Post on 14-Jan-2016
transcript
Chapter 10: Distribution and Spatial Structure of
Populations
Robert E.
Next chapter
Friday: we’ll do both Chapters 14 and 15
We’re skipping chapters 11-13
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Habitat Fragmentation and Landscape Ecology
Fragmentation of formerly continuous habitats is happening worldwide, caused by: clearing of forests construction of roads channeling of rivers
Landscape ecology addresses how size and arrangement of habitat patches influence: activities of individuals growth and regulation of populations interactions between species
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Consequences of Habitat Fragmentation
Plants and animals can use a habitat patch only if they have access to it.
Changes in human land use patterns have reduced such access.
Small, isolated populations in habitat fragments are vulnerable to extinction: they suffer from loss of genetic diversity they are subject to random perturbations
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Forest Fragmentation in the Amazon
When habitats are fragmented, most areas are closer to edges, often with negative consequences.
Forest fragmentation in the Amazon basin results in greater exposure of trees within 100 m of forest edges, resulting in: drying of vegetation excessive wind damage losses of up to 15 tons of biomass per hectare
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Habitat fragmentation (Brazil)
Brown-Headed Cowbirds and Kentucky Warblers
Cowbirds are nest parasites of other birds, such as the Kentucky warbler. Cowbirds: prefer open farms and fields venture into the edges of forests in search of host nests
In one study, parasitism on warblers was as high as 60% within 300 m of forest edges: warblers had to be 1.5 km from the forest edge to
escape parasitism
Nest predators also venture into forest from edges.
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Habitat fragmentation can affect population dynamics
Many species are in decline.
Warblers and many other forest birds of eastern North America have declined in recent years.
Populations of most species have persisted for millions of years: many species are now threatened with
extinction, a cause for great concern to understand this problem and potential
solutions we must explore population structures
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Terminology 1
A population is made up of the individuals of a species within a particular area: each population lives in patches of suitable habitat
Habitats naturally exist as a mosaic of different patches: many populations are thus broken into somewhat
isolated subpopulations
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Terminology 2
Population structure refers to: the density and spacing of individuals within
suitable habitat the proportions of individuals in various age
classes mating system genetic structure
Populations exhibit dynamic behavior, changing through time because of births, deaths, and movements of individuals.
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Geographic distributions are determined by suitable habitats.
The distribution of a species is its geographic range.
Consider the geographic range of sugar maple in eastern North America: broader outlines of the range are
determined by climatic factors within its range, the species only occurs in
suitable habitats (absent from many habitats such as marshes and serpentine barrens)
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Within a population’s geographic range, only suitable habitats are occupied
Barriers to long-range dispersal limit geographic distribution.
Introduced species often expand successfully into new regions: 160 European starlings were introduced near New
York City in 1890 and 1891; within 60 years, the North American population of starlings covered more than 3 million square miles
Other examples of successful introductions: dogs in Australia, pigs and rats in Pacific islands fast-growing pines and eucalyptus trees
worldwide
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migration
The geographic range of a population includes ALL of the areas its members occupy during their ENTIRE life history
Sockeye salmon spawning grounds in Canada plus vast areas of the North Pacific Ocean where individuals grow to maturity before making the long migration back
East Africa: migration of many large ungulates…following the geographic pattern of seasonal rainfall and fresh vegetation
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Ecological niche modeling
Map the known occurrences of a species in a geographic space
Catalog the combination of ecological conditions (temp and precipitation) at the locations were the species has been recorded
Catalog of ecological conditions = ecological envelope
Then map the geographic area that has the same combination of conditions to predict the broader occurrence of species w/in a region
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Dispersion of Individuals within Populations
Dispersion of individuals within a population describes their spacing with respect to one another.
A variety of patterns is possible: clumped (individuals in discrete groups) evenly spaced (each individual maintains
a minimum distance from other individuals) random (individuals distributed
independently of others within a homogeneous area)
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Dispersion patterns describe the spacing of individuals
Causes of Dispersion
Even spacing may arise from direct interactions among individuals: maintenance of minimum distance between
individuals or direct competition for limited resources may cause this pattern
Clumped distribution may arise from: social predisposition to form groups clumped distribution of resources tendency of progeny to remain near parents
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Evenly spaced desert shrubs in Sonora, Mexico
Vegetative reproduction clumped distribution
Start here
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Populations exist in heterogeneous landscapes.
Uniform habitats are the exception rather than the rule: most populations are divided into
subpopulations living in suitable habitat patches
Degree to which members of subpopulations are isolated from one another depends on: distances between subpopulations nature of intervening environment mobility of the species
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Causes of Isolation
Whether or not areas of unfavorable habitat are substantial barriers to mobility depends on: distance between subpopulations nature of intervening habitat mobility of the species
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Mobility and Isolation
The extent of isolation of subpopulations depends on the mobility of the species: snail kites in southern Florida are linked
into a single population geckos in Australia are separated by
agriculture into subpopulations between which there is little movement of individuals
Several models address patchiness...
