Growth of streptomycetes in soil and their impact on bioremediation

Journal of Hazardous Materials

Volumn 267, Issue , 2014, Pages 128-135

  Schütze, Eileen ^a   Klose, Michael ^a   Merten, Dirk ^a   Nietzsche, Sandor ^b   Senftleben, Dominik ^a   Roth, Martin ^c   Kothe, Erika ^a  

^a FRIEDRICH SCHILLER UNIVERSITY JENA   (Germany)

^b JENA UNIVERSITY HOSPITAL   (Germany)

^c HANS KNÖLL INSTITUTE   (Germany)

Author keywords

Bioremediation; Heavy metals; Phytoextraction; REE; Streptomycetes

Indexed keywords

CONTAMINATED SOILS; HEAVY METAL CONTAMINATED SOILS; METAL MOBILIZATIONS; METAL-CONTAMINATED SOILS; PHYTOEXTRACTION; PLANT GROWTH PROMOTING; REE; STREPTOMYCETES;

BACTERIA; BIOREMEDIATION; BIOTECHNOLOGY; HEAVY METALS; METALS; SOIL POLLUTION CONTROL; SOILS;

SOIL POLLUTION;

HEAVY METAL;

ADSORPTION; BACTERIUM; BIOREMEDIATION; GROWTH RATE; MOBILIZATION; PHYTOREMEDIATION; SOIL MICROORGANISM; SOIL POLLUTION; SOIL REMEDIATION; SOIL STABILIZATION; SORGHUM;

ACTINOMYCETALES; ADSORPTION; ARTICLE; BACTERIAL GROWTH; BIOMASS; BIOREMEDIATION; CONTROLLED STUDY; DRY WEIGHT; MICROCOSM; NONHUMAN; PHYTOREMEDIATION; PLANT GROWTH; SOIL INOCULATION; SOIL POLLUTION; SORGHUM; STREPTOMYCES; STREPTOMYCES LIVIDANS; STREPTOMYCES MIRABILIS; STREPTOMYCETACEAE;

BIOREMEDIATION; HEAVY METALS; PHYTOEXTRACTION; REE; STREPTOMYCETES;

BIODEGRADATION, ENVIRONMENTAL; BIOMASS; CHLOROPHYLL; DNA; ENVIRONMENTAL POLLUTANTS; FLUORESCENCE; METALS; MICROSCOPY, ELECTRON, SCANNING; SOIL MICROBIOLOGY; SORGHUM; STREPTOMYCES;

EID: 84892473169     PISSN: 03043894     EISSN: 18733336     Source Type: Journal    
DOI: 10.1016/j.jhazmat.2013.12.055     Document Type: Article

References (53)

