted from 1997 to 1999, during periods of low flow. Sampling areas were established
in three streams containing rainbow trout with natural reproduction (Kauaikinana, Koai'e, Wai'alae), one
stream where rainbow trout escaped from a nearby ditch stocked in 1998 (Waiakoali), and along a stream
devoid of rainbow trout (Kawaikoi).
The presence or absence of naturally reproducing trout in all of the stream reaches under study was
determined by visual observation at very low flows, angling, netting, and discussions with knowledgeable
local anglers and wildlife biologists. To assess potentially available rainbow trout forage, the abundance and
species richness of aquatic invertebrate populations were surveyed in each stream using a variety of
methods. To evaluate actual rainbow trout diet, stomach contents were collected from rainbow trout in the
four streams containing large trout populations, as noted above.
Aquatic Insect Sampling
In order to obtain comprehensive samples of the aquatic entomofaunas present in each study stream,
collections of both immature and adult specimens were made using aerial sweep netting, dip nets and Surber
(benthic) samplers; in addition, Malaise traps were placed over each stream for a 24-hour period. Visual
observations of flying adult insects, particularly Odonata, were also conducted while traversing the stream
reaches under study. Total numbers of aquatic insect taxa collected at each stream were determined by
combining collection data from all the above methods. Sampling effort was focused on habitat suitable for
Hawaiian aquatic insects, particularly splash zones around riffles and cascades, wet rock faces associated with
springs and seeps, waterfalls, and rock overhangs.
46
The sampling of damselflies and dragonflies (Odonata) was emphasized, because six species of endemic
Megalagrion damselflies are currently held as candidates for listing under the Endangered Species Act on the
United States Federal Register. In addition, Hawaiian damselflies provide an indication of the relative
'health' of a stream system, and are typically absent in highly disturbed catchments (Polhemus and Asquith,
1996), or those containing high densities of introduced fishes (Englund 1999). Initial attempts were made to
census native adult (i.e., flying) damselflies in order to obtain quantitative density data, but these were
abandoned after it was determined that such damselfly species were too abundant to accurately census
without the possibility of double-counting the same individuals. Instead, qualitative species richness data
were utilized, similar to those gathered for the remaining groups of aquatic insects in this study.
Benthic aquatic insect densities were assessed at each stream using randomly sited Surber samples set in
riffles. All of the streams studied contained many moderate gradient riffles, with similarly sized substrate
(6--25 cm), allowing comparable samples at each.
Drifting invertebrates were collected with cone shaped Wildco® drift nets 0.9 m long with an aperture area
of 0.09 m2 and a mesh size of 450 jIm. The center of the net was placed in the middle of the stream and
was set at approximately 60% of the water column depth (Filbert and Hawkins 1995). Each drift collection
consisted of one lO-min sample collected at midday (1200 hrs) in each stream sampled. All drift collections
were made within a one-week time period during the winter 1999 sampling. Time and budgetary constraints
did not allow for comprehensive diel drift sampling that would have included nighttime or replicated
sampling. Rather, these preliminary samples were collected to assess drift species composition and provide
inferences on the propensity of endemic aquatic insects to drift. Such qualitative drift samples were collected
in Kauaikinana, Kawaikoi, Waiakoali, and Koai'e streams, but not at Wai'alae Stream.
47
All insect specimens were stored in 75 percent ethanol and subsequently transported to the Smithsonian
Institution and Bishop Museum for curation and identification. Voucher specimens are currently housed in
the Bishop Museum and Smithsonian Institution collections.
Rainbow Trout Diet Analysis
Rainbow trout were captured by angling for this study, killed immediately after capture, and the stomachs
injected with and placed in 70% ethanol for later laboratory analysis. Gut contents were removed from the
portion of the gut between the anterior of the esophagus and pyloric sphincter (Kimball and Helm 1971).
Contents of each rainbow trout stomach were identified to the lowest possible taxonomic level, and in
many cases to genus and species. Species level identification was not always possible for partially digested
insects, or in some orders such as Diptera where adult males are required for identification. The geographic
origin (i.e., indigenous and endemic versus introduced) of individual arthropod taxa was evaluated using
Nishida (1997). Total prey item numbers in each trout stomach were recorded, and if contents were broken
into pieces, head capsules were then counted as an indication of individual prey item numbers. Terrestrial or
aquatic status was determined for each identifiable prey item, and the percent composition of trout diet
represented by any given prey item class was calculated by adding the total number of identifiable prey
items and dividing by the number in each prey item category. The proportion of introduced and endemic
aquatic prey items in the trout stomachs was calculated for the aquatic species where such information
regarding geographic origin could be ascertained. The processed stomach contents are stored in the
collections of the Hawaii Biological Survey, Bishop Museum.
Data Analysis
Proportions Tests - Proportion tests were conducted to assess whether the presence of rainbow trout
influenced the number of endemic aquatic insect species in a particular stream (Ramsey and Schaefer 1997).
The null hypothesis of no significant difference in the proportion of endemic aquatic insect species between
48
streams with and without trout was tested against the alternative hypothesis that the proportion of endemic
species in streams without trout is higher than that in streams with trout. A two-sample test for equality of
proportions with continuity correction tests was conducted using the S-Plus®2000 statistical program
(MathSoft, Inc., 1999). Streams used in the proportion test included all assessed streams in Koke'e State
Park, and two other relatively high elevation Kaua'i Streams lacking rainbow trout; the Lumaha'i River
(430 m elevation) and Hanalei River (380 m elevation), using data from Polhemus (1995).
Poisson Regression for Count Data - A Poisson regression model for count data was used to test if the
main constituent of the benthic fauna collected in Surber samples, Cheumatopsyche pettiti, varied by
stream. The null hypothesis of there being no significant difference in the number of C. pettiti per stream
was tested against the alternative hypothesis that densities varied among streams.
RESULTS
Our data indicate that the streams sampled within Koke'e State Park maintain diverse populations of
endemic aquatic insects. This is true both of streams containing rainbow trout, such as the upper reaches of
Wai'alae, Koai'e, and Kauaikinana, and of streams where trout are lacking, such as the upper reaches of
Kawaikoi, the latter being comparable to other trout-free streams such as the upper Hanalei and Lumaha'i
rivers (Table 2.1). A large number of aquatic and terrestrial taxa were identified during this study; these are
summarized in Table 2.2. Terrestrial species were only included when found in trout stomachs or collected
during invertebrate drift sampling (Table 2.2); even so, they comprise a large proportion (47.4%) of all the
taxa consumed by rainbow trout. The aquatic entomofauna was composed largely of endemic species, as
shown in Figure 2.2. Except for Wai'alae Stream where drift samples were not collected, terrestrial species
were included in Figure 2.2 in order to show the proportions of endemic versus introduced species present in
the stream drift. A summary of the aquatic and terrestrial taxa collected in rainbow trout stomachs is shown
in Figure 2.3, and clearly indicates the importance of drifting terrestrial taxa to the diet of rainbow trout on
49
Table 2.1. Aquatic insect species and native or introduced status collected at each Kaua'i stream.
I~
l': '10 -; 1il·z ~ (l) .~l': ..>d 0-; :;;l .(;; :"; ~ ..>d -;
l': ~ :"edAquatic Insects Species (I =Indigenous; E =Endemic; ~.(;; ~ 0 8 .(;;
::I: ::l ~ ~ ::l~Int =Introduced) ~ ~ .....:I ~
~
OdonataAeshnidae Anax strenuus (E) X X X X X X XLibellulidae Nesogonia blackbumi (E) X X X
PantaIa flavescens (I) XCoenagrionidae Megalagrion eudytum (E) X
Megalagrion heterogamias (E) X X X X X X XMegalagrion oresitrophum (E) X X X X X X XMegalagrion orobates (E)l X XMegalagrion vagabundum (E) X X X X X X X
HeteropteraSaldidae SaIdula exulans (E) X X X X X X X
SaIduia oahuensis (E) XSaldula procellaris (E) X X X X X X
Veliidae Microvelia vagans (E) X X X X X X XColeoptera
Dytiscidae Rhantus pacifus (E) X X XHydrophilidae Limnoxenus semicylindricus (E) X
LepidopteraCosmopterigidae Hyposmocoma sp. (E) X X X
Hyposmocoma sp. Dr montivolans X X X X X X X(E)Hyposmocoma sp. Dr saccophora (E) X X X X X X X
DipteraCanacidae Procanace sp. (E) X
Procanace bifurcata (E) XProcanace nigroviridis (E) X X X XProcanace quadrisetosa (E) X X XProcanace wirthi (E) X X X
Ceratopogonidae Forcipomyia hardyi (E) X X X X X XChironomidae Chironomus sp. (E) X X X
Orthocladius sp. (E) X XMicropsectra sp. (E) XTelmatogeton sp. (E) XTelmatogeton hirtus (E) X
Dolichopodidae Campsicnemus nigricollis (E) X X X X X XCampsicnemus n. sp. (E) X XEurynogaster mediocris (E) X XEurynogaster minor (E) X XParaliancalus metallicus (E) XSigmatineurum napali (E) X X X XSigmatineurum n. sp. 1 (E) XSigmatineurum n. sp. 2 (E) X
Ephydridae Scatella cilipes (E) X X X XScatella clavipes (E) X X XScatella hawaiiensis (E) X X X X XScatella kauaiensis (E) X X X X X X X
Tipulidae Dicranomyia hawaiiensis (E) X X X X XDicranomyia pcoba(E) X X X X X X X
50
Table 2.1 (cont.). Aquatic insect species and native or introduced status collected at each Kaua'i stream.
l«l.~l:: °10'Q) «l "«l <; Il.l
l:: ~ Y 0«l
<; :.::l 'a 'a ~ ~<;
Aquatic Insects Species (I =Indigenous; E =Endemic; l:: 'a ~ 0 8 :;«l 'a:::c: g «l ~ ::l
~Int =Introduced) ~ .....:l ~~
Dicranomyia perkinsi (E) XDicranomyia stygipennis (E) X X X X X
OdonataCoenagrionidae Ischnura posita (Int) X X X X X
Ischnura ramburii (Int) XEnallgma civilie (Int) X X
HeteropteraMesoveliidae Mesovelia amoena (Int) X
Mesovelia mulsanti (Int) XColeoptera
Hydrophilidae Tropisternus lateralis (Int) XTrichoptera
Hydropsychidae Cheumatopsyche pettiti (lnt) X X X X X X XHydroptilidae Hydroptila arctia (Int) X X X X X
Oxyethira maya (Int) X X XDiptera
Chironomidae Cricotopus bicinctus (Int) X X X X X X XDolichopodidae Chrysotus longipalpus (Int) X X
Syntormon flexible (Int) XDolichopus exsul (Int) X X X X
Ephydridae Ochthera circularis (Int) XTipulidae Dicranomyia advena (Int) X X X
'Not found in upper Koke'e streams because it is only found only in lower to upper mid-reaches of Kaua'i streams(Polhemus and Asquith 1996).
Table 2.2. Total number of aquatic species collected during benthic, drift, and aerial (general) collectionsduring this study.
Total Aquatic Native Total Native
Method Spp.' Aquatic Terrestriae Terrestriae Total Species
General!Aerial 48 33 n/a n/a 48
Drift 15 7 26 13 41
Benthic (Surber) 9 3 n/a nla 9
Trout Stomach 43 21 85 36 128
lIncludes fish, crustaceans, mollusks, and aquatic insects.urerrestrial species not sampled during benthic (Surber) or general species collections.
51
oNative Aquatic .Intro Aquatic ~ Native Terrestrial IIlntro Terrestrial
VI 30Q)
'g 2Sa.(J) ~o~o... 15~E 10:::l
Z 5
Kauaikinana KawaJk~ Koale Walakoali Waialae
Figure 2.2 Summary of aquatic species collected in Koke'e State Park streams from all sampling methodscombined (general sampling, Malaise traps, drift, benthic samples).
oNative Aquatic • Introduced Aquatic 0 Native Terrestrial • Introduced Terrestrial
25
VI 2DQ)
'0Q)
~ 15
'0...Q) 10.0E:::lZ 5
Kauaikinana Koaie WaiakoaU Waialae
Figure 2.3. Summary of all insect species collected from rainbow trout stomachs (n =80) and theirterrestrial or aquatic, and native or introduced status in Koke'e State Park Streams.
52
Q)
a.EellV)...Q)Q.
>.+'"'iiit:Q)
ot:ellQ)
~
oCheumatopsyche pettiti • Cricotopus bicinctus
18
16
14
1210
8
6
4
2o-IL-~~~----=~~--.-----=~~------':~~~-=~~
Kauaikinana Kawaikoi Koaie Waiakoali Waialae
Figure 2.4. Mean density by stream for the two most important constituents of benthic (Surber) samples,the caddisfly C. pettiti and midge C. bicinctus.
DNative Aquatic Insect Spp.• Introduced Aquatic Insects Spp.
VIQ)
'uQ)Q.Vl+JUQ)VIc::
.~+Jro:J0«~o~
Q).cE:JZ
3S
30
2S
20
1S
10
S
0Kauaikinana Koaie Waiakoali Waialae Kawaikoi Lumahai Hanalei
Figure 2.5. Summary graph of number of aquatic species in Kaua'i Streams and the presence or absence ofnaturally reproducing trout in each stream; Lumaha'i and Hanalei have never been stocked with trout.
53
Kaua'i. Figure 2.3 also shows the lack of feeding selectivity by rainbow trout in regard to any particular
aquatic or terrestrial taxon in their diet.
Surber <Benthic) Sample Results
A total of 60 Surber samples were randomly collected from riffles in the five streams surveyed. Benthic
sampling was completely ineffective in assessing aquatic insect diversity in upland Kaua'i streams. Only 5
aquatic insect species were collected via benthic sampling: Cheumatopsyche pettiti (Trichoptera:
Hydropsychidae), Cricotopus bicinctus (Diptera: Chironomidae), Rhantus pacificus (Coleoptera:
Dytiscidae), Megalagrion heterogamias (Odonata: Coenagrionidae) and an unidentified crane fly (Diptera:
Tipulidae), the latter accounting for little more than 1% (by number) of all invertebrate taxa collected in the
benthic samples. Of these five insect species, only two (Rhantus pacificus and Megalagrion heterogamias)
are unequivocally known to be endemic, and comprised a relatively small percentage of the sample, while
two demonstrably introduced taxa (Cheumatopsyche pettiti and Cricotopus bicinctus) comprised over 80%
of the total collected benthic macrofauna.
Mean benthic sample densities for Cheumatopsyche pettiti and Cricotopus bicinctus are shown in Figure
2.4. There is evidence that the extra-Poisson dispersion model fits this data (p-value = 0.5584 > 0.05).
Statistical tests of Surber samples using this Poisson regression indicate that the counts of C. pettiti in
Kauaikinana Stream, a stream with naturally reproducing trout, are higher than in upper Kawaikoi Stream,
which lacks trout (p-value = 0.0004), with the mean number of C. pettiti counts being 3.5 times higher in
Kauaikinana than in Kawaikoi (95% CI = [1.75, 6.86]).
In summary, the Poisson regression statistical test indicates that the densities of the most important
constituent of benthic aquatic insect fauna, C. pettiti, are independent of the presence or absence of rainbow
trout. Rather, densities of this species are hypothesized to instead be dependent on favorable water quality
54
characteristics, with more stable groundwater-fed streams such as Kauaikinana having higher densities of
introduced caddisflies. There is also correlational evidence suggesting that introduced Trichoptera in Hawai'i
exhibit lower densities in high acidity blackwater streams fed by surface runoff from upland swamps and
bogs (Polhemus 1995) than in streams fed by pH-neutral deep groundwater. This is supported by results
from Wai'alae Stream, where Surber samples were unintentionally taken upstream of several groundwater
springs and tributaries that enter the stream just below Wai' alae Cabin. The stream in this reach is highly
tannic, and the benthic samples had anomalously low numbers of C. pettiti; had the samples been taken
downstream of the pH-neutral groundwater inputs, we suspect the numbers would have been more similar to
those observed in other systems with less acidic waters.
General Aquatic Insect Collections
In contrast to benthic sampling, general collections, mainly conducted with sweep and dip nets in the
splash-zones of riffles and cascades, were an effective method of qualitatively assessing aquatic insect species
richness in the streams under study. Because the larval stages of most endemic aquatic insects in Hawai'i
have not yet been described or adequately associated with the adults on which most classifications are based
(Howarth and Polhemus 1991), collection of adult stages was emphasized. By this measure, all streams
sampled were found to have large absolute numbers (and high relative percentages) of endemic aquatic insect
taxa. A low of 20 endemic aquatic insect species were collected at Wai'alae Stream, while 33 endemic taxa
were found in Koai'e Stream. The endemic species assemblage found at Koai'e represents the greatest
number of endemic aquatic insect species so far recorded for any individual stream yet sampled in the
Hawaiian archipelago (for comparative data see Polhemus 1995; Englund and Preston 1999), despite the
presence of naturally reproducing rainbow trout in this system.
A two-sample test for equality of proportions found the number of endemic aquatic insect species in streams
with and without trout (p-value =0.6861) did not significantly differ. Streams without trout included
Kawaikoi, Lumaha'i (430 m elevation), and Hanalei (380 m elevation); while streams containing trout
55
included Kauaikinana, Koai' e, Waiakoali, and Wai'alae (Figure 2.5). A summary of the presence of endemic
damselfly taxa, and the presence or absence of naturally reproducing or stocked rainbow trout in the stream
reaches sampled can be found Table 2.3. This table illustrates the full complement of Megalagrion
damselfly species were found in streams both lacking and containing rainbow trout.
The reasons for high endemic aquatic insect diversity in Koai' e Stream, despite the presence of trout, may
be attributed to several factors. First, the reach of Koai' e Stream sampled exhibited greater habitat diversity
than the other streams under study, having waterfalls, large rheocrene seeps (wetted rock faces), and a wide
diversity of substrate size classes. Second, Koai'e Stream received significant groundwater spring inputs that
may have provided more favorable water chemistry for aquatic insects than the acidic, tannin-rich surface
waters typical ofWai'alae and Kawaikoi streams.
Drift Samples
Drift samples were collected in Kauaikinana, Kawaikoi, Waiakoali, and Koai'e Streams. While it was
beyond the scope of this study to provide a comprehensive and quantitative analysis of diel stream drift,
these preliminary findings are of interest and will possibly stimulate further research into endemic aquatic
insect drift in Hawaiian streams. The terrestrial component of drift was relatively small (15%) when
compared to the large numbers of aquatic insects present. Introduced aquatic insects dominated and
numerically accounted for 60% of drift for all streams combined. Our drift samples were taken during low
basal flows, concurrently with collection of rainbow trout stomach samples in the winter of 1999. It is
likely that samples taken during a rain event would contain a higher proportion of terrestrial insects because
of flooding of the riparian zones, and the action of rain in dislodging terrestrial insects from trees in the
adjacent rain forest.
By far the most numerically abundant aquatic insect species captured in the drift samples was the introduced
midge Cricotopus bicinctus, which comprised 45% of the drift, although the endemic midge Forcipomyia
56
hardyi, at 14%, also represented an important, though lesser, component (Figure 2.6). Other taxa found in
large numbers in the drift samples included endemic midges such as Chironomus sp. at 9%, and introduced
caddisflies (Trichoptera) at 5% (Figure 2.6). Larvae of several undescribed semi-aquatic moth species in the
genus Hyposmocoma (Cosmopterigidae), which are algal grazers on emergent boulders within the stream
channels, were also found in the drift samples. Little is known regarding the biology of the Hawaiian
Hyposmocoma species, and although there is anecdotal evidence that larvae enter the water to move between
rocks (Merritt and Cummins 1996), it cannot currently be established whether they should be viewed as
terrestrial taxa that are occasionally washed into the stream, or typical aquatic constituents of the stream
drift. For this study we chose to categorize Hyposmocoma as aquatic because of their clear relationship to
stream habitats.
Though common as immatures in the drift samples, adult individuals of the endemic midge Forcipomyia
hardyi were not collected by other sampling methods employed during this study (e.g., aerial collections,
Table 2.3 Presence or absence in surveyed K6ke'e State Park streams of naturally reproducing and stockedrainbow trout and native Megalagrion damselflies.
Rainbow Trout Naturally Reproducingor Stocked?
M. eudytum +1M. heterogamias + + + +M. oresitrophum + + + +M. vagabundum + + + +
NaturalKauaikinana
No TroutKawaikoi
NaturalKoai'e
StockedWaiakoali
NaturalWai'alae
+++
No TroutHanalei(380 m)
+++
No TroutLumaha'i(430 m)
+++
1Rheocrene habitat for this species only found at this stream.
Malaise traps, trout stomachs, benthic sampling). This absence of adults in general collecting samples
could be related to seasonal emergence patterns, or to adults leaving the stream corridor following
emergence. This anomaly highlights the importance of using multiple sampling techniques at different
57
times of year to obtain comprehensive biodiversity information on endemic aquatic insects in Hawaiian
streams.
250
200
50
O~----::==--..-----==:::.......,.-----==:"""'--=='------r--==-----.--==--t'
Cricolopus Forcipomyia Chironomus sp. Chironomidae Trichoplera Hyposmocomabicinclus hardyi
Figure 2.6. The six numerically most abundant aquatic insect taxa captured in drift samples taken in Koke'estate park streams
A wide variety of terrestrial taxa were also captured in drift samples, with terrestrial mites (Acari)
predominating, intermixed with numerous other groups including beetles (Coleoptera), flies (Diptera), bark
lice (Psocoptera), planthoppers and aphids (Homoptera), and others. For those terrestrial drift taxa that could
be identified to the species level, most proved to be endemic species. This reflects the nearly pristine
character of the riparian vegetation found along many of Kauai's upland streams. Although ginger,
blackberry and guava were encountered along the lower sections of streams such as Waiakoali and
Kauaikinana, the surrounding forests are nevertheless generally dominated by an overstory of Metrosideros
polymorpha (Myrtaceae) and an understory of other indigenous and endemic plants, which support a
correspondingly native insect biota.
Trout Diet
A total of 80 rainbow trout stomachs were collected from the five streams under study. The potential
impacts of rainbow trout on endemic aquatic insects could be unambiguously assessed, since the streams
58
examined were above the altitudinal ranges of endemic insectivorous fish. These streams were also above
the normal elevational range of the one endemic upland freshwater crustacean species occurring in Hawai'i,
Atyoida bisulcata, which is typically found below 900 m elevation.
A complete breakdown of the aquatic versus terrestrial, and endemic versus introduced status of all identified
prey items found in rainbow trout stomachs is presented in Table 2.4. As is evident in this table, rainbow
trout consume a wide variety of prey items, but endemic aquatic insects, the category of greatest interest to
this study, accounted for only 7.5% of the diet. Introduced aquatic insects accounted for 28.9% ofthe diet
and terrestrial insects accounted for 47.4% of trout diet, while organisms with an unknown geographic
origin represented 16.2% (Table 2.4).
Four species of Megalagrion were present along the streams involved in the present study:
Megalagrion heterogamias - this was the most commonly encountered damselfly along streams in
K6ke'e State Park during the course of this study, and is the largest and most conspicuous stream-breeding
damselfly on Kaua'i (Polhemus and Asquith 1996). The immatures are confined to high velocity habitats in
main stream channels, such as runs, riffles and cascades, and were one of the few aquatic insects taken by
benthic sampling, while the adults were generally observed patrolling beats above these same areas. The
remains of 5 M heterogamias immatures were among the 1,596 identifiable prey items recovered from the
80 rainbow trout stomachs analyzed. This result is interesting in light of the fact that rainbow trout are
found primarily in slow pool habitats, while immature M. heterogamias inhabit fast riffles and cascades.
The observed trout predation on these damselfly immatures is therefore hypothesized to occur when the
latter become dislodged from their preferred habitats and are entrained in the water column, becoming a
component of the stream drift.
MegaJagrion vagabundum - this was the second most common damselfly observed in the study
area; adults were commonly encountered around streamside seeps, in mossy riparian areas, and more
59
Table 2.4. Geographic origin and terrestrial or aquatic status of prey items found in 80 Koke'e troutstomachs, 1997-1999.
Taxon Native Introduced Unknown Native Introduced Unknown TotalAquatic Aquatic Aquatic Terrestrial Terrestrial Terrestrial
Amphipoda 23 23Anura 2 2Aranae 16 17Arhynchobdellida 53 53Basommatophora I IBlattodea 12 12Coleoptera 9 2 18 12 16 58Collembola I ICypriniformes 3 3Decapoda 6 3 9Diptera 27 64 35 6 133Gordioidea 6 6Heteroptera 8 22 25 5 6 66Homoptera 30 6 36Hymenoptera 4 94 5 103Isopoda 35 35Isoptera I ILepidoptera 37 11 46 94Limacoidea 35 35Lymnaeoidea 198 198Neuroptera IOdonata 33 34Oligochaeta 21 21Oribatida 2 2Orthoptera 5 5 IIPhthiraptera I 1Planorbioidea 2 2Polydesmida 215 215Psocoptera 2 2Spirostreptida 115 115Trichoptera 306 306Totals: 120 462 258 227 435 94 1596(%) (7.5%) (28.9%) (16.2%) (14.2%) (27.3%) (5.9%) (100%)
infrequently along slow-water stream reaches. None were recovered from rainbow trout stomachs, probably
because of their preference for riparian rather than lotic breeding sites (Polhemus and Asquith 1996).
MegaJagrion oresitrophum - this slender species was also moderately abundant in the study area,
being found mainly in slackwater side pools and along stream overflow channels. Adults were also
relatively common along small, shaded tributaries away from the main stream corridors. Although M.
60
oresitrophum would appear to be the native damselfly species at greatest risk for consumption by rainbow
trout, due to its preference for breeding in pools, no remains were found in any of the 80 trout stomachs
examined.
Megalagrion eudytum - although M. eudytum remains a locally common species throughout
Kaua'i, occupying an elevational range from sea level to 1220 m, it was encountered during the present
study only at Koai'e Stream. This localized occurrence is due to the hygropetric habits of the immatures,
which are found only on mossy rheocrenes or wet vertical waterfall faces (Polhemus and Asquith 1996),
sometimes at considerable distances from the main stream channel. The breeding habitat requirements appear
to be vertical faces of 2 m height or greater; small seeps or in-stream cascades are apparently unsuitable. No
immature remains were found in trout stomachs, probably due to the mutually exclusive habitats occupied
by the two species.
