Ralstonia metallidurans: Difference between revisions
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[[Image:060718_gold_bacteria_01.jpg|thumb|300px|right|'' Bacterial induced formation of Cd crystals by Ralstonia metallidurans on Zirfon M5 membranes in the continuous tubular membrane reactor.''. [http://images.livescience.com/images/060718_gold_bacteria_01.jpg]]] | |||
==Classification== | ==Classification== | ||
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Kingdom: Bacteria | Kingdom: Bacteria | ||
Phylum: Proteobacteria | Phylum: Proteobacteria | ||
Class: Beta Proteobacteria | Class: Beta Proteobacteria | ||
Order:Burkholderiales | |||
Order: Burkholderiales | |||
Family: Ralstoniaceae | Family: Ralstoniaceae | ||
Genus: Ralstonia | Genus: Ralstonia | ||
Species: R. metallidurans | Species: R. metallidurans | ||
Strain: CH3 | |||
===Species=== | ===Species=== | ||
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'''NCBI: [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Tree&id=2&lvl=3&lin=f&keep=1&srchmode=1&unlock Taxonomy]''' | '''NCBI: [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Tree&id=2&lvl=3&lin=f&keep=1&srchmode=1&unlock Taxonomy]''' | ||
|} | |} | ||
Ralstonia solanacearum | |||
Ralstonia oxalatica | |||
Ralstonia paucula | |||
Ralstonia pickettii | |||
''Genus species'' | ''Genus species'' | ||
==Description and significance== | ==Description and significance== | ||
Ralstonia | |||
Alcaligenes eutrophus CH34, was just recently renamed Ralstonia Metallidurans. It was first isolated in 1976 from the sludge of a zinc decantation tank in Belgium that was polluted with high concentrations of several heavy metals, it and other metal-resistant members of the genus Ralstonia are frequently found in sediments and soils with a high content of heavy metals from diverse geographical locations. | |||
Ralstonia metallidurans is gram-negative, non-spore forming bacterium which thrives in the presence of millimolar concentrations of several heavy-metals; Zn, Cd, Co,Pb,Hg, Ni and Cr. Metal resistance functions are mainly encoded on two plasmids, pMOL28 and pMOL30, which produce metal exporters that pump metal ions out of the cell, protecting intracellular macromