A Chromium-Tolerant Plant Growing in Cr-Contaminated Land

REFERENCES

• Ali , M. B. , Vajpayee , P. , Tripathi , R. D. , Rai , U. N. , Singh , S. N. and Singh , S. P. 2003 . Phytoremediation of lead, nickel and copper by Salix acmophylla Boiss.: Role of antioxidant enzymes and antioxidant substances . Bull. Environ. Contam. Toxicol , 70 : 462 – 469 .
   PubMed Web of Science ®Google Scholar
• Asada , K. 1994 . “ Production and action of active oxygen species in photosynthetic tissues ” . In Causes of Photooxidative Stress and Amelioration of Defence Systems in Plants , Edited by: Foyer , C. H. and Mullineaux , P. M. 77 – 104 . Boca Raton, FL : CRC .
   Google Scholar
• Assche , F. Van and Clijsters , H. 1990 . Effect of metals on enzyme activity in plants . Plant Cell Environ , 13 : 195 – 206 .
   Web of Science ®Google Scholar
• Bollard , E. G. 1983 . “ Involvement of unusual elements in plant growth and nutrition. ” . In Encyclopedia of Plant Physiology, Inorganic Plant Nutrition , Edited by: Läuchli , A. and Bielski , R. L. 696 – 744 . Berlin : Springer .
   Google Scholar
• Bonet , A. , Poschenrieder , C. and Barcelo , J. 1991 . Chromium III-ion interaction in Fe-deficient and Fe-sufficient bean plants I. Growth and nutrient content . J. Plant Nutr , 14 : 403 – 414 .
   Web of Science ®Google Scholar
• Cary , E. E. , Allaway , W. H. and Olson , O. E. 1997 . Control of chromium concentrations in food plants. II. Chemistry of chromium in soils and its availability to plants . J. Agric. Food Chem , 25 : 305 – 309 .
   Google Scholar
• Cervantes , C. , Garcia , J. C. , Devars , S. , Corona , F. G. , Tavera , H. L. , Carlos , Torres-Guzman , J. and Sanchez , R. M. 2001 . Interactions of chromium with micro-organisms and plants . FEMS Microb. Rev , 25 : 335 – 347 .
   PubMed Web of Science ®Google Scholar
• Chandra , P. , Sinha , S. and Rai , U. N. 1997 . “ Bioremediation of Cr from water and soil by vascular aquatic plants. In ” . In Phytoremediation of Soil and Water Contaminants , Edited by: Kruger , E. L. , Anderson , T. A. and Coats , J. R. 274 – 282 . Washington, DC : ACS Symposium Series 664, American Chemical Society .
   Google Scholar
• Cheng , W. D. , Zhang , G. P. , Yao , H. G. , Dominy , P. , Wu , W. and Wang , R. Y. 2004 . “ Possibility of predicting heavy-metal contents in rice grains based on DTPA-extracted levels in soil ” . In Commun. Soil Sci. Plant Anal. Vol. 35 , 2731 – 2745 . (19–20)
   Google Scholar
• Clijsters , H. , Cuypers , A. and Vangronsveld , J. 1999 . Physiological responses to heavy metals in plants; Defence against oxidative stress . Zeitschrift fur Naturforsch , 54c : 730 – 734 .
   Google Scholar
• Flores-Tavizón , E. , Alarcón-Herrera , M. T. , González-Elizondo , S. and Olguín , E. J. 2003 . Arsenic tolerating plants from mine sites and hot springs in the semi-arid region of Chihuahua . Mexico. Acra Biotechno. l , 23 : 113 – 119 .
   Google Scholar
• Hara , T. and Sonoda , Y. 1979 . Comparison of the toxicity of heavy metals to cabbage growth . Plant Soil , 51 : 127 – 133 .
   Web of Science ®Google Scholar
• Hauschild , M. Z. 1993 . Putrescine (1,4-diaminobutane) as an indicator of pollution-induced stress in higher plants: Barley and rape stressed with Cr(III) or Cr(VI) . Ecotoxicol. Environ. Saftey , 26 : 228 – 247 .
   PubMed Web of Science ®Google Scholar
• Hunter , J. G. and Vergnano , O. 1953 . “ Trace-element toxicities in oat plants. ” . In The Annals of Applied Biology , Edited by: Marsh , R. W. and Thomas , I. 761 – 776 . Cambridge, UK : Cambridge University Press .
   Google Scholar
• Kabata-Pendias , A. 2001 . Trace Elements in Soils and Plants , (3rd ed.) 413 – 432 . London, CRC
   Google Scholar
• Kabata-Pendias , A. and Pendias , H. 1992 . Trace Elements in Soils and Plants , (2nd ed.) 227 – 233 . London, CRC
   Google Scholar
• Khan , A. G. 2001 . Relationships between chromium biomagnification ratio, accumulation factor, and mycorrhizae in plants growing on tannery effluent-polluted soil . Environ. Int , 26 : 417 – 423 .
   PubMed Web of Science ®Google Scholar
• Kleiman , I. D. and Cogliatti , D. H. 1998 . Chromium removal from aqueous solutions by different plant species . Environ. Technol. , 19 : 1127 – 1132 .
   Web of Science ®Google Scholar
• Lin , C. C. and Kao , C. H. 2000 . Effect of NaCl stress on H2 O2 metabolism in rice leaves . Plant Growth Regul. , 30 : 151 – 155 .
   Web of Science ®Google Scholar
• McGrath , S. P. 1982 . The uptake and translocation of tri-and hexavalent chromium and effects on the growth of oat in flowing nutrient solution and in soil . New Phytologist. , 92 : 381 – 390 .
   Web of Science ®Google Scholar
• Murashige , T. and Skoog , F. 1962 . A revised medium for rapid growth and bio-assays with tobacco tissue cultures . Physiologia Plantarum , 15 : 473 – 497 .
   Web of Science ®Google Scholar
• Pandey , N. and Sharma , C. P. 2003 . Chromium interference in iron nutrition and water relations of cabbage . Environ. Exp. Bot. , 49 : 195 – 200 .
   Web of Science ®Google Scholar
• Poschenrieder , C. , Vazquez , M. D. , Bonet , A. and Barcelö , J. 1991 . Chromium III-ion interaction in iron sufficient and iron deficient bean plants. II. Ultrastructural aspects . J. Plant Nutr. , 14 : 415 – 428 .
   Web of Science ®Google Scholar
• Pratt , P. F. 1966 . “ Chromium. In ” . In Diagnostic Criteria for Plants and Soils , Ch. 9 , Edited by: Chapman , H. D. 136 – 141 . Riverside, CA : University of California Press .
   Google Scholar
• Shanker , A. K. , Djanaguiraman , M. , Sudhagar , R. , Chandrashekar , C. N. and Pathmanabhan , G. 2004 . Differential antioxidative response of ascorbate glutathione pathway enzymes and metabolites to chromium speciation stress in green gram (Vigna radiata L.) R. Wilczek. Cv CO 4) roots . Plant Sci , 166 : 1035 – 1043 .
   Web of Science ®Google Scholar
• Tang , Q. Y. and Feng , M. G. 1997 . Practical Statistics and Its Data Processing System Statistical Software Package , Edited by: Tang , Q. Y. and Feng , M. G. Bejing China Agriculture Press .
   Google Scholar
• Vajpayee , P. , Rai , U. N. , Ali , M. B. , Tripathi , R. D. , Yadav , V. , Sinha , S. and Singh , S. N. Chromium-induced physiologic changes in Vallisneria spiralis L. and its role in phytoremediation of tannery effluent . Bull. Environ. Contam. Toxicol , 67 246 – 256 .
   PubMed Web of Science ®Google Scholar
• Welch , R. M. , Allaway , W. H. , House , W. A. and Kubota , J. 1991 . “ Geographic distribution of trace element problems. In: ” . In Micronutrients in Agriculture , (2 nd ed.) , Edited by: Mortvedt , J. J. , Cox , F. R. , Schumann , L. M. and Welch , R. M. 31 – 37 . Madison, WI : Soil Science Society of America .
   Google Scholar
• Wu , F. B. and Zhang , G.P. 2002 . Genotypic variation in kernel heavy metal concentrations in barley and as affected by soil factors . J Plant Nutri. , 25 ( 6 ) : 1163 – 1173 .
   Web of Science ®Google Scholar
• Wu , F. B. , Zhang , G. P. and Dominy , P. 2003 . Four barley genotypes respond differently to cadmium: Lipid peroxidation and activities of antioxidant capacity . Environ. Exp. Bot. , 50 : 67 – 78 .
   Web of Science ®Google Scholar
• Zayed , A. , Lytle , C. M. , Terry , N. and Qian , J. H. 1998 . Chromium accumulation, translocation and chemical speciation in vegetable crops . Planta , 206 : 293 – 299 .
   Web of Science ®Google Scholar
• Zayed , A. M. and Terry , N. 2003 . Chromium in the environment: factors affecting biological remediation . Plant Soil , 249 : 139 – 156 .
   Web of Science ®Google Scholar