As noted above, 5 endemic damselfly larvae, all representing M heterogamias, were present among the total
of 1,596 identified prey items recovered from the 80 trout stomachs during this study (Table 2.5), giving a
frequency of occurrence of 6%. Four of these five Megalagrion larvae came from fish collected in Wai'alae
Stream, with the remaining individual coming from Koai'e Stream. The endemic dragonfly Anax strenuus
was more commonly consumed by rainbow trout, with 28 individuals collected from 20% of the examined
trout stomachs (Table 2.5). In contrast to the riffle-dwelling immatures of M heterogamias, the larvae of
A. strenuus prefer slow-water habitats, where they are apparently more susceptible to consumption by trout.
Table 2.5. Summary numbers and percent frequency of native prey items of special concern collected inrainbow trout stomachs during this study, compared to the number of taxa collected per stream.
Stream Native Native Other Native Introduced Other PreyDamselflies Dragonflies Aquatic Insects Aquatic Insects Items' Total
Kauaikinana 0 4 II 128 164 307Kawaikoi 0 0 2 4 34 40Koai'e 1 23 17 99 363 503Waiakoali 0 0 6 31 184 221Wai'alae 4 1 51 169 300 525
Totals (%) 5 28 87 431 1045 1596(0.3%) (1.8%) (5.5%) (27.0%) (65.4%) (100%)
lIncludes snails, terrestrial insects, other invertebrates and vertebrates.
61
Other endemic aquatic insects exclusive of Odonata constituted 7.5% (by number) of the prey items found in
Kaua'i rainbow trout stomachs. This probably reflects the fact that drift-feeding trout are finding relatively
few endemic aquatic insects in the drift, and instead must rely on introduced aquatic insects, terrestrial
insects, snails, and any other opportunistic food source, such as introduced crayfish or frogs, that becomes
available. Numerically, the three most important items in the rainbow trout diet were introduced caddisflies
(Trichoptera) at 19%, followed by terrestrial millipedes (Polydesmida) at 13%, and aquatic snails of
unknown geographic origin (Lymnaeoidea) at 12% (Table 2.4). Trout diet appeared to vary between streams
for reasons likely related to food availability. For example, lymnaeid snails were consumed by trout only in
Koai'e and Wai'alae Streams, but then sometimes in great numbers, with up to 41 snails found in an
individual trout.
DISCUSSION
Native to the Pacific drainages of westem North America, rainbow trout have been introduced into the
continents of Africa, Asia, Australia, Europe, and South America and formed naturally reproducing
populations in all of these areas (MacCrimmon 1971). In the Pacific Island region (excluding Hawai'i)
unsuccessful attempts have been made to establish trout on Fiji (Andrews 1985), Tahiti (Maciolek 1984),
and New Caledonia (Gargominy et ai. 1996). Most research on the impacts of introduced trout has taken
place in Australia and New Zealand and focused on the impacts in relation to indigenous fish (Fletcher
1986; Townsend and Crowl 1991, Crowl et aJ. 1992; Cadwallader 1996), although a limited number of
studies or observations have been published on trout impacts to invertebrates as well. The available
literature regarding the impacts of trout on the invertebrate taxa of most interest to this study, Odonata,
consists of one study in Australia (Faragher 1980) and observations in South Africa (Samways 1995; 1996;
1999). In New South Wales, an Australian dragonfly, Hemicordulia tau, was found to play an important
role in the diet of brown and rainbow trout in Lake Eucumbene (Faragher 1980). However, the long-term
survival of the dragonfly population in Lake Eucumbene was not believed to be affected by trout predation
because of seasonal changes in trout prey composition and density, as well as varying lake levels (Faragher,
62
1980). In South Africa the situation appears to be different. Samways (1995; 1996; 1999) observed that a
rare and threatened damselfly (Ecchlorolestes peringueyl) living in clear upland streams in the southwestern
Cape area may have had its range restricted by introduced rainbow trout. This Gondwana relict damselfly
was found only in stream reaches above waterfalls that rainbow trout could not surmount, and the larvae
appear to be behaviorally susceptible to trout predation as they crawl on the surfaces of rocks and plants.
Impacts of Rainbow Trout on Native Damselflies and Other Aquatic Invertebrates
Rainbow trout are opportunistic predators and usually select the largest and most readily accessible prey
(Tilzey 1977). Based on an analysis of contents from 80 individual trout stomachs, we conclude that
rainbow trout in these systems are functioning primarily as opportunistic drift feeders, exploiting both
aquatic insect drift, and the steady stream of terrestrial insects and other arthropods falling into streams from
the adjacent forest. Although aquatic insect species accounted for 52.6% of rainbow trout diet (by number),
endemic aquatic insects amounted to only 7.5% of the diet. The low percentage of endemic aquatic insects
directly reflects their low numbers in the stream drift, a phenomenon that is likely related to the natural
absence in Hawai'i of the major orders of drift-prone stream insects such as Ephemeroptera (mayflies),
Plecoptera (stoneflies), and Trichoptera (caddisflies) (Howarth and Polhemus 1991). Instead, most of the
endemic aquatic insect fauna in the ~ve streams surveyed consisted of a diverse array of species dwelling in
splash zones, all of which, though abundant, appear less prone to be entrained in the drift. While it is now
impossible to recreate conditions prior to the introduction of rainbow trout into the inland waters of Kaua'i,
our results also indicate that the endemic aquatic insect assemblages seen in the streams under study
compare favorably with other isolated and unimpacted streams lacking introduced fish elsewhere in the
Hawaiian archipelago (Polhemus 1995; Englund and Preston 1999).
Unlike amphidromous animals such as endemic stream fish and shrimp, Megalagrion damselflies and other
endemic Hawaiian aquatic insects complete the immature stage of their life cycles entirely within streams or
other freshwater ecosystems. Until recently, such damselflies were common in virtually every such
63
ecosystem throughout the Hawaiian Islands, being found from slightly brackish basal spring wetlands near
the ocean to the highest upland springs, seeps, rheocrenes, and streamlets, exploiting the full range of
available lotic and lentic habitats (Polhemus and Asquith 1996). In recent decades, however, a combination
of alien species introductions, stream channelization and diversion, and water quality degradation has caused
a significant reduction or local extirpation of many endemic damselfly populations throughout Hawai'i
(Polhemus and Asquith 1996; Englund 1999). Because Hawaiian streams differ from larger continental
stream systems in that they are high gradient and do not generally form integrated networks, lateral and
longitudinal movement of endemic aquatic insects occurs primarily during the aerial adult stage, rather than
as upstream migration or downstream drift within the water column. As a result, the local extirpation of
aquatic insect species such as damselflies within individual Hawaiian catchments can often be persistent, and
has been conclusively documented from Bishop Museum collection records (Liebherr and Polhemus 1997;
Englund 1999).
Two primary ecological requirements for endemic damselflies are good water quality (clear, low turbidity
water) and the absence of certain alien fish species such as tilapia (Sarotherodon melanotheron) and members
of the family Poeciliidae. In particular, endemic damselflies have been shown to be sensitive to the presence
of introduced poeciliid fishes such as the green swordtail (Xiphophorus hellen) or the shortfin molly
(Poecilia mexicana) (Englund 1999). Extensive surveys on O'ahu have determined that the distributions of
introduced Poeciliidae, including green swordtails, mollies and guppies (Poecilia reticulata), show a negative
correlation with those of Megalagrion damselflies (Englund 1999), indicating an adverse interaction between
the two groups. By contrast, a similar strongly allopatric distribution pattern was not evident in regard to
introduced rainbow trout and endemic damselflies (or any other native aquatic insect taxon) in the K6ke'e
State Park streams examined during this study.
Our study found that Megalagrion account for only 0.3% of rainbow trout diet in upland Kaua'i. This
compares to a 13% frequency of occurrence of Megalagrion recorded in the diet of the endemic Hawaiian
64
freshwater gobiid Lentipes concolor(n = 8) (Way and Burky 1991), the only published study to identify
Megalagrion remains in the stomachs of Hawaiian native freshwater fish. This low dietary percentage,
coupled with a high abundance of Megalagrion damselfly adults during the summer months along all the
K6ke'e State Park streams sampled, and the presence of immatures in our benthic samples throughout the
year, indicates that the low Megalagrion component in the trout diet is not simply indicative of the loss of
this genus over time from the K6ke'e stream insect community.
The fact that individual taxon frequency in trout diet is not merely a reflection of relative abundance of such
taxa in the overall stream invertebrate community is further illustrated by the introduced midge Cricotopus
bicinctus, which comprised a substantial portion of both the stream benthic fauna (23.3% by number in our
benthic (Surber) samples) and also 46% of qualitative drift samples. Although it represented a dominant
portion of stream drift and benthos, C. bicinctus comprised only 4% of trout diet, probably because this
midge is small when compared to other available prey items. Likewise, the endemic midge Forcipomyia
hardyi was the most important endemic component of stream drift, at 14%, but was absent from trout diet.
Although Cricotopus bicinctus is nearly three times the size of the endemic F. hardyi (Hardy 1960), both
taxa may either be too small for trout to notice, or their behaviors may exclude them from trout habitats
such as deep pool areas. In any case, data from these taxa clearly further indicate that the proportional
abundance of any given aquatic insect taxon does not necessarily correlate with its relative utilization by
rainbow trout.
Other Hawaiian aquatic insects, such as flies in the endemic genus Sigmatineurum are also sensitive to
environmental disturbance (Evenhuis and Polhemus 1994; Englund and Preston 1999) and would
presumably also be at risk for trout predation. However, this study found no indication of impacts from
trout on such species. Habitat requirements for these endemic torrenticolous Diptera are quite narrow, and
including seeps, and high velocity sections of riffles, cascades, and waterfalls. In contrast to other areas
surveyed on Kaua'i (see Evenhuis and Polhemus 1994; Polhemus 1995), Sigmatineurum were common in
65
Koke'e streams with and without trout. The Kaua'i endemic Sigmatineurum napaJi was found in high
numbers in two streams (Wai'alae and Koai'e) with naturally reproducing populations of rainbow trout, and
none were found in rainbow trout stomachs. These streams appear to have more robust populations of
Sigmatineurum than other areas sampled in the Hawaiian Islands; during this study several hundred S.
napali were captured at these sites, while only five individuals had ever been collected previously (Evenhuis
and Polhemus 1994), despite a history of extensive stream surveys on Kaua'i.
The Future - Options and Concerns
After examining 80 rainbow trout stomachs collected between 1997-1999 we have found no evidence that
rainbow trout, from either stocked or naturally reproducing populations, significantly impact Megalagrion
damselflies, Federally Endangered aquatic species such as Newcomb's Snail, or any other putatively
sensitive endemic aquatic species not currently listed on the United States Federal Register. In fact, rainbow
trout maintain a precarious existence in Kaua'i streams, apparently persisting only in those with the proper
hydrological and geomorphological conditions. Streams at the identical elevations (1035 m) and less than a
1 km apart, such as Kauaikinana and Kawaikoi, vary widely in their ability to support trout. Contrary to
the findings of Kido et a1., (1999), we found that stocked trout do not survive even in many of the upper
elevation headwater reaches of the Koke'e State Park streams, much less in the warmer waters of the mid
and terminal reaches below, and therefore represent a minimal threat to endemic biota in low-elevation areas.
Furthermore, our findings that rainbow trout reproduce and hold-over only in high elevation sections of
certain Koke'e area streams, feeding heavily on terrestrial drift, indicate that the impacts and risks, if any, to
endemic aquatic invertebrate species as a result of the continued presence of trout in these catchments are
relatively minor.
These findings are at odds with the widespread but poorly supported perception that rainbow trout are highly
destructive elements in Hawaiian stream ecosystems. This perception has arisen primarily from the
reasoning that because the trout represent a conspicuous introduced species with known predatory habits,
66
they must automatically be having widespread deleterious effects. Our results clearly show that trout do
exert some degree of predation pressure on endemic damselfly populations, but probably are no more
harmful than endemic and indigenous gobiid species. Across the entire spectrum of threats facing
Megalagrion damselflies, trout thus appear to represent a relatively minor component. Of far greater
concern, in our opinion, are introduced poeciliid fishes, which are widespread in lower and middle stream
reaches on all Hawaiian high islands, and have a demonstrable mutually exclusive distribution with endemic
damselflies that would otherwise occupy such habitats (Englund 1999). By contrast, we have not been able
to identify any indigenous or endemic Hawaiian aquatic insect species that appears to be eliminated from
streams in which trout are present. Given this, the current concerns over the continued persistence of trout
in the streams of upland Kaua'i, while understandable, are probably overstated.
In terms of trout eradication, the only way to restore the upland streams in K6ke'e State Park to their
original condition devoid of trout would be to use a chemical piscicide (fish poison) such as rotenone.
Despite the rugged terrain that would make trout removal difficult, it would likely be possible, although
prohibitively expensive. Not only would the extensive use of helicopters be required, but repeated
treatments of the selected piscicide would be necessary.
We see four major problems with using such methods for the complete or partial removal of trout from
K6ke'e streams where naturally reproducing populations are maintained:
1) A piscicide would not necessarily eliminate other introduced aquatic fauna found in these
watersheds.
2) Use of piscicides, particularly rotenone, would in all likelihood have non-target impacts on
indigenous and endemic aquatic arthropods. Rotenone is toxic to insects as well as fish, and was originally
used as an insecticide prior to the development of synthetic chemicals (Hynes 1970). Potential non-target
impacts of the large-scale use of rotenone in K6ke'e streams could include extirpation of locally common
endemic aquatic insect species with ranges restricted to upper elevation areas, including Megalagrion
67
damselflies and endemic torrenticolous Diptera such as Sigmatineurum napali. The alternative piscicide
antimycin would have lesser but still unpredictable impacts on such indigenous and endemic arthropods.
3) According to the results of our study, the removal of rainbow trout would not measurably
enhance the indigenous and endemic aquatic fauna of these streams in terms of overall species composition.
Kawaikoi Stream has not had rainbow trout stocked since 1992. Even so, the species composition of the
endemic aquatic fauna in Hanalei, Lumaha'i, and Kawaikoi Streams in areas devoid of trout is not markedly
different from that of Koai' e, Kauaikinana, or Wai'alae Streams, ~l of which have naturally reproducing
rainbow trout populations (Polhemus 1995).
4) Such a program would no doubt be politically unpopular; according to a recent review of the use
of rotenone in North America from 1988-1997, public acceptance was one of the most important issues
facing management agencies when using this method (McClay 2000). The chemical treatment of Koke'e
State Park streams to remove rainbow trout would face nearly unanimous opposition from anglers on
Kaua'i and throughout Hawai'i, and if the streams were restored to their formerly fishless state, it is almost
certain these streams would be clandestinely restocked with rainbow trout by anglers, thus defeating any
control or eradication efforts.
Given these considerations, coupled with the minimal impact that trout appear to be having on such
systems, the potential cure is clearly worse than the current problem. Rainbow trout, though undesirable,
appear to have low impacts on endemic aquatic fauna, and their elimination would therefore be unlikely to
result in substantive benefits to any endemic aquatic species. Unless extreme actions are regularly
undertaken to remove rainbow trout, there will continue to be naturally reproducing populations in the
upper reaches of certain catchments draining from the Alaka'i Plateau, at least in the near term. Considering
the marginal existence of these limited naturally reproducing Kaua'i trout populations, however, it seems
likely that they will decline over time in any case, falling victim to normal stochastic variations in
temperature and discharge rate typical of Hawaiian stream environments, so that these streams will return
naturally to a closer semblance of their original states. We believe that future efforts aimed at control of
68
introduced fishes in relation to Hawaiian damselfly conservation would be better concentrated on elimination
of poeciliids, which constitute a much more pervasive and demonstrable threat to the long term survival of
many rare Megalagrion species, particularly in the lowlands (Englund, 1999).
Assessing the relative degrees of threat posed by the various constituents in suites of introduced taxa will
continue to be a challenge for conservation managers, particularly on vulnerable tropical oceanic islands.
The current study has illustrated that certain introduced taxa can take on the status of "flagship threats" due
to their conspicuous or notorious nature, even though they may in fact represent lesser threats than other,
less obvious introductions. In a world of limited resources for conservation initiatives, it is therefore
prudent to obtain comparative data as to impacts, and to then channel resources first and foremost toward
control of those species that represent the most clear and present danger.
69
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(Ephemeroptera: Caenidae) in Waimanalo Stream, O'ahu. Bishop Museum Occasional Papers 64:
30-31.
Townsend, C. R. and Crowl, T. A. 1991. Fragmented population structure in a native New Zealand fish: an
effect of introduced brown trout? Oikos 61: 347-354.
Tilzey, R. D. 1. 1977. Key factors in the establishment and success of trout in Australia. Proceedings of the
Ecological Society ofAustralia 10: 97-105.
Usinger, R. L. 1972. Robert Lee Usinger: autobiography of an entomologist. California Academy of
Sciences. San Francisco. 330 pp.
74
Way, C. M. and Burky, A. J. 1991. A preliminary survey of macroinvertebrates and a preliminary
assessment of the diet ofthe endemic Hawaiian goby ('o'opu alamo '0), Lentipes concolor(Gill).
In: New directions in research, management, and conservation of Hawaiian freshwater stream
ecosystems, Proceedings of the 1990 Symposium on Freshwater Stream Biology and
Management, State of Hawaii, pp. 158-164. Hawaii Division of Aquatic Resources, Honolulu.
75
CHAPTER 3. LONG-TERM MONITORING OF ONE OF THE MOST RESTRICTED INSECT
POPULATIONS IN THE UNITED STATES, Megalagrion xanthomelas Selys-Longchamps, 1876, AT
TRIPLER ARMY MEDICAL CENTER, 0'AHU, HAWAI'I
76
ABSTRACT
Long-term monitoring of a remnant population of the Candidate Threatened Megalagrion xanthomelas
(orangeblack Hawaiian damselfly) located at TripIer Army Medical Center (TAMC), O'ahu, Hawai'i began
in May 1997 and continued to February 2000 for the mitigation ponds and June 2000 for the TAMC
stream. This species has been reduced to little more than 100 m of stream habitat on O'ahu at the TAMe.
Threats to M. xanthomelas include alien fish species, stream dewatering, and habitat alteration. The TAMC
stream now requires augmented water flow because construction of a facility up gradient of the TAMC
stream disrupted the normal hydrology of the small stream. The O'ahu race of M xanthomelas will soon
become extinct if the stream were allowed to become dry, as nearly happened in June 1997. The most cost
effective way to ensure the survival of this species on 0'ahu would be to continue some mitigation water
flows to the TAMC stream. The next step would be the establishment of another wild population of M.
xanthomelas to a stream lacking alien fish species. It is highly recommended that a cooperative association
of biologists from the Bishop Museum, University of Hawai'i, U.S. Fish and Wildlife Service, and U.S.
Army environmental staff continue to monitor the population of M. xanthomelas, arguably the rarest insect
population in the United States.
INTRODUCTION
Monitoring of the last remnant O'ahu population of Megalagrion xanthomelas Selys-Longchamps, 1876, a
Candidate Threatened species on the U.S. Federal Register, began in May 1997 and continued through
February 2000. This damselfly population is located in a small unnamed stream (henceforth called TAMC
stream) in a U.S. military installation at the TripIer Army Medical Center (TAMC) near Honolulu, Hawai'i
(Figure 3.1). Although formerly a common insect on O'ahu (Liebherr and Polhemus 1997; Englund 1999)
this species has currently been reduced to little more than 100 m of stream habitat. Threats to the endemic
M. xanthomelas include alien fish species, stream dewatering, and habitat alteration (Polhemus 1996). This
species was considered extinct on 0' ahu until the discovery of this remnant population by N.L. Evenhuis of
the Bishop Museum in 1994 (Evenhuis and Cowie 1994). Concerns were raised about the
77
Megalagrion xanthomelas
0= Historic records (1892-1989)
• = Recent records (1990-2000)
Tripier Army Medical Center
Figure 3.1. Map of O'abu, Hawai'i showing locations of current and historic records for Megalagrionxanthomelas (from Evenhuis et a1., 1995).
long-term viability of this remnant damselfly population because construction of a large U.S. Veterans
Administration facility had the potential to disturb the watershed. Prior to the construction and large-scale
upslope disturbance, four mitigation ponds constructed adjacent to the stream (Figure 3.2) and were
completed in October 1995. These ponds were built to ensure the survival of M. xanthomelas in case a
flood event or other catastrophe disrupted their habitat. Because of budgetary constraints the mitigation
ponds were drained and dismantled in March 2000, however, stream augmentation flows currently provide
suitable aquatic habitats for M. xanthomelas.
78
Figure 3.2. TAMC Mitigation ponds prior to drainage, February 2000.
STUDY AREA
The TAMC stream is located on leeward O'ahu at 79 m elevation, and flows through a forest of introduced
plants. An in-depth description and map of the stream study area can be found in Evenhuis et al. (1995),
Polhemus (1996), and Pange1inan (1997). The TAMC stream now requires augmented water flow because
construction in 1995 of a large Veterans Administration facility up gradient of the TAMC stream disrupted
the normal hydrology of this small stream. The cement-lined mitigation ponds are approximately 200 m
northwest of the TAMC stream, and measure 7.3 m long by 3 m wide and have an average water depth of
0.6 m. These ponds contained cobble substrate brought from the TAMC stream and aquatic plants such as
algae, water lily (Nymphaea sp.), water lettuce (Pistia stratiotes), and a large aquatic sedge (Cyperus
altemifolius). To ensure the survival of this damselfly species, quarterly monitoring of the four mitigation
ponds began in May 1997 and continued until their being dismantled in February 2000. Quarterly
monitoring of the TAMC stream began in May 1997 and continued until June 2000.
79
METHODS
Stream Sampling
The objectives of the damselfly mark-recapture sampling efforts were to 1) document recruitment of new
individuals to the population between quarterly sampling efforts, 2) assess the relative abundance of
damselflies between monitoring periods using a standardized methodology, and 3) provide a quick means of
determining if the TAMC M. xanthomelas population was threatened by disturbance or stream dewatering.
The entire length of wetted stream (95 m) was sampled starting at the upstream end of the man-made culvert
where stream flow originates. Methods used were identical to previous research conducted on the M
xanthomelas TAMC population (Pangelinan 1997). For this study, damselflies were marked beginning on
15 May 1997. Two observers conducted monitoring after the fIrst quarter (May 1997) in which methods
were established. While slowly walking down the stream each observed damselfly was netted and its wings
marked with a permanent black extra fIne felt tip marker. The number was recorded if a captured damselfly
had been previously marked. After completing the slow downstream walk, which would take up to three
hours, we returned slowly upstream and marked any previously unmarked damselflies. Collection and
observation times were consistent during each quarterly monitoring event to standardize sample effort, and
ranged between 3.5 to 4.0 hours. Individuals were not counted unless they were netted and the wings marked
with a number.
Pond Sampling
Thirty-minute damselfly counts were conducted at each of the four concrete mitigation ponds. Damselfly sex
and behavioral activity was recorded during each thirty-minute count. Individual adults were not counted
unless they were captured and the wings marked with a number. Quantitative aquatic net samples were taken
at the ponds starting during the November 1997 monitoring. Three aquatic net sweeps approximately 1.25
m in length were taken at the surface, middle, and bottom of each pond. The net contents were then placed
in a 500-micron sieve and inspected for immature damselfly naiads.
80
The number of distinctive M. xanthomelas oviposition scars on water lily leaves in the mitigation ponds
was counted each quarter to provide a measure of relative breeding attempts. After observing female M.
xanthomelas ovipositing on water lilies, it was easy to distinguish Megalagrion oviposition scars from
dragonflies and Ischnura spp. Megalagrion xanthomelas leaf scars were larger and more curved when
compared to Ischnura spp. oviposition leaf scars. The presence of other aquatic insects was also recorded.
Additionally, the presence of dragonflies, ants, water boatmen (Notonecta indica) and other potential
predators or threats was noted at each pond. Pond levels were noted and when necessary the pond outlets
were cleaned.
RESULTS
TAMC Damselfly Counts
Stream
Long-term monitoring of M. xanthomelas populations at the TAMC stream indicates a robust damselfly
population after flow restoration started in June 1997 (Englund 1998). During the present study the number
of adult damselflies marked each quarter varied from a low of 17 in May 1997 to a high of 162 in February
1998 (Figure 3.3). Observations of adults atthe TAMC stream were lower in the month of December 1999,
and winter 1999 counts may not be directly comparable to other monitoring periods because of the cool,
cloudy weather. Four separate monitoring attempts were made at the TAMC stream in November and
December of 1999. Megalagrion xanthomelas adults are only active during sunny weather (Polhemus 1996),
and a long period of cloudy, cool, and very wet weather in the final quarter of 1999 reduced the numbers of
captured adult damselflies at the TAMC stream. Additionally, the most severe weather and heavy flooding
during the entire study period in November and December 1999 may have caused some adult mortality at the
stream area. During this time heavy rains scoured the streambed to bedrock, and caused minor rockslides
into some areas of the TAMC stream. Fortunately, numerous immature individuals were observed in the
stream immediately after the heavy rains and flooding in December 1999. The restoration of stream flow
81
180
III 160~.a 140Q.
~ 120
~ 100
~ 80Enl 60Cnl 40....~ 20
o
-r-- r-
-r- - r-
r--
--
r-r-
n nMay- June July Sept Nov Jan- Feb May Aug Nov Jan- May Aug Dec Feb- Jun-~ 00 W 00 00
Figure 3.3. Megalagrion xanthomelas captures at TAMC stream, May 1997-June 2000
continues to provide optimal aquatic habitats at the TAMC stream, and also ensured this damselfly
population could survive a severe environmental disturbance in the form of heavy flooding in November and
December of 1999. Monitoring conducted in February and June 2000 confirmed December results resulted
from poor weather conditions, and subsequent visits to the TAMC stream indicate M. xanthomelas remains
abundant.
