Have a personal or library account? Click to login
Effect of copper upon the actions of sulphate-reducing bacteria isolated from soil contaminated by crude oil and heavy metals / Wpływ miedzi na aktywność bakterii redukujących siarczany wyizolowanych z gleby zanieczyszczonej ropą naftową i metalami ciężkimi Cover

Effect of copper upon the actions of sulphate-reducing bacteria isolated from soil contaminated by crude oil and heavy metals / Wpływ miedzi na aktywność bakterii redukujących siarczany wyizolowanych z gleby zanieczyszczonej ropą naftową i metalami ciężkimi

Environmental Protection and Natural Resources
Volume 26 (2015): Issue 4 (December 2015)
By:
Open Access
|Dec 2015

References

  1. AUERNIK K., KELLY R. 2010. Physiological Versatility of the Extremely Thermoacidophilic Archaeon Metallosphaera sedula Supported by Transcriptomic Analysis of Heterotrophic, Autotrophic, and Mixotrophic Growth. Applied and Environmental Microbiology 76, 3: 931-935.
    Search in Google Scholar
  2. BADURA L. 1984. Rozważania nad stopniem zanieczyszczenia środowiska emisjami przemysłowymi i wynikającymi z tego implikacjami ekologicznymi. Postępy Mikrobiologii 13, 2: 31-62.
    Search in Google Scholar
  3. CABRERA G., PEREZ R., GOMEZ J.M., ABALOS A., CANTERO, D. 2006. Toxic effects of dissolved heavy metals on Desulfovibrio vulgaris and Desulfovibrio sp. strains. Journal of Hazardous Materials, 135: 40-46.
    Search in Google Scholar
  4. CASTRO H.F., WILLIAMS N.H., OGRAM A. 2000. Phylogeny of sulfate-reducing bacteria. FEMS Microbiology Ecology, 31: 1-9.
    Search in Google Scholar
  5. COLLINS M.D., RODRIGUEZ U., ASH C., AGUIRRE M., FARROW J.A.E., MARTINEZ-MURCIAA., PHILLIPS B.A., WILLIAMS A.M., WALLBANKS S. 1991. Phylogenetic analysis of the genus Lactobacillus and related lactic acid bacteria as determined by reverse transcriptase sequencing of 16S rRNA. FEMS Microbiology Letters, 77: 5-12.
    Search in Google Scholar
  6. DURSKA G. 2006. Wpływ miedzi i cynku na wzrost bakterii metylotroficznych wyodrębnionych z gleby ryzosferowej i pozarizosferowej jęczmienia. Zeszyty Naukowe Uniwersytetu Przyrodniczego we Wrocławiu. Rolnictwo LXXXIX, 546: 57-63.
    Search in Google Scholar
  7. EHRLICH H.L. 2001. Vol. 6 Geomicrobial Processes: A Physiological and Biochemical Overview, pp. 117-148, Geomicrobiology, Marcel Dekker, New York.10.1201/9780824744458.ch6
    Search in Google Scholar
  8. FAUQUE G., LEGALL J., BARTON L.L. 1991. Sulfate-reducing and sulfur-reducing Bacteria. In: ‘‘Variations in Autotrophic Life’’ (J.M. Shively and L.L. Barton, Eds.), pp. 271-337, Academic Press Limited, London.
    Search in Google Scholar
  9. HATTORI H. 1992. Influence of heavy metals on microbial activities. Soil Sci. Plant Nutr., 38: 93-100.
    Search in Google Scholar
  10. HUBER G., SPINNLER C., GAMBACORTA A., STETTER K.O. 1989. Metallosphaera sedula gen. nov. and sp. nov. represents a new genus of aerobic, metal-mobilizing, thermoacidophilic archaebacteria. Systematic and Applied Microbiology, 12: 38-47.
    Search in Google Scholar
  11. JONG T., PARRY D.L. 2003. Removal of sulfates and heavy metals by sulfate reducing bacteria in short-term bench scale upflow anaerobic packed bed reactors runs. Water Research, 37: 3379-3389.
    Search in Google Scholar
  12. KABATA-PENDIAS A., PENDIAS H. 1999. Biogeochemia pierwiastków śladowych. PWN, Warszawa.
    Search in Google Scholar
  13. LOVLEY D.R. 1995. Microbial reduction of iron, manganese, and other metals. Advances in agronomy, 54: 175-231.
    Search in Google Scholar
  14. MOOSA S., NEMATI M., HARRISON S.T.L. 2002. A kinetic study on anaerobic reduction of sulphate, Part I: Effect of sulphate concentration. Chemical Engineering Science, 57: 2773-2780.
    Search in Google Scholar
  15. NIES D.H. 1999. Microbial heavy-metal resistance. Applied and Environmental Microbiology 6, 51: 730-750.
    Search in Google Scholar
  16. PETRIE L., NORTH N.N., DOLLHOPF S.L., BALKWILL D.L., KOSTKA L.E. 2003. Enumeration and characterization of iron(III)-reducing microbial communities from acidic subsurface sediments contaminated with uranium. Applied and Environmental Microbiology, 69: 7467-7479.
    Search in Google Scholar
  17. POSTGATE J.R. 1984. The Sulfate-Reducing Bacteria. Cambridge University Press, Cambridge.
    Search in Google Scholar
  18. SANFORD R.A., COLE J.R., TIEDJE J.M. 2002. Characterization and description of Anaeromyxobacter dehalogenans gen. nov., sp. nov., an aryl halorespiring facultative anaerobic myxobacterium. Applied and Environmental Microbiology, 68: 893-900.
    Search in Google Scholar
  19. SHEN Y., BUICK R. 2004. The antiquity of microbial sulfate reduction. Earth Science Reviews, 64: 243-272.
    Search in Google Scholar
  20. SŁABA M., DŁUGOŃSKI J. 2002. Mikrobiologiczne usuwanie i odzyskiwanie metali ciężkich. Postępy Mikrobiologii 2, 41: 167-183.
    Search in Google Scholar
  21. WOLICKA D., BORKOWSKI A. 2007. The geomicrobiological role of sulphates-reducing bacteria in environments contaminated by petroleum products. Geomicrobiology Journal, 24:1-9.
    Search in Google Scholar
  22. WOLICKA D. 2010. Microorganisms in crude oil and formation waters. Nafta i gaz, 66: 267-273.
    Search in Google Scholar
DOI: https://doi.org/10.1515/oszn-2015-0028 | Journal eISSN: 2353-8589 | Journal ISSN: 1230-7831
Journal RSS Feed
Language: English
Page range: 20 - 25
Published on: Dec 30, 2015
Published by: National Research Institute, Institute of Environmental Protection
In partnership with: Paradigm Publishing Services
Publication frequency: 4 times per year
Keywords:
sulphate-reducing bacteria,
heavy metals,
contaminated environments
Related subjects:
Life sciences,
Ecology

© 2015 Ewa Izabela Podobas, Agnieszka Rożek, published by National Research Institute, Institute of Environmental Protection
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

Previous articleVolume 26 (2015): Issue 4 (December 2015)Next article