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Geomicrobiology Journal Volume 33, 2016 - Issue 3-4: Biomineralization, Bioremediation and Biorecovery of Toxic Metals and Radionuclides
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Original Articles

Bioremediation of Cesium-Contaminated Soil by Sorghum Bicolor and Soil Microbial Community Analysis

Xu WangCollaborative Innovation Center for Advanced Nuclear Energy Technology, INET, Tsinghua University, Beijing, China
,
Can ChenCollaborative Innovation Center for Advanced Nuclear Energy Technology, INET, Tsinghua University, Beijing, China
&
Jianlong WangCollaborative Innovation Center for Advanced Nuclear Energy Technology, INET, Tsinghua University, Beijing, China;Beijing Key Laboratory of Radioactive Waste Treatment, Tsinghua University, Beijing, ChinaCorrespondence[email protected]
Pages 216-221 | Received 23 Aug 2015, Accepted 24 Aug 2015, Published online: 04 Aug 2015

References

  • Avery SV, Codd GA, Gadd GM. 1991. Cesium accumulation and interactions with other monovalent cations in the Cyanobacterium Synechocystis PCC-6803. J Gen Microbiol 137:405–413.
  • Avery SV, Codd GA, Gadd GM. 1995. Characterization of cesium transport in the microalga Chlorella salina. Biochem Soc Trans 23:S468–S468.
  • Broadley MR, Willey NJ, Mead A. 1999. A method to assess taxonomic variation in shoot caesium concentration among flowering plants. Environ Pollut 106:341–349.
  • Calvino M, Messing J. 2012. Sweet sorghum as a model system for bioenergy crops. Curr Opin Biotech 23:323–329.
  • Chiang PN, Wang MK, Wang JJ, Chiu C. 2005. Low-molecular-weight organic acid exudation of RAPF (Brassica campestris) roots in cesium-contaminated soils. Soil Sci 170:726–733.
  • Classen AT, Boyle SI, Haskins KE, Overby ST, Hart SC. 2003. Community-level physiological profiles of bacteria and fungi: plate type and incubation temperature influences on contrasting soils. FEMS Microbiol Ecol 44:319–328.
  • Cook LL, Inouye RS, McGonigle TP, White GJ. 2007. The distribution of stable cesium in soils and plants of the eastern Snake River Plain in southern Idaho. J Arid Environ 69:40–64.
  • Cook LL, Inouye RS, McGonigle TP. 2009. Evaluation of four grasses for use in phytoremediation of Cs-contaminated arid land soil. Plant Soil 324:169–184.
  • Djedidi S, Kojima K, Yamaya H, Ohkama-Ohtsu N, Bellingrath-Kimura SD, Watanabe I, Yokoyama T. 2014. Stable cesium uptake and accumulation capacities of five plant species as influenced by bacterial inoculation and cesium distribution in the soil. J Plant Res 127:585–597.
  • Dushenkov S. 2003. Trends in phytoremediation of radionuclides. Plant Soil 249:167–175.
  • Gadd GM. 1996. Influence of microorganisms on the environmental fate of radionuclides. Endeavour 20:150–156.
  • Gadd GM. 2000. Bioremedial potential of microbial mechanisms of metal mobilization and immobilization. Curr Opin Biotechnol 11:271–279.
  • Gadd GM. 2004. Microbial influence on metal mobility and application for bioremediation. Geoderma 122:109–119.
  • Gadd GM. 2008. Bacterial and fungal geomicrobiology: a problem with communities? Geobiol 6:278–284.
  • Gadd GM. 2010. Metals, minerals and microbes: geomicrobiology and bioremediation. Microbiology 156:609–643.
  • Gadd GM, Gharieb MM, Ramsay LM, Sayer JA, Whatley AR, White C. 1998. Fungal processes for bioremediation of toxic metal and radionuclide pollution. J Chem Technol Biotechnol 71:364–366.
  • Gadd GM, Rhee YJ, Stephenson K, Wei Z. 2012. Geomycology: metals, actinides and biominerals. Environ Microbiol Rept 4:270–296.
  • Garau G, Castaldi P, Santona L, Deiana P, Melis P. 2007. Influence of red mud, zeolite and lime on heavy metal immobilization, culturable heterotrophic microbial populations and enzyme activities in a contaminated soil. Geoderma 142:47–57.
  • Garland JL. 1996. Analytical approaches to the characterization of samples of microbial communities using patterns of potential C source utilization. Soil Biol Biochem 28:213–221.
  • Garland JL. 1997. Analysis and interpretation of community-level physiological profiles in microbial ecology. FEMS Microbiol Ecol 24:289–300.
  • Garland JL, Mills AL, Young JS. 2001. Relative effectiveness of kinetic analysis vs single point readings for classifying environmental samples based on community level physiological profiles (CLPP). Soil Biol Biochem 33:1059–1066.
  • Gomez E, Ferreras L, Toresani S. 2006. Soil bacterial functional diversity as influenced by organic amendment application. Bioresour Technol 97:1484–1489.
  • Gomez E, Garland J, Conti M. 2004. Reproducibility in the response of soil bacterial community-level physiological profiles from a land use intensification gradient. Appl Soil Ecol 26:21–30.
  • Hmid A, Al Chami Z, Sillen W, De Vocht A, Vangronsveld J. 2015. Olive mill waste biochar: a promising soil amendment for metal immobilization in contaminated soils. Environ Sci Poll R 22:1444–1456.
  • Kong WD, Zhu YG, Fu BJ, Marschner P, He JZ. 2006. The veterinary antibiotic oxytetracycline and Cu influence functional diversity of the soil microbial community. Environ Poll 143:129–137.
  • Lloyd JR, Gadd GM. 2011. The Geomicrobiology of radionuclides. Geomicrobiol J 28:383–386.
  • Luo K, Ma TT, Liu HY, Wu LH, Ren J, Nai FJ, Li R, Chen LK, Luo YM, Christie P. 2015. Efficiency of repeated rhytoextraction of cadmium and zinc from an agricultural soil contaminated with sewage sludge. Int J Phytoremed 17:575–582.
  • Marchiol L, Fellet G, Perosa D, Zerbi G. 2007. Removal of trace metals by Sorghum bicolor and Helianthus annuus in a site polluted by industrial wastes: a field experience. Plant Physiol Biochem 45:379–387.
  • Pinto AP, de Varennes A, Goncalves MLS, Mota AM. 2006. Sorghum detoxification mechanisms. J Plant Nutr 29:1229–1242.
  • Qin SJ, Jiao KB, Lyu DG, Shi L, Liu LZ. 2015. Effects of maize residue and cellulose-decomposing bacteria inocula on soil microbial community, functional diversity, organic fractions, and growth of Malus hupehensis Rehd. Arch Agron Soil Sci 61:173–184.
  • Tang S, Liao S, Guo J, Song Z, Wang R, Zhou X. 2011. Growth and cesium uptake responses of Phytolacca americana Linn. and Amaranthus cruentus L. grown on cesium contaminated soil to elevated CO2 or inoculation with a plant growth promoting rhizobacterium Burkholderia sp D54, or in combination. J Hazard Mater 198:188–197.
  • Tian YL, Zhang HY, Guo W, Wei XF. 2015. Morphological responses, biomass yield, and bioenergy potential of sweet sorghum cultivated in cadmium-contaminated soil for biofuel. Int J Green Energy 12:577–584.
  • Tsukada H, Hasegawa H, Hisamatsu S, Yamasaki S. 2002. Rice uptake and distributions of radioactive Cs-137, stable Cs-133 and K from soil. Environ Pollut 117:403–409.
  • Wang JL, Chen C. 2014. Chitosan-based biosorbents: modification and application for biosorption of heavy metals and radionuclides. Bioresource Technol 160:129–141.
  • White PJ, Broadley MR. 2000. Mechanisms of caesium uptake by plants. New Phytol 147:241–256.
  • White PJ, Swarup K, Escobar-Gutierrez AJ, Bowen HC, Willey NJ, Broadley MR. 2003. Selecting plants to minimise radiocaesium in the food chain. Plant Soil 249:177–186.
  • Willey N, Martin MH. 1995. Annual patterns of Cs-133 concentration in British upland vegetation. Chemosphere 30:717–724.
  • Wu H, Tang S, Zhang X, Guo J, Song Z, Tian S, Smith DL. 2009. Using elevated CO2 to increase the biomass of a Sorghum vulgare x Sorghum vulgare var. sudanense hybrid and Trifolium pratense L. and to trigger hyperaccumulation of cesium. J Hazard Mater 170:861–870.
  • Zhu YG, Smolders E. 2000. Plant uptake of radiocaesium: a review of mechanisms, regulation and application. J Exp Bot 51:1635–1645.
  • Zhuang P, Shu W, Li Z, Liao B, Li J, Shao J. 2009. Removal of metals by sorghum plants from contaminated land. J. Environ Sci 21:1432–1437.

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