Captures of M xanthome1as at the TAMC mitigation ponds were variable, but overall the ponds received
some use during each quarter. During the present study the number of adult damselflies marked at the ponds
each quarter varied from a low of 0 in May 1997 to a high of 23 in January 1998 (Figure 3.4). During this
study, immature Megalagrion damselflies were not collected in dip net sampling at the surface, middle, and
bottom layers of each pond. However, at least two cast skins and one teneral M. xanthomelas were found at
82
the ponds during the time-frame of this study by u.s. Fish & Wildlife Service personnel, indicating that
there was at least limited reproductive success between 1997-2000.
1/1 25l!!:::JC. 20ltl()~ 15
!EG)1/1 10EltlC 5ltl...o 0I-
r-- -
- - -r--- - -
r-- -
n n nMay- June July Sept Nov Jan- Feb May Aug Nov Jan- May Aug Dec Feb-W W ~ 00
Figure 3.4. Megalagrion xanthomelas captures at TAMC mitigation ponds from May 1997-February 2000.
Five species of native and introduced dragonflies were abundant at the ponds both as adults and larva. Two
native dragonfly species, AnaxJunius and Pantala flavescens were abundant, as were the introduced Tramea
abdominalis, Orthemis ferruginea, and Crocothemis servilia. These immature dragonflies were captured in
virtually every dip net sample. Cast skins of these dragonflies were also common and found on vegetation
within the ponds. Two species of introduced damselflies were also observed and captured at the ponds,
Ischnura posita and Ischnura ramburii, and cast skins of these damselflies were also found at the ponds.
Introduced water boatman (Notonecta indica) were common and a potential predator, and introduced long-
legged ants (Anoplolepes longipes) were observed by u.S. Fish & Wildlife Service personnel (A.
Pangelinan, pers. comm.) to kill freshly emerged M. xanthomelas at the ponds. The most shaded and lowest
pond received the greatest use by adult damselflies, with most damselflies being caught at this pond.
83
Damselfly oviposition scars observed on water lily leaves likely reflect a lesser percentage of attempts by
females to lay eggs, as it has been observed that M. xanthomelas preferentially oviposit on algae both at
the TAMC ponds and on Molokai (Englund, pers. obs.). However, these scars provided a useful relative
index of breeding attempts at the ponds. Oviposition scars on lily leaves declined since the peak in January
1998 and were variable thereafter (Figure 3.5). The presence of some oviposition scars on water lily leaves
indicates breeding occurred at the mitigation ponds throughout the study period. Thick algal mats were a
continual problem in the ponds and necessitated weekly removal of algae. Pangelinan (1997) found very
limited movement between the TAMC stream population and pond population; thus most of the individuals
observed at the ponds were likely the result of pond reproduction.
20l!!lU(J
en 15l:0E
10//I0Q.
'>50
~J
0
--
- r--- - --- -
n n nJul-97 Sept Nov Jan- Feb May Aug
98Nov Jan- May Aug
99Dec Feb
00
Figure 3.5. Oviposition scars on water lilies at the TAMC mitigation ponds July 1997-February 2000.
On 2 March 2000 the mitigation ponds were drained and as many damselfly larvae as possible were
recovered and saved for later identification. Hundreds of Ischnura posita larvae along with high numbers of
dragonfly larvae were examined, but no M. xanthomelas larvae were found.
84
DISCUSSION
The experience of preserving the O'ahu population of M. xanthomelas at TAMC for the past 6 years has
been one of the most notable conservation success stories in the Hawaiian Islands. A catastrophic flood in
1995 killed the entire stream population because of a massive sediment input into the stream during
construction of the previously mentioned Veterans Administration facility. The mitigation ponds provided a
reserve population for M. xanthome1as that would otherwise have gone extinct on O'ahu. The completion
of the ponds and translocation of immatures and adults in October 1995 was fortuitous as the flood occurred
in November 1995. This success has not come without a major expenditure of money and time by U.S.
government agencies such as the U.S. Department of Veterans Affairs and the U.S. Fish & Wildlife
Service. For example, the mitigation pond planning, engineering and construction cost totaled U.S.
$200,000, while pond maintenance cost $6000 per year, starting in 1995. Other major expenses include a
$200-300 per month water bill for maintaining stream flows and pond levels.
While the mitigation ponds initially proved to be a major success and ensured the survival of M.
xanthome1as on O'ahu, the long-term success in native damselfly recruitment was less dramatic, and
hampered by sometimes unfavorable conditions. When the ponds were first filled in 1995 there were low
numbers of predators such as dragonflies, and the water lacked thick algae growths. In 1995, reproductive
success of M. xanthomelas was definitive and verified by numerous cast skins found around the ponds (Zoll
1995). However, over time, thick growths of filamentous green algae were the biggest problem at the
ponds, interfering with emerging larvae and resulting in stagnant water conditions. Floating algae mats also
allowed ants access to the interior of the ponds where they would prey on emerging M. xanthomelas. High
densities of native and introduced dragonfly larvae at the ponds undoubtedly influenced M. xanthomelas
numbers. These dragonflies were noticeably absent from the TAMC stream most likely because thick
riparian vegetation and flowing water did not provide favorable dragonfly habitat.
85
With hindsight it appears that the ponds could have been designed to more closely mimic conditions found
at the TAMC stream. The sunny and hot exposure of the ponds was the biggest problem because water
temperatures at the ponds were much higher than in the TAMC stream. For example during a warm period
in August 1999 pond temperatures were 27°C while stream temperatures were 22.5-23°C. A long-term
solution for reducing water temperature and also algae growth at the ponds would have been to plant shade
trees around the ponds. In contrast to the TAMC ponds, the stream area is heavily shaded but still provides
some sun penetration at midday. In the future it is recommended that mitigation habitat more closely
resemble a stream channel with riffles and pools and maintaining a moderate current velocity. This would
also reduce predatory dragonfly numbers in the mitigation habitat.
The TAMC stream nearly became dry in June 1997 (EnglundI998) after construction upslope of the stream
two years earlier disrupted the hydrology of this small watershed. However, because of mitigative water
flows paid for by the U.S. Department of Veterans Affairs, stream flow remained at 100% of stream length
and aquatic habitats were optimal at the TAMC stream through May 2000. In March 1999, the U.S. Army
and U.S. Fish & Wildlife service attempted to translocate M. xanthomelas to another O'ahu stream in
attempts to establish a second O'ahu population. Fifty-five adults and 44 larvae were collected from the
TAMC stream and transported to an unnamed stream near Dillingham Airfield. This attempt apparently
failed because the translocation stream contained the introduced red swamp crayfish [Procambarus c1arkii
(Girard, 1852)] (K. Johnson pers. comm.), a species absent from the TAMC stream.
The taking of a large number of adult and immature damselflies from the TAMC stream had no observable
impact on this restricted population (Figure 3.3). Although a more suitable translocation site needs to be
found, the lack of impacts to the TAMC damselfly population is encouraging. It is imperative that current
mitigation flows be provided at the TAMC stream for a minimum of at least two years after it has been
shown that translocated populations of M. xanthomelas are naturally reproducing. If successful reproduction
is observed in the form of unmarked damselflies at the next relocation site, then monitoring at this site
86
should be continued for at least two years to ensure the population is self-sustaining. An example that
translocation of a rare tropical damselfly species can be successful is the translocation of M xanthomelas
from the TAMC stream to the mitigation ponds.
Monitoring has also shown that removal of damselflies for translocations does not adversely effect
populations at the TAMC stream. Without mitigation stream flows the TAMC stream will cease to flow
and cause the extinction of damselflies from the TAMC stream, and O'ahu. Thus, it would be prudent to
make additional translocations while the TAMC damselflies are abundant, perhaps to a second relocation
site at the U.S. Naval Magazine at Lualualei, O'ahu. Possible candidate relocation streams were observed
during Bishop Museum surveys of Lualualei (Evenhuis 1997a), although some of these streams may need
to be treated with rotenone to remove alien poeciliid fish such as the western mosquitofish (Gambusia
affinis), that are believed to be responsible for the decline of this species (Englund1999).
The most obvious and cost-effective way to ensure the survival of M. xanthomelas would be to continue at
least some water flow to the TAMC stream. The $200-300 per month water bill to provide mitigation
flows is a small price to pay for one of the most formerly common insects on O'ahu. Construction
adversely affected water flow at the TAMC stream and caused the stream to become dry before mitigation
flows were implemented in June 1997. Now that the ponds have been dismantled there is only one O'ahu
location where M. xanthomelas can be found. As stated earlier, the fate of the translocation efforts for this
species are very uncertain, and have failed in at least one attempt to move them out of the TAMC
watershed. Thus, to ensure the survival of this species it is necessary to maintain mitigation flows at the
TAMC stream until after at least two additional populations have been conclusively established in other
areas on O'ahu.
Recent genetic work on M. xanthomelas indicates that populations between the various Hawaiian islands
can be quite different (S. Jordan pers. comm.). Although the mitochondrial haplotype obtained from TAMC
87
specimens has also been found on Molokai and Lanai, other loci might reveal significant differences
between the O'ahu TAMC population and other islands, however, more work needs to be done. The O'ahu
population also has much less genetic diversity than populations on other islands, probably due to genetic
bottlenecks (S. Jordan pers. comm.). Therefore it is critical that habitats and populations from O'ahu be
maintained to preserve the distinct O'ahu race of this damselfly.
In conclusion, it is recommended that a collaboration of specialists from the Bishop Museum, University of
Hawai'i, U.S. Fish and Wildlife Service, and U.S. Army environmental staff continue to monitor the
TAMC population of the M. xanthomelas. Additionally, this collaborative team should work on
establishing at least two separate populations on the island of O'ahu. Until other populations have been
established, monitoring on at least a quarterly basis at the TAMC stream could identify potential threats and
ensure proper management actions are taken to allow this rare damselfly to survive.
88
REFERENCES
Englund, R. A. 1999. The impacts of introduced poeciliid fish and Odonata on endemic Megalagrion
(Odonata) damselflies on Oahu Island, Hawaii. Journal ofInsect Conservation 3: 225-243.
Englund, R. A. 1998. Response of the orangeblack Hawaiian damselfly (Megalagrion xanthomelas), a
candidate threatened species to increases in stream flow. Bishop Museum Occasional Papers 56:
19-24.
Evenhuis, N. L. and Cowie, R. H. 1994. A survey of the snails, insects and related arthropods in the
grounds of the TripIer Army Medical Center, Honolulu, Hawaii. Bishop Museum Technical
Report 3. 21 pp.
Evenhuis, N. L, D. Polhemus, S. Swift, K. Arakaki and Preston, D. 1995. A study of the biology of the
orangeblack Hawaiian damselfly (Megalagrion xanthomelas), with special reference to conservation
of the population at TripIer Army Medical Center, Oahu. Bishop Museum Technical Report 8: 81
pp.
Evenhuis, N. L. 1997. Diversity of insects and related arthropods of the Naval Magazine Lualualei,
Headquarters Branch, Oahu, Hawaii. Final report prepared for the U.S. Navy. Bishop Museum
Technical Report 9: 170 pp.
Liebherr,1. and Polhemus, D. A. 1997. Comparisons to the century before: the legacy of the R.C.L.
Perkins and Fauna Hawaiiensis as the basis for a long-term ecological monitoring program. Pacific
Science 51: 490-504.
89
Pangelinan, A. A. 1997. Demography and life history of the orangeblack Hawaiian damselfly (Megalagrion
xanthomelas) (Selys-Longchamps, 1876) on Oahu, Hawaii. Masters Thesis, University of Guam.
Polhemus, D. A. 1996. The orangeblack Hawaiian damselfly, Megalagrion xanthomelas (Odonata:
Coenagrionidae): clarifying the current range of a threatened species. Bishop Museum Occasional
Papers 45: 30-53.
Zoll, M. 1995. Orange-black damselfly mitigation at TripIer Army Medical Center: population
enhancement via artificial ponds. Final Report to U.S. Department of Interior, U.S. Fish &
Wildlife Service, Pacific Islands Ecoregion, Honolulu, Hawaii. 30 pages.
90
CHAPTER 4. THE LOSS OF NATIVE BIODIVERSITY AND CONTINUING NONINDIGENOUS
SPECIES INTRODUCTIONS IN FRESHWATER, ESTUARINE, AND WETLAND COMMUNITIES
OF PEARL HARBOR, 0'AHU, HAWAIIAN ISLANDS.
91
ABSTRACT
The benthic organisms and fishes of the estuarine, lower stream areas, and wetlands of Pearl Harbor were
sampled from 1997-1998 as a companion study to inventories conducted in the more marine areas of Pearl
Harbor. This study, the first comprehensive assessment of the non-marine areas of Pearl Harbor, found that
nonindigenous species comprise the dominant portion of the biota in the estuaries, wetlands, and lower
stream reaches. Many species of aquatic organisms have been introduced into these areas, altering the
species composition of the aquatic fauna, resulting in the lower portions of Pearl Harbor streams, springs,
and wetlands being dominated by nonindigenous species. A total of 191 aquatic species in 8 phyla were
identified in the estuarine reaches of Pearl Harbor. Nonindigenous species dominated with 48% of the
species recorded, while only 33% were native and 19% were cryptogenic. Two new nonindigenous species
to Hawai'i were found during this study--a species offang-toothed blenny (Omobranchus ferox) and an
estuarine hydrobiid snail (Pyrgophorus cf. coronatus) introduced from the Caribbean. No geographic region
is a predominant source of aquatic species introductions into the Pearl Harbor area, although more species
come from the Americas than other areas. For example, 57% originated from the Americas, 30% from Asia
and the Pacific, 5% from Australia/New Zealand, 5% have a world-wide distribution, with fewer than 3% of
species originating from Africa. An increase in non-native species in the freshwater and estuarine portions
Pearl Harbor will probably continue. This is because of the wide variety of sources from which
introductions take place. The majority of nonindigenous species appear to have come from five major
sources: 1) intentional and accidental aquarium releases, 2) intentional biocontrol releases, and 3) intentional
food source releases, 4) ballast water or hull fouling releases, 5) brought in with airplanes.
INTRODUCTION
Numerous studies have been conducted in marine habitats of Pearl Harbor (Coles et a1. 1999), but little
baseline research has been conducted in the lower reaches of streams and coastal wetlands in the harbor
despite the large extent of these habitats. The large Pearl Harbor spring, coastal wetland, and riverine
systems represent an ecologically important and unique natural resource and formerly contained a significant
92
endemic fish and invertebrate fauna (Titcomb 1972). However, prior to the present survey little was known
about the current status of the fauna in these areas.
Over the past several hundred years the Pearl Harbor watershed has undergone tremendous environmental
degradation, changing from an area of fishponds and taro fields with reportedly high water quality in pre
European contact times (before 1778) to a highly urbanized area with poor water quality (Coles et a1. 1999).
Many spring, wetland, and stream mouth areas have been channelized and filled, and the arrival of
mangroves in the early part of the 20th century (Wester 1981) also considerably changed the shoreline.
Nonindigenous species are an increasing threat to Hawaiian stream, wetland, estuarine, and anchialine pond
ecosystems. Not only do nonindigenous aquatic species in tropical Pacific insular environments compete
with and prey upon native species (Eldredge 1994), they have also brought with them a complement of
diseases and parasites to which native species are not resistant (Font and Tate 1994). The severity of
nonindigenous species impacts varies according to island, elevation, and watershed; with adjacent streams
often having significantly different compositions of nonindigenous species (Englund et a1. 2000a). Even the
most remote estuarine and anchialine habitats found in the main Hawaiian Islands contain nonindigenous
aquatic species (Maciolek 1984). However, some relatively pristine stream, wetland, and anchialine pond
areas can still be found on the islands of Kaua'i, Maui, Molokai, and Hawai'i, and still have robust
populations of freshwater and estuarine native fish, crustaceans, mollusks, and aquatic insects (Maciolek
1984; Polhemus 1995a). Because of naturally low base flows (Nichols et a1. 1997) and watersheds being
smaller and shorter, O'ahu streams and estuaries have a lower flushing out capability than the generally
larger streams found on other islands such as Kaua'i and Hawai' i. Many formerly common native aquatic
insect species are now absent or rare in many lower elevation O'ahu stream and estuarine areas, including
Pearl Harbor, and appear to have been displaced by nonindigenous species (Polhemus 1996; Englund 1999).
93
In Hawai'i, estuarine habitats are important for a wide variety of native species including several species of
culturally important food fish such as the native Mugil ceph81us and the endemic Kuhlia sandvicensis and
Awaous guamensis. Native crustaceans such as Macrobrachium grandimanus and Atyoida bisulcata also
require estuaries for various stages of their life histories. Hawaiian streams exhibit low endemicity among
the freshwater and estuarine macrofauna because amphidromy (Meyers 1949) has lead to gene flow between
islands (Zink et al. 1996). Also, the relatively small quantity of non-marine aquatic habitats found in
Hawai'i compared to continental areas has led to low native diversity. Nonetheless, these habitats supported
an important native fauna. By 1991, however, at least 58 intentionally and accidentally introduced
freshwater species (excluding aquatic insects) had become established throughout the Hawaiian Islands
(Devick 1991). The purpose of the present study was to assess the aquatic biodiversity of freshwater and
brackish habitats in Pearl Harbor and identify known or probable origins and mechanisms of nonindigenous
species introductions.
Study Area
Located in south-central O'ahu (Figure 4.1), seventy percent of the natural freshwater discharge into Pearl
Harbor originates from a spring complex that is the largest and most significant in the Hawaiian Islands,
with an average combined pre-development flow of about 8 m3/sec (Nichols et 81. 1997). Although the
abundance of fresh water in spring areas within Pearl Harbor has diminished because of upgradient
groundwater pumping (Nichols et al. 1997), this area still supports one of the largest coastal spring and
wetland systems in the Pacific Islands.
Pearl Harbor is formed from a drowned river system that has been submerged during various glacial epochs,
with oyster beds and thin coral reefs flourishing during periods of higher sea level (Stearns 1985). The lower
sections of Pearl Harbor streams, wetlands, and springs now lie largely over a fill of oyster beds, reefs,
gravel and mud deposits that have resulted from erosion of the upper elevation areas of the Ko'olau and
94
Waianae Mountains, from where both surface and sub-surface water for Pearl Harbor springs and streams
originates. Groundwater from these mountain ranges flows down gradient in the Ko'olau basalt until coastal
sediments near Pearl Harbor are encountered. The zone of springs is restricted to a narrow strip lying
J57'59'OO"W
N
w••S
500 0 500 1000 Meters--21"22'OO"N
1574:56'30"W
Figure 4.1. Map of Pearl Harbor with sampling locations.
between the inland edge of marine sediments and the caprock at approximately 6.1 m above sea level
(Visher and Mink 1964). Streams in the Pearl Harbor watershed are now eroding the cap rock that was left
above sea level with artesian springs discharging from bedrock where the cap rock has been removed
(Stearns and Vaksvik 1935). These springs are fed from breaks or low points in the caprock that allow
escape of groundwater; this consequently results in a series of large freshwater releases (Stearns and Vaksvik
1935). Water also emerges seaward of the exposed basalt cliff, through the thin caprock of the Pearl Harbor
95
coastal plain, but in lesser quantities than at the base of the break in the Ko'olau basalt (Visher and Mink
1964). Flow is perennial only in the Ko'olau Mountain headwaters and near the mouth in the area of the
basal Pearl Harbor springs, and has been reduced by approximately 50% from pre-development flows
(Nichols et al. 1997). Above the areas of spring influence, Pearl Harbor streams are characterized by high
flood peaks and low baseflows (Nichols et al. 1997). Streamflows are more constant downstream of the
Pearl Harbor springs, and have characteristics of groundwater (low salinity, high silica, high nitrate levels)
rather than surface water (Nance 1998).
METHODS
Nonindigenous aquatic species have been brought into Hawai'i both accidentally and intentionally. In many
cases the method of introduction into O'ahu and geographic origin can be determined. Species of
undetermined geographic origin are termed cryptogenic (Carlton 1996). The native or nonindigenous status
of arthropods was ascertained from Nishida (1997), and for this study we assumed that organisms classified
as probably endemic or indigenous were native species. Aquatic species introductions have been separated
into the following categories: governmental biocontrol, intentional food introduction, probable ballast water
or hull fouling, accidentally introduced with baitfish, aquarium release or with aquarium plants, brought in
with airplanes, and unknown.
Sampling began in October 1997 and ended in August 1998. Representative sampling stations were
established in each major Pearl Harbor estuarine and coastal wetland and spring area (Figure 4.1) with
sampling extending to areas just above the limit of tidal influence. Most sampling stations were generally
at or just above sea level. Aquatic insect sampling was conducted according to Polhemus (1995a) and
Englund et al. (2000b). Collections of both immature and adult specimens were made with aerial sweep
nets, aquatic dip nets, seines, and benthic samplers. Bottom communities, including insects and taxa other
than insects in the soft-sediment areas of streams were sampled with a Wildco Petite Ponar" 15.2 x 15.2 cm
weighted dredge. Three dredge samples were collected at each stream mouth, and after collection sediments
96
were rinsed through a 1 x 1 mm sieve. The contents were preserved in 75% ethanol for laboratory analysis.
Visual observations of aquatic insects were also conducted above the waterbody. The sampling of
damselflies and dragonflies (Odonata) was also emphasized as several endemic Hawaiian species are currently
listed as candidate threatened or endangered species under the United States Endangered Species Act.
Seine netting using a fine-mesh, 5 m long net was the main technique used to sample fish, and dip nets
were also used to sample areas not accessible to seines. Experimental gill nets of varying sized mesh were
also used to sample fish in areas that were too deep to seine. Efforts were also made to visually observe and
collect native gobiid fish at each sampling site.
Although some fish, crustacean, and mollusk species were identifiable in the field, many smaller specimens
had to be preserved (in 75% ethanol) and taken to the laboratory for identification. The reference used for the
scientific and common names of fishes was from the American Fisheries Society (1991), crustaceans
(American Fisheries Society 1989), and Nishida (1997) for insect names. Salinity was also recorded at least
once at each location sampled.
RESULTS
A total 191 aquatic species were identified within the lower reaches of Pearl Harbor streams and wetlands
(Table 4.1). A complete list of species found at each sampling site during this survey and in previous
surveys can be found at http://hbs.bishopmuseum.org/lists/pearl-spp.html. Nonindigenous species
dominated with 48% of the species recorded, while only 33% were native, and 19% cryptogenic (Figure
4.2). The one new species (cryptogenic) collected was an aquatic mite (Acari) in the family Ascidae.
Arthropods (mainly insects) comprised nearly 61 % of the species collected and included 89 species of aquatic
insects, 26
97
Table 4.1. Summary of the native or nonindigenous status and total number (percent) of aquatic speciesfound in Pearl Harbor estuarine habitats.
Geographic All Aquatic l Aquatic Insects Fishes Crustaceans MollusksStatus Species
Nonindigenous 91 (48%) 49 (55%) 18 (46%) 5 (19%) 10 (62%)Native 64 (33%) 22 (25%) 20(51%) 14 (54%) 3 (19%)
Cryptogenic 35 (18%) 18 (20%) 1 (3%) 7 (27%) 3 (19%)New 1 «1%) 0 0 0 0Tolal 191 89 39 26 16
I Miscellaneous species such as Annelida, Nematoda, and Cnidaria are included in this total.
• Nonindigenous 0 Native • Cryptogenic
80
70
60 •III • I.!!!~ 50
I IV) • •~ 400
I-.1l •E 30 •::::J •Z
20 - ~•10
~I~ ~I~0 ~ ---r- ~ ~ -r- ---r-
E ~ E E .. " E E .J:;
j i E ., .. E E
~.. .. " § .. .. e .. E r .. ..
~ !! ~ ~ ~ " % ~ !! !til Vi Vi lI. 5l ~ Vi " Vi ViII>
.~ II> II> .. 0< II>.. .0 ! :; g 0 :E 1 " ~ ~ ~ " " "-'! w I: C"..
i .f! OJ OJ ]<{ " g " " " ~ -a ..!! li .l! .><
" ~.. ..
~ .. :it .. a;:I: "'iii ;;;
~ ~ ~ ~..
~ '" '" .. ~>< ;.!!..~
Figure 4.2. Number of species by stream and native or nonindigenous status for combined aquatic faunafound in estuarine regions of Pearl Harbor.
98
crustaceans and 5 aquatic mites. Other phyla included vertebrates (22%), mollusks (8%) and annelid worms
(7%). Other components of the fauna collectively composed only 2% of the species, and included Cnidaria,
Platyhelminthes, Nematoda, and Sipuncula.
Aquatic Insect Species Composition
Twenty-two, or only 25%, of the aquatic insect species were known to be native. Nonindigenous species
accounted for nearly 55% (49 species) of the aquatic insect species, and cryptogenic species comprised 20%
(18). Of the native species of aquatic insects, approximately 59% (13) were endemic, while 41 % (9) were
indigenous. Aquatic Diptera (flies) were by far the most species-rich order found and comprised 81 % (72) of
all aquatic insect species. A large percentage of aquatic Diptera (28%,20 species) could not be identified to
the species level, and thus were considered cryptogenic, while 46% (33 species) were nonindigenous.
Odonata (dragonflies and damselflies) were the next most common (8% of species) followed by aquatic
Heteroptera (true bugs, 6%) and Coleoptera (aquatic beetles, 6%). Nonindigenous caddisflies (Trichoptera)
such as Cheumatopsyche pettiti were collected in lower Waikele Stream, and composed only 1% of the
sampled aquatic insect fauna.
Areas where the introduced fly Ephydra gracilis had previously been recorded in Pearl Harbor such as
Hickam Field and Iroquois Point (Wirth 1947) were resampled. Intensive sampling of these and other
suitable wetland areas found numerous species of other native and nonindigenous ephydrid flies, but did not
find Ephydra gracilis.
No native Megalagrion damselflies were found, while three species of nonindigenous damselflies, Ischnura
posita, Ischnura ramburii, and Ena1lagma civile, were abundant. Two native and two nonindigenous species
of dragonflies were also common; the indigenous species Pantala flavescens and Anax junius, were some of
the most common native aquatic insects remaining in Pearl Harbor. Larvae and adults of A. junius were
always collected from sites with many species of nonindigenous fish. The two nonindigenous dragonfly
99
species, Crocothemis servilia, which was first observed in O'ahu in 1994, and the well-established
Orthemis ferruginea, were common throughout the surveyed area.
