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Phytoremediation of PCBs and PAHs with Phytoremediation of PCBs and PAHs with Monoterpene Producing PlantsMonoterpene Producing Plants
David Crowley, David Crowley, JoongJoong--WookWook Park, Park, HaakrhoHaakrho YiYiDepartment of Environmental SciencesDepartment of Environmental Sciences
University of California, RiversideUniversity of California, Riverside
XenobioticXenobiotic
PlantPlantUptakeUptakeMetabolismMetabolismVolatilizationVolatilizationCarbonCarbon
exudateexudatequantityquantitycomponentscomponents
SurfactantsSurfactantsO2, CO2, pHO2, CO2, pHNitrogenNitrogen
Rhizosphere CommunityRhizosphere CommunitySoilSoil
SolubilitySolubilityAdsorptionAdsorption
% OM% OMClayClay
Organic matterOrganic matterTextureTexture
water contentwater contentaerationaeration
TemperatureTemperatureNutrient ContentNutrient Content
Species CompositionSpecies CompositionPopulation numbersPopulation numbers
DegradersDegradersCometabolizersCometabolizers
ActivityActivityCataboliteCatabolite repressionrepressionGene recombinationGene recombinationPlasmid transferPlasmid transfer
MineralizationMineralizationMetabolite FormationMetabolite Formation
Phytochemical Analogs of Xenobiotic Contaminants
Terpenes:Terpenes:
FlavonoidsFlavonoids
LigninLignin
QuinonesQuinones
AlkaloidsAlkaloids
PyrazinesPyrazines
NapthaleneNapthalene
FluoreneFluorene
PhenanthrenePhenanthrene PyrenePyrene
Structures of Common Aromatic Soil PollutantsStructures of Common Aromatic Soil Pollutants
Polychlorinated BiphenylsPolychlorinated Biphenyls
++
++
++
biphenylbiphenyl
PCBPCB
biphenyl +biphenyl +PCBPCB
growthgrowth
no growthno growth
growth + growth + degradation of degradation of PCBsPCBs
bacteriabacteria
bacteriabacteria
bacteriabacteria
Cometabolism of PCBsCometabolism of PCBs
OH
OH
COOHO
OH
COOH
COOH
BiphenylBiphenyl BiphenylBiphenyldioldiol
phenylhexadienoatephenylhexadienoatering fission productring fission product
hydrolysis hydrolysis productsproducts
Assay for Cometabolism of PCBsAssay for Cometabolism of PCBs
OH
Colorimetric AssayColorimetric AssayAbs. 434 nmAbs. 434 nm
Plant Screening AssayPlant Screening AssayGilbert and Crowley 1996Gilbert and Crowley 1996
Spearmint (Spearmint (MenthaMentha spicataspicata))Active component: carvoneActive component: carvone
ArthrobacterArthrobacter B1BB1B
Evidence:Evidence:PCB ring oxidation productPCB ring oxidation productchlorobenzoate product formationchlorobenzoate product formationdisappearance of disappearance of AroclorAroclor 12421242
00
10102020
30304040
5050
60607070
80809090
100100
diCBdiCB tritri--CBCB tetratetra--CBCB pentapenta--CBCB total PCBtotal PCB
PCB congener typePCB congener type
PCB
rem
aini
ng (%
)PC
B r
emai
ning
(%) Carvone induced cellsCarvone induced cells
NonNon--induced cellsinduced cellscarvonecarvone--fructosefructoseindigenous bacteriaindigenous bacteria
Degradation of 100 ppm Degradation of 100 ppm AroclorAroclor 1242 PCBs in Soil after 9 Weeks1242 PCBs in Soil after 9 WeeksAfter Inoculation With CarvoneAfter Inoculation With Carvone--Induced Induced ArthrobacterArthrobacter B1BB1B
O
O O
OHOO
O OFatty Acid Composition:
Oleic acid 74%Linoleic acid 7%Linolenic acid 2%Palmitoleic acid 7%Palmitic acid 10%
Criteria:Criteria:
NontoxicNontoxic
Selective Growth SubstrateSelective Growth Substrate
SolubilizesSolubilizes PCBPCB
BiodegradableBiodegradable
Development of a Field Application VectorDevelopment of a Field Application Vector
Sorbitan TrioleateSorbitan Trioleate
00
10102020
30304040
5050
60607070
80809090
100100
diCBdiCB tritri--CBCB tetratetra--CBCB pentapenta--CBCB total PCBtotal PCB
TreatmentTreatment
Perc
ent D
egra
datio
nPe
rcen
t Deg
rada
tion
Arthrobacter B1B cellsArthrobacter B1B cellsCarvone surfactant Carvone surfactant -- indigenousindigenouscontrolcontrol
Degradation of Degradation of AroclorAroclor 1242 PCBs after 9 Weeks of 1242 PCBs after 9 Weeks of Repeated Inoculation Using CarvoneRepeated Inoculation Using Carvone--Surfactant Grown CellsSurfactant Grown Cells
Induction of PCB degradation by Carvone and Related Compounds
PCB ring fission product formation by Arthrobacter B1B following enzyme induction by carvone or biphenyl. (Gilbert and Crowley 1998)
CarvoneBiphenyl
ngpr
oduc
t mg-
1pr
otei
n h-
13000
2000
1000
0
0 400 800 1200 1600µmol
Salicylate Salicylate cumenecumene limonene cymene carvonelimonene cymene carvone
cineole camphor cineole camphor pinenepinene vanillin vanillin
biphenylbiphenyl
citralcitral
nariniginnarinigin
O
OHO
OO
O OHOO
HO
HO
OHHO
HO
O
OO
HOO
O
OH
OHO
BRDU Labeled 16S rDNA Profile of Terpene BRDU Labeled 16S rDNA Profile of Terpene EnrichedSoilEnrichedSoil
Bip
heny
lB
iphe
nyl
Van
illi
nV
anil
lin
Citr
alC
itral
Pine
nePi
nene
Lim
onen
eL
imon
ene
Nar
ingi
nN
arin
gin
Cum
ene
Cum
ene
Cym
ene
Cym
ene
Cin
eole
Cin
eole
Car
vone
Car
vone
Cam
phor
Cam
phor
Fruc
tose
Fruc
tose
Con
trol
Con
trol
Correspondence Analysis of BRDU Labeled 16S rDNA Correspondence Analysis of BRDU Labeled 16S rDNA from Terpene Enriched Soilsfrom Terpene Enriched Soils
cumenecumene
camphorcamphor
carvonecarvonelimonenelimonene
pinenepinene
biphenylbiphenylcymenecymene
citralcitral
naringinnaringin
vanillinvanillin
fructosefructose
cineolecineole
controlcontrol
27%27%
17%17%
OO
OOOO
O O OO
OO OOOOOO
OO
OO
OOOO
OO
OO
OO
OOOO
OO
OO
OO
Salicylate: Plant Signal Compound, Siderophore,Salicylate: Plant Signal Compound, Siderophore,and Inducer of Xenobiotic Degradation Enzymesand Inducer of Xenobiotic Degradation Enzymes
Toluene dioxygenase substrates:Toluene dioxygenase substrates:
Benzene, toluene, Benzene, toluene, xylenexylene (BTEX)(BTEX)
Trichloroethylene (TCE)Trichloroethylene (TCE)
Trinitrotoluene (TNT)Trinitrotoluene (TNT)
Naphthalene, Naphthalene, benzopyrenebenzopyrene (PAH)(PAH)
Polychlorinated biphenyls (PCB)Polychlorinated biphenyls (PCB)
PCB congener PCB congener ArthrobacterArthrobacter RalstoniaRalstoniacoinoculationcoinoculation
2,3,6,2'2,3,6,2' 34 34 ±± 55 45 45 ±± 662,5,2',5'2,5,2',5' 29 29 ±± 33 56 56 ±± 772,4,2',5'2,4,2',5' 27 27 ±± 33 49 49 ±± 662,4,2',4', 2,4,5,2'2,4,2',4', 2,4,5,2' 30 30 ±± 55 44 44 ±± 662,3,2',3'2,3,2',3' 30 30 ±± 66 51 51 ±± 662,3,5,2',4', 2,4,5,2',52,3,5,2',4', 2,4,5,2',5 13 13 ±± 44 25 25 ±± 44
Coinoculation with Arthrobacter sp. B1B and Ralstonia eutrophus H850
Summary
�� Gram positiveGram positive bacteria induced by bacteria induced by monoterpenes.monoterpenes.
�� Gram negativeGram negative bacteria induced by bacteria induced by salicylic acid.salicylic acid.
�� Many indigenous PCB degraders can be enriched Many indigenous PCB degraders can be enriched by growth on these substances.by growth on these substances.
Common terpene producing plant species
Origanum majorana O. syriacumO. vulgare Salvia cabulicaThymus zygis T. piperellaCurcuma longa Carum copticumEucalyptus species Tanacetum partheniumVitex negundo Acanthopanax trifoliatusLigusticum porteri Ocimum basilicumAndropogon sp. Chenopodium sp.
Alpha-pinene, Aritasone, Ascaridole, Ascorbic-acid, Beta-carotene, Butyric-acid, Calcium, D-camphor, EO, Ferulic-acid, Geraniol, L-pinocarvone, Leucine, Limonene, Malic-acid, Menthadiene, Methyl-salicylate, Myrcene, Niacin, P-cymene, P-cymol, Phosphorus, Safrole, Saponins, Spinasterol, Tartaric-acid, Terpinene, Terpinyl-acetate, Terpinyl-salicylate, Thiamin, Triacontyl-alcohol, Trimethylamine, Urease, Vanillic-acid
Chenopodium ambrosioides
Phytoremediation of Pyrene using Celery RootPhytoremediation of Pyrene using Celery Root
Root essential oil:ppm
β pinene 15,000carvone 5000dihydro-carvone 5000P-cymene 31,000 limonene 117.000 myrcene 18,000 terpenoline 33,000trans-ocimine 290,000 cis-ocimine 68,000
Duke, J. A. 1992. Handbook of phytochemical constituents of GRAS herbs and other economic plants. Boca Raton, FL. CRC Press.
0.0
10.0
20.0
30.0
40.0
50.0
60.0
70.0
80.0
90.0
100.0
5 10 15 20 25 30 35 40 45
Days
ppm
Degradation of pyrene in soil amended with celery rootDegradation of pyrene in soil amended with celery root
Celery rootmg/g soil
10100200
Yardwastemg/g soil
10100200
Degradation of pyrene in the rhizosphere of wheat and celery plants
0.00.0
20.020.0
40.040.0
60.060.0
80.080.0
100.0100.0
11 22 33 44 55 66 77 88 99 1010 1111
WeekWeek
Pyre
ne (p
pm)
Pyre
ne (p
pm)
CeleryWheatControl
Selective inhibitors suggest Gram + bacteria are Selective inhibitors suggest Gram + bacteria are predominant pyrene degraders induced by celery root.predominant pyrene degraders induced by celery root.
00
2020
4040
6060
8080
100100
ControlControl CeleryCeleryrootroot
StrepStrep.. CycHexCycHex S+CS+C
Pyre
ne (p
pm)
Pyre
ne (p
pm) Gram �
Gram +Fungi
Gram �Gram +Fungi
Gram �Gram +Fungi
55--OxoOxo--1,21,2--campholidecampholide
camphorcamphor
5 5 exoexo--hydroxycamphorhydroxycamphor
camphor 5camphor 5--monooxygenase monooxygenase (cytochrome P450 cam)(cytochrome P450 cam)
2,5 2,5 diketocamphanediketocamphane
5-exo-hydroxycamphor dehydrogenase
camphor 1,2camphor 1,2--monooxygenase monooxygenase ((Baeyer-Villiger monooxygenase)
What enzymes are induced by monoterpenes?Biodegradation of Camphor: Role of P450CAM
Pairwise sequence alignment scores for α subunits of ring hydroxylating oxygenases (Nam et al 2000)
Analine
Toluene
PAH /Terpene
Biphenyl
DitANidANahAc G4PahAcDoxBNdoBNahAc 9816-4PahA3NtdAcDntAcNagAcPhnAc RP007PhnAc AFK2
96 VTLNVOPHRGMRISTADCGNTQ-IHKOIYHGWAFR 119…201 IVNANWKTAGEQSAADGFHT-LTLHRWLGE 22983 GHLNAORHRGMQVCRAEMGNAS-HFROPYHGWTYS 116…198 VVDANWKLGADNFVGDAYHT-MMTHRSMVE 22676 AFLNVORHRGKTLVNAEAGNAK-GFVOSYHGWGFG 109…190 VIKANWKAPAENFVGDAYHV-GWTHASSLR 21876 AFLNVORHRGKTLVNAEAGNAK-GFVOSYHGWGFG 109…190 VIKANWKAPAENFVGDAYHV-GWTHASSLC 21876 AFLNVORHRGKTLVSVEAGNAK-GFVOSYHGWGFG 109…190 VIKANWKAPAENFVGDAYHV-GWTHASSLR 21876 AFLNVORHRGKTLVSVEAGNAK-GFV0SYHGWGFG 109…190 VIKANWKAPAENFVGDAYHV-GWTHASSLR 21876 AFLNVORHRGKTLVSVEAGNAK-GFVOSYHGWGFG 109…190 VIKANWKAPAENFVGDAYHV-GWTHASSLR 21876 AFLNVORHRGKTLVHAEAGNAK-GFVOSYHGWGFG 109…190 IIKANWKAPAENFTGDAYHV-GWTHASSLR 21874 AFLNVORHRGKTLVHTEAGNAK-GFVOGYHGWGYG 107…188 VVKANWKPFAENFVGDTYHV-GWTHAAALR 21679 AFLNVORHRGKTIVDAEAGNAK-GFVOGYHGWGYG 112…193 VVKGNWKVFAENFVGDTYHI-GWTHASILR 22174 AFLNVORHRGKTLVHAEAGNAK-GFVOSYHGWGFG 107…188 VIKANWKAPAENFVGDAYHV-GWTHASSLR 21677 AFLNVORHRGARLCAVEAGNAR-GFAONYHGWAYG 110…191 FIEANWKAPSENFVGDAYHV-GWTHASALR 21981 AFLNVOTHRGARLVAAEAANAR-AFSOTYHGWSFG 114…194 LLNCNWKTPAENFVGDAYHV-GWTHLASLM 222
Amino Acid Sequence Alignments of Riske Iron Center Regions of Group 3 PAH and Terpine Dioxygenases
ConclusionsConclusions
� Degradation of xenobiotics in the rhizosphere is� Degradation of xenobiotics in the rhizosphere islikely enhanced by a combination of mechanisms,likely enhanced by a combination of mechanisms,including: fortuitous enrichment of degraders, including: fortuitous enrichment of degraders, growth linked metabolism, and cometabolism. growth linked metabolism, and cometabolism.
� Plant signal molecules including terpenes, � Plant signal molecules including terpenes, flavonoidsflavonoids, and , and salicylatesalicylate have multiple ecological have multiple ecological functions. When released into the rhizosphere,functions. When released into the rhizosphere,these compounds also have signal functionsthese compounds also have signal functionsfor inducing cometabolism of organic xenobiotics.for inducing cometabolism of organic xenobiotics.
Research NeedsResearch Needs
� Identification of specific plants that produce � Identification of specific plants that produce substances that can substances that can biostimulatebiostimulate xenobioticxenobioticdegradation.degradation.
� Evaluation of the role of plant, microbial, and � Evaluation of the role of plant, microbial, and earthworm enzymes (earthworm enzymes (oxygenaseoxygenase, cytochrome P450 �) , cytochrome P450 �) for effectiveness in degrading soil contaminants.for effectiveness in degrading soil contaminants.
� Studies on the ecology of rhizosphere microbial � Studies on the ecology of rhizosphere microbial consortia for enhancing bioremediation.consortia for enhancing bioremediation.
AcknowledgmentsAcknowledgments
Eric GilbertEric GilbertAndrew Singer Andrew Singer EkawanEkawan LuepromchaiLuepromchaiJoongJoong WookWook Park Park HaakrhoHaakrho YiYi
Development of Methods for Soil Bioaugmentation
Enzymes for Transformations of Monoterpenes