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International Journal of Phytoremediation Volume 9, 2007 - Issue 2
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Original Articles

Chromate-Tolerant Bacteria for Enhanced Metal Uptake by Eichhornia Crassipes (MART.)

R. A. I. Abou-Shanab Environmental Biotechnology Department, Mubarak City for Scientific Research, Genetic Engineering and Biotechnology Research Institute, Borg El-Arab, Alexandria, Egypt
,
J. S. Angle College of Agricultural and Environmental Sciences, University of Georgia, Athens, Georgia, USA
&
P. van Berkum USDA-ARS, Beltsville, Maryland, USA
Pages 91-105 | Published online: 01 Jun 2007

REFERENCES

  • Abou-Shanab , R.A. 2003 . Ecological and Molecular Studies on the Role of Rhizosphere Microflora on Phytoremediation Efficiency , Ph.D. Thesis, Faculty of Science, Alexandria University, Alexandria, Egypt, Natural Resources Sciences Dept., College Park, University of Maryland, USA
  • Abou-Shanab , R.A. , Angle , J.S. , Delorme , T.A. , Chaney , R.L. , van Berkum , P. , Moawad , H. , Ghanem , K. and Ghozlan , H.A. 2003a . Rhizobacterial effects on nickel extraction from soil and uptake by Alyssum murale . New Phytol , 158 : 219 – 224 .
  • Abou-Shanab , R.A. , Delorme , T.A. , Angle , J.S. , Chaney , R.L. , Ghanem , K. , Moawad , H. and Ghozlan , H.A. 2003b . Phenotypic characterization of microbes in the rhizosphere of Alyssum murale . Int. J. Phytorem , 5 : 367 – 379 .
  • Abou-Shanab , R.A. , Ghozlan , H. , Ghanem , K. and Moawad , H. 2005 . Behavior of bacterial populations isolated from rhizosphere of Diplachne fusca dominant in industrial sites . World J. Microbiol. Biotechnol , 21 : 1095 – 1101 .
  • Altschul , S.F. , Thomas , L.M. , Alejandro , A.S. , Jinghui , Z. , Webb , M. and David , J.L. 1997 . Gapped BLAST and PSt-BLAST: A new generation of protein database search programs . Nucleic Acids Res. , 25 : 3389 – 3402 .
  • Amarger , N. , Bours , M. , Revoy , F. , Allard , M.R. and Laguerre , G. 1994 . Rhizobium tropici nodulates field-grown Phaseolis vulgaris in France . Plant Soil , 161 : 147 – 156 .
  • Ausubel , F.M. , Brent , R. , Kingston , R.E. , Moore , D.D. , Seidman , J.A. , Smith , J.G. and Struhl , K. 1987 . Current Protocols in Molecular Biology , New York : John Wiley .
  • Babich , H. , Schiffenbauer , M. and Statzky , G. 1982 . Effect of sterilization method on toxicity of Cr3+ and Cr6+ to fungi . Microbios. Lett. , 20 : 55 – 64 .
  • Barber , D.A. and Lee , R.B. 1974 . The effect of microorganisms on the absorption of manganese by plants . New Phytol. , 73 : 97 – 106 .
  • Belimov , A.A. , Hontzeas , N. , Safronova , V.I. , Demchinskaya , S.V. , Piluzza , G. , Bullitta , S. and Glick , B.R. 2005 . Cadmium-tolerant plant growth-promoting bacteria associated with the roots of Indian mustard (Brassica juncea L. Czern.) . Soil Biol. Biochem , 37 : 241 – 250 .
  • Bennicelli , R. , Stepniewska , Z. , Banach , A. , Szajnocha , K. and Ostrowski , J. 2004 . The ability of Azolla caroliniana to remove heavy metals (Hg (II), Cr (III), Cr (VI)) from municipal waste water . Chemosph. , 55 : 141 – 146 .
  • Burd , G.I. , Dixon , D.G. and Glick , B.R. 2000 . Plant growth-promoting bacteria that decrease heavy metal toxicity in plants . Can. J. Microbiol. , 46 : 237 – 245 .