The endemic marine water strider Halobates hawaiiensis, an aquatic heteropteran, were locally common. It
was often found in the shelter of nonindigenous mangroves, and was always found in areas of water with>
34 ppt salinity. It is not known from Pearl Harbor prior to the introduction of mangroves. However, it was
also common in areas without mangroves. Other aquatic Heteroptera found include four common,
nonindigenous species in the families Corixidae (Trichocorixa reticulata), Mesoveliidae (Mesovelia amoena
and Mesovelia mulsantl) and Saldidae (Micracanthia humilis).
Four nonindigenous aquatic beetle species (Coleoptera) were found but no native species were collected. The
most recent introduction is the small mangrove mudflat beetle, Parathroscinus cf. mmphyi, which was first
recorded in Pearl Harbor in 1996 (Samuelson 1998). Parathroscinus cf. mmphyi populations have now
exploded, and they were found in extremely high densities throughout Pearl Harbor mudflats, with flying
adults forming thick clouds above the mud. Two other species of nonindigenous water scavenger beetles,
Enochrus sayi and Tropistemus salsamentus, were common in areas of still water. Both of these species
were saline tolerant, occurring in the lowest reaches of streams in areas with salinity as great as 16 ppt.
Fish Species Composition
Many species (nearly 44%) were Perciformes, including both native and nonindigenous species: gobies,
cichlids (e.g., blackchin tilapia), blennies, and mullet. Other Orders were represented solely by
nonindigenous species: Characiformes (pacu), Siluriformes (armored catfish), Cyprinodontiformes
(poeciliids or mosquitofish), Cypriniformes (carp or koi), and Synbranchiformes (rice paddy eel). Larvae of
Dussumieriinae (family Clupeidae) could not be determined as native or nonindigenous because of their
small size.
100
A total of 39 fish species were collected with 51 % native, 46% nonindigenous, and 3% cryptogenic. Fish
were found in salinities ranging from 0 to 37 ppt with fish species found in a wide range of salinities.
Important exceptions were the two species of nonindigenous South American armored catfish (Ancistrus
temminckii and Hypostomus cf. watwata), which were restricted to freshwater; and three poeciliids, Poecilia
reticulata (guppy), Xiphophorous helleri (green swordtail), and Xiphophorus maculatus (southern platyfish)
that were restricted to waters of <3.0 ppt salinity. A general but not significant (chi-square test) trend for the
percentage of native fish species to increase as salinities increased was observed, with areas of low salinity
containing fewer native species (Figure 4.3). Areas of completely freshwater contained relatively few native
species. Another introduced species, the fang-toothed blenny (Omobranchus ferox) was found in lower
Halawa Stream in areas having salinities of 35 ppt, and only in approximately 15 m of rocky mangrove
habitat.
• Nonindigenou5 o Native
100%
90%
80%12 9 6 14
50%
70%
0%
40%
30%
20%
10%
-c:
eQ)a.
I/)Q)
.(3
~ 60%(/)
'0
0-5 ppt 6-25 ppt 26-30 ppt > 30 ppt
Figure 4.3. Native or nonindigenous status of fish species and total numbers found at different salinitylevels in Pearl Harbor estuaries.
101
The large (> 30 ha) spring complex including Kalauao and Waiawa Springs had low salinity levels (1 to 4
ppt) and was almost entirely dominated by high densities of nonindigenous fish such as blackchin tilapia
(Sarotherodon melanotheron) and livebearers (Gambusia affinis, Poecilia latipinna, Poecilia mexicana, etc.).
Along with Waimano-Waiau Springs, the Waikele Springs area was completely freshwater (0 ppt salinity),
and no native fish species were observed in these areas.
The nonindigenous goby Mugilogobius cavifrons was abundant at most sampling stations. The native goby
A waous guamensis was observed or collected in low numbers at only two sampling areas: Waikele and
Waimalu Streams. Other native gobiid estuarine fish found include Oxyurichthys lonchotus, and
Stenogobius hawaiiensis. Eleotris sandwicensis was the most common native stream fish, occurring widely
in a variety of habitats. The endemic native gobiid Stenogobius hawaiiensis was less common and was
found in only 6 of the 15 sampling stations. Blackchin tilapia (Sarotherodon melanotheron) was the
dominant inshore fish, occurring in high densities at every sampling location. In many enclosed wetland
areas, such as at the Pearl Harbor National Wildlife Refuge, blackchin tilapia appeared stunted (only 7 to 10
cm in length but in breeding colors). In comparison, tilapia were generally larger in areas where they had
direct access to Pearl Harbor such as in Halawa Stream, and adults ranged in size from 20 to 30 cm.
Crustacean Species Composition
Twenty-six taxa were distinguished; all were identified to order but some could not be identified to species.
Of those identified to species level, 54% (14 species) were native, 19% (5) nonindigenous, and 27% (7)
cryptogenic. Nearly 60% were decapods, while isopods (15%) and amphipods (11 %) comprised the next
most abundant taxa. Less species-rich orders included mysids and copepods, although large numbers of
individuals of these orders were found in some sampling areas. The number of crustacean species found was
highest in Halawa Stream and lowest in Pouhala Marsh.
102
Native estuarine decapods that were abundant and found at most sampling sites included Periclimenes cf.
grandis, Pa1aemon debilis, and Tha1amita crenata; Macrobrachium grandimanus was relatively common but
was restricted to more freshwater habitats. Two nonindigenous species, Macrobrachium 1ar and Procambarus
clarkii, were also common and found exclusively in freshwater. Two isopod crustaceans were identified to
the species level, the endemic Ligia hawaiiensis, a common marine shoreline species, and Porcellio 1aevis,
a widespread nonindigenous species. A nonindigenous freshwater shrimp was identified as Neocaridina
denticu1ata sinensis, a subspecies previously known only from the Chinese mainland and Taiwan; it was
abundant in lower Waikele Stream in 1998 but absent from the same location in 1993 (Englund and Cai
1999).
Mollusk Species Composition
Sixteen species of mollusks were collected but these included no native freshwater or estuarine species.
Three (19%) of the 16 were native marine mollusks often found in estuarine regions; 10 (63%) were
nonindigenous freshwater/brackish species and three (19%) were cryptogenic species. Two of the
cryptogenic species could only be identified to the family level (Terebridae and Thiaridae), while an
undetermined bivalve was the third cryptogenic species.
The number of mollusk species found at each sampling site ranged from one species to a high of eight
species collected at Halawa Stream. Nonindigenous species predominated within all stream and estuary
areas, with the exception of two common native marine species (Cerithium nesioticum and Ceritihium cf.
zebrum) found in the lowest reaches of Halawa Stream. Two especially significant species of nonindigenous
snails were found. Apple snails (Pomacea canalicu1ata) were recorded for the first time in a Pearl Harbor
drainage (Lach and Cowie 1999). High densities of apple snails were also observed in taro fields in a spring
within 25 m of lower Waikele Stream; however, they were not observed in the stream channel. The
presence of apple snails so close to the stream (and in the floodplain) means that it is highly likely they
will soon be in Waikele Stream itself. A new Pacific Ocean record was also established for a species of a
103
hydrobiid snail, Pyrgophorus cf. coronatus, found in Pouhala Marsh and Waiawa Springs. The genus
Pyrgophorus originates in the Caribbean region, and these snails are found in fresh-to-brackish-marine
waters in streams and wetlands in their native regions (Cowie 1999). Pyrgophorus cf. coronatus was found
in water ranging from 1 to 9 ppt salinity and always on a silty mud bottom. Densities of this newly
introduced species were high, with numerous individuals incidentally captured in a single fish haul seine.
Miscellaneous Species
Three species of annelids, one species of cnidarian, one species of nematode, and one species of
platyhelminthes were also collected. Most of these species were collected from sediment samples taken with
an Ekman dredge, while leeches (Hirudinea), aquatic earthworms (Oligochaetes), and flatworms
(Platyhelminthes) were found during general collections. Nematodes were also found inside fish guts.
Because of the cosmopolitan nature of many of these sediment dwelling species, with two exceptions
(Eldredge and Miller 1997), their geographic status is uncertain. Myzobdella lugubris is known to be
nonindigenous; it was restricted to freshwater and was commonly observed attached to both native and
nonindigenous fish species. The indigenous leech Aestabdella abditovesiculata was also common, mainly
on marine fish.
DISCUSSION
Origins and Modes of Introductions of Nonindigenous Species Found in Pearl Harbor Estuarine Areas
Invasions in a number of other estuarine areas of the world have been examined, for example, San Francisco
Bay (Cohen and Carlton 1995; 1998), Chesapeake Bay (Smith et a1. 1999), and the Baltic Sea (Olenin and
Leppakoski 1999). High percentages of nonindigenous species were found in the San Francisco Bay area
(Cohen and Carlton 1995) similar to the findings of this study in the estuarine regions of Pearl Harbor.
However, most studies on the biodiversity of estuarine invasions have been in cool temperate regions, not
tropical waters as in the present study. Furthermore, the present study is a faunal wide assessment that
included aquatic insects, a major component of the estuarine biota that was not assessed in other estuarine
104
invasion studies. In the present study, 89 species of aquatic insects were recorded (native and introduced),
whereas insect invasions associated with or proximal to estuarine waters were not examined in other studies
(e.g., San Francisco Bay or the Hudson River (Mills et a1., 1996) (J. T. Carlton, pers. comm, September
2000), further limiting comparisons.
This study found that nonindigenous species comprise the dominant portion of the biota, and the lower
portions of Pearl Harbor streams, springs, and wetlands are now dominated by nonindigenous species. The
probable origins and mode of introductions of these established nonindigenous species are shown in Table
4.2, and only organisms identified to the species level were included in this table (76 species). Determining
the mode of transport of aquatic insects into Hawai'i is often difficult because of the inconspicuous nature
of both the insects and how they are introduced.
The Pearl Harbor area has grown from a small, shallow harbor in the early 20th century to a large military
port with adjacent civilian and military airports, with traffic arriving from all over the world (Coles et a1.
1997). No geographic region is a predominant source of aquatic species introductions into the Pearl Harbor
area (Table 4.2), although more species come from the Americas than other areas. For example, 57% (43
species) originated from the Americas, 30% (23) from Asia and the Pacific, 5% (4) from AustraliafNew
Zealand, 5% (4) have a world-wide distribution, and fewer than 3% (2) of species originated from Africa. It
is not surprising that these introductions come from a wide range of areas, and illustrates with modern
transportation how easily nonindigenous organisms become established in vulnerable insular tropical island
environments. The findings of this study further illustrate that Pearl Harbor is the "crossroads of the Pacific
Ocean" for nonindigenous species introductions Coles et ai. (1997).
Post-Introduction Spread of Nonindigenous Species in Lower Pearl Harbor Watersheds
It is highly likely that once an organism is introduced into a stream or adjacent wetland on O'ahu it will
spread to other aquatic habitats throughout the island, and potentially to the other Hawaiian Islands. The
105
nonindigenous goby Mugilogobius cavifrons was first observed in 1987 in Pearl Harbor (Randall et a1.
1993) and is now common in estuarine areas throughout windward and leeward O'ahu (Englund et al.
106
Table 4.2. Geographic source (year of introduction) and known (or probably known) mode of introduction ofnonindigenous species of aquatic macrofauna found in Pearl Harbor streams and estuaries.
TaxaAquatic Insects
Coleoptera-HydrophilidaeEnochrus sayi
Tropistemus lateralis humeralis
Tropistemus salsamentus
Coleoptera-Liminchidae
Parathroscinus cf. murphyi
Diptera- Canacidae
Canaceiodes angulatus
Procanace wi1liamsi
Diptera-Ceratopongonidae
Atrichopogon jacobsoni
Diptera-Chironomidae
Chironomus crassiforceps
Cricotopus bicinctus
Goeldichironomus holoprasinus
Diptera-Culicidae
Aedes albopictus
Diptera-Dolichopodidae
Chrysotus longipalpus
Condylostylus longicomis
Pelastoneurus lugubris
Syntonnon flexible
Tachytrechus angustipennis
Thinophilus hardyi
Diptera-EmpididaeHemerodromia stellaris
Diptera-Ephdridae
Brachydeutera ibari
Ceropsilopa coquilletti
Clasiopella uncinata
Discocerina mera
Donaceus nigronotatus
Ephydra milbrae
Hecamede granifera
Hydrellia willamsi
Lytogaster gravida
Mosi11us tibialis
Ochthera circularis
Paratissa pollinosa
PlacopsideIla marquesana
Psilopa girschneri
ScateIla stagnalis
Native Region(Year first released or found inHawaii)
Eastern North America (1931)
North America (Pacific Coast)
(1948)
North America (California) (1968)
Southeast Asia (1996)
N. and S. America- West Coasts
(1922)Oriental region? (1944)
Oriental and Pacific Regions (1958)
Oriental and Pacific Regions (1944)
Holarctic (1955)N. and S. America (1969)
Mexico (1826)
West Indies (1930)
Neotropics to French Polynesia(1996)
North America (1994)
Taiwan, Australia (1917)
N. and S. America (1993)
Australasia (1996)
Southwest United States (1982)
Oriental region? (1980)
Nearctic (1946)West Indies? (1946)
Pacific (1948)Oriental Region (1958)
North America (west coast) (1950)
Pacific Region (1923)Australia/New Zealand (1931)
North America (1937)
North America (1944)Oriental and E. Palaearctic (1982)
Neotropics (1945)
Pacific (1951)Holarctic (1952)
Holarctic (1946)
107
Mode of Introduction3
AirplaneAquarium Release or with Aquarium Plants
Ballast Water
Ballast Water
Cryptogenic (Unknown)
Airplane
Airplane
AirplaneAquarium Release or with Aquarium Plants
Cryptogenic (Unknown)
Ballast Water
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Airplane
Cryptogenic (Unknown)
Airplane
Cryptogenic (Unknown)
Cryptogenic (Unknown)Aquarium Release or with Aquarium PlantsCryptogenic (Unknown)
Cryptogenic (Unknown)Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)Cryptogenic (Unknown)
Cryptogenic (Unknown)
Mode of Introduction3
Taxa
Table 4.2 (cont.). Geographic source (year of introduction) and known (or probably known) mode ofintroduction of nonindigenous species of aquatic macrofauna found in Pearl Harbor streams and estuaries.
Native Region(Year first released or found inHawaii)
Diptera-Tethinidae
Tethina variseta
Diptera-Tipulidae
Stryringomyia didyma
Symplecta piIipes
Heteroptera-Corixidae
Trichocorixa reticulata
Heteroptera-Mesovellidae
Mesovelia amoena
MesoveIia mulsanti
Heteroptera-SaldidaeMicranthia humiIis
Odonata-Coenagrionidae
Enallagma civile
Ischnura posita
Ischnura ramburii
Odonata-LibellulidaeCrocothemis serviIia
Orthemis ferruginea
Trichoptera-Hydropsychidae
Cheumatopsyche anaIis
CrustaceansMacrobrachium lar
Neocaridina denticulata sinensis
Panopeus lacustris
Panopeus pacificus
Procambarus clarkii
MollusksCipangopaludina chinensis
Corbicula flurninea
Planorbella duryi
Pomacea canilliculata
FishesAncistrus cf. temminckii
Clarias fuscus
Colossoma macropomum1
Cyprinus carpio
Gambusia affinis
Hemichromis elongatus
Hypostomus cf. watwata
Limia vittata
Monopterus albus
Moolgarda engeIi
Mugilogobius cavifrons
Omobranchus ferox
North America (1946)
Australasia (1896)
Tropical Widespread species (1892)
N. and S. America (1878)
N. and S. America (1971)
N. and S. America (1933)
N. America (1988)
Western North America (1936)N. and Central America (1936)
North America (1973)
Middle East, Asia to Australia
(1994)
South America to Florida (1977)
Western North America (1965)
Guamrrahiti (1957)China-Taiwan (1991)
Northwest Atlantic (1947)
Philippines (1929)
North America (1923)
Southeast Asia (1900)
Asia (1981)
North America (1994)South America (1989)
South America (1985)
Asia «1900)South America (1987)
Asia «1900)Texas (1905)Africa (1991)
South America (1984)
Cuba (1950)
Asia « 1905)Marquesas (1955)Western Pacific (Japan to
Indonesia) (1987)South Pacific (Philippines toMadagascar) (1998)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Cryptogenic (Unknown)
Aquarium Release or with Aquarium Plants
Aquarium Release or with Aquarium Plants
Aquarium Release or with Aquarium PlantsAquarium Release or with Aquarium Plants
Airplane
Aquarium Release or with Aquarium Plants
Aquarium Release or with Aquarium Plants
Aquarium Release or with Aquarium Plants
IntentionlliFoodIntroductionAquarium Release or with Aquarium Plants
Ship fouling (hull or seachest)
Ship fouling (hull or seachest)
Intentional Food Introduction
Aquarium Release or with Aquarium Plants
Intentional Food Introduction
Aquarium Release or with Aquarium PlantsIntentional Food Introduction
Aquarium Release or with Aquarium Plants
Intentional Food Introduction
Aquarium Release or with Aquarium Plants
Intentional Food IntroductionIntentional Biocontrol
Aquarium Release or with Aquarium Plants
Aquarium Release or with Aquarium PlantsAquarium Release or with Aquarium Plants
Intentional Food Introduction
Accidentlli with Baitfish
Ballast Water
Ballast Water
108
Mode of Introduction3
Taxa
Table 4.2 (cont.). Geographic source (year of introduction) and known (or probably known) mode ofintroduction of nonindigenous species of aquatic macrofauna found in Pearl Harbor streams and estuaries.
Native Region(Year first released or found inHawaii)
Poecilia latipinna
Poecilia mexican!?
Poecilia reticulata
Tilapia (Sarotherodon)
melanotheron
Xiphophorus helleri
Xiphophorus maculatus
Amphibians
Bufo marinus
Rana catesbeiana
Rana rugosa
Texas (1905)
North America (1940-1950)
South America (1922)Africa (1951)
Central America (1922)
Central America (1922)
South America (1932)
North America (1902)
Japan (1896)
Intentional Biocontrol
Aquarium Release or with Aquarium Plants
Intentional BiocontrolIntentional Biocontrol
Intentional BiocontrolIntentional Biocontrol
Intentional Biocontrol
Intentional Biocontrol
Intentional Biocontrol
Percent (number)
25% (19)Summary of Introduction Pathways
Aquarium Release or withAquarium PlantsIntentional Biocontrol 12% (9)
Ballast Water 5% (4)Ship Fouling (hull or seachest) 3% (2)
Intentional Food Introduction 9% (7)
Accidental with Baitfish 1% (1)
Airplane 11% (8)
Cryptogenic (Unknown) 34% (26)
lBreeding populations of Colossoma macropomumnot yet known to be established, only large live adultsobserved. 2Poecilia mexicana possibly hybridized before introduced to Hawaii, however, the source of these fish isthought to be from Mexico or the southern U.S. Randall (1987) believed they were released before 1950, and thisprobably occurred after 1930's surveys conducted by G.B. Mainland (1939). \References: Van Dine 1907,Brock 1960, Edmondson 1962, Randall 1987, Evenhuis 1989, Devick 1991, Cowie 1997, Englund et al.2000a, Yamamoto and Tagawa 2000).
2000a). This small « 50 mm) estuarine goby species is cryptically colored and is not found in the
aquarium trade, nor used as a potential food source. It is likely only a matter of time before M. cavifrons
spreads to the other Hawaiian Islands. Aquarium observations of M. cavifrons also indicate this species is
carnivorous and will consume most prey items smaller than itself. The impacts of predation by M.
cavifrons on native biota are unknown, but the fact that it will prey on native species is cause for concern,
especially as it was much more abundant than any native stream goby. Also, a nonindigenous fang-toothed
blenny (Omobranchus ferox) first detected in the Hawaiian Islands during this study in 1998 had by 2000
spread 24 km away from Pearl Harbor (Yamamoto and Tagawa 2000). Sampling conditions in Pearl Harbor
were sometimes difficult, and poor water visibility and deep silt sometimes hampered fish collection efforts
in many areas, and partially saline conditions prevented the effective use of electrofishing. However, similar
109
to the native goby species, Mugilogobius cavifrons is cryptic and benthic in nature, and our routine capture
of this species but not A waous guamensis indicates gear limitations may not have been the reason that
native A waous guamensis were so uncommon during this study.
The introduced dragonfly Crocothemis servilia was first observed on O'ahu in 1994 (Polhemus 1995b) and
by 1999 had spread to the island of Kaua'i (Englund, personal observation). Nonindigenous aquatic insects
fIrst sighted in Pearl Harbor before spreading to other areas in Hawai'i include the non-biting midge
Chironomus crassiforceps first recorded in 1944 (Van Zwaluwenburg 1945), Cricotopus bicinctus first
recorded in 1955 (Hardy 1956), and the ephydrid flies Ephydra gracilis and Clasiopella uncinata, both first
recorded in 1946 (Wirth 1947; Adachi 1952). Cricotopus bicinctus is one of the most widespread aquatic
insect species in low-elevation areas in the Hawaiian Islands and now comprises a substantial portion of
invertebrate drift in Hawaiian streams (Englund et al. 2000b).
New Invasions Detected in this Study
An average of four species of terrestrial and aquatic snails became established, per decade, in Hawai'i during
the twentieth century (Cowie 1998). At least 58 species of freshwater organisms (excluding aquatic insects)
became established in the Hawaiian Islands from 1900 to 1991 (Devick 1991), i.e. nearly 6.4 species per
decade. The present study suggests that these trends are continuing. For example, three new nonindigenous
species colonized the lower Waikele Stream estuary area between 1993 and 1998: a dragonfly (Crocothemis
servilia), an atyid shrimp (Neocaridina denticulata sinensis), and the apple snail (Pomacea canaliculata). At
least two of these species, the atyid shrimp and apple snail could have colonized Pearl Harbor watersheds
through human-mediated actions, or perhaps through accidental transport by birds or flooding (Lach et al.
2000).
A species of African cichlid (Hemichromis elongatus), previously unknown in Pearl Harbor watersheds was
common in the lower portions of Waiawa Stream. A new and potentially harmful species of fish was found
110
during these surveys. Native to the Philippines and South China Sea region, the fang-toothed blenny
(Omobranchus ferox) appears to have recently become established in Pearl Harbor. Our collection of a wide
range of size classes indicates that it is successfully reproducing. In its native habitat in the Philippines,
Omobranchus ferox inhabits a wide range of shallow estuarine and freshwater habitats, ranging from
mangrove swamps to rivers and freshwater lakes (Springer and Gomon 1975). It thus represents a potential
threat not only to the ecologically similar indigenous Oxyurichthys lonchotus but also to other native
freshwater and estuarine fish and invertebrates.
The freshwater shrimp Neocaridina denticulata sinensis was found in high densities in the Waikele Springs
area. The finding of N d. sinensis on O'ahu is also the first Pacific Island record for this species. Unlike the
native freshwater atyid shrimp Atyoida bisulcata, N d. sinensis does not have an obligate marine phase
(Hung et a1. 1993) and is restricted to freshwater. Neocaridina denticulata sinensis could have spread into
separate watersheds by repeated human introductions, through flooding, or perhaps through other agents
such as birds. It is possible that N d. sinensis will compete for food and space with Atyoida bisulcata, as
they occupy similar habitats and have overlapping elevational distributions (Englund and Cai 1999). Its
native range includes Japan, Taiwan, the Ryukyu Islands, Korea, mainland China, and Vietnam (Hung et a1.
1993). Another new Pacific Island record was established for a species of hydrobiid snail, Pyrgophorus cf.
coronatus, that was found in several estuarine wetland areas. This species was found in high densities in
wetland habitats, and its impacts on native species are unknown.
The Distribution of Native versus Introduced Taxa
In high elevation areas, Pearl Harbor streams still contain significant reservoirs of native aquatic species, in
contrast to the dominance of nonindigenous species found during the present study of estuarine areas (Figure
4.4). That high-elevation reaches of Pearl Harbor watersheds are still relatively unimpacted by introduced
aquatic species may be attributed to a combination of factors including the lack of urbanization in upper
111
elevation areas, the lack of water diversions, or that invasive species may be more adapted to disturbed
conditions (Courtenay 1997) or may be more generalist in nature (e.g., Lach et al. 2000).
o Native. Nonindigenous • Cryptogenic
....ikete(480-490 m)
WlIike..(370-390m)
Hal_(290-315 m)
""'ik."(0-1 m)
HalllWll(0-1 m)
110 .,--------------------------,
100
90fJ)
~ 80Q)
[Ji 70
2 60c:~ 50~ 40
30
20
10
o
Figure 4.4. Native or nonindigenous status of aquatic insects at varying elevations on O'ahu: upper Halawadata from Polhemus (1994), upper Waikele data from Englund (1993).
The difference in the abundance of native species of aquatic insects between lower Waikele Stream (10%)
and Halawa Stream (38%) is of interest and may result from differences in salinity between the two sites.
Waikele Stream empties a large amount of water, whereas lower Halawa Stream is generally dry or contains
a minimal amount of waterflow. Halawa Stream is more marine in character (30 to 37 ppt salinity), and is
often intermittent in its lower reaches because of stream diversions. This is in contrast to a large freshwater
plume of <15 ppt salinity in Waikele Stream that extended well out into Pearl Harbor (Nance 1998). The
low salinity conditions in Waikele Stream may better foster biological invasions. This could be because
human-mediated introductions of freshwater organisms appear more likely to occur than marine ones. For
example, freshwater introductions, such as apple snails, the shrimp Neocaridina denticulata sinensis, or
112
aquatic insects coming in with aquarium plants, occur on a regular basis. It also may be that marine
environments are somewhat more resistant to invasions than freshwater environments, but the human factor
of introducing freshwater species for sport, through aquarium escapes, and for additional food sources is
more likely to be the case than with marine species. Although the freshwater areas surveyed in this study
contained relatively fewer native species than the more marine areas (Figure 4.3), this difference was not
statistically significant.
