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Applied Microbiology and Biotechnology

, Volume 84, Issue 2, pp 205–216 | Cite as

Bioremediation of the organochlorine pesticides, dieldrin and endrin, and their occurrence in the environment

  • Emiko Matsumoto
  • Youhei Kawanaka
  • Sun-Ja Yun
  • Hiroshi Oyaizu
Mini-Review

Abstract

Dieldrin and endrin are persistent organic pollutants that cause serious environmental problems. Although these compounds have been prohibited over the past decades in most countries around the world, they are still routinely found in the environment, especially in the soil in agricultural fields. Bioremediation, including phytoremediation and rhizoremediation, is expected to be a useful cleanup method for this soil contamination. This review provides an overview of the environmental contamination by dieldrin and endrin, along with a summary of our current understanding and recent advances in bioremediation and phytoremediation of these pollutants. In particular, this review focuses on the types and abilities of plants and microorganisms available for accumulating and degrading dieldrin and endrin.

Keywords

Bioremediation Phytoremediation Dieldrin Endrin Persistent organic pollutants 

References

  1. Adeyeye A, Osibanjo O (1999) Residues of organochlorine pesticides in fruits, vegetables and tubers from Nigerian markets. Sci Total Environ 231:227–233CrossRefGoogle Scholar
  2. Ahn JH, Kim MS, Kim MC, Lim JS, Lee GT, Yun JK, Kim T, Kim T, Ka JO (2006) Analysis of bacterial diversity and community structure in forest soils contaminated with fuel hydrocarbon. J Microbiol Biotechnol 16:704–715Google Scholar
  3. Anderson JPE, Lichtenstein EP, Whittingham WF (1970) Effect on Mucor alternans on the persistence of DDT and dieldrin in culture and in soil. J Econ Entomol 63:1595–1599Google Scholar
  4. Baba D, Yasuta T, Yoshida N, Kimura Y, Miyake K, Inoue Y, Toyota K, Katayama A (2007) Anaerobic biodegradation of polychlorinated biphenyls by a microbial consortium originated from uncontaminated paddy soil. World J Microbiol Biotechnol 23:1627–1636CrossRefGoogle Scholar
  5. Baczynski TP, Grotenhuis T, Knipscheer P (2004) The dechlorination of cyclodiene pesticides by methanogenic granular sludge. Chemosphere 55:653–659CrossRefGoogle Scholar
  6. Battersby NS, Wilson V (1989) Survey of the anaerobic biodegradation potential of organic chemicals in digesting sludge. Appl Environ Microbiol 55:433–439Google Scholar
  7. Bedford CT, Huston DH, Natoff IL (1975) The acute toxicity of endrin and its metabolites of rates. Toxicol Appl Pharmacol 33:114–121CrossRefGoogle Scholar
  8. Bixby MW, Boush GM, Matsumura F (1971) Degradation of dieldrin to carbon dioxide by a soil fungus Trichoderma koningi. Bull Environ Contam Toxicol 6:491–494CrossRefGoogle Scholar
  9. Campanella B, Paul R (2000) Presence, in the rhizosphere and leaf extracts of zucchini (Cucurbita pepo L.) and melon (Cucumis melo L.), of molecules capable of increasing the apparent aqueous solubility of hydrophobic pollutants. Int J Phytoremediation 2:145–158CrossRefGoogle Scholar
  10. Campbell S, Arakaki AS, Li QL (2009) Phytoremediation of heptachlor and heptachlor epoxide in soil by Cucurbitaceae. Int J Phytoremediation 11:28–38CrossRefGoogle Scholar
  11. Chiu TC, Yen JH, Hsieh YN, Wang YS (2005) Reductive transformation of dieldrin under anaerobic sediment culture. Chemosphere 60:1182–1189CrossRefGoogle Scholar
  12. Collins C, Fryer M, Grosso A (2006) Plant uptake of non-ionic organic chemicals. Environ Sci Technol 40:45–52CrossRefGoogle Scholar
  13. Donoso J, Dorigan J, Fuller B, Gordon J, Kornreich M, Saari S, Thomas L, Walker P (1979) Reviews of the environmental effects of pollutants XIII Endrin. Oak Ridge National Laboratory, Oak Ridge (EPA-600/1-79-005)Google Scholar
  14. Ecker S, Horak O (1994) Pathways of HCB-contamination to oil pumpkin seeds. Chemosphere 29:2135–2145CrossRefGoogle Scholar
  15. Fantroussi SE, Agathos SN (2005) Is bioaugmentation a feasible strategy for pollutant removal and site remediation? Curr Opin Microbiol 8:268–275CrossRefGoogle Scholar
  16. Gans J, Wolinsky M, Dunbar J (2005) Computational improvements reveal great bacterial diversity and high metal toxicity in soil. Science 309:1387–1390CrossRefGoogle Scholar
  17. Gao HJ, Jiang X, Wang F, Wang DZ, Bian YR (2005) Residual levels and bioaccumulation of chlorinated persistent organic pollutants (POPs) in vegetables from suburb of Nanjing, People’s Republic of China. Bull Environ Contam Toxixol 74:673–680CrossRefGoogle Scholar
  18. Georgacakis E, Khan MAQ (1971) Toxicity of the photoisomers of cyclodiene insecticides to freshwater animals. Nature 233:120–121CrossRefGoogle Scholar
  19. Goldstein RM, Mallory LM, Alexander M (1985) Reasons for possible failure of inoculation to enhance biodegradation. Appl Environ Microbiol 50:977–983Google Scholar
  20. Gonçalves C, Alpendurada MF (2005) Assessment of pesticide contamination in soil samples from an intensive horticulture area, using ultrasonic extraction and gas chromatography-mass spectrometry. Talanta 65:1179–1189CrossRefGoogle Scholar
  21. Harner T, Wideman JL, Jantunen LMM, Bidleman TF, Parkhurst WJ (1999) Residues of organochlorine pesticides in Alabama soils. Environ Pollut 106:323–332CrossRefGoogle Scholar
  22. Hashimoto Y (2005) Dieldrin residue in the soil and cucumber from agricultural field in Tokyo. J Pestic Sci 30:397–402CrossRefGoogle Scholar
  23. Hilber I, Mäder P, Schulin R, Wyss GS (2008) Survey of organochlorine pesticides in horticultural soils and there grown Cucurbitaceae. Chemosphere 73:954–961CrossRefGoogle Scholar
  24. Hiraishi A (2003) Biodiversity of dioxin-degrading microorganisms and potential utilization in bioremediation. Microbes Environ 18:105–125CrossRefGoogle Scholar
  25. Hong SH, Yim UH, Shim WJ, Li DH, Oh JR (2006) Nationwide monitoring of polychlorinated biphenyls and organochlorine pesticides in sediments from coastal environment of Korea. Chemosphere 64:1479–1488CrossRefGoogle Scholar
  26. Hugenholtz P, MacRae IC (1990) Stimulation of aldrin and dieldrin loss from soils treated with carbon amendments and saturated-ring analogues. Bull Environ Contam Toxicol 45:223–227CrossRefGoogle Scholar
  27. Hülster A, Muller JF, Marschner H (1994) Soil-plant transfer of polychlorinated dibenzo-p-dioxins and dibenzofurans to vegetables of the cucumber family (Cucurbitaceae). Environ Sci Technol 28:1110–1115CrossRefGoogle Scholar
  28. Hung DQ, Thiemann W (2002) Contamination by selected chlorinated pesticides in surface waters in Hanoi, Vietnam. Chemosphere 47:357–367CrossRefGoogle Scholar
  29. Inui H, Wakai T, Gion K, Kim YS, Eun H (2008) Differential uptake for dioxin-like compounds by zucchini subspecies. Chemosphere 73:1602–1607CrossRefGoogle Scholar
  30. IPCS (1998) International Chemical Safety Card—Dieldrin. World Health Organization/International Programme on Chemical Safety, Geneva (ICSC 0787)Google Scholar
  31. IPCS (2000) International Chemical Safety Card—Endrin. World Health Organization/International Programme on Chemical Safety, Geneva (ICSC 1023)Google Scholar
  32. Jiries AG, Al Nasir FM, Beese F (2002) Pesticide and heavy metals residue in wastewater, soil and plants in wastewater disposal site near Al-Lajoun Valley, Karak/Jordan. Water Air Soil Pollut 133:97–107CrossRefGoogle Scholar
  33. Johgenson JE (2001) Aldrin and dieldrin: a review of research on their production, environmental deposition and fate, bioaccumulation, toxicology, and epidemiology in the United States. Environ Health Perspect 109:113–139CrossRefGoogle Scholar
  34. Katayama A, Matsumura F (1993) Degradation of organochlorine pesticides, particularly endosulfan, by Trichoderma harzianum. Environ Toxicol Chem 12:1059–1065CrossRefGoogle Scholar
  35. Kennedy DW, Aust SD, Bumpus JA (1990) Comparative biodegradation of alkyl halide insecticides by the white rot fungus, Phanerochaete chrysosporium (BKM-F-1767). Appl Environ Microbiol 56:2347–2353Google Scholar
  36. Khan SU (1980) Pesticides in the soil environment. Elsevier, AmsterdamGoogle Scholar
  37. Konzdroj J, van Elsas JD (2001) Structural diversity of microorganisms in chemically perturbed soil assessed by molecular and cytochemical approaches. J Microbiol Methods 43:197–212CrossRefGoogle Scholar
  38. Lal R, Saxena DM (1982) Accumulation, metabolism, and effects of organochlorine insecticides on microorganisms. Microbiol Rev 46:95–127Google Scholar
  39. Lalah JO, Yugi PO, Jumba IO, Wandiga SO (2003) Organochlorine pesticide residues in Tana and Sabaki Rivers in Kenya. Bull Environ Contam Toxicol 71:298–307CrossRefGoogle Scholar
  40. Lichtenstein EP, Schulz KR, Skrentny RF, Stitt PA (1965) Insecticidal residues in cucumbers and alfalfa grown on aldrin- or heptachlor-treated soils. J Econ Entomol 58:742–746Google Scholar
  41. Lunney AI, Zeeb BA, Reimer KJ (2004) Uptake of weathered DDT in vascular plants: potential for phytoremediation. Environ Sci Technol 38:6147–6154CrossRefGoogle Scholar
  42. Macedo AJ, Timmis KN, Abraham WR (2007) Widespread capacity to metabolize polychlorinated biphenyls by diverse microbial communities in soils with no significant exposure to PCB contamination. Environ Microbiol 9:1890–1897CrossRefGoogle Scholar
  43. Macek T, Mackova M, Kucerova P, Chroma L, Burkhard J, Demnerova K (2002) Phytoremediation. In: Agathos SN, Reineke W (eds) Biotechnology for the environment: soil remediation. Kluwer, London, pp 115–137Google Scholar
  44. Malik A, Ojha P, Singh KP (2009) Levels and distribution of persistent organochlorine pesticide residues in water and sediments of Gomti River (India)—a tributary of the Ganges River. Environ Monit Assess 148:421–435CrossRefGoogle Scholar
  45. Manirakiza P, Akinbamijo O, Covaci A, Pitonzo R, Schepens P (2003) Assessment of organochlorine pesticide residues in west African city farms: Banjul and Dakar case study. Arch Environ Contam Toxicol 44:171–179CrossRefGoogle Scholar
  46. Matin MA, Malek MA, Amin MR, Rahman S, Khatoon J, Rahman M, Aminuddin M, Mian AJ (1998) Organochlorine insecticide residues in surface and underground water from different regions of Bangladesh. Agric Ecosyst Environ 69:11–15CrossRefGoogle Scholar
  47. Matsumoto E, Kawanaka Y, Yun SJ, Oyaizu H (2008) Isolation of dieldrin- and endrin-degrading bacteria using 1, 2-epoxycyclohexane as a structural analog of both compounds. Appl Microbiol Biotechnol 80:1095–1103CrossRefGoogle Scholar
  48. Matsumura F, Boush GM (1967) Dieldrin: degradation by soil microorganisms. Science 156:959–961CrossRefGoogle Scholar
  49. Matsumura F, Boush GM (1968) Degradation of insecticides by a soil fungus, Trichoderma viride. J Econ Entomol 61:610–612Google Scholar
  50. Matsumura F, Patil KC, Boush GM (1970) Formation of “photodieldrin” by microorganisms. Science 170:1206–1207CrossRefGoogle Scholar
  51. Matsumura F, Khanvilkar VG, Patil KC, Boush GM (1971) Metabolism of endrin by certain soil microorganisms. J Agric Food Chem 19:27–31CrossRefGoogle Scholar
  52. Mattina MJI, Iannucci-Berger W, Dykas L (2000) Chlordane uptake and its translocation in food crops. J Agric Food Chem 48:1909–1915CrossRefGoogle Scholar
  53. Mattina MJI, Eitzer BD, Iannucci-Berger W, Lee WY, White JC (2004) Plant uptake and translocation of highly weathered, soil-bound technical chlordane residues: data from field and rhizotron studies. Environ Toxicol Chem 23:2756–2762CrossRefGoogle Scholar
  54. Mattina MJI, Berger WA, Eitzer BD (2007) Factors affecting the phytoaccumulation of weathered, soil-borne organic contaminants: analyses at the ex Planta and in Planta sides of the plant root. Plant Soil 291:143–154CrossRefGoogle Scholar
  55. Maule A, Plyte S, Quirk AV (1987) Dehalogenation of organochlorine insecticides by mixed anaerobic microbial populations. Pestic Biochem Physiol 27:229–236CrossRefGoogle Scholar
  56. Mawussi G, Sanda K, Merlina G, Pinelli E (2009) Assessment of average exposure to organochlorine pesticides in southern Togo from water, maize (Zea mays) and cowpea (Vigna unguiculata). Food Addit Contam Part A Chem Anal Control Expo Risk Assess 26:348–354Google Scholar
  57. McDougall KW, Harris CR, Fenton IG, Dowman A (1995) Persistence and effect of management practices on organochlorine residues in soils of sub-tropical New South Wales. Bull Environ Contam Toxicol 54:177–184CrossRefGoogle Scholar
  58. Meijer SN, Halsall CJ, Harner T, Peters AJ, Ockenden WA, Johnston AE, Jones KC (2001) Organochlorine pesticide residues in archived UK soil. Environ Sci Technol 35:1989–1995CrossRefGoogle Scholar
  59. Mohn WW, Tiedje JM (1992) Microbial reductive dehalogenation. Microbiol Rev 56:482–507Google Scholar
  60. Otani T, Seike N (2006) Comparable effects of rootstock and scion on dieldrin and endrin uptake by grafted cucumber (Cucumis sativus). J Pestic Sci 31:316–321CrossRefGoogle Scholar
  61. Otani T, Seike N (2007) Rootstock control of fruit dieldrin concentration in grafted cucumber (Cucurmis sativus). J Pestic Sci 32:235–242CrossRefGoogle Scholar
  62. Otani T, Seike N, Sakata Y (2007) Differential uptake of dieldrin and endrin from soil by several plant families and Cucurbita genera. Soil Sci Plant Nutr 53:86–94CrossRefGoogle Scholar
  63. Otsubo Y, Kudo T, Tsuda M, Nagata Y (2004) Strategy for bioremediation of polychlorinated biphenyl. Appl Microbiol Biotechnol 65:250–258Google Scholar
  64. Ozkoc HB, Bakan G, Ariman S (2007) Distribution and bioaccumulation of organochlorine pesticides along the Black Sea coast. Environ Geochem Health 29:59–68CrossRefGoogle Scholar
  65. Patil KC, Matsumura F, Boush GM (1970) Degradation of endrin, aldrin, and DDT by soil microorganisms. Appl Microbiol 19:879–881Google Scholar
  66. Philips TM, Seech AG, Lee H, Trevors JT (2005) Biodegradation of hexachlorocyclohexane (HCH) by microorganisms. Biodegradation 16:363–392CrossRefGoogle Scholar
  67. Pilon-Smits E (2005) Phytoremediation. Annu Rev Plant Biol 56:15–39CrossRefGoogle Scholar
  68. Richardson PT, Baker DA, Ho LC (1982) The chemical composition of cucurbit vascular exudates. J Exp Bot 33:1239–1247CrossRefGoogle Scholar
  69. Shegunova P, Klánová J, Holoubek I (2007) Residues of organochlorinated pesticides in soils from the Czech Republic. Environ Pollut 146:257–261CrossRefGoogle Scholar
  70. Siddarame Gowda TK, Sethunathan N (1977) Endrin decomposition in soils as influenced by aerobic and anaerobic conditions. Soil Sci 124:5–9CrossRefGoogle Scholar
  71. Singh RP (2001) Comparison of organochlorine pesticide levels in soil and groundwater of Agra, India. Bull Environ Contam Toxicol 67:126–132CrossRefGoogle Scholar
  72. Singh SK, Raha P, Banerjee H (2006) Banned organochlorine cyclodiene pesticide in ground water in Varanasi, India. Bull Environ Contam Toxicol 76:935–941CrossRefGoogle Scholar
  73. Škrbić B (2007) Organochlorine and organophosphate pesticide residues in wheat varieties from Serbia. Food Addit Contam Part A Chem Anal Control Expo Risk Assess 24:695–703Google Scholar
  74. Vogel TM (1996) Bioaugmentation as a soil bioremediation approach. Curr Opin Biotechnol 7:311–316CrossRefGoogle Scholar
  75. Wan MT, Kuo J, Pasternak J (2005) Residues of endosulfan and other selected organochlorine pesticides in farm areas of the lower Fraser valley, British Columbia, Canada. J Environ Qual 34:1186–1193CrossRefGoogle Scholar
  76. Wang F, Jiang X, Bian Y, Yao F, Gao H, Yu G, Munch JC, Schroll R (2007a) Organochlorine pesticides in soils under different land usage in the Taihu lake region, China. J Environ Sci 19:584–590CrossRefGoogle Scholar
  77. Wang H, He M, Lin C, Quan X, Guo W, Yang Z (2007b) Monitoring and assessment of persistent organochlorine residues in sediments from the Daliaohe river watershed, northeast of China. Environ Monit Assess 133:231–242CrossRefGoogle Scholar
  78. Watanabe K, Yoshikawa H (2008) Enrichment and isolation of anaerobic microorganisms concerned with reductive degradation of hexachlorobenzene from soils. J Pestic Sci 33:166–170CrossRefGoogle Scholar
  79. Watanabe K, Yoshikawa H, Goto M, Furukara K (2007) Enrichment and isolation of novel anaerobic microorganisms capable of degrading various kinds of POPs. Organohalogen Compounds 69:2500–2503Google Scholar
  80. Wedemeyer G (1968) Partial hydrolysis of dieldrin by Aerobacter aerogenes. Appl Microbiol 16:661–662Google Scholar
  81. White JC (2001) Plant-facilitated mobilization and translocation of weathered 2, 2-bis(p-chlorophenyl)-1, 1-dichloroethylene (p, p’-DDE) from an agricultural soil. Environ Toxicol Chem 20:2047–2052CrossRefGoogle Scholar
  82. White JC, Wang X, Gent MPN, Iannucci-Berger W, Eitzer BD, Schultes NP, Arienzo M, Mattina MI (2003a) Subspecies-level variation in the phytoextraction of weathered p, p’-DDE by Cucurbita pepo. Environ Sci Technol 37:4367–4373CrossRefGoogle Scholar
  83. White JC, Mattina MI, Lee WY, Eitzer BD, Iannucci-Berger W (2003b) Role of organic acids in enhancing the desorption and uptake of weathered p, p’-DDE by Cucurbita pepo. Environ Pollut 124:71–80CrossRefGoogle Scholar
  84. White JC, Parrish ZD, Isleyen M, Gent MPN, Iannucci-Berger W, Eitzer BD, Kelsey JW, Mattina MI (2006) Influence of citric acid amendments on the availability of weathered PCBs to plant and earthworm species. International Journal of Phytoremediation 8:63–79CrossRefGoogle Scholar
  85. WHO/IPCS (1989) Aldrin and Dieldrin, Environmental Health Criteria 91. WHO/IPCS, GenevaGoogle Scholar
  86. WHO/IPCS (1992) Endrin—Environmental Health Criteria 130. WHO/IPCS, GenevaGoogle Scholar
  87. Zhang Z, Hong H, Zhou JL, Yu G, Chen W, Wang X (2002) Transport and fate of organochlorine pesticides in the River Wuchuan, Southeast China. J Environ Monit 4:435–441CrossRefGoogle Scholar

Copyright information

© Springer-Verlag 2009

Authors and Affiliations

  • Emiko Matsumoto
    • 1
  • Youhei Kawanaka
    • 1
  • Sun-Ja Yun
    • 1
  • Hiroshi Oyaizu
    • 2
  1. 1.The Institute of Basic Environmental ResearchEnvironmental Control Center Co., Ltd.TokyoJapan
  2. 2.Biotechnology Research CenterThe University of TokyoTokyoJapan

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