  • Camargo , F. A.O. , Okeke , B.C. , Bento , F.M. and Frankenberger , W.T. 2005 . Diversity of chromium-resistant bacteria isolated from soils contaminated with dichromate . Applied Soil Ecology , 29 : 193 – 202 .
  • Campos , J. , Martinez-Pacheco , M. and Cervantes , C. 1995 . Hexavalent-chromium reduction by a chromate-resistant Bacillus sp. strain . Antonie van Leeuwenhoek , 68 : 203 – 208 .
  • Cervantes , C. and Silver , S. 1992 . Plasmid chromate resistance and chromate reduction . Plasmid , 27 : 65 – 71 .
  • Cervantes , C. , Campos-Garcia , J. , Devars , S. , Gutierrez-Corona , F. , Loza-Tavera , H. , Torres-Guzman , J.C. and Moreno-Sanchez , R. 2001 . Interaction of chromium with microorganisms and plants . FEMS Microbiol. Rev. , 25 : 335 – 347 .
  • Cheung , K.H. and Gu , J.D. 2003 . Reduction of chromate (CrO4−2) by an enrichment consortium and an isolate of marine sulfate-reducing bacteria . Chemosph. , 52 : 1523 – 1529 .
  • Chigbo , F.E. , Smith , R.W. and Shore , F.L. 1982 . Uptake of arsenic, cadmium, lead, and mercury from polluted waters by the water-hyacinth Eichhornia crassipes . Environ. Pollut. , A27 : 31 – 36 .
  • Delorme , T.A. , Gagliardi , J.V. , Angle , J.S. and Chaney , R.L. 2001 . Influence of the zinc hyperaccumulator Thlaspi caerulescens J.&C. PresI. and the nonmetal accumulator Trifolium pratense L. on soil microbial populations. . Can. J. Microbio , 47 : 773 – 776 .
  • de Oliveira , I.A. , Vasconcellos , M.J. , Seldin , L. , Paiva , E. , Vargas , M.A. and de Sa Horta , M.N. 2000 . Random amplified polymorphic DNA analysis of effective Rhizobium sp. associated with beans cultivated in Brazilian cerrado soils . Brazilian J. Microbio. , 31 : 39 – 44 .
  • Dushenkov , S. and Kapulnik , R. 2000 . “ Phytofiltration of metals ” . In Phytoremediation of Toxic Metals. Using Plants to Clean Up the Environment , Edited by: Raskin , I. and Ensley , B. 89 – 106 . New York : John Wiley .
  • Ellis , R.J. , Morgan , P. , Weightman , A.J. and Fry , J.C. 2003 . Cultivation dependent approaches for determining bacterial diversity in heavy-metal-contaminated soil . Appl. Environ. Microbiol. , 69 : 3223 – 3230 .
  • Francisco , R. , Alpoim , M.C. and Morais , P.V. 2002 . Diversity of chromium-resistant and reducing bacteria in chromium contaminated activated sludge . J. Appl. Microbiol. , 92 : 837 – 843 .
  • Giller , K.E. , Witter , E. and McGrath , S.P. 1998 . Toxicity of heavy metals to microorganisms and microbial processes in agricultural soils: A review . Soil Biol. Biochem. , 30 : 1389 – 1414 .
  • Glick , R.B. 2003 . Phytoremediation: Synergistic use of plants and bacteria to clean up the environment . Biotech. Advance , 21 : 383 – 393 .
  • Hassen , A. , Saidi , N. , Cherif , M. and Boudabous , A. 1998 . Resistance of environmental bacteria to heavy metals . Biores. Tech. , 64 : 7 – 15 .
  • Kamal , M. , Ghaly , A.E. , Mohmoud , N. and Cote , R. 2004 . Phytoaccumulation of heavy metals by aquatic plants . Environ. Int. , 29 : 1029 – 1039 .
  • Lasat , M.M. 2002 . Phytoextraction of toxic metals: A review of biological mechanisms . J. Environ. Qual. , 31 : 109 – 120 .
  • Luli , G.W. , Talanagi , J.W. , Strohl , W.R. and Pfister , R.M. 1983 . Hexavalent chromium resistant bacteria isolated from river sediments . Appl. Environ. Microbiol. , 46 : 846 – 854 .