The native or nonindigenous status of many species of Hawaiian aquatic insect species in disturbed lowland
habitats such as Pearl Harbor is not yet known. For example, 20 species of aquatic Diptera (flies) could not
be identified to the species level, thus rendering determination of geographic origin impossible. The native
Hawaiian insect fauna in accessible lowland areas has been relatively well studied since the 1880s, starting
with early collectors such as Blackburn and Perkins (Liebherr and Polhemus 1997; Englund 1999), and it
would seem reasonable to assume that most native aquatic insect species in these lower elevation areas of
Pearl Harbor have been described. If it is assumed that most, if not all, cryptogenic aquatic insect species
found in Pearl Harbor are new introductions, then 75% of the aquatic insects found in Pearl Harbor estuarine
regions are nonindigenous species. Additionally, extensive surveys in upper elevation areas of the Hawaiian
Islands in the 1990s have generally yielded either known native and nonindigenous species, or undescribed
native species of aquatic insects (Evenhuis and Polhemus 1994; Evenhuis 1997b, Evenhuis 2000). For
example, only one cryptogenic aquatic insect was found during extensive surveys of the nearly pristine
stream systems in the upper Alaka'i plateau on Kaua'i between 1997 to 1999 (Englund et a1. 2000b).
Ecological Impacts of Invasions
The ecological impacts of invasions into Hawaiian estuarine and freshwater appear to be easily observable
in the field, for example, recovering only introduced blackchin tilapia and other introduced fish when seining
in a wetland. However, with the exception of the documentation of the extinction of certain taxa from these
habitats (Polhemus 1996; Englund 1999) no ecological data exist documenting these impacts; additionally,
113
the lack (or extirpation) of native species in these areas also currently makes establishing cause and effect
difficult. Recent food introductions, such as the apple snail and Asiatic clam (Corbicula fluminea) (Eldredge
1994), are now causing great ecological and economic damage. Apple snails (Pomacea canaliculata), first
introduced illegally as a food source in 1989, are now a major pest threatening the cultivation of an
important Hawaiian staple food, taro (Cowie, in press). The Asiatic clam has caused enormous economic
losses on the u.s. mainland similar to those caused by zebra mussel infestation of the Great Lakes (U.S.
Congress 1993). In Hawai'i, Asiatic clams have clogged irrigation pipes with resulting economic damage in
Maui and elsewhere (Devick 1991). The ecological impacts of these species on native aquatic biota are
unknown. Blackchin tilapia (Sarotherodon melanotheron) were first introduced in 1951 for aquatic weed
control and as baitfish, and may impact the abundance and distribution of native Hawaiian waterbirds by
leaving little invertebrate forage for them, although no studies exist demonstrating these impacts.
Aquarium trade and subsistence food introductions are some of the most serious threats facing native aquatic
species in Hawai'i, with ballast water and hull fouling representing another potential introduction pathway,
although only 6 (8%) of the 76 species listed in Table 4.2 are considered likely to have come from the latter
sources. Since 1987, for example, a goby (Mugilogobius cavifrons), the fang-toothed blenny (Omobranchus
ferox), and the small mangrove mudflat beetle (Parathroscinus ef. murphyl) were all first observed or
collected in Pearl Harbor. None of these small species are food introductions, and all of these species are
also unlikely aquarium introductions.
Evidence For Extirpation or Reduction of Native Biota
Poecilia latipinna, Fundulus grandis, and Gambusia affinis were the first recorded introductions of
nonindigenous species into Pearl Harbor waters (Van Dine 1907), although unrecorded aquatic species
introductions undoubtedly occurred earlier. Native damselflies (Megalagrion spp.) were formerly common in
the Pearl Harbor area (Polhemus 1996; Liebherr and Polhemus 1997) but are now absent. Poeciliid fish
114
may be a major cause of the extinction of Megalagrion damselflies in low-elevation areas of Hawaiian
streams and wetlands (Englund 1999).
The well-documented loss in Pearl Harbor of major taxa such as the native damselflies suggests that much
has changed because of nonindigenous species introductions. Although habitats have been changed because
of urbanization in this watershed, large amounts of brackish to freshwater spring and wetland habitats still
remain yet are dominated by alien species. With the exception of a few taxa such as the native damselflies,
little information can be found on conditions in Pearl Harbor prior to the massive influx of nonindigenous
species into the freshwater to estuarine areas that started in the early part of the 20th century. Other native
groups that have apparently been lost from Pearl Harbor but are not as well documented include the water
bugs in the family Saldidae, aquatic beetles (Coleoptera), and freshwater mollusks; none were found during
this study. For example, Saldidae are some of the most common native aquatic insects in the Hawaiian
Islands, with as many as three native species found in a single stream (Polhemus 1995a). However, in the
lower areas of Pearl Harbor streams and wetlands only the nonindigenous saldid Micracanthia humilis was
found. Four species of introduced aquatic beetles were found during this study, but none of the 9 native
species (Nishida 1997) were collected.
The decline of native species in Pearl Harbor will likely continue as more introductions occur. The decline
will also be influenced by the environmental degradation that has occurred, which provides more favorable
habitat for invading aquatic species than for native species. The low percentage of native aquatic insects, the
absence of native freshwater mollusks, and the scarcity of native fish in the lower stream regions are
evidence of this decline. There are no comparable studies of other large Hawaiian estuarine systems, so it is
not possible to ascertain whether this is an archipelago wide trend, or a phenomenon restricted to Pearl
Harbor. However, it is likely that most Hawaiian estuaries have experienced similar alterations in the
composition of native aquatic fauna, as most of the introduced species found in this study are vagile, and as
115
discussed earlier, many species first recorded in Pearl Harbor have now spread to other areas of O'ahu and
throughout the Hawaiian Islands.
116
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124
CHAPTER 5. FLOW RESTORAnON AND PERSISTENCE OF INTRODUCED SPECIES IN WAIKELE
STREAM,O'AHU
125
ABSTRACT
Unintentional stream flow restoration in Waikele Stream, O'ahu, Hawai'i resulted from the demise of sugar
cane cultivation on O'ahu and subsequent cessation of direct surface water diversions in 1989. Previous
artificial stream studies in Hawai'i have suggested that increases in the base flow of a diverted stream would
displace or reduce introduced fish populations. Surveys of Waikele Stream, conducted in 1993 and 1997
1998 from the Waikele Springs area downstream to the beginning of the tidal reach found that despite an
increase in stream flow, introduced fish remained abundant and native species appeared to have declined. In
fact, two new introduced aquatic taxa, a dragonfly and a shrimp, had appeared. These results indicate that
although restoring hydrological conditions is an important first step in overall restoration of degraded
aquatic ecosystems, flow restoration alone is not a panacea, especially in O'ahu streams with naturally low
discharge rates. For stream and wetland restoration to fully succeed, introduced fish and other alien aquatic
species must be eradicated by methods other than simply increasing stream base flows.
INTRODUCTION
Hawaii has a significant and endemic freshwater fauna that is now seriously threatened. Native Hawaiian
stream animals have been adversely affected by the accelerated introduction of non-native species (Devick
1991a), urban development, stream diversions, and stream channelization (Norton et al. 1978, Timbol and
Maciolek 1978). In O'ahu streams, escaped ornamental species are increasingly displacing native organisms.
Although the adverse effects associated with introduced freshwater species have been well documented in the
Pacific region (Maciolek 1984, Arthington & Lloyd 1989, Crowl et al. 1992, Eldredge 1994), reliable
solutions to the problem have not been developed. The Hawaii Division of Aquatic Resources has attempted
to limit the spread of new introductions through educational advertisements in the media on the harmful
effects of introduced species. However, limited efforts have been made to decrease the effects of introduced
species already in Hawaiian streams, and success in eliminating or reducing introduced fish in freshwater
habitats in Hawai'i has been equivocal.
126
One method, currently under discussion, to reduce the numbers of introduced species in Hawaiian streams
involves restoring water flow to natural levels through the removal of agricultural water diversions. Flow
restoration has been suggested as an effective way of eliminating or reducing the abundance of introduced
animals in historically diverted Hawaiian streams (Fitzsimons & Nishimoto 1996, Fitzsimons et a1. 1997).
These results were based on laboratory studies conducted in artificial streams. However, it is not obvious
how applicable the artificial stream results are to field situations, such as unchannelized streams.
Increases in water velocity associated with increases in flow are believed to displace non-native organisms
that have evolved in slow-water environments (Fitzsimons et a1. 1997). An obvious problem with this
argument, however, is that regardless of flow regime, a stable unchannelized stream will always contain
some slow-water habitats (Platts et a1. 1983, Helm et a1. 1985). In this study we examine Waikele Stream,
an O'ahu catchment that was diverted from prior to 1931 until 1989. Species composition was assessed in
this stream four and nine years after the cessation of large-scale agricultural water diversions in 1989. The
purpose of this study was to document species composition of native and introduced aquatic animals in the
area downstream of a hydrologically restored O'ahu stream, and to assess the success of flow restoration in
regard to the removal or reduction of introduced species.
STUDY AREA
Waikele Stream drains the leeward slope of the Ko'olau Mountains and the windward slope of the Waianae
Mountains in central O'ahu. From its origin in the Ko'olau range, the stream flows for 28 Ian to Pearl
Harbor. The Wai'anae Mountain tributaries ofWaikele Stream are intermittent, and flow only following
heavy rains. The main channel of Waikele Stream consists of alternating sections of flowing and dry stream
except during and after periods of heavy precipitation. This is a natural condition caused by percolation of
water into the alluvium. Flow is perennial only in the Ko'olau Mountain headwaters and near the mouth in
the area of Waikele Springs. As in many O'ahu streams, streamflow is characteristically flashy, with high
flood peaks and low baseflows (Nichols et a1. 1997).
127
The study area extended from approximately 250 m above Waikele Springs to a concrete weir spanning
lower Waikele Stream 1.3 km downstream of the springs (Figure 5.1). This weir completely separates
Figure 5.1. Waikele Stream study area.
freshwater from the tidal reach on the downstream side, and the difference in stream levels can range from 1
1.5 m (Nance 1998). The terminal reach ofWaikele Stream is mainly fed by a series of large basal springs
that are collectively called Waikele Springs. Waikele Springs issue from low points in the cap rock that
release groundwater (Stearns and Vaksvik 1935). At base flow, Waikele Springs contribute approximately
80% of the water to the lower Waikele Stream (Nance 1998).
128
Unintentional stream flow restoration resulted from the demise of sugar cane cultivation on O'ahu and
subsequent cessation of direct surface water diversions in 1989, and groundwater well pumping between
1994 and 1995 (Nance 1998). The earliest recorded diversion ofWaikele Springs was conducted in 1931 by
the 0' ahu Sugar Company and consisted of 0.1 m3Is (Stearns & Vaksvik 1935). Although it is known that
diversions occurred prior to 1931, records are not available for these early diversions. From 1951 to 1989
flow diversion averaged 0.19 m3/s (Nance 1998). Diversions greater than 0.6 m3/s frequently occurred during
droughts. Direct diversions from the Waikele Springs ceased in July 1989. The last groundwater pumping
that could have affected flow in the Waikele Springs occurred in 1995 (Nance 1998). It is not known to
what extent these wells affected Waikele Stream flow, but it appeared to be insignificant compared to direct
diversions that occurred prior to 1989 (T. Nance, personal communication, 1998).
During this study, habitat downstream of the Waikele Springs input consisted of high-velocity runs (0.3
0.6 m in depth) connecting shallow pools (0.2 -0.6 m in depth) with stream widths of 4-8 m. Unlike many
low-elevation sections of O'ahu streams, Waikele Stream is not lined with concrete or channelized in the
area ofWaikele Springs. The natural stream channel is maintained from above Waikele Springs downstream
for 1.3 km until the stream is impounded by the concrete weir.
METHODS
Stream animals were sampled during two periods: March 1993, and December 1997 to April-August 1998.
Sampling effort in 1997 and 1998 was close enough in time to be considered one sampling period. In 1993,
sampling methods consisted of snorkeling, netting, and above-water observations. Quantitative fish
sampling was not conducted in 1993, but relative abundance and fish species composition were noted. In
1998, one quantitative seine haul was used to characterize the relative abundance of introduced fish
immediately below Waikele Springs.
129
A fine-mesh, 5 m long seine was used to sample stream animals and assess species composition.
Snorkeling and above-water observation were also used, especially in fast-water habitats. During both
periods aquatic insect collection focused on dragonflies and damselflies (Odonata). Odonata were captured
with both aerial and dip nets, and dip nets were also used to sample areas not accessible to seines. Water
velocity was measured with a Swoffer 2100 current meter in the main channel downstream of Waikele
Springs. Velocity measurements were collected at 0.6 to 1.2 m intervals along transects that were
perpendicular to stream flow. Three transects were established in areas of relatively laminar flow: 4, 18, and
33 m downstream of the beginning of the Waikele Springs input. Water velocities were measured at the
water's surface and six tenths of total stream depth below the stream surface. The latter measurement
location corresponds to the location of average water velocity in an ideal channel (Nielsen & Johnson
1983).
Sampling effort in March 1993 consisted of approximately 50 hours of observations and organism
collection in the study area. In 1997-1998, sampling effort increased to approximately 100 hours, with
similar proportions of time spent snorkeling and netting. In both sampling periods observations were also
made directly below the weir.
RESULTS
Water velocity measurements for each transect are shown in Table 5.1. In 1998, relatively high average
water velocities were encountered downstream of the restored Waikele Springs. Water velocities as low as
10 cm/s were recorded near the streambanks.
In 1997-1998, two previously unrecorded introduced species were collected in Waikele Stream (Table 5.2).
Only three of the five freshwater fish species known from Hawaiian streams (Stenogobius hawaiiensis,
A waous guamensis, and Eleotris sandwicensis) were captured. Most observations of native fish species
130
Table 5.1. The range and mean water velocities (:I: standard error) recorded in transects downstream ofWaikele Springs.
Distance from start of restoredWaikele Springs outlet
(stream width-m)4 m (7.9 m wide)
18 m (7.0 m wide)
33 m (5.2 m wide)
Surface Velocity(range-cm/s)
10-67
25-9210-80
Mid-Channel Velocity(range-cm/s)
10-67
16-9313-65
Mean Mid-ChannelVelocity (cm/s)
33 :t 752 :t 748 :t 6
occurred in the tidal reach below the 1.5 m high concrete weir in lower Waikele Stream. Native fish such as
Kuhlia sandvicensis, Mugil cephalus, and Eleotris sandwicensis, were common but found only downstream
of this weir which precluded their upstream movement. The weir did not prevent upstream movement by
native stream gobies. However, neither Sicyopterus stimpsoni nor Lentipes concolor were encountered
during this or previous surveys.
The stream gobies A. guamensis and S. hawaiiensis appear to have declined since 1993 in the study area. In
1993, high densities of post-larvae of both of these species were observed and collected below the weir
(Figure 5.1). Although adults of both of these species were observed in 1998, post-larvae were not observed
in that same location during extensive sampling conducted in 1997-1998. While not common, S.
hawaiiensis was collected both up and downstream in the vicinity of the weir, but was not observed
upstream near Waikele Springs in 1998, in contrast to 1993. Despite greater sampling effort than in 1993,
only a few A. guamensis were observed just below the concrete weir in 1997-1998. Additionally, native
fish were not observed in the vicinity of Waikele Springs in 1998, despite intensive sampling effort. In
1993, native gobies were common at the Waikele Springs area, with 12 A. guamensis in a wide range of
size classes netted, including relatively recent recruits as small as 24 mm total length (Englund 1993).
131
Table 5.2. Introduced and native species found in Waikele Stream, Oahu in 1993 and 1997-1998 from 250m above Waikele Springs downstream to concrete weir. Oahu introduction dates from Beardsley (1980),Devick (1991a), Cowie (1995), Polhemus & Asquith (1996), Randall (1996), Cowie (1998).
Taxon 1993 1998Biogeographic Status Year of Oahu Introduction
or Discovery
192319571991
19941977
198819901856
197319361936
1955198519511922196019051922
IndigenousEndemicEndemic
IntroducedEndemic
IndigenousIntroducedIntroducedIntroducedIntroducedIntroducedIntroducedIntroduced
IntroducedIntroducedIntroducedIndigenousIndigenous
New IntroductionIntroduced
EndemicIntroducedIntroduced
New Introduction
IntroducedNew Introduction!
Introduced
XXX
XXXXXXX
XXXX
XXXXXXXXXXXXX
X
XX
X
X
XX
XXX
XXXXXXXXXXXXX
FishA waous guamensisStenogobius hawaiiensisE1eotris sandwicensisMugi1ogobius cavifronsKuh1ia sandvicensisMugil cepha1usMoo1garda engeliAncistris cf. temminckiiSarotherodon me1anotheronPoecilia reticu1ataPoecilia mexicanaGambusia affinisXiphorphous helleri
CrustaceansMacrobrachium grandimanusProcambarus c1arkiiMacrobrachium 1arNeocaridina denticu1ata
MollusksCorbicu1a flumineaPomacea canalicu1ataTarebia granifera
Damselflies/dragonflies (Odonata)Ischnura ramburiiIschnura positaEnallagma civilePantala flavescensAnaxjuniusCrocothemis serviliaOrthemis ferruginea
AmphibiansBufo marinus X X Introduced 1932Rana catesbeiana X X Introduced 1867
!Apple snails not directly found in stream, but in taro fields 25 m away from stream channel
132
Introduced fish were common throughout the study area. Tilapia (Sarotherodon melanotheron) were found
both upstream and downstream of Waikele Springs. Bristle-nosed or armored catfish (Ancistris cf.
temminckiI) were extremely abundant in runs and riffles downstream of Waike1e Springs. Two species of
alien fish known to inhabit lower Waikele Stream, Chinese catfish (Clarias fuscus) and the rice paddy eel
(Monopterus albus) (Hawaii Division of Aquatic Resources, personal communication, 1998), were not
observed at this location in 1993 or 1997-1998. This is likely due to their wariness, or to gear limitations,
since electrofishing is the most effective means of sampling these species.
As in 1993, large numbers of introduced poeciliids such as Gambusia affinis, Poecilia mexicana, P.
reticulata, and Xiphophorus helleri were observed in the Waikele Springs area downstream to the tidal reach.
Densities of poeciliids remained high in 1997-1998. Using a haul seine (in a pool) in 1998 we found
densities of 2.2/m2 for G. affinis, 1.5/m2 for P. reticulata, 0.4/m2 for P. mexicana, and O.2/m2 for X.
helleri, for a total of 4.3/m2 for all poeciliids combined.
Introduced dragonflies and damselflies dominated the aquatic insect fauna of Waikele Stream. All damselfly
species were introduced (Table 5.2). Native Megalagrion damselflies were not observed in lower Waikele
Stream in 1993 or 1998. The indigenous dragonfly Anaxjunius was common around Waikele Springs, and
the introduced dragonfly Crocothemis servilia was absent in 1993, but common in 1998.
The introduced freshwater shrimp, Neocaridina denticulata sinensis, was abundant in 1998 but was not found
in 1993. Introduced apple snails (Pomacea canaliculata) were observed in taro fields in a separate and lower
spring area that is adjacent to the weir below Waikele Springs. This area was within 25 m of the stream,
but apple snails were not observed within the stream channel.
133
DISCUSSION
In the last five years, two new species, a dragonfly and a shrimp, have become established in lower Waikele
Stream, and an additional species of introduced aquatic snail was found within 25 m of the stream. At the
same time, native stream animals have become less common despite flow restoration.
The dragonfly C. servilia was fIrst collected around taro fields in Waiahole Stream, O'ahu in 1994
(Polhemus 1995). The rapid spread of this dragonfly across O'ahU was expected because of its vagility, thus
its appearance at Waikele Stream is not surprising. Moreover, this dragonfly is suited to the disturbed,
lowland aquatic habitats common on O'ahu. The long-term effects of this introduced dragonfly on native
aquatic organisms are unknown. However, its distribution overlaps with the native dragonfly Anaxjunius,
suggesting a potential for negative interactions.
The freshwater shrimp, N. denticulata sinensis, was probably introduced to O'ahu streams as an escaped or
released ornamental species. Its native range includes Taiwan, the Ryukyu Islands, Korea, mainland China,
and Vietnam (Hung et a1. 1993). Recently this species has been found in several widely separated windward
and leeward O'ahu streams (Devick 1991b). However, the Waikele record is the fIrst time it has been found
in a Pearl Harbor stream. Previously this shrimp was incorrectly identified from Nu'uanu Stream, O'ahu, as
Caridina weberi (Devick 1991b). It is possible that N. denticulata sinensis could compete with the native
atyid shrimp Atyoida bisulcata.
High densities of adult and immature apple snails were seen in an area of taro fields less than 25 m from
Waikele Stream and within the floodplain. The presence of apple snails within 25 m of the stream means
that it is highly likely they will soon be in Waikele Stream itself.
Introduced poeciliids were abundant in the unchannelized and restored flow areas of Waikele Stream. Total
poeciliid densities in Waikele Stream were equal to or greater than those found in other similarly degraded
134
O'ahu streams. For example, poeciliid densities in low elevation areas of Kawa Stream (0-1.5 m above sea
level) ranged from 1.6 to 2.9Im2 (Filbert and Englund 1995), compared to 4.3/m2 found in Waikele Stream.
The high poeciliid densities appear not to support predictions made from artificial stream research. Using
species found in Hawai'i, Fitzsimons et a1. (1997) found strong water flows displaced introduced poeciliids
in an artificial stream, and then applied these displacement velocities to natural stream channels. Fitzsimons
et a1. (1997) concluded that, " ... a stream with a base flow of 20 em/second or greater will be ideal for native
fishes and will eliminate or at least suppress non-native poeciliids and the copepod [parasite] intermediate
hosts ... ". Water velocities in the restored Waikele Stream ranged from 33 to 52 em/second (Table 5.1).
Although the average mid-column and surface water velocities in Waikele Stream (below Waikele Springs)
now far exceed 20 cm/s, poeciliids and other alien fish remain abundant in areas of high water velocities.
Armored catfish (A. cf. temminckil} appear to preferentially select areas of highest water velocities, and
were less common in pool habitats. The likely reason that introduced poeciliids were not displaced by the>
20 cm/s water velocities in Waikele Stream may be due to the habitat complexity found in natural,
unchannelized streams. Large rocks, downed trees, side channels, and aquatic vegetation all offer a velocity
refuge to introduced fish (such as poeciliids or tilapia) which favor slower water velocities than do the native
stream gobies. Additionally, many O'ahu streams are small, and naturally have low water velocities at the
stream mouth or in other low-elevation sections of the stream.
The negative effects of introduced poeciliids on other vertebrates and invertebrates have been widely
documented (Hurlbert et a1. 1972, Meffe & Snelson 1989). For example, G. affinis_prey upon eggs, larvae,
and fry of sportfish and native fish in areas outside of their native habitat (Courtenay & Meffe 1989).
Predation by introduced poeciliids was believed to be a significant cause of extirpation of native fish in
Nevada (Courtenay & Meffe 1989) and invertebrates in Australia (Arthington & Lloyd 1989). In south
western Australia, Morgan et a1. (1998) found fin nipping by G. affinis holbrooki, the eastern
mosquitofish, caused extensive caudal fin damage to native fish species.
135
The persistence of poeciliids in Waikele Stream after flow restoration will also likely prohibit the
recolonization of this area by native stream breeding Megalagrion damselflies. Polhemus & Asquith (1996)
believed the presence of introduced poeciliids was responsible for the absence of native Megalagrion species
in areas where they co-occurred. These authors found a complete absence of native damselflies in low
elevation areas similar to Waikele Stream where introduced poeciliids were found.
Additionally, bristle-nosed catfish densities were high, and may also be contributing to the absence of A.
guamensis in the study area in 1998. Native stream gobies are undoubtedly adversely affected by loricariid
catfish through competition for food and space. The species of loricariid catfish found on 0'ahu are
primarily algivores, but will also readily consume fish eggs (1. Armbruster, personal communication,
1998). Native stream gobies are rare in low elevation areas of O'ahu streams containing very high densities
of introduced armored catfish (Kawa Stream, Filbert & Englund 1995; Manoa Stream, Bishop Museum
unpublished database).
Flow restoration between 1989 and 1998 appears to have had little beneficial effect on native stream
animals. Our surveys in 1993 and 1997-1998 indicate native animals are rare to non-existent and introduced
species are more abundant. This suggests that elements other than flow may be important to the
rehabilitation of native stream communities in Hawai'i. However, there may be situations in which flow
restoration alone has had a beneficial effect on native organisms. Flow restoration in an unnamed stream at
TripIer Army Medical Center (O'ahu) led to an increased abundance of a rare native damselfly (Megalagrion
xanthomelas). After ten months of flow restoration, adult damselfly observations increased from 17 to 162
adults per monitoring period (Englund 1998). The absence of introduced fish in this stream likely explains
the success of flow restoration in this case. In the presence of an introduced fish damselfly abundance would
likely not have increased (Polhemus & Asquith 1996).
136
The results of this study corroborate other field observations that flow restoration alone will not reduce the
numbers of alien species. On O'ahu, recovery of native freshwater vertebrates and invertebrates will not
occur until it is understood that alien species now dominate the system in low elevation aquatic habitats.
For stream and wetland restoration to succeed, introduced fish and other harmful aliens must first be
eradicated. Introduced poeciliids occur in almost every major wetland in the Hawaiian archipelago. Even if it
were possible to flush introduced fish out of an Hawaiian stream, adjoining wetlands or side-channel
habitats would still provide low velocity refugia. This would limit the recolonization of streams by native
aquatic insects such as Megalagrion damselflies.
Introduced freshwater fish now occur in many parts of the world, including Australia, New Zealand, and on
most Pacific islands with freshwater habitats (Maciolek 1984, Eldredge 1994). They threaten the
biodiversity of aquatic ecosystems throughout the Pacific region. Restoring hydrological conditions is an
important first step in restoring degraded aquatic ecosystems but flow restoration is not a panacea, especially
in areas having streams with a naturally low baseflow discharges such as those on O'ahu. To preserve
native fish and invertebrate biodiversity in Hawai'i and the Pacific region, creative management solutions
must be found, including the elimination of introduced species. Every step should also be taken to ensure
that new species introductions do not occur in pristine aquatic habitats.
