Copper Resistance Mechanisms of Biomining Bacteria and Archaea Living under Extremely High Concentrations of Metals

A. Orell; C.A. Navarro; Carlos A. Jerez

doi:10.4028/www.scientific.net/AMR.71-73.279

Paper Titles

Experimental Study of Ferrous Iron Biooxidation by Leptospirillum Ferriphilum in Different Biofilm Reactors
p.263

Effect of the Energy and Carbon Source Limitations and Ferric Inhibition on Metabolic Parameters of Leptospirillum Ferrooxidans Growing in Chemostat
p.267

Ferrous Iron and Pyrite Oxidation by “Acidithiomicrobium” Species
p.271

ATP Measurements in Iron-Oxidizing Acidithiobacillus Ferrooxidans
p.275

Copper Resistance Mechanisms of Biomining Bacteria and Archaea Living under Extremely High Concentrations of Metals
p.279

The Characterization of Salt Tolerance in Biomining Microorganisms and the Search for Novel Salt Tolerant Strains
p.283

Interrelation between Cells and Extracellular Polymeric Substances (EPS) from Acidiphilium 3.2Sup(5) on Carbon Surfaces
p.287

Reductive Action of Activated Carbon on Ferric Iron Interferes on the Determination of the Oxidative Activity of Acidithiobacillus Ferrooxidans on Ferrous Iron
p.291

Mechanisms of Bioleaching and the Visualization of these by Combined AFM & EFM
p.297

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 71-73Copper Resistance Mechanisms of Biomining Bacteria...

Copper Resistance Mechanisms of Biomining Bacteria and Archaea Living under Extremely High Concentrations of Metals

Abstract:

Extremophiles such as the acidophilic Sulfolobus metallicus (Archaea) and Acidithiobacillus ferrooxidans (Bacteria) can resist Cu (CuSO4) concentrations of 200 mM and 800 mM respectively. These microorganisms are important in biomining processes to extract copper and other metals. A. ferrooxidans grown at low Cu concentrations (5 mM) expressed genes coding for ATPases most likely involved in pumping the metal from the cytoplasm to the periplasm of the bacterium. At 100 mM Cu the previous systems were repressed and there was a great induction in the expression of efflux systems known to use the proton motive force energy to export the metal outside the cell. These Cu-resistance determinants from A. ferrooxidans were found to be functional since when expressed in Escherichia coli they conferred higher Cu tolerance to it. Novel Cu-resistance determinants for A. ferrooxidans were found and characterized. S. metallicus possessed at least 2 CopM metallochaperones and 2 CopA ATPases whose expressions were induced by Cu (5 to 50 mM). Furthermore, we previously reported that both microorganisms accumulate high levels of inorganic polyphosphate (PolyP) and that intracellular Cu concentration stimulates polyP hydrolysis. The resulting Pi would then be transported out of the cell as a metal-Pi complex to detoxify the cells. In addition, our results suggest that at high Cu concentrations polyP could also provide energy for the metal efflux. All the data suggest that both biomining microorganisms use different systems to respond to Cu depending on the extracellular concentrations of the metal and suggest that the presence of different additional systems to respond to Cu may explain the extremely high metal resistance of these extremophiles.

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Periodical:

Advanced Materials Research (Volumes 71-73)

Pages:

279-282

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.71-73.279

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Online since:

May 2009

Authors:

A. Orell, C.A. Navarro, Carlos A. Jerez

Keywords:

Archaea, Bacteria, Biomining, Copper Resistance, Metal

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References

[1] A. Schippers: Chapter 1, in: Microbial Processing of Metal Sulfides, edited by E.R. Donati and W. Sand. ISBN: 978-1-4020-5588-1, Springer (2007), p.3.

Google Scholar

[2] C. Baker-Austin and M. Dopson: Trends Microbiol. Vol. 15 (2007), p.165.

Google Scholar

[3] S. Franke and C. Rensing, in: Physiology and Biochemistry of Extremophiles, edited by C. Gerday and N. Glansdorff. ASM Press, Washington, D.C. (2007) p.271.

Google Scholar

[4] M. Dopson, C. Baker-Austin, P.R. Koopineedi and P.L. Bond: Microbiology. Vol. 149 (2003), p. (1959).

Google Scholar

[5] H.R. Watling: Hydrometallurgy. Vol. 84 (2006), p.81.

Google Scholar

[6] C.A. Jerez: Hydrometallurgy. Vol. 94 (2008), p.162.

Google Scholar

[7] R. Quatrini, C. Lefimil, F. Veloso, I. Pedroso, D.S. Holmes and E. Jedlicki: Nucleic Acids Res. Vol. 35 (2007), p.2153.

DOI: 10.1093/nar/gkm068

Google Scholar

[8] C. Navarro, L. Orellana, C. Mauriaca and C. A. Jerez: submitted to Appl Environ Microbiol (2009).

Google Scholar

[9] T.J. Ettema, M.A. Huynen, W.M. de Vos and J. van der Oost: Trends Biochem Sci. Vol. 28 (2003), p.170.

Google Scholar

[10] A. Kornberg, N. Rao and D. Ault-Riche: Annu Rev Biochem. Vol. 68 (1999), p.89.

Google Scholar

[11] M. Vera, N. Guiliani and C.A. Jerez: Hydrometallurgy. Vol. 71(2003), p.125.

Google Scholar

[12] S. Alvarez and C.A. Jerez: Appl Environ Microbiol. Vol. 70 (2004), p.5177.

Google Scholar

[13] F. Remonsellez, A. Orell and C.A. Jerez: Microbiology. Vol. 152 (2006), p.59.

Google Scholar

[14] U. Fristedt, M. van Der Rest, B. Poolman, W. N. Konings and B. L. Persson: Biochemistry. Vol. 38 (1999), p.16010.

Google Scholar

[15] R.N. Reusch, R. Huang and D. Kosk-Kosicka: FEBS Lett. Vol. 412 (1997), p.592.

Google Scholar