  • Maine , M.A. , Sune , N.L. and Lagger , S.C. 2004 . Chromium bioaccumulation: Comparison of the capacity of two floating aquatic macrophytes . Water Res. , 38 : 1494 – 1501 .
  • McGrath , S.P. and Cunliffe , C.H. 1985 . A simplified method for the extraction of the metals Fe, Zn, Cu, Ni, Cd, Pb, Ni, Cr, Co, and Mn from soils and sewage sludge . J. Sci. Food Agric. , 36 : 794 – 798 .
  • Megharaj , M. , Avudainayagam , S. and Naidu , R. 2003 . Toxicity of heaxavalent chromium and its reduction by bacteria isolated from soil contaminated with tannery waste . Curr. Microbiol. , 47 : 51 – 54 .
  • Mengoni , A. , Barzanti , R. , Gonnelli , C. , Gabbrielli , R. and Bazzicalupo , M. 2001 . Characterization of nickel-resistant bacteria isolated from serpentine soil . Environ. Microbiol. , 11 : 691 – 698 .
  • Muramoto , S. and Oki , Y. 1983 . Removal of some heavy metals from polluted water by water hyacinth (Eichhornia crassipes) . Bull. Environ. Contam. Toxicol. , 30 : 170 – 177 .
  • Ohtake , H. and Silver , S. 1994 . “ Bacterial detoxification of toxic chromate ” . In Biological Degradation and Bioremediation of Toxic Chemicals , Edited by: Chaudhry , G.R. 403 – 415 . Portland, OR : Discorides .
  • Pattanapipitpaisal , P. , Brown , N.L. and Macaskie , L.E. 2001 . Chromate reduction and 16 S rRNA identification of bacteria isolated from a Cr (VI)-contaminated site . Appl. Microbiol. Biotechnol. , 57 : 257 – 261 .
  • Paul , A.K. and Pal , A. 2004 . Aerobic chromate reduction by chromium-resistant bacteria isolated from serpentine soil . Microbiol. Res. , 159 : 347 – 354 .
  • Penrose , D.M. and Glick , B.R. 2001 . Levels of 1-aminocyclopropane-1-carboxylic acid (ACC) in exudates and extracts of canola seeds treated with plant growth-promoting bacteria . Can. J. Microbiol. , 47 : 368 – 372 .
  • Qian , J.H. , Zayed , A. , Zhu , Y.L. , Yu , M. and Terry , N. 1999 . Phytoaccumulation of trace elements by wetland plants. III. Uptake and accumulation of ten trace elements by twelve plant species . J. Environ. Qual. , 28 : 448 – 1455 .
  • Ralph , D. , McClelland , M. , Welsh , J. , Baranton , G. and Perolat , P. 1993 . Leptospira species categorized by arbitrary primed polymerase chain reaction (PCR) and by mapped restriction polymorphism in PCR-amplified rRNA genes . J. Bacteriol , 175 : 973 – 981 .
  • Rhodes , M.W. , Kator , H. , Kotob , S. , van Berkum , P. , Kaattari , I. , Vogelbein , W. , Quinn , F. , Floyd , M.M. , Butler , W.R. and Ottinger , C.A. 2003 . Mycobacterium shottsii sp. nov., a slowly growing species isolated from Chesapeake Bay striped bass (Morone saxatilis) . Int. J. Syst. Evol. Microbiol , 53 : 421 – 424 .
  • Rohlf , F.J. 1988 . NTSYS-pc Numerical Taxonomy and Multivariate Analysis System , Setauket, NY : Exeter .
  • Santos , M. and Lenzi , E. A.A. 2000 . The use of aquatic macrophytes (Eichhornia crassipes) as a biological filter in the treatment of lead contaminated effluents . Environ. Technol. , 21 : 615 – 622 .
  • Selenska-Pobell , S. , Evguenieva-Hackenberg , E. , Radeva , G. and Squartini , A. 1996 . Characterization of Rhizobium ‘hedysar’ by RFLP analysis of PCR amplified rDNA and by genomic PCR fingerprinting . J. Appl. Bacteriol. , 80 : 517 – 528 .
  • Selenska-Pobell , S. , Otto , A. and Kutschke , S. 1998 . Identification and discrimination of Thiobacilli using ARDREA, RAPD and Rep-APD . J. Appl. Bacteriol. , 84 : 1085 – 1091 .
  • So , L.M. , Chu , L.M. and Wong , P.K. 2003 . Microbial enhancement of Cu2+ removal capacity of Eichhornia crassipes (Mart.) . Chemosph. , 52 : 1499 – 1503 .
  • Soltan , M.E. and Rashed , M.N. 2003 . Laboratory study on the survival of water hyacinth under several conditions of heavy metal concentrations . Adv. Environ. Res , 7 : 321 – 334 .
  • Srinath , T. , Verma , T. , Ramteke , P.W. and Garg , S.K. 2002 . Chromium (VI) biosorption and bioaccumulation by chromate resistant bacteria . Chemosph. , 48 : 427 – 435 .
  • St-Cyr , L. , Fortin , D. and Campbell , P.G. 1993 . Microscopic observations of the iron plaque of a submerged aquatic plant . Aquat. Bot. , 46 : 155 – 167 .
  • Szulczewski , M.D. , Helmke , P.A. and Bleam , W.F. 1997 . Comparison of XANES analysis and extractions to determine chromium speciation in contaminated soils . Environ. Sci. Technol. , 31 : 2954 – 2959 .
  • Trivedy , R.K. 1998 . “ Water hyacinth based systems for waste treatment ” . In Advances in Wastewater Treatment Technologies , Edited by: Trivedy , R.K. 463 – 486 . Aligarh, , India : Global Science .
  • van Berkum , P , Beyene , D. and Eardly , B.D. 1996 . Phylogenetic relationships among Rhizobium species nodulating the common bean (Phaseolus vulgaris L.) . Int. J. Syst. Bacteriol. , 46 : 240 – 244 .
  • van Berkum , P and Fuhrmann , J.J. 2000 . Evolutionary relationships among the soybean bradyrhizobia reconstructed from 168rRNA gene and internally transcribed spacer region sequence divergence . Int. J. Syst. Evolution. Microbiol. , 50 : 2165 – 2172 .
  • Vesk , P.A. and Allaway , W.G. 1997 . Spatial variation of copper and lead concentrations of water hyacinth plants in a wetland receiving urban run-off . Aquat. Bot. , 59 : 33 – 44 .
  • Vesk , P.A. , Nockolds , C.E. and Allaway , W.G. 1999 . Metal localization in water hyacinth roots from an urban wetland . Plant Cell Environ. , 22 : 149 – 158 .
  • Weis , J.S. and Weis , P. 2004 . Metal uptake, transport and release by wetland plants: Implications for phytoremediation and restoration . Environ. Int. , 30 : 685 – 700 .
  • Welsh , J. and McClelland , M. 1990 . Fingerprinting genomes using PCR with arbitrary primers . Nucleic Acids Res. , 18 : 7213 – 7218 .
  • Whiting , S.N. , De Souza , M. and Terry , N. 2001 . Rhizosphere bacteria mobilize Zn for hyperaccumulator by Thalaspi caerulescens . Environ. Sci. Technol. , 35 : 3144 – 3150 .
  • Williams , J. G.K. , Kubelik , A.R. , Livak , K.J. , Rafalski , J.A. and Tingey , S.V. 1990 . DNA polymorphisms amplified by arbitrary primers are useful as genetic markers . Nucleic Acid Res , 18 : 6531 – 6535 .
  • Zaranyika , M.F. and Ndapwadza , T. 1995 . Uptake of Ni, Zn, Fe, Co, Cr, Pb, Cu and Cd by water hyacinth in Mukuvisi and Manyame rivers, Zimbabwe . J. Environ. Sci. Health A , 30 : 157 – 169 .
  • Zhu , Y.L. , Zayed , A. M. , Qian , J.H. , de Souza , M. and Terry , N. 1999 . Phytoaccumulation of trace elements by wetland plants: II. Water Hyacinth . J. Environ. Qual. , 28 : 339 – 344 .
  • Zurayk , R. , Sukkariyah , B. , Baalbaki , R. and Abi Ghanem , D. 2001 . Chromium phytoaccumulation from solution by selected hydrophytes . Int. J. Phytorem. , 3 : 335 – 350 .

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