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Genetic differences between populations in small, isolated habitat patches indicate lack of movement between them (gecko Oedura reticulata in SW Australia)
Metapopulation Model
The metapopulation model views a population as a set of subpopulations occupying patches of a particular habitat: intervening habitat is referred to as the
habitat matrix: the matrix is viewed only as a barrier to
movement of individuals between subpopulations
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Source-Sink Model
The source-sink model recognizes differences in quality of suitable habitat patches: in source patches, where resources are
abundant: individuals produce more offspring than needed to
replace themselves surplus offspring disperse to other patches
in sink patches, where resources are scarce: populations are maintained by immigration of
individuals from elsewhere
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Landscape Model
The landscape model considers effects of differences in habitat quality within the habitat matrix: the quality of a habitat patch can be affected
by the nature of the surrounding matrix quality is enhanced by presence of resources, such
as nesting materials or pollinators quality is reduced by presence of predators or
disease organisms some matrix habitats are more easily
traversed than others
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Models of population structure
Ideal Free Distributions 1
Individuals can make decisions regarding the quality of habitat patches. Where to live? Where not to live?
How do they make these decisions?
Quality of a patch depends on: its intrinsic quality density of other individuals:
occupied patches may have fewer remaining resources
competing individuals may engage in conflicts
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In an ideal free distribution, each individual exploits a patch of the same apparent quality
Ideal Free Distributions 2
Each individual chooses among patches to maximize its access to resources.
As a patch with high intrinsic quality fills with individuals, its resources are depleted and its apparent quality decreases: at some point, a patch with lower intrinsic quality
has greater apparent quality and it too begins to fill thus all patches reach the same apparent quality,
despite different intrinsic qualities and different densities of individuals, the ideal free distribution
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Individuals move from sources to sinks.
The ideal free distribution would suggest equivalent reproductive success among individuals occupying habitat patches of differing intrinsic quality: this ideal is rarely realized:
individuals do not have perfect knowledge of patch quality
free choice may be reduced in subordinate individuals
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Sources and Sinks
Some patches are population sources and others are population sinks with net movement from sources to sinks: evident in European blue tit:
populations in deciduous oak habitats are sources, with potential for rapid growth
populations in evergreen oak habitats are sinks, with potential for rapid decline
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Estimating population size.
Population size (number of individuals) is the ultimate measure of a population: we typically wish to know what factors cause size to
change and processes that regulate size
Total population size has two components: density, the number of individuals per unit area area occupied
Density area occupied = size.
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How do we measure density?
A total count may be feasible: suitable for small populations where individuals
can be distinctively marked often employed for endangered species,
particularly for larger animals such as mammals and birds
For sessile organisms, local density may be determined in plots, then extrapolated to entire area occupied.
Other techniques may be needed for mobile organisms.
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Mark-Recapture Method
Mark-recapture methods are often used with animal populations: an initial sample is collected and all individuals are
distinctively marked marked animals are released into the population
and allowed to mix a second sample is collected and marked and
unmarked animals are tallied
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Mark-Recapture Computations
For an initial marked sample of size M, a second sample of size n, containing x marked individuals, the population size N is:
N = nM/x
If 20 fish are captured, marked, and returned to a small pond, and a second sample of 50 fish contains 6 marked fish, the population estimate is 50(20)/6 = 167.
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Variation in Populations over Space and Time
Populations tend to vary in size over time.
Long-term records often reveal fluctuations that might be overlooked in shorter term: infestation by chinch bugs in Illinois monitored over
decades reveals populations fluctuations: in some years, populations averaged 1000/m2 over an area
of 300,000 km2
in other years farmers reported little damage
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Movement of individuals maintains spatial coherence.
Movements within populations are referred to as dispersal.
Movements between subpopulations are referred to as migrations, or more specifically: emigration (leaving a subpopulation) immigration (entering a subpopulation)
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Monitoring Dispersal
Monitoring dispersal is difficult: organisms must be marked and recaptured large areas must be covered to ensure an adequate
sampling of movements
Population biologists often use ingenious methods to monitor dispersal: dispersal in fruit flies was investigated by releasing
individuals with a visible mutation
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Lifetime Dispersal Distance
Average lifetime dispersal distance is a useful index of movement within populations: this indicates how far an individual moves from its
birthplace to where it settles and reproduces: a circle with radius equal to the lifetime dispersal distance
is the lifetime dispersal area the number of individuals within this circle is the
neighborhood size of the population
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Neighborhood size: # of individuals w/in a circle whose radius is the average lifetime dispersal distance
European starling
marcoecology
Analyzing and interpreting the patterns revealed by large samples of species
The distribution and population size of a species reflects the distribution of conditions to which individuals of the species were well adapted. If these conditions are common population should also be common
Plus: a species should be more abundant at the center of its distribution where its conditions are most favorable
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Range size and pop density
Species adapted to a broad range variety of resources and conditions are likely to be more abundant in the center of their distribution than are species that are more specialized
geographic range and population density in the center of the distribution should be positively correlated
Can be tested in a sample of species for which both geographic range and population density have been measured – eg: populations of birds within North America
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Range size and pop density
1. area occupied by a species and its max population density are positively correlated
Among457 species - those species with larger ranges have higher max abundances
Body size, distribution, and abundance
Population density decreases with increasing body size
Why?
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Pop density in carnivores is closely related to their food supply