137
REFERENCES
Arthington, A H. and L. N. Lloyd. 1989. Introduced Poeciliids in Australia and New Zealand. In G.K.
Meffe and F.F. Snelson, Jr. (eds.), Ecology and evolution of livebearing fishes (Poeciliidae), pp.
333-348. Prentice Hall.
Beardsley, 1. W. 1980. New record of Orthemis ferruginea (Fabricius) from Oahu. Proceedings of the
Hawaiian Entomological Society 23: 83.
Courtenay, WK, & G.K. Meffe. 1989. Small fishes in strange places: a review of introduced poeciliids.
In: G.K. Meffe and F.F. Snelson, Jr. (eds.), Ecology and evolution of livebearing fishes
(Poeciliidae), pp. 319-331. Prentice Hall.
Crowl, T. A, A R. Townsend and A. R. McIntosh. 1992. The impact of introduced brown and rainbow
trout on native fish: the case of Australasia. Reviews in Fish Biology and Fisheries 2: 217-241.
Cowie, R. H. 1995. Identity, distribution and impacts of introduced Ampullariidae and Viviparidae in the
Hawaiian Islands. Journal ofMedical and Applied Malacology 5: 61-67.
Cowie, R. H. 1998. Patterns of introductions of non-indigenous non-marine snails and slugs in the
Hawaiian Islands. Biodiversity and Conservation 7: 349-368.
Devick, W. S. 1991a. Patterns of introductions of aquatic organisms to Hawaiian freshwater habitats. In:
New directions in research, management, and conservation of Hawaiian freshwater stream
ecosystems, Proceedings ofthe 1990 Symposium on Freshwater Stream Biology and
Management, State of Hawaii, pp. 189-213. Hawaii Division of Aquatic Resources.
138
Devick, W. S. 1991b. Job progress report F-14-R-15 [Fresh water fisheries and surveys]. Disturbances and
fluctuations in the Wahiawa Reservoir Ecosystem. Hawaii Division of Aquatic Resources.
Eldredge, L. G. 1994. Perspectives in aquatic species management in the Pacific islands. Volume 1,
introductions of commercially significant aquatic organisms to the Pacific Islands. South Pacific
Commission, Noumea, New Caledonia. 127 pp.
Englund, R. A. 1993. A survey of the fish and aquatic insect fauna of the Waikele/Kipapa streams, Oahu,
Hawaii. BHP Environmental Technologies report prepared for Halekua Development Corp.,
Honolulu. 20 pages.
Englund, R. A. 1998. Response of the Orangeblack Hawaiian Damselfly (Megalagrion xanthomelas), a
Candidate Threatened Species, to increases in stream flow. Bishop Museum Occasional Papers 56:
19-24.
Filbert, R. B. and R. A. Englund. 1995. Assessment of the freshwater macrofauna of Kawa Stream, Oahu.
Pacific Aquatic Environmental report prepared for Pacific Atlas Hawaii, Inc. 19 pages.
Fitzsimons, J. M. and R. T. Nishimoto. 1996. Recovery of three Kauai streams from Hurricane Iniki and
implications for the restoration and regeneration of freshwater ecosystems in Hawaii. In: Will
Stream Restoration Benefit Freshwater, Estuarine, and Marine Fisheries? Proceedings of the
October 1994 Hawaii Stream Restoration Symposium.
Fitzsimons, J. M., H. L. Schoenfuss, & T. C. Schoenfuss. 1997. Significance of unimpeded flows in
limiting the transmission of parasites from exotics to Hawaiian stream fishes. Micronesica 30:
117-125.
139
Helm, W. T., P. Brouha, M. Aceotima, C. Armour, P. Bisson, J. Hall, G. Holton, & M. Shaw. 1985.
Glossary of stream habitat terms. Western Division, American Fisheries Society. 34 pp.
Hung, M. S., T. Y. Chan, & H. S. Yu. 1993. Atyid shrimps (Decapoda: Caridea) of Taiwan, with
descriptions of three new species. Journal ofCrustacean Biology 13: 481-503.
Hurlbert, S. H., J. Zedler, & D. Fairbanks. 1972. Ecosystem alteration by mosquitofish (Gambusia afflnis)
predation. Science 175: 639-41.
Maciolek, J. A. 1984. Exotic fishes in Hawaii and other islands of Oceania. In: W.R. Courtenay, Jr. and
J.R. Stauffer, Jr. (eds.), Distribution, biology, and management of exotic fishes, pp. 131-161.
Johns Hopkins University Press, Baltimore.
Meffe, G. K. & F. F. Snelson. 1989. An ecological overview of poeciliid fishes. In G.K. Meffe and F.F.
Snelson, Jr. (eds.), Ecology and evolution of livebearing fishes (Poeciliidae), pp. 13-31. Prentice
Hall.
Morgan, D. L., H. S. Gill, & I. C. Potter. 1998. Distribution, identification and biology of freshwater
fishes in south-western Australia. Records of the Westem Australian Museum (supplement 56) 97
pp.
Nance, T. 1998. Effect of the proposed use ofthe WP-18 pump station on Waikele Stream and West Loch.
Tom Nance Water Resource Engineering, 680 Ala Moana Boulevard, Suite 406. 39 pages +
appendices.
140
Nichols, W. D., Shade, P. J. & C. D. Hunt, Jr. 1997. Summary of the Oahu, Hawaii, regional aquifer
system analysis. U.S. Geological Survey Professional Paper 1412-A. 61 pp.
Nielsen, L. A., & D. L. Johnson. 1983. Fisheries Techniques. American Fisheries Society. 468 pp.
Norton, S. E., Timbol, A. S., & J. D. Parrish. 1978. Stream channel modification in Hawaii. Part B:
effect of channelization on the distribution and abundance of fauna in selected streams. FWS/OBS
78117. USFWS National Stream Alteration Team, Columbia, Missouri. 47 pp.
Platts, W. S., Megahan, W. E, & G. W. Minshall. 1983. Methods for evaluating stream, riparian, and
biotic conditions. Intermountain Forest and Range Experiment Station. U.S. Forest Service,
Ogden, Utah. 70 pp.
Polhemus, D. A. 1995. New Heteroptera and Odonata (Insecta) records and range extensions in the Hawaiian
Islands. Bishop Museum Occasional Papers 42: 42-43.
Polhemus, D.A. & A. Asquith. 1996. Hawaiian damselflies: a field identification guide. Bishop Museum
Press. 122 pp.
Randall, J.E. 1996. Shore Fishes of Hawaii. Natural World Press. 216 pp.
Stearns, H. T., and K. N. Vaksvik. 1935. Geology and ground-water resources of the island of Oahu,
Hawaii. Territory of Hawaii, Department of Public Lands, Division of Hydrography, Bulletin 1,
479 p.
141
Timbol S. A. and J. A. Maciolek. 1978. Stream channel modification in Hawaii, Part A: Statewide
inventory of streams, habitat factors and associated biota. FWS/OBS-78-16. USFWS National
Stream Alteration Team, Columbia, Missouri. 157 pp.
142
CHAPTER 6: INVASIVE SPECIES THREATS TO NATIVE AQUATIC INSECT AND ARTHROPOD
BIODIVERSITY IN HAWAI'I, THE PACIFIC AND OTHER RELEVANT AREAS WITH DISCUSSION
OF CONSERVATION MEASURES
INTRODUCTION
143
The conservation status of the native aquatic insect faunas of tropical insular regions, especially in highly
diverse groups such as Odonata, Diptera, and Heteroptera, is poorly known. A notable exception is Hawai'i,
where extinctions in some groups have been documented (Liebherr and Polhemus 1997; Englund 1999).
Restricted habitats, small population sizes, and a lack of defenses against invasive species make tropical
insular species especially vulnerable to disturbance and extinction (Simberloff 1986, 1995; Paulay 1994).
Conservation biologists working on isolated oceanic islands such as Hawai'i and other areas of Polynesia
have long recognized that introduced species represent the most pervasive and persistent threat to the
survival of these insular biotas (Elton 1958, Vitousek 1988; Meyer and Florence 1997; Loope et aI. 2001;
Staples and Cowie 2001). Within the Pacific region, the Hawaiian Islands have received the greatest amount
of attention related to the spread of invasive species and their impacts on native aquatic biota (Eldredge
1994), although a few other tropical regions including Fiji (Andrews 1985), French Polynesia (Polhemus et
a1. 2000; Keith et a1. 2002; Englund 2003) and New Caledonia (Gargominy et a1. 1996; Marquet et aI.
2003) have had limited research devoted to this problem. This review assesses the susceptibility of native
arthropods to invasive species in island or island-like environments. A brief review of the impacts of
invasive species on native insects in other tropical and temperate warm regions is provided, as well as a
synthesis of the invasive species problem facing freshwater insects and other terrestrial arthropods in
Hawai'i, the Pacific, and other relevant areas. Some terrestrial systems are included as they provide many
relevant examples of invasive species impacts, and remedial practices that have been effective in some cases.
It may be possible to extend findings from terrestrial systems to aquatic systems for effective conservation
of insects. The Hawaiian example of invasive species impacts on native insects and other arthropods such as
certain spiders has many parallels to insect biotas in other vulnerable island and island-like habitats, and
therefore forms a central component of this overview. Finally, drawing on a mixed record of past mistakes
and successes in Hawai'i and elsewhere, some practical conservation measures intended to preserve and
restore endemic aquatic insects are proposed.
144
In Hawai' i, the first record of any invasive insect species in the literature is the 1826 introduction of the
mosquito Culex quinquefasciatus Say (Hardy 1960). The introduction of this mosquito species and its
subsequent vectoring of avian malaria have resulted in catastrophic impacts to much of the native Hawaiian
forest bird fauna (Van Riper et a1. 1986; Van Riper and Scott 2001). While extinctions among Hawaiian
forest birds and the current restriction of their remaining populations to elevations above the range of
mosquitoes has received considerable worldwide attention, a less publicized but nevertheless ongoing pattern
of species extirpation has also been occurring among native Hawaiian insects, both terrestrial and aquatic. In
both cases the common thread is invasive species.
In addition to the problems caused by invasive species, lack of taxonomic resolution remains one of the
greatest problems related to arthropod conservation on oceanic islands (Gillespie 1999; Nishida and
Evenhuis 2000). This is particularly true for aquatic insects, as relatively few species have been collected or
described from the insular tropical Pacific. While the Pacific region from New Guinea to Hawai'i probably
contains at least 900,000 arthropod species, amounting to an estimated 15% of the world's total (Allison
and Englund, in press), a lack of basic knowledge prevents effective conservation measures from being
established. The remote nature and consequent difficulty in accessing oceanic islands has also been a major
obstacle in providing basic taxonomic assessments for those areas. Outside of Hawai' i, only the most
economically important aquatic insects such as the biting blackflies and sandflies (Simuliidae and
Ceratopogonidae respectively) and mosquitoes (Culicidae) have received any great amount of ecological or
taxonomic treatment. For example, other than the research conducted on the anthropophilic black flies of
French Polynesia (Craig 1997,2001,2003; Craig and Currie 1999; Craig and Joy 2000; Craig et a1. 1995;
Craig et a1. 2001), biting Ceratopogonidae (Macfie 1935), and Dolichopodidae (Bickel 1994; Evenhuis
1999), little is known about the aquatic insect fauna of the Society Islands or French Polynesia (e.g.,
Paulian 1998; Sechan 1998).
145
The lack of attention to aquatic systems throughout the insular Pacific region may have resulted from the
fact that initial biological assessments of freshwater ecosystems were generally haphazard and secondary to
terrestrial arthropod assessments. Although thousands of new terrestrial arthropod species were collected
during the Pacific Entomological Surveys of French Polynesia and elsewhere by Bishop Museum and
Hawaii Sugar Planters' Association staff during the late 1920s and 1930s (Zimmerman 1935; Adamson
1936, 1939) only a small portion of these were aquatic insects, consisting mostly of a few aquatic species
of Tipulidae (Alexander 1932,1933,1935), Dolichopodidae (Lamb 1933), and Odonata (Mumford 1935,
1936; Needham 1942). Additionally, the biting flies that created an obvious nuisance to researchers
(Simuliidae and Ceratopogonidae) (Edwards 1932, 1933a, 1933b) and a few shorefly species (Ephydridae)
(Malloch 1935) were also described from these early surveys.
The overall dearth of Pacific aquatic insect collections in general contrasts greatly with the treatment of
Hawaiian Odonata, which attracted the attention of both professional and amateur naturalists from the first
stages of European exploration, probably due to their large size and stunning appearance. The first native
aquatic insect described from Hawai'i was Anax strenuus (Hagen 1867), collected during the expedition of
the Danish corvette Galathea in 1846 (Bille 1851). The first native damselfly collected and described from
Hawai'i was Megalagrion xanthomelas (Selys Longchamps 1876) taken by G.F. Matthew of the Royal
Navy some time prior to 1876 (the specimens were apparently labeled only "Sandwich Islands") (Polhemus
1996). A few years later, McLachlan (1883) described five endemic damselfly and one dragonfly species
from specimens collected in Hawai'i by Reverend Thomas Blackburn. In the 1880s, Blackburn made further
collections of native aquatic insects in Hawai'i, describing three Megalagrion damselflies from O'abu,
Uina'i and Maui (Blackburn 1884).
Just a few years after Blackburn's collections, the most comprehensive historical collections of Hawaiian
aquatic insects began in 1892 with the formation of the British Association for the Advancement of
Science's Sandwich Islands Committee, which sent R.C.L. Perkins to Hawai'i to collect and catalog the
146
islands' fauna (Juvik 2001). Perkins's work led to the publication of the Fauna Hawaiiensis, which included
descriptions of many new aquatic insect species (Perkins 1913). The aquatic insect specimens collected by
Perkins and later collectors such as F.X. Williams (Williams 1936) provided a wealth of historical
information on aquatic insect distributions prior to large-scale perturbations from urbanization and the
introduction of the majority of non-native species into Hawai'i.
By contrast, relatively few aquatic insect species were described or documented from the Pacific
Entomological Surveys of the 1920s and 1930s, or surveys such as the St. George Expedition to Tahiti in
the 1920s. For example, two new species of Veliidae (Cheesman 1926), a few widespread dragonflies and
one dolichopodid species (Parent 1934) were collected by Evelyn Cheesman during the St. George
Expedition (Cheesman 1927). The historical record of Hawaiian aquatic insects largely provided by Perkins
and Williams is thus lacking from most other Pacific island areas.
CASE STUDIES OF IMPACTS AND DOCUMENTED EXTINCTIONS CAUSED BY
INVASIVE SPECIES
Hawai'i
Because surveying an entire island or all of its suitable habitats in typically rugged Pacific island terrain is
difficult, extinction is often a complicated matter for researchers to verify, especially in the case of smaller
and less conspicuous arthropods. Extinctions of established populations are the result of these species being
unable to adapt to perturbations or changes in their environment to which they have not been previously
exposed, or if the population drops below a level necessary for its continued survival (Howarth and Ramsay
1991). In Hawai'i, there are many notable cases of presumed arthropod extinctions. However, with the
exception of a small percentage of the insect biota, recent systematic surveys to verify the status of a
particular group of insects have rarely been conducted. There are 5,368 described species of native insects in
the Hawaiian Islands, accounting for 26% of the 20,440 species of native plants and animals found in the
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archipelago (Eldredge and Evenhuis 2003). Ninety-eight percent (5,233) of these insects are endemic to
Hawai'i (Eldredge and Evenhuis 2003) with many species found only on a single island.
While definitive figures on the conservation status of the entire Hawaiian insect fauna are not available,
extrapolations can be made from groups that have been the subject of detailed study since the early 1990s
(Table 1). These groups include all of the Odonata, some Diptera (Foote and Carson 1995, Evenhuis and
Polhemus 1994, Evenhuis 1997a, 1997b, Englund unpub!. data), all Heteroptera (Tummons 2003,
Polhemus in litt.), carabid beetles (Liebherr and Zimmerman 2000; Liebherr 2005), nitidulid beetles (C.
Ewing, pers. comm.), Rhyncogonus weevils (Samuelson 2003), Hylaeus bees (Daly and Magnacca 2003),
and geometrids in the genus Scotorythra (Heddle 2003), totaling 997 species (Table 1). Recently well
surveyed insect groups in Hawaii then account for 18.7% of the taxa that have had their conservation status
examined. Of this total, 12.1% of the included species are presumed extinct, with the presumption of
extinction for this review based on the fact that a particular taxon has not been collected in the past 50 years
(Liebherr and Zimmerman 2000). The calculated extinction rate of 12.1% is probably an overestimate for all
native taxa as recent studies for several groups (e.g., damselflies, Rhyncogonus weevils) were funded
because some of these taxa were believed to be threatened and at risk. However, even if this percentage was
overly pessimistic it indicates that of the 5,368 described native insect species, at least 4,700 or more
species are still likely extant. These estimates also do not factor in the many undescribed native insects,
estimated to be as high as several thousand species (Howarth and Ramsay 1991). Thus, with an even more
conservative 7-10% extinction rate estimate, there still remains a large number of native Hawaiian insect
species of great cultural, scientific, and aesthetic value worthy of conservation attention. The Hawaiian
situation of some documented terrestrial and aquatic insect extinctions contrasts with that of continental
North America where no extinctions of aquatic insect taxa have been documented, and only 204 out of
10,000, or 2% of estimated taxa were considered at risk for extinction in 1993 (Polhemus 1993).
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Table 6.1. Extinction status of native insect taxa in the Hawaiian Islands that have recently had theirconservation status examined, to lowest taxonomic resolution.
No. Species Examined in Total Presumed % PresumedTaxa Study Extinct ExtinctOdonata
Zvgoptera 29 2 7Anisoptera 4 0 0
Heteroptera 370 38 10Coleoptera
Carabidae 193 32 17Nitidulidae l 142 16 11Curculionidae: Rhvncogonus 47 2 4
DipteraDrosophilidae: Drosophila 14 0 0Dolichopodidae: Campsicnemus 26 0 0Dolichopodidae: Emperoptera 5 4 80Dolichopodidae: Sigmatineurum 11 0 0Canacidae: Procanace2 7 0 0Ephydridae: Scatell:r 16 1 6Chironomidae: Telmatogeton2 7 0 0
LepidopteraCrambidae: Omiodes 23 9 39Geometridae: Scotorythra 43 4 9
HymenopteraColletidae: Hvlaeus 60 11 18
Totals 997 121 12.1IC. Ewing, pers. comm, 2Englund, unpublished data. From: Foote and Carson (1995); Polhemus andAsquith (1996); Evenhuis and Polhemus (1994) Evenhuis (1997a, 1997b); Liebherr (2005); Liebherr andZimmerman (2000); Nishida (2002); Evenhuis (2003); Daly and Magnacca (2003); Heddle (2003);Samuelson (2003); Tummons (2003), Haines (2004), Polhemus (in litt.); C. Ewing (pers. comm.);Englund (unpub!. data)
Invasive species appear to be a leading cause of insect extinctions in Hawai'i and throughout the tropical
insular Pacific. A nonindigenous or alien species is considered invasive if it spreads rapidly on its own and
causes serious problems to human health, agriculture, commerce, or the environment (Simberloff 1997a;
Staples and Cowie 2001). Invasive species have certain intrinsic features that allow them to outcompete
native species including: a) being adaptable enough to thrive in different habitats; b) tolerance of a wide
range of disturbances; c) being fast growing and capable of displacing other species; d) being highly
dispersible to new locations; and e) a high reproductive rate (Simberloff 1997a; Staples and Cowie 2001).
Invasive aquatic species are introduced to new habitats through a wide variety of pathways (Polhemus and
149
Englund 2003) including sportfish introductions, intentional food and aquaculture or aquarium introductions,
association with aquarium plants, and ballast water (Englund et a1. 2000a; Englund 2002). Extrinsic factors
such as habitat disturbance and transport by humans may also facilitate or increase the spread of invasive
species. The majority of plant (Mueller-Dombois and Fosberg 1998) and animal species (Staples and Cowie
2001; Yamamoto and Tagawa 2000) encountered in and near the urbanized lowlands of Hawai'i are
invasives, and likely are even more important in terms of native species declines than direct habitat losses
caused by urban and agricultural development. Invasives are thus the primary factor in the demise of most of
the lowland Hawaiian biota, and unlike anthropogenic perturbations that are amenable to regulation, control
of an invasive species is quite difficult, though not impossible, once it becomes well established (Howarth
and Ramsay 1991; Simberloff 1997b; Cox 1999).
Because invasive ungulates such as feral pigs or goats directly modify large areas of native habitat, and other
invasives prey upon or parasitize native species, their impacts on Hawaiian arthropods are likely much
greater than those of direct anthropogenic habitat modification such as urban or agricultural developments.
0'ahu exemplifies the impacts of invasives, and even though large portions of the island are now devoted to
housing, agriculture, or commercial developments, there still remain numerous undeveloped low-elevation
areas that are dominated by invasive plants and insects. For example, surveys of Pearl Harbor wetland areas
showed that 25% of identified taxa were native aquatic insect species (Englund et a1. 2000a), while terrestrial
insect surveys in the undeveloped Wa'ahila Ridge area of O'ahu yielded 16% native species (Cowie et a1.
1999). Arthropods collected during similar surveys around the Kahului, Maui airport area identified only
11% native species (Howarth and Preston 2002). On Kaua'i, only 24 of 283 (<10%) identified insect
species from surveys of a 900 ha lowland mixed agricultural and undeveloped area were native species
(Asquith and Messing 1993). These findings clearly indicate that invasive insect species are now dominant
in the Hawaiian lowlands.
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Overview of Invasive Ant Impacts on Hawaiian Arthropods
Ants provide a particularly dramatic illustration of the impact of invasive species, and a thorough review of
ant impacts in Hawai'i and the Pacific was recently provided by Nishida and Evenhuis (2000). The Hawaiian
archipelago was one of the few large island groups in the world originally lacking native ant species
(Wilson 1996), and 43 established invasive species of ants have been implicated in the demise of many
native arthropod species (Howarth et a1. 2001). Without predatory social insects such as ants, a unique and
disharmonic insect fauna developed in Hawai'i from the 350-400 colonizers that evolved into an estimated
10,000 endemic species (Howarth and Mull 1992). Additionally, without ants there have been large
radiations of non-formicid predators and scavengers such as the predatory caterpillars (Eupithecia spp.), and
certain groups such as carabid beetles are often extremely abundant (Wilson 1996; Liebherr and Zimmerman
2000). Characteristics such as flightlessness and naivete in island species have lead to the vulnerability of
native insects to predation pressures from highly invasive and aggressive social insects such as ants. For
example, the current distributional range in Hawai'i of native Tetragnatha spiders does not overlap with that
of Pheidole megacephala (Fabricius), even in mostly native forests found at low elevations, and habitat
disturbance seems to have lesser impacts on native Tetragnatha as long as P. megacephala is absent
(Gillespie 1999). Gillespie and Reimer (1993) found that the crazy ant Anoplolepis gracilipes (F. Smith)
[referred to as "longipes" by Gillespie and Reimer] and P. megacephala were the most problematic and that
these ant species excluded native spiders from both native and non-native forests. They also found that
introduced spiders have either strong exoskeletons or can lose their legs enabling them to escape when
attacked by ants, or they can wrap the attacking ants in silk. Native Tetragnatha spiders have softer bodies,
are smaller-sized, and never wrap their prey in silk for immobilization. Forest-inhabiting Tetragnatha were
more at risk than riparian species, the latter having far fewer interactions with ants because of their
occurrence in proximity to water barriers.
The endemic Hawaiian Hylaeus bees also are quite susceptible to ant predation; and the absence of Hylaeus
from otherwise suitable coastal habitats appears to be correlated with the presence of ants (Daly and
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Magnacca 2003). In Haleakala National Park, Hylaeus have been severely impacted by the presence of the
Argentine ant (Linepithema humile (Mayr», because the ants form large colonies and are attracted to sugar
and nectar (Daly and Magnacca 2003) thus interfering with the feeding habitats of native bees. Currently,
Argentine ants are found only in small areas of HaleakaIa, but if their spread remains unchecked then
Hylaeus, which represents the largest extant group of native Hawaiian bees, will likely be decimated or at
least significantly reduced in numbers.
Other examples of taxa probably impacted by ants include the flightless fly Emperoptera mirabilis
Grimshaw (Diptera: Dolichopodidae) that lived on the forest floor on Mt. Tantalus near Honolulu, but has
not been collected since 1900 and is now considered extinct (Zimmerman 1970; Evenhuis 1997a). The
extinction of this species occurred apparently quite rapidly, as Perkins was unable to recollect it on Mt.
Tantalus between 1900 and 1907 (Perkins 1907) after finding it locally abundant during his original
collections in 1900 (Evenhuis 1997a). Perkins remarked on the rapid changes that had occurred on Mt.
Tantalus in the short period of time between his collections in 1900 and his subsequent visit in 1907, with
Pheidole ants having become a problem in the lowlands of Hawai'i, including the Tantalus area, starting in
the late 1890s (Perkins 1913). Similarly, Colpacaccus tantalus (Blackburn) a lowland generalist predator and
scavenger that was formerly the most common O'ahu carabid beetle species, has also become extinct
(Liebherr and Polhemus 1997) and was likely unable to compete with aggressive ant species such as P.
megacephala (Liebherr and Zimmerman 2000). Areas of Haleakala National Park with Argentine ants
contained significantly reduced densities of the carabid beetle Mecyc1othorax robustus (Blackburn) in
contrast to areas of lacking Argentine ants (Cole et a1. 1992). A wide range of other native arthropods in
Haleakala National Park were found to have depressed populations, including Araneidae, Collembola,
Hymenoptera, and Lepidoptera in areas where Argentine ants were present, as compared to areas where this
ant species was absent (Cole et a1. 1992).