1. Huang P.-M., Wang M.-K., Chiu C.-Y. Soil mineral-organic matter-microbe interactions: impacts on biogeochemical processes and biodiversity in soils. Pedobiologia 2005, 49:609-635.
2. de Jonge L.W., Moldrup P., Schjonning P. Soil infrastructure, interfaces & translocation processes in inner space ('soil-it-is'): towards a road map for the constraints and crossroads of soil architecture and biophysical processes. Hydrology and Earth System Sciences 2009, 13:1485-1502.
3. Lamparter A., Bachmann J., Goebel M.O., Woche S.K. Carbon mineralization in soil: impact of wetting-drying, aggregation and water repellency. Geoderma 2009, 150:324-333.
4. Banks D., Younger P.L., Arnesen R.T., Iversen E.R., Banks S.B. Mine-water chemistry: the good, the bad and the ugly. Environmental Geology 1997, 32:157-174.
5. Haferburg G., Kothe E. Microbes and metals: interactions in the environment. Journal of Basic Microbiology 2007, 47:453-467.
6. Xie X.H., Xiao S.M., Liu J.S. Microbial communities in acid mine drainage and their interaction with pyrite surface. Current Microbiology 2009, 59:71-77.
7. Kothe E., Bergmann H., Büchel G. Molecular mechanisms in bio-geo-interactions: from a case study to general mechanisms. Chemie der Erde - Geochemistry 2005, 65(S1):7-27.
8. Liang H.C., Thomson B.M. Minerals and mine drainage. Water Environment Research 2009, 81:1615-1663.
9. Evangelou V.P., Zhang Y.L. A review: pyrite oxidation mechanisms and acid mine drainage prevention. Critical Reviews in Environmental Science and Technology 1995, 25:141-199.
10. Jabeen R., Ahmad A., Iqbal M. Phytoremediation of heavy metals: physiological and molecular mechanisms. Botanical Review 2009, 75:339-364.
11. Van Nevel L., Mertens J., Oorts K., Verheyen K. Phytoextraction of metals from soils: how far from practice?. Environmental Pollution 2007, 150:34-40.
12. Rosselli W., Keller C., Boschi K. Phytoextraction capacity of trees growing on a metal contaminated soil. Plant and Soil 2003, 256:265-272.
13. Kamaludeen S.P.B., Ramasamy K. Rhizoremediation of metals: harnessing microbial communities. Indian Journal of Microbiology 2008, 48:80-88.
14. Kuffner M., Puschenreiter M., Wieshammer G., Gorfer M., Sessitsch A. Rhizosphere bacteria affect growth and metal uptake of heavy metal accumulating willows. Plant and Soil 2008, 304:35-44.
15. Nogueira M.A., Nehls U., Hampp R., Poralla K., Cardoso E. Mycorrhiza and soil bacteria influence extractable iron and manganese in soil and uptake by soybean. Plant and Soil 2007, 298:273-284.
16. Shao H.B., Chu L.Y., Ruan C.J., Li H., Guo D.G., Li W.X. Understanding molecular mechanisms for improving phytoremediation of heavy metal-contaminated soils. Critical Reviews in Biotechnology 2010, 30:23-30.
17. Lasat M.M. Phytoextraction of toxic metals: a review of biological mechanisms. Journal of Environmental Quality 2002, 31:109-120.
18. Epelde L., Mijangos I., Becerril J.M., Garbisu C. Soil microbial community as bioindicator of the recovery of soil functioning derived from metal phytoextraction with sorghum. Soil Biology & Biochemistry 2009, 41:1788-1794.
19. Kaplan M., Orman Å., Kadar I., Koncz J. Heavy metal accumulation in calcareous soil and sorghum plants after addition of sulphur-containing waste as a soil amendment in Turkey. Agriculture, Ecosystems & Environment 2005, 111:41-46.
20. Mendoza J., Garrido T., Castillo G., Martin N.S. Metal availability and uptake by Sorghum plants grown in soils amended with sludge from different treatments. Chemosphere 2006, 65:2304-2312.
21. Murillo J.M., Maranon T., Cabrera F., Lopez R. Accumulation of heavy metals in sunflower and Sorghum plants affected by the Guadiamar spill. Science of the Total Environment 1999, 242:281-292.
22. Zhuang P., Shu W., Li Z., Liao B., Li J., Shao J. Removal of metals by Sorghum plants from contaminated land. Journal of Environmental Sciences 2009, 21:1432-1437.
23. Massoud M.I. Suitability of Sorghum bicolor L. stalks and grains for bioproduction of ethanol. Annals of Agricultural Sciences 2011, 56:83-87.
24. Medeiros C.A.B., Clark R.B., Ellis J.R. Growth and nutrient uptake of sorghum cultivated with vesicular-arbuscular mycorrhiza isolates at varying pH. Mycorrhiza 1994, 4:185-191.
25. Toler H.D., Morton J.B., Cumming J.R. Growth and metal accumulation of mycorrhizal Sorghum exposed to elevated copper and zinc. Water, Air & Soil Pollution 2005, 164:155-172.
26. Yamato M., Ikeda S., Iwase K. Community of arbuscular mycorrhizal fungi in a coastal vegetation on Okinawa island and effect of the isolated fungi on growth of Sorghum under salt-treated conditions. Mycorrhiza 2008, 18:241-249.
27. Jankong P., Visoottiviseth P., Khokiattiwong S. Enhanced phytoremediation of arsenic contaminated land. Chemosphere 2007, 68:1906-1912.
28. Schindler F., Gube M., Kothe E. Bioremediation and heavy metal uptake: microbial approaches at field scale. Bio-Geo Interactions in Metal-Contaminated Soils 2012, 365-383. Springer, Heidelberg.
29. Schütze E., Kothe E. Heavy metal-resistant streptomycetes in soil. Soil Biology 2012, Springer-Verlag, Berlin, Heidelberg.