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The Hawaiian Islands contain twice as many species of crickets as found in the entire continental United
States (Otte 1994) and this large radiation is also threatened by ants. Most of the literature on the impacts
of ants in Hawai'i has necessarily been anecdotal as many ants were introduced at about the same time
Perkins was conducting the initial entomological surveys of the islands in 1892. However, Laupala cricket
populations have been documented to have undergone catastrophic population declines when ants have been
introduced. LaPolla et a1. (2000) found that cricket populations disappeared on eastern Kaua'i after the
invasion of Pheidole megacephaIa. LaPolla et aI. (2000) demonstrated that LaupaIa crickets are now
consistently absent or scarce in other areas that have been recently invaded by P. megacephala; these ants
also invaded and quickly killed a laboratory colony of the native crickets being kept for research purposes at
the University of Hawai'i during the same study. In contrast to native Trigonidium crickets that lay their
eggs under bark in trees, LaPolla et a1. (2000) found that LaupaIa crickets lay their eggs in leaf litter and are
more vulnerable to P. megacephala predation because this species is not generally arboreal. As a result,
Trigonidium crickets appear to be unimpacted by ants in contrast to the large-scale disappearance of LaupaIa
crickets from regions with these invasive ants.
Ants also have likely played a major role in the extinction and rarity of some of the Hawaiian Odonata.
Although not believed to be a direct cause of the severe range contraction of a remnant Megalagrion
xanthomelas population at TripIer Medical Center on O'ahu, ant predation on emerging damselfly larvae of
this species was documented at this site (Englund 2001a). Ants present a much more direct threat to the
terrestrial naiads of Hawaiian damselfly species that appear to breed beneath banks of Dicranopteris linearis
ferns. While one only species, Megalagrion oahuense (Blackburn, 1884), has been conclusively shown to
have a terrestrial naiad life stage in fern litter (Williams 1936), phylogenetic evidence suggests that several
closely related species also have a terrestrial immature stage (Jordan et a1. 2003). These include the Maui
endemic MegaIagrion nesiotes (Perkins) and the Kaua'i endemic Megalagrion williamsoni (Perkins), species
that appear to have been severely impacted by ant introductions and are now known from only one
population each in lower mid-elevation sites (330-450 meters) still lacking ants along riparian areas. Other
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presumed terrestrially breeding Megalagrion damselfly species probably impacted by ants and likely extinct
include M. molokaiense (a Moloka'i endemic) last collected in 1927, Mjugorum (endemic to Maui and
Uina'i) last found in 1896, and the Hawai'i Island population of M. nesiotes, last collected in 1906.
Collectors have failed to rediscover these three species despite intense collection efforts since 1990
(Polhemus and Asquith 1996).
Although the impacts of ants on endemic Hawaiian aquatic insects are generally difficult to assess because
ants are now commonly found in most riparian areas below 800-900 meters elevation, Hardy (1979)
reported that the recent invasion of the crazy ant, Anoplolepis gracilipes [referred to as "longipes" by Hardy]
completely eliminated the aquatic insect fauna in certain sections ofPua'alu'u Stream, Maui. Crazy ants had
completely invaded and "wiped out" most of Pua'alu'u Stream between 50 to 150 meters elevation (Hardy
1979). Hardy (1979) also noted that he had conducted surveys of nearby 'O'heo Stream many times prior to
the invasion of crazy ants and he found it "a shocking contrast" that formerly large populations of endemic
aquatic flies such as Te1matogeton, Scatella ["Neoscatella"], and Procanace were gone, with the exception of
a few individual Scatella that had escaped the ants by living under waterfalls.
Feral ungulates and rats have also directly affected habitats and native plant species, and also likely preyed
on larger invertebrate taxa such as some of the native beetle species. The large, flightless, endemic
Rhyncogonus weevils of Hawai'i appear to be particularly susceptible to invasive species and disturbance.
Although only 4% of these species are currently reported as possibly extinct, virtually all Hawaiian species,
particularly those of the lowlands are now rare and the entire genus is listed as Species of Concern by the
U.S. Fish & Wildlife Service (Samuelson 2003). Rhyncogonus bryani Perkins, a Laysan Island endemic,
has not been collected since the introduction of the European rabbit (Oryctolagus cuniculus (Linnaeus,
1758)) in 1902 resulted in Laysan Island being denuded and also caused the extinction of three of five
endemic island birds (Carlquist 1980) and at least three species of noctuid moths (Gagne and Howarth 1985).
Rhyncogonus extraneus Perkins has not been collected since 1941 despite searches by numerous O'ahu
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entomologists and this species is now believed extinct through a combination of rat and ant impacts
coupled with pesticide applications (Samuelson 2003).
Phytophagous insect species in Hawai'i are also at risk from the effects of feral ungulates. The first
Hawaiian Heteroptera were collected 170 years ago and since then over 370 species have been described. Of
these, 38 species have not been found during recent intensive collecting throughout the Hawaiian Islands by
D.A. Polhemus (Tummons 2003). Because phytophagous Hawaiian Heteroptera are usually host-plant
specific (Gagne 1997), native plant communities at greatest risk would be expected to also contain the most
threatened insect communities. However, Polhemus (in litt.) has found that the greatest Heteroptera
extinctions have occurred in the relatively abundant mid-elevation wet forest areas but, surprisingly, not in
the more endangered lowland dry forest communities (Mueller-Dombois and Fosberg 1998). Even so, the
floristically more diverse lowland dry forests are now found only in small remnant patches, and although
they currently retain much of their Heteropteran diversity, they are critically threatened by fire and by a wide
array of invasive plant and animal species (Wagner et aI. 1999).
Invasive Species Impacts on Insects Outside Hawai'i
Because early collections of insects in Hawai' i were made subsequent to Polynesian disturbances but prior
to the more devastating urbanization and large-scale invasive species introductions that accompanied
European contacts, there has been a thorough documentation of species impacts in the Hawaiian
Archipelago. However, in many other parts of the tropics it is much more difficult to document extinctions
or even invasive species impacts on native arthropods. This is because the biotas of most other tropical
areas have not received the taxonomic treatment and study that has occurred in Hawai'i since the 1890s. The
Hawaiian Islands occupy a relatively small and discrete area, so changes over time are easier to document
than in continental areas or large islands like New Guinea. However, there are interesting parallels between
the well-documented extinctions and negative impacts resulting from invasive species introductions in
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Hawai'i and those on other Pacific islands and elsewhere such as South Africa in the Cape Fynbos, an
island-like Mediterranean floral region.
A suite of invasive plant and animal species often work in combination to eliminate native species by
changing and eliminating native species habitat (Vitousek 1986). For example, feral pigs accelerate the
spread of strawberry guava (Psidium cattleianum) into native wet Metrosideros forests above Hilo on the
island Hawai'i, leading to a strawberry guava monoculture with virtually no native plant species (Englund
et al. 2002). This same pattern of susceptible populations being displaced by invasive species has been
repeatedly observed not only in Hawai'i, but also in other vulnerable areas of high endemism including
isolated islands like New Zealand or continental areas such as Australia and South Africa.
A clear example of an island insect group impacted by invasives would be the largest native insects on New
Zealand, the large bodied (up to 40 g) orthopteran weta in the Families Anostostomatidae and
Rhaphidophoridae, a group currently occupying a broad range of modified and unmodified habitats. As is the
case with many island species, anthropogenic habitat disturbance does not appear to be a major cause of
weta extirpation, as extinctions occurred long before the onset of landscape changes (Gibbs 1998). Most of
the very large weta species such as Deinacrida rugosa Buller and Deinacrida heteracantha White were extinct
on the mainland North Island prior to 1900, where they formerly coexisted with native avian and reptilian
predators, many of which are also now currently endangered or extinct (Gibbs 1998). Introduced in the past
200 years, the main threat to weta today are the Norway rat (Rattus norvegicus, Berkenhout) and the ship rat
(Rattus rattus, (Linnaeus, 1758». Such land mammals are not native to New Zealand, and are more effective
predators than the now rare and extinct native predators, especially because weta have a strong olfactory
presence and are easily detected by mammals (Gibbs 1998). While some of the smaller, more aggressive
weta species survive, albeit in lower densities, in areas with rats, the larger and more docile weta species
have been completely eliminated except on island refugia lacking rats (Gibbs 1998). One undescribed
species of weta survives today by feeding upon and living in hedges of invasive introduced gorse (Ulex
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europaeus Linneaus) lining pasture areas, with the gorse thickets apparently providing protection from
introduced predators because of the thick thorn layers. This weta species has never been found in the nearby
indigenous forests that apparently do not provide sufficient refugia from rat predation (Gibbs 1998).
Situated on the far southeastern tip of South Africa, the Cape Floristic Region with its Fynbos biome
exhibits an island-like high endemicity for many plant and insect species (Wright and Samways 1998) that
are vulnerable to invasive species. Although overall little research has been published on the impacts of
invasive species on aquatic insect populations, the South African Odonata are one of the few exceptions
(Samways 1995; 1996; 1999) and because of this are well worth examining. With 155 species of Odonata
of which 6.5% are threatened, and a moderately high endemism rate of nearly 19%, South Africa contains a
rich fauna, including species with narrow habitat ranges making them vulnerable to extinction (Samways
1999). Of the 29 endemic South African Odonata taxa, the most restricted species are mainly from the
Eastern and Western Cape Provinces, and of the 10 highly threatened species, 6 are damselflies and 4 are
dragonflies. Threats to the South African endemics include habitat disturbance and invasive species.
Samways (1995; 1996; 1999) observed that a rare and threatened damselfly (Ecchlorolestes peringueyi
Barnard) living in clear upland streams in the southwestern Cape area may have had its range restricted by
introduced rainbow trout (Oncorhynchus mykiss Walbaum). This Gondwana relict damselfly was found only
in stream reaches above waterfalls that rainbow trout could not ascend, and the larvae appear to be
behaviorally susceptible to trout predation as they crawl on the surfaces of rocks and plants. A dragonfly
species, Syncordulia gracilis Burmeister, also found in the Western Cape province, was similarly cited as
being under pressure from introduced rainbow trout (Samways 1999). The policy of the conservation
authorities for many years was to encourage trout in those South African streams for recreational fishing;
this policy has recently been changed, and the trout are now considered to be invasive species, as are another
sportfish introduction, smallmouth bass (Micropterus dolomieui Lacepede) (M. Wright, pers. comm.).
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Overall, impacts of invasive species on the South African Odonata appear to be relatively small, with only
1.3% of the fauna known to be suffering negative effects (Samways 1999). The situation of introduced
rainbow trout impacting native Odonata species in South Africa contrasts with that of Hawai'i, where
neither extinctions nor range contractions were found in trout streams containing endemic damselflies
(Englund and Polhemus 2001). This is hypothesized to result from the restricted range of trout in Hawai'i
because of thermal limitations, and also possibly habitat segregation, given that trout and Hawaiian
damselfly larvae occur in different habitats. Trout were mainly found in deeper pools while damselfly larvae
inhabit waterfall faces and cascades and appear to rarely enter into the stream drift (Englund and Polhemus
2001). By contrast, other species of invasive fish in Hawai'i such as mosquitofish in the family Poeciliidae
have been found to be much more serious threats to Hawaiian damselflies (Englund 1999).
Other regions where the impacts of introduced fish on native Odonata have been examined include New
South Wales, where a native Australian dragonfly, Hemicordulia tau Selys Longchamps, was found to be an
important component in the diet of brown and rainbow trout in Lake Eucumbene (Faragher 1980).
However, the long-term survival of the dragonfly population in Lake Eucumbene was not believed to be
affected by trout predation because of seasonal changes in trout prey composition and density, as well as
varying lake levels (Faragher 1980). Trout have also been extensively stocked throughout New Zealand, and
reproduce naturally in both the North and South Islands, having been shown to negatively impact native
stream fish populations (Townsend and Crowl 1991; Crowl et aI. 1992; Townsend 1996). Several New
Zealand studies have shown that the presence of trout reduced native mayfly biomass and caused behavioral
changes (McIntosh and Townsend 1994; 1995), forcing mayflies to graze algae less efficiently at night
resulting in increased algal biomass in streams (Flecker and Townsend 1994). Although invertebrate
biomass was reduced in streams containing trout as compared to areas containing only native galaxiid fish
(McIntosh and Townsend 1996), extirpations or range reductions of aquatic insects were not shown, in
contrast to well-documented range contractions caused by trout to the New Zealand native fish fauna.
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SUCCESS AND FAILURE IN CONTROLLING HARMFUL AQUATIC INSECTS AND
INVASIVE SPECIES IN HAWAI'I AND FRENCH POLYNESIA
French Polynesia
The potential difficulty of eliminating established invasive species is well illustrated by programs aimed at
controlling species affecting human health, particularly blackflies and mosquitoes. In French Polynesia,
attempted control programs have been mostly unsuccessful in reducing native biting aquatic fly populations
of such problematic species as nona noir (Simuliidae) and nono blanc (Ceratopogonidae). By far the most
serious of these biting flies is Simulium buissoni Roubaud, a species endemic to Nuku Hiva and Eiao
Islands in the Marquesas (Craig et a1. 2001). Simulium buissoni bites any endothermic animal and makes
life virtually unbearable for humans living near stream and wetland areas.
Attempts to control of disease vectoring species such as the mosquito Aedes polynesiensis Marks and other
nuisance native aquatic insects found in French Polynesia began in 1970. The first recorded effort involved a
native carnivorous fish, Kuhlia rupestris, in attempts to eliminate filariasis from the Marquesas Islands
(Sechan et a1. 1998). Efforts were then made in Nuku Hiva to unsuccessfully replace the anthropophilic S.
buissoni with non-biting simuliid species (Sechan et a1. 1998), although the species name and original
location of the replacement black fly specie(s) was not mentioned. After these fruitless attempts at
biological control, a shift to insecticides was made to eradicate S. buissoni in the Marquesas, and trials of
different insecticides showed that temephos (Abate™) exhibited the greatest promise (Sechan et a1. 1998). In
1986, the entire Taiohae watershed of Nuku Hiva was treated with temephos with "excellent results"
(Sechan et a1. 1998). By 1993 the government of French Polynesia sponsored a black fly eradication project
for S. buissoni on the entire island of Nuku Hiva (Craig et a1. 1995; Sechan et a1. 1998). From January to
April 1993, temephos was added to all flowing rivers on Nuku Hiva on a bi-weekly basis. Populations of
biting female S. buissoni were reduced to 4% of previous levels after the first two applications of
insecticides (Craig et a1. 1995). However, the eradication plan was cut short by heavy rains in March 1993.
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By October 1993, S. buissoni populations had increased to pre-treatment levels (Craig et al. 1995). This
failed effort cost nearly U.S. $200,000 and has not been repeated on Nuku Hiva or elsewhere.
The Hawaiian Islands provide one of the few examples of a successfully controlled and eradicated invasive
aquatic insect species, the mosquito Aedes aegypti (Linnaeus). This species was responsible for the great
dengue fever epidemics in Hawai'i during World War II and earlier, as documented by Hardy (1960). Aedes
aegypti is a domestic species and preferentially breeds in artificial containers holding clean water, such as
old tires, flower vases, beverage containers and other urban debris, and was formerly found in great numbers
in urban Honolulu. However, the yellow fever outbreak of 1911 in the crew of a visiting vessel from
Mexico led to drastic mosquito control measures around the city. Starting in 1911, banana plants within the
city were eradicated as possible breeding sites, and other strict control measures by the State Board of Health
were implemented that eventually led to the last A. aegyptibeing collected on O'ahu in 1957. It is probable
the control efforts in the 1950s were successful while earlier efforts were not because of the diligent and
continuous long term cleanup operations conducted by the State Board of Health. The last statewide
collection of Aedes aegypti was in1971 based on BPBM collection data and subsequent surveys in the
1970s and 1980s (Evenhuis in litt.). Although Aedes albopictus (Skuse) was responsible for the 2002
dengue fever outbreak on Maui and O'ahu, A. aegypti is a far more efficient dengue vector than A.
albopictus. It is quite likely the recent dengue fever outbreak would have been much worse if A. aegypti had
not been eliminated from the Hawaiian Islands.
Overall attempts to control and eliminate invasive species in Hawai'i and elsewhere in the Pacific islands
have been successful in relatively few cases. Elimination of feral mammals such as rats and ungulates has
been successful mostly on smaller, dry islands (Table 2). Although the results shown in Table 2 indicate
only a few invasive animal species have been completely eradicated from the Hawaiian Islands, it provides
further justification for intensive management of invasive species in small, discrete areas such as offshore
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islets and the Northwest Hawaiian Islands. Perhaps the successes of eradicating vertebrates from these
islands can also be applied to other isolated, non-overlapping habitats or remnant biological islands within
Hawai'i. The same may apply to many freshwater streams, anchialine pools, and wetland areas that also
represent disconnected insular habitats. Many streams on Hawaii's rocky Hfunakua coast include no estuary
habitat and enter the ocean as waterfalls. These areas could be described as isolated islands of habitat similar
to many anchialine pond areas on the islands of Hawai'i and Maui. Because of this disconnection, these
areas would be suitable for removal of invasive fish species. In fact, anchialine pools on Hawai'i Island
containing alien fish can be observed just meters away from ponds lacking alien fish (Englund, unpubl.
data; Brock and Kam 1997).
Table 6.2. Successfully eradicated invasive animal species in the Hawaiian Islands.
Island!Area Year Year Eradicated or ExtirpatedSpecies Established (Reference)
MammalsEuropean Rabbit Laysan1 1902 1923 (Rauzon 2001)
Pearls and Hermes <1916 1928 (Tomich 1986)
HaleakaHi National Park, Maui 1989 1991 (Bishop Museumwebsite)
Manana 1890 2002 (D. Smith, pers. com.)
RatsRattus rattus Midwav/Sand Island 1944 1996 (Rauzon 2001)
Rattus exulans Kure Atoll <1778? 1993 (Rauzon 2001)
Goats, Sheep Kahoolawe early 1800s 1988 (HEAR website)*
Axis Deer O'ahu > 1868 1950 (Tomich)
InsectsAedes aegvvti O'ahu 1895 1957 (Hardv 1960)
1A rabbit colony at nearby Lisianski Atoll caused its own demise after destroying all vegetation on thatisland before 1923 (Tomich 1986).*[http://www.hear.org/naturalareas/kahoolawel]
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DISCUSSION
Lessons Learned from Successful Eradication Programs
As stated earlier, successful eradication of invasive species has been decidedly erratic in the Pacific, with
small islands being the primary area of notable success. Table 2 lists the invasive animal species
successfully eradicated from the Hawaiian archipelago, but there have also been successful eradications of a
variety of mammal and insect species from a number of other islands in the Pacific and elsewhere.
Vertebrates such as black rats (R. rattus), Norway rats (R. norvegicus), European rabbits (Oryctolagus
cuniculus) and the house mouse (Mus musculus Linneaus) have been completely removed from a number of
New Zealand islands (Myers et a1. 2000). Harmful insects such as the tse-tse (Glossina spp.) were eradicated
from the island of Principe in the Gulf of Guinea (Simberloff 2003), as was the screw-worm fly
(Cochliomyia hominivorax (Coquerel)) from Curacao (Baurnhover 1955), and the Asian citrus blackfly
(Aleurocanthus woglumi Ashby) from Key West, Florida (Hoelmer and Grace 1989). Only a short list
exists for insects eradicated in the Pacific region. This includes the Oriental fruit fly (Bactrocera dorsalis
(Hendel)) from Rota, Guam, Tinian, and Saipan (Steiner et al. 1965; Steiner et a1. 1970), and also from
Okinawa (Tsubaki 1998). The tussock moth (Orgyia thyellina Butler) was eradicated from New Zealand
(Hosking et a1. 2003); two species of ants, Pheidole megacephala and Solenopsis geminata (Fabricius) from
33 hectares of Kakadu National Park, Australia (Hoffman and O'Connor 2003); and the melon fly Bactrocera
cucurbitae (Coquillett) from the Ryukyu Archipelago (Kuba et a1. 1996).
Ongoing monitoring programs are critically important for successful eradication of incipient populations of
invasives. This is because newly introduced species are found in localized areas and this limited distribution
greatly increases the chances of eradication (Myer et a1. 2000). For example, in 1999 the black-striped
mussel (Mytilopsis sallei Recluz) was eliminated from an enclosed marina in Darwin, Australia by a rapid
response involving high doses of copper sulphate (Bax et a1. 2002). Christmas Island (Indian Ocean) has
been severely impacted by invasive crazy ants (Anoplolepis gracilipes). An infestation of some 2500
hectares has resulted in an estimated 15-20 million land crabs being killed by these ants (Australian
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Government Website 2004). This ant invasion led to a total forest ecosystem disruption as weed seedlings
previously eaten by crabs were allowed to grow. The ants were also responsible for an explosive increase in
the scale insect population feeding on native trees, which in turn further stressed the native forests. A
control program in place on Christmas Island since 2000 has achieved some initial successes and
significantly reduced the size of the crazy ant super colonies (Australian Government Website 2004), and it
may be possible to ultimately eradicate them from the island. The ant eradication program at Kakadu
National Park and ongoing ant eradication efforts on Christmas Island are relevant for managing and
preserving native biodiversity at HaleakaHi National Park, other critical habitats for native arthropods in
Hawai'i, and small island areas containing invasive ant species such as Palmyra Atoll (see page 150,
Overview of Invasive Ant Impacts on Hawaiian Arthropods). It shows that ant eradication is feasible, and
also points out the devastating ecosystem impacts of ants on native species if they are not controlled.
Previous ant eradication success stories illustrate that coordinated efforts are needed to stop invasions at a
relatively early stage, such as at Kakadu National Park. In that reserve, Pheidole megacephala colonies were
first detected in mainly developed areas in June 2001. By October 2001 mapping of ant distributions
throughout the park took place. Treatment with Amdro ant baits commenced at the end of October and into
November 2001, prior to the beginning of the wet season. Post-treatment surveys indicated eight small
remnant populations that remained within buildings, which were then treated with additional baits. After 17
months (April 2003) the ant colonies had been eliminated (Hoffman and O'Connor 2004). The Kakadu
example of an immediate response followed by post-eradication monitoring has been a notable success. It is
also important to note that when an invasion is past the point of eradication scarce resources should not
continue to be poured into a hopeless control effort. Simberloff (2003) stated the failed U.S. $200 million
program to eradicate the red imported fire ant (Solenopsis invicta Buren) in the southern U.S. is considered
the "Vietnam" of eradication programs. This because it was a non-winnable situation and the widespread use
of heptachlor for fire ant controlled to non-target impacts such as death of wildlife, cattle, and even
predators of fire ants (Simberloff 1997b).
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The failed blackfly control effort on Nuku Hiva also provides additional perspective on eradication of
undesirable species. For instance, prior to launching any eradication project it is important that the biology
of the target species be well-known and that potential non-target impacts are evaluated. On Nuku Hiva,
temephos was considered target-specific to black flies because Odonata and chironomid larvae were reportedly
found alive both before and after treatments of streams. Sechan (1993) did not "notice mortality of other
invertebrates associated with Simulium buissom", in spite of the fact that quantitative toxicity tests were
conducted only on freshwater prawns; these studies found that native prawns (Macrobrachium spp.) were not
harmed by concentrations of temephos used during field treatments (Sechan 1993). The authors of this black
fly eradication project stated that "the taxa [in Nuku Hiva streams] have been identified which do not differ
from that reported in Moorea, in the Society Archipelago" (Sechan et aI. 1998). However, the freshwater
fauna found in Moorea, Society Islands, and in Nuku Hiva, Marquesas Islands are dissimilar (Keith et aI.
2002) as each French Polynesian island, similar to the Hawaiian Islands, has its own suite of endemic
aquatic insects (Polhemus et a1. 2000, Englund 2003). Recent joint Smithsonian/Bishop Museum
expeditions to Nuku Hiva in 1999 and 2001 have found many undescribed species of native aquatic insects,
with descriptions of these new species just beginning (Evenhuis 2004). For example, a radiation of at least
5 undescribed, large, endemic damselfly species on Nuku Hiva was recently recorded (Polhemus et aI. 2000)
along with two new species of large, endemic aquatic flies (Dolichopodidae) from that island (Evenhuis
1999). Evenhuis (2004) also described an additional three new species of endemic aquatic Dolichopodidae
from elsewhere in the Marquesas. Thus there was the potential for serious negative impacts to the endemic
aquatic fauna in Nuku Hiva streams because of the lack of biodiversity surveys and toxicity data on aquatic
organisms other than Macrobrachium prawns before the implementation of the control program for
Simulium buissoni.
Other efforts to control biting flies such as the introduced nona blanc (ceratopogonids) in the Marquesas
have been more environmentally benign and involve the construction of seawalls in populated areas such as
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Atuona on Hiva Oa and Taiohae on Nuku Hiva. These seawalls reduce the amount of available brackish
water habitat favored as breeding sites for the nono blanc along beach areas by holding back the freshwater
lens. Although there are no published accounts or studies on the efficacy of these freshwater retaining
seawalls, many local residents claim they do work, and anecdotal observations of biting nono blanc in the
areas where the seawalls have been installed indicate relatively low-levels of these ceratopogonids (Englund,
pers. observ). Impacts on estuarine organisms from seawall construction are unknown.
Threats and Opportunities in Conserving Native Aquatic Species in the Tropical
Pacific
Freshwater species and their habitats are currently suffering severe negative impacts worldwide (Saunders et
a1. 2002) with invasive species and water diversions being the primary threats to such systems on tropical
Pacific islands. Most water diversions in island groups other than Hawai'i, such as those in French
Polynesia, are in the lower stream reaches and thus cause relatively minimal impacts. While little can be
done in the long-term to reduce water diversions for municipal and agricultural uses on these islands, the
threat of invasive species can still be addressed. An optimal conservation plan for freshwater organisms
therefore needs to not only discourage the spread of invasive species, but also to target watershed protection
and include freshwater protected areas to provide whole-catchment integrity (Saunders et a1. 2002). Although
reserve designation does not automatically guarantee protection, it does at least provide legal and political
recognition regarding the importance of watersheds and some regulatory mechanisms to deal with current
and future threats.
In some respects, the conservation of tropical Pacific island streams such as those found in Hawai'i and
French Polynesia will be simpler than trying to protect and conserve much larger continental systems.