30. Schmidt A., Haferburg G., Schmidt A., Lischke U., Merten D., Ghergel F., Büchel G., Kothe E. Heavy metal resistance to the extreme: Streptomyces strains from a former uranium mining area. Chemie der Erde - Geochemistry 2008, 69:35-44.
31. Amoroso M.J., Oliver G., Castro G.R. Estimation of growth inhibition by copper and cadmium in heavy metal tolerant actinomycetes. Journal of Basic Microbiology 2002, 42:231-237.
32. Ravel J., Wellington E.M., Hill R.T. Interspecific transfer of Streptomyces giant linear plasmids in sterile amended soil microcosms. Applied and Environmental Microbiology 2000, 66:529-534.
33. Schmidt A., Haferburg G., Sineriz M., Merten D., Büchel G., Kothe E. Heavy metal resistance mechanisms in actinobacteria for survival in AMD contaminated soils. Chemie der Erde - Geochemistry 2005, 65:131-144.
34. Zeien H., Brümmer G.W. Chemische Extraktion zur Bestimmung der Schwermetallbindungsformen in Böden 1989, vol. 59/I:505-515. Mitteilungen der Deutsche Bodenkundliche Gesellschaft, Sonderh.
35. Taylor S.R., McLennan S.M. The Continental Crust: Its Composition and Evolution 1985, Blackwell, Oxford.
36. Maxwell K., Johnson G.N. Chlorophyll fluorescence - a practical guide. Journal of Experimental Botany 2000, 51:659-668.
37. Albarracin V.H., Avila A.L., Amoroso M.J., Abate C.M. Copper removal ability by Streptomyces strains with dissimilar growth patterns and endowed with cupric reductase activity. FEMS Microbiology Letters 2008, 288:141-148.
38. Benimeli C.S., Polti M.A., Albarracín V.H., Abate C.M., Amoroso M.J., Khan M.S., Zaidi A., Goel R., Musarrat J. Bioremediation potential of heavy metal-resistant actinobacteria and maize plants in polluted soil. Biomanagement of Metal-Contaminated Soils 2011, 459-477. Springer, Netherlands. M.S. Khan, A. Zaidi, R. Goel, J. Musarrat (Eds.).
39. Haferburg G., Merten D., Büchel G., Kothe E. Biosorption of metal and salt tolerant microbial isolates from a former uranium mining area. Their impact on changes in rare earth element patterns in acid mine drainage. Journal of Basic Microbiology 2007, 47:474-484.
40. Gremion F., Chatzinotas A., Harms H. Comparative 16S rDNA and 16S rRNA sequence analysis indicates that Actinobacteria might be a dominant part of the metabolically active bacteria in heavy metal-contaminated bulk and rhizosphere soil. Environmental Microbiology 2003, 5:896-907.
41. Navarro-Noya Y., Jan-Roblero J., del Carmen González-Chávez M., Hernández-Gama R., Hernández-Rodríguez C. Bacterial communities associated with the rhizosphere of pioneer plants growing on heavy metals-contaminated soils. Antonie Van Leeuwenhoek 2010, 97:335-349.
42. Margesin R., Plazab G.A., Kasenbacher S. Characterization of bacterial communities at heavy-metal-contaminated sites. Chemosphere 2011, 82:1583-1588.
43. Kuffner M., De Maria S., Puschenreiter M., Fallmann K., Wieshammer G., Gorfer M., Strauss J., Rivelli A.R., Sessitsch A. Culturable bacteria from Zn- and Cd-accumulating Salix caprea with differential effects on plant growth and heavy metal availability. Journal of Applied Microbiology 2010, 108:1471-1484.
44. Sessitsch A., Puschenreiter M., Dion P., Nautiyal C.S. Endophytes and rhizosphere bacteria of plants growing in heavy metal-containing soils microbiology of extreme soils. Microbiology of Extreme Soils 2008, 317-332. Springer, Berlin, Heidelberg. P. Dion, C. Shekhar Nautiyal (Eds.).
45. Merten D., Geletneky J., Bergmann H., Haferburg G., Kothe E., Büchel G. Rare earth element patterns: a tool for understanding processes in remediation of acid mine drainage. Chemie der Erde - Geochemistry 2005, 65(S1):97-114.
46. Acheampong M.A., Meulepas R.J.W., Lens P.N.L. Removal of heavy metals and cyanide from gold mine wastewater. Journal of Chemical Technology and Biotechnology 2010, 85:590-613.
47. Amoroso M.J., Castro G.R., Duran A., Peraud O., Oliver G., Hill R.T. Chromium accumulation by two Streptomyces spp. isolated from riverine sediments. Journal of Industrial Microbiology & Biotechnology 2001, 26:210-215.
48. Lin Y., Wang X., Wang B., Mohamad O., Wei G. Bioaccumulation characterization of zinc and cadmium by Streptomyces zinciresistens, a novel actinomycete. Ecotoxicology and Environmental Safety 2012, 77:7-17.
49. Dimkpa C.O., Merten D., Svatos A., Büchel G., Kothe E. Metal-induced oxidative stress impacting plant growth in contaminated soil is alleviated by microbial siderophores. Soil Biology and Biochemistry 2009, 41:154-162.
50. Dimkpa C., Svatos A., Merten D., Büchel G., Kothe E. Hydroxamate siderophores produced by Streptomyces acidiscabies E13 bind nickel and promote growth in cowpea (Vigna unguiculata L.) under nickel stress. Canadian Journal of Microbiology 2008, 54:163-172.
51. Bruins M.R., Kapil S., Oehme F.W. Microbial resistance to metals in the environment. Ecotoxicology and Environmental Safety 2000, 45:198-207.
52. Gadd G.M. Bioremedial potential of microbial mechanisms of metal mobilization and immobilization. Current Opinion in Biotechnology 2000, 11:271-279.
53. Schütze E., Kothe E. Heavy metal-resistant streptomycetes in soil. Soil Biology 2012, Springer, Heidelberg.