Because of the relatively recent volcanic origin of these islands, these watersheds are much shorter in length,
less integrated and have steeper topographic profiles (Craig 2003), allowing for an easier delineation of
specific watersheds. Conversely, although these watersheds may be easier to protect because of their small
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size, they are also more vulnerable to disturbance because of this same compact nature. In islands
throughout Hawai'i and French Polynesia the entire watershed from the ocean to its mountain headwaters is
often only a few kilometers long, and can be quickly comprised by invasives. Streams that are separated by
steep topography often contain different suites of specialized and endemic aquatic insect species (Englund
and Polhemus 2001), thus each stream should be viewed as a separate ecological and conservation unit.
Potential Conservation Measnres for Rapa, French Polynesia
Current opportunities in French Polynesia to protect both terrestrial and aquatic taxa include governmental
officials from the Delegation 11 la Recherche working with indigenous people to protect native plants and
habitats from feral ungulates through fencing. Rapa, in the Austral Islands of French Polynesia is a small
(40 krn2), 65O-m high island located at 27°S, with a temperate warm climate, and provides an example of
the difficulties in achieving conservation goals in remote areas. Despite its small size, Rapa has a diverse
flora and fauna, including many island endemics having large adaptive radiations, such as the Miocalles
weevils (Paulay 1984), certain Lepidoptera (Clark 1971), a remarkably species-rich land snail fauna (Solem
1982; Fontaine and Gargominy 2003), and a highly diverse endemic flora (Florence 1997; Meyer 2003;
Meyer et al. 2003). Working with the people of Rapa, the French Polynesian government is taking
conservation steps to protect its most valuable biological and cultural assets: the cloud forests and dry
forests. Recent biodiversity surveys on Rapa (Englund 2003; Fontaine and Gargominy 2003; Meyer 2003)
funded by the French Polynesian Government have provided insights into potential conservation measures
to help ensure that the unique biodiversity of this small, remote island is not lost.
The primary invasive species problem on Rapa is the presence of feral cows, goats, and horses that have
denuded and destroyed all but a small portion of the high elevation cloud forest. The ungulate problem has
significantly worsened since the 1980s, with the horse population apparently increasing from one in 1980
(Paulay 1985) to a substantial herd of more than 50 that were observed in the lower Agairao Valley alone in
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December 2003 (Englund 2003). Only a few high summit areas containing the original undisturbed cloud
forest and middle elevation moist forest area survive (Meyer 2003).
The central volcanic mass on Rapa is Mt. Perau, containing the last area of middle-elevation moist forest
and cloud forest, and is important from a global biodiversity perspective (Paulay 1984, Clarke 1971). The
native vegetation on Mt. Perau remains extant mainly because the slopes of Mt. Perau are generally steep,
up to 800 (Paulay 1984), making sampling and conservation efforts in this area quite difficult, but also
limiting access by ungulates to many areas around the summit. Current efforts are focused on saving this
globally significant and biologically valuable high cloud forest.
Rapa is a wet island and receives an average of 2500--3000 mm of rain at sea level per year but undoubtedly
is much wetter in the cloud-covered mountains (Paulay 1985). It has many relatively large stream systems
for an island of its size, and these streams are still completely free of any introduced aquatic species
(Englund 2003). Despite its small size, Rapa has an endemic aquatic fauna of worldwide interest. For
example, the endemic damselfly Ischnura thelmae is the world's largest (up to 34 mm in length) in that
cosmopolitan genus (Lieftinck 1966). Although common in the 1960s (Lieftinck 1966),1. thelmae now
appears to be seriously threatened not by introduced alien fish species, such as what has occurred in Hawai'i
(Englund 1999), but by riparian forest losses (Englund 2003). This species seems to be an obligate forest
dweller; it was never observed during thorough surveys along riparian habitats on Rapa in overgrazed stream
and open pasture areas, and was only found in heavily forested areas (Englund 2003). A significant
observation was that Ischnura thelmae forages long distances away from streams in areas of native forest.
Thus, there was a clear link between the condition of the native forest and the health of the native damselfly
populations.
Most of the native terrestrial insect biodiversity remaining on the island of Rapa is found in a narrow zone
of native forest between 500--650 m at the summit of Mt. Perau (Englund 2003) that is estimated now to
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be no more than 20 ha in size (J.Y. Meyer, pers. comm). The collection of many undescribed species from
Mt. Perau in December 2002 by Englund (2003) illustrates that much remains to be discovered about the
insect fauna from this mostly intact native forest area. The cattle grazing line at the summit of Mt. Perau
starts at about 370-400 m elevation, and cattle were visibly trampling down Freycinetia sp. to gain further
access up into the summit areas, with evidence of goats found near the very summit. In 2002, goat damage
was observed as high as the 550 m elevation on the ridgelines of Mt. Perau.
Habitat loss caused by feral ungulates clearly requires immediate actions to preserve the cloud forest of Mt.
Perau. On Rapa, knives are still used to hunt cattle and goats. As authorities have strictly controlled
firearms and ammunition, and hunting with knives is very inefficient, hunting will not be a short- or long
term answer to control the large ungulate populations, which were estimated to number 500 cattle and
5,000 goats in 1984 (Paulay 1984). The permanent population of Rapa was 497 people in 1996
(Recensement General de la Population website) thus the amount of livestock present on the island far
exceeds what could be consumed locally.
The remaining option is to fence ungulates out of the Mt. Perau summit area and to work with and employ
local residents to implement this plan. Dry forest areas are even more imperiled than cloud forests on Rapa
and a small patch (1-2 ha) containing rare plant species at Pariati Bay will be fenced to exclude livestock as
soon as funding becomes available. Plans are also currently being put in place to start a fencing project for
the Mt. Perau area sometime after the Pariati Bay dry forest is fenced (J.Y. Meyer, pers. comm.), which
will be a major step in protecting the high cloud forest region. Because relatively few invasive plant species
are found in Rapa, fenced off areas should regenerate quickly with native species. The protection of this
terrestrial ecosystem will have the added benefit of protecting streams flowing off Mt. Perau. Saving this
unique terrestrial ecosystem will thus lead to the preservation of aquatic habitats and their associated aquatic
insects, including Ischnura thelmae.
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RECOMMENDATIONS
Recommendations for the Conservation and Restoration of Island Insects
This section briefly reviews previous recommendations regarding the conservation of island insects by
limiting new species invasions, and provides new recommendations based on the research of this
dissertation. Constant vigilance is needed to effectively keep invasive species from becoming established.
Snake interceptions and captures in Hawai'i from 1990-2000 (Kraus and Cravalho 2001) are a good
example of the concerted efforts required to keep out undesirable species entering as smuggled pets or via
commerce. Even though in theory it may be easier to control incipient invasions of highly vocal animals,
such as the coqui frog (Eleutherodactylus coquiThomas) in Hawai'i, because they are simpler to detect than
the usually more cryptic invaders, a political and regulatory framework still needs to be in place at the time
of invasion to allow eradication at an early stage. New freshwater fish invasions may be more difficult to
detect than the more visible animals such as reptiles or amphibians because of the great number of
established alien tropical aquarium fish throughout Hawai'i (Englund and Eldredge 2001), combined with
relatively few competent observers monitoring the wide range of Hawaiian freshwater habitats. Terrestrial
and aquatic insect invasions are even more difficult to detect and manage because of the small and
inconspicuous nature of larval and adult stages. Because of these factors, insects have the greatest rate of
yearly establishment of all animal or plant groups in Hawai'i (Staples and Cowie 2001), with 2,782
established nonindigenous insects occurring in Hawai'i (Eldredge and Evenhuis 2003) and becoming
established at an alarming yearly rate of 20-30 species (Howarth et a1. 2001). Eradication efforts for
invasive insects are also problematic because after their initial detection they have usually already undergone
a population explosion and often are found in high densities across a wide range of habitats.
An ideal conservation strategy would of course attempt to prevent invasions from ever occurring, but it is
of interest to examine the recommendations of Howarth and Ramsay (1991) which still provide a valid set
of solutions regarding the conservation of island insects and the habitats upon which they depend. The
guidelines included a comprehensive and integrated program of research and monitoring, education, reserve
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management, legal and legislative actions, controlling the introduction of alien species, and pest control
programs. While these suggestions provided a solid framework, many of the recommendations have
unfortunately not been implemented, resulting mainly from a lack of funding attributable to a lack of
political support. The recent publication of the State of Hawai'i Aquatic Invasive Species Management Plan
(Shluker 2003) provides a much-needed comprehensive framework to prevent or at least reduce future
problems caused by invasive aquatic plant species, such as the Salvinia molesta infestation in Hawai'i that
cost U.S. $1.25 million to remove in 2003 (Gima 2003). Because this plan involved all interested
stakeholders (aquarium, aquaculture, and shipping industries), and resource managers on each island from the
very beginning (Shluker 2003), it has a reasonable chance of success. Other recent developments, such as
the formation of the various Invasive Species Councils for each main Hawaiian Island (e.g., Big Island
Invasive Species Council, etc.), have shown that grass-roots efforts at controlling invasive species can be
successful if invasions are detected at an early phase. Examples of this include the nearly complete
eradication of the invasive tree Miconia calvescens on O'ahu and the early elimination of many other
incipient alien plant invasions on Maui Nui (F. Starr, pers. com.). Of course, interception and early
detection of invaders is by far the most-cost effective manner to deal with invasive species, but even if
enforcement and quarantine resources were unlimited there would still remain a need for the capacity to
eradicate incipient invasions given the daily volume of commerce and visitor arrivals to Hawai'i.
Because so many indigenous aquatic insect taxa, particularly in Hawai'i but also elsewhere in the Pacific,
now have seriously reduced ranges (Englund 1999,2001,2003), the ultimate goal of biodiversity
preservation should be to restore populations to a level robust enough to allow species to withstand major
environmental disturbances such as hurricanes or droughts. Population restoration should at first involve
small, discrete habitat units that can be permanently cleared of the invasive species identified to have caused
declines. Native species should then be translocated and reintroduced to areas having either natural or
constructed dispersal barriers to prevent re-invasion by the problematic alien species, but this should only
be done within the same island or nearby islands that have identical or very similar taxa. In some cases
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active management to protect aquatic insects may be required, such as ant monitoring and control for the
protection of terrestrially breeding damselfly species such as Megalagrion nesiotes or M williamsoni.
Recommendations for Successful Invasive Species Removal
Attempts to remove invasive aquatic species need to be well planned, and a thorough understanding of their
ecology and life history is necessary to ensure success. For example, treatment of lower Kane'ohe Bay
streams in O'ahu, Hawai'i, with a ichthyocide such as rotenone to eliminate invasive fishes would
ultimately be unsuccessful because low salinity estuarine regions provide refugia for several species of
salinity-tolerant poeciliids and tilapia that are currently harming native aquatic life. The large size of
Kane'ohe Bay and potential public outcry over treating the entire bay would certainly preclude the effective
use of rotenone in this region.
Isolated and unconnected stream habitats are common on geologically younger islands in volcanic
archipelagoes such as Hawai'i or the Society Islands. Because many aquatic habitats such as high gradient
stream areas entering the ocean as terminal waterfalls include little to no estuarine habitat, there would be a
higher probability for aquatic ecosystem restoration once detrimental alien species such as poeciliid fish
were removed, similar to what has occurred in the successful eradications listed in Table 2. Anchialine
ponds provide another example of a discrete habitat where full ecological restoration is not only feasible,
but has actually taken place with a few small-scale experiments on Hawai'i Island. Brock and Kam (1997)
conducted pilot studies in several anchialine ponds where they found the only viable alternative to remove
alien fish was through the use of an ichthyocide like rotenone. They found native biota recolonized treated
ancialine pools shortly after the alien fish were removed, and that full ecological restoration took at least
one year. Their findings have significant implications in restoration of aquatic ecosystems, and they
emphasized that their greatest restoration success was in isolated, smaller pools where invasive fish had no
chance to recolonize or obtain refugia during the application phase of the ichthyocide (Brock and Kam
1997). Anchialine ponds are one of Hawaii's most endangered ecosystems, supporting native damselflies
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such as Megalagrion xanthomelas and other aquatic insects. Even in the highly protected Kaloko
Honokohau National Historic Park on Hawai'i Island, 84% of these habitats were infested with invasive
fish such as guppies in 1997 (Brock and Kam 1997).
Recommendations for Regular Monitoring to Detect New Invasions
For Hawaiian aquatic systems there is currently no regular monitoring program in place to detect new
invasions of aquatic biota. Regular monitoring is necessary for managers and researchers to detect and find
new invasions at an early stage. Although staff of both the Hawaii Division of Aquatic Resources and the
Hawaii Biological Survey of the Bishop Museum conduct numerous surveys throughout the year, these are
mainly on a contract, project, or as-needed basis. The monitoring program to detect early invasions of
aquatic species initiated in the year 2000 at Pelekunu Stream could serve as a statewide model. The
Pelekunu Nature Preserve, Moloka'i contains large, free-flowing streams that are a refuge for some of the
rarest aquatic animals in Hawai'i and the world, and is one of the last areas in Hawai'i lacking alien aquatic
vertebrates of any kind. The Nature Conservancy Hawai'i, Moloka'i office, along with cooperating
scientists from Bishop Museum's Hawaii Biological Survey and Hawaii Division of Aquatic Resources,
conducted surveys from 2000-2002 to monitor the status of certain native aquatic species in this system.
Aquatic invertebrate monitoring was conducted in conjunction with endemic freshwater fish monitoring to
provide information to help effectively manage and preserve native aquatic biodiversity. The initial
monitoring of Pelekunu Stream provided extremely valuable information (Englund 2000, 2001b; Englund
and Arakaki 2003), but because of lack of funding has not been conducted in either 2003 or 2004. Because
alien fish and other invasive aquatic species continue to rapidly spread throughout the Hawaiian Islands, this
monitoring program should be reinstated as a matter of priority.
In addition to regular monitoring, a contingency or rapid-response plan should be drawn up that would
immediately eliminate any alien aquatic vertebrate species accidentally or intentionally introduced into
Pelekunu Stream. For example, immediate chemical treatment of the stream with rotenone should occur if
172
any introduced fish species were detected during monitoring. Although this would also eliminate most
native aquatic invertebrates in the treated areas, recolonization from nearby areas should be immediate, and
harm would be short-term and inconsequential compared to the much longer-term threat of alien fish. By
contrast, lack of action when fish or other major alien species introductions occur into the Pelekunu
watershed would deal a severe blow to the preservation of native Hawaiian aquatic fauna biodiversity.
Currently, high mountain ridges keep introduced amphibians out ofPelekunu Stream, even though
bullfrogs (Rana catesbeiana Shaw) are found in the adjacent Wailau Stream watershed. Bullfrog control at
Pelekunu Stream would be much more difficult than eliminating invasive fish species, and research into
controlling and reducing frog numbers in neighboring Wailau Stream should be undertaken to alleviate this
threat. The necessity of early detection of invasive aquatic species underscores the importance of periodic
aquatic monitoring in the Pelekunu watershed. Similarly, regular monitoring of a select number of
waterbodies on each main Hawaiian island could have been accomplished for a small fraction of the cost
required to remove invasive Salvinia molesta from Lake Wilson on 0'ahu in 2003.
As the above example of Pelekunu Valley demonstrates, in tropical insular Polynesian streams even small
areas devoid of alien species currently provide a last refuge for native aquatic species, and are of great
conservation value. The most dramatic illustration of this is the 95-meter section of an unnamed tributary
at TripIer Army Medical Center containing the last O'ahu population of Megalagrion xanthomelas. The
continued precarious existence of M. xanthomelas there provides the impetus for translocating to a suitable
alien-free habitat and restoring this formerly common damselfly species (Englund 200la). The case of M.
xanthomelas at TripIer indicates endemic aquatic biota can survive in extremely restricted habitats for up to
90+ years after the introduction of poeciliid fish to an area (Englund 1999). Although this is not an optimal
situation for the long-term survival of this species, it does provide an indication of the resilience of island
species when even small amounts of habitat lacking invasive species are available. The TripIer habitat is
relatively secure because of its location inside a U.S. military facility, but other similarly restricted habitats
for endangered aquatic organisms are in need of similar protections, such the last known Megalagrion
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nesiotes population (Englund, unpub. data) occurring along a small reach of East Wailua Iki Stream on
Maui next to a major highway.
Preservation of Aquatic Biodiversity through Invasive Species Prevention and
Watershed Preservation
A prudent recommendation would be that at a minimum, one relatively intact watershed from each island in
an archipelago should be selected as a biodiversity reservoir for aquatic species. Specialized habitats in island
areas are of particular concern as they may be considered islands within islands, and many have restricted
populations of endemic biota. It is important to have one reserve on each island within a given archipelago,
because numerous single island endemics have been found during surveys of the few island groups so far
examined in detail, such as Hawai'i (Polhemus and Asquith 1996), the Marquesas (Evenhuis 1999,2003;
Polhemus et al. 2000), and the Australs (Englund 2003, 2004). Such reserves would also be beneficial by
providing baseline sites as control areas for assessing changes in other watersheds within an island or island
group. Realistically, funding for surveys and taxonomic expertise will remain limited for the foreseeable
future, therefore efforts to preserve native species by providing a reserve protection framework may end up
being implemented in the absence of such baseline information.
Measures such as providing at least one watershed preserve per island could be instituted throughout tropical
Polynesia in areas such as Hawai'i, the Marquesas, and the Austral Islands where there are currently sizable
uninhabited valleys containing significant streams. These valleys historically supported large Polynesian
populations cultivating taro (Kirch 1985), but today are nearly or completely uninhabited. Notable
examples in Hawai'i would include virtually all north shore Moloka'i streams; Hanakoa, Nualolo, and
Kalalau Valleys on Kaua'i; the Hakaui Valley on Nuku Hiva in the Marquesas; and virtually the entire
island of Rapa in the Austral chain. The native aquatic fauna of these areas remains largely intact because it
has not sustained measurable long-term impacts from historical Polynesian taro cultivation and settlement
and these areas were subsequently depopulated and neglected after European colonization. For example, the
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north shore Moloka'i streams, used for taro cultivation by ancient Polynesians, now contain some of the
rarest aquatic species in Hawai'i because they lack invasive species (Englund and Arakaki 2003) that spread
elsewhere in Hawai'i after European contact. The stream areas mentioned above present opportunities for the
creation of freshwater reserves in lightly populated regions with little corresponding human conflict. The
Nature Conservancy's Pelekunu Preserve on Moloka'i provides the best example in tropical Polynesia of an
intact, pristine watershed formerly heavily cultivated for taro that has been abandoned and is now
uninhabited, yet highly protected. In order to preserve the rare native aquatic species found there, the
Pelekunu Preserve is now intensively protected from feral ungulates with the support and assistance of local
Moloka'i hunters, and as previously mentioned was monitored for invasive aquatic species.
Because of the severity of the invasive species threats, it is urgent that conservation actions are
implemented without delay even if comprehensive taxonomic treatments of the fauna found on each
archipelago or individual island within an island group are unavailable. Limited knowledge of Pacific island
biotas is the norm, and there are presently few taxonomists available to describe the many new species
found within each archipelago. Because ever-increasing global trade is leading to the rapid spread of invasive
species, and human population increases are leading to greater resource demands, it is necessary to protect
the relatively intact watersheds in the tropical Pacific as soon as possible. Hawai'i clearly demonstrates that
even in a relatively well-studied tropical island system, new taxa are constantly being discovered. For
example, eight undescribed native aquatic insect species were found during recent helicopter-accessed surveys
of 14 remote stream areas on three Hawaiian islands (Englund et a1. 2003). These findings were noteworthy
as a literature review from the period 1990-2003 revealed an average of only 0.9 new aquatic insect species
described per year from the Hawaiian Islands (Englund et a1. 2003). This, despite the fact that aquatic insect
collection efforts had been unusually high in Hawai'i throughout the 1990-2003 period. Additionally, this
example illustrates how little basic information is known regarding the numbers and types of aquatic insect
species in Hawaiian inland waters, let alone their basic ecological, evolutionary, or life history parameters;
this lack of knowledge is even more acute in the remainder of the Pacific. In the best-case scenario of
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planning ecological reserves to preserve native biodiversity, a systematic inventory of the aquatic insect
fauna for all major Pacific high islands would occur ftrst, with conservation priorities and candidate reserve
areas subsequently delineated for highly diverse, sensitive, and intact watersheds.
Realistically, however, the preservation of aquatic ecosystems prior to the full or even partial delineation of
all their component taxa is necessary to avoid future large-scale biodiversity losses. If only limited funds are
available then rapid biodiversity surveys targeting a select number of indicator species from each proposed
area (Howarth 1990) would have great value in prioritizing conservation agendas. In the tropical insular
Paciftc, damselflies (Zygoptera) (Polhemus and Asquith 1996) and certain aquatic Heteroptera such as
Veliidae (Polhemus and Polhemus 2004) or Saldidae (Cobben 1980), could serve as indicator species
sensitive to disturbance in a wide of range aquatic habitats. Damselflies are also striking in appearance and
charismatic enough to be easily observed and collected by amateurs, and are often known and appreciated by
indigenous peoples, making these insects good "flagship species" (Englund et al. in press).
Such an approach could be appropriate for the Marquesas archipelago, which is exceptional in Polynesia
because they lack introduced fish (Polhemus et a1. 2000; Keith and Marquet 2002), therefore providing a
unique opportunity to preserve native aquatic biodiversity. The easiest and most cost-effective way to
preserve the Marquesan aquatic biota would be to maintain a strict prohibition on the importation of any
non-native freshwater or estuarine ftsh species.
Because freshwater is limited and the Marquesas Islands undergo frequent severe droughts, it is doubtful that
aquaculture (a worldwide primary source of invasives) would ever be promoted, however, the aquarium trade
might. Direct jet service from Papeete, Tahiti provides a two-hour link between the island groups, and has
the potential to facilitate importation of aquarium ftsh, which are sold in Papeete. To enhance awareness
among the public in French Polynesia, educational materials on the potential impacts of releasing aquarium
fish into streams should be prepared and distributed to pet stores, governmental agencies, and particularly
176
schools. This material would explain the nature of the threat, and advocate the preservation and protection of
the native aquatic fauna, since most island residents are not aware of the unique biota found in Marquesan
streams and elsewhere in French Polynesia. Educational information in the form of color posters, brochures,
and especially lesson plans and materials for school teachers could also inform the public and children as to
why freshwater stream animals are an important part of their cultural heritage, and explain the steps that
they can take to preserve this patrimony. Educational fact sheets stressing the importance of native aquatic
life can be prepared and handed out with every aquarium-related purchase. These fact sheets can discuss how
to properly dispose of freshwater aquarium plants and animals, and the implications of improper disposal,
including potential cleanup costs to stakeholders (e.g., the Salvinia molesta in Hawai'i).
SUMMARY OF CONSERVATION EFFORTS
Conservation of aquatic ecosystems in Hawai'i and French Polynesia has come a long way in the past
century, from advocacy of large-scale introductions of invasive species by governments to a current
recognition that many, if not most, species of the aquatic invasives introduced into insular environments
have had long-term, deleterious consequences. Introductions of species in the mosquitofish family
(Poeciliidae) started in Hawai'i in 1905 (Van Dine 1907) and in Tahiti in 1920 (Keith et a1. 2002), and
proved to have deadly consequences for native aquatic biota. A pattern of state-sponsored early biological
control introductions of fish shifted after World War II to sportfish introductions (Maciolek 1984; Polhemus
and Englund 2003). Some of these sportfish species, such as smallmouth bass, have had negative
consequences for stream biota, while others like trout have either not become established in the case of
Tahiti (Keith et a1. 2002) or are so thermally restricted (as in Hawai'i) that they exhibit few measurable
impacts (Englund and Polhemus 2002).
Within the past 20 or so years there has been a shift away from the state-sponsored fish and other aquatic
species introductions that occurred in Hawai'i and Tahiti, to introductions by individuals. Most
introductions of aquatic biota into insular Pacific environments since the 1980s have been from aquarium
177
releases, intentional food releases by migrant populations, or the intentional spread of sportfish by
individual anglers. For example, several species of armored catfish common in the aquarium trade have been
introduced into Hawai'i (Sabaj and Englund 1999) and appear to be anthropogenically spreading to new
watersheds; in Tahiti, green swordtails, Xiphophorus helleri (Heckel), were first observed in 2003 in the
Papeno'o River (Englund, unpubl. data) and are also probably spreading. Smallmouth bass were stocked
intentionally in Waikele Stream, O'ahu since 2000 by individual anglers, and likely will be spread further
on that island. Intentional food releases are a continuing problem and are exemplified by the apple snail,
Pomacea canaliculata (Lamarck). Apple snails were first introduced to Hawai'i in 1989 and greatly harm the
culturally important wetland taro crop and are now widely distributed throughout the archipelago (Lach and
Cowie 1999).
Drawing on relevant examples of invasive species introductions in island areas and also certain vulnerable
terrestrial systems, general trends on the impacts of invasive species can be discerned. Endemic island biotas
are particularly susceptible to invasive species, with disruptive species such as ants causing major problems
in both terrestrial and aquatic ecosystems on a world-wide basis. Some terrestrial invasives such as feral
ungulates have also had clearly discernible negative impacts on aquatic species through their destruction of
watersheds by eliminating riparian vegetation thereby severely reducing water quality. Because of their
insular nature and limited size in island environments, aquatic habitats are particularly at risk from invasive
species. Where introduced, fish and other harmful aquatic species introductions have eliminated key elements
of the native aquatic insect fauna had other unintended side effects. These negative impacts include predation
on native fish, spreading new parasites to which the native aquatic biota has not been previously exposed,
and competition for food resources. Proposed measures such as regular monitoring for new invasives,
stricter quarantine laws, and aquatic biodiversity reserves on maintained on each island would provide a
measure of stability for endemic insular biotas in the tropical Pacific. Research is now beginning to reveal
why certain native aquatic insect taxa have declined in tropical Pacific stream areas such as Hawai'i and
French Polynesia, but arresting this decline and beginning the process of restoration will require the
178
concerted efforts of a variety of governmental agencies, nongovernmental organizations, and private citizens.
Community involvement, particularly "grassroots" participation in the conservation of aquatic biotas will
provide the greatest protection to these systems in the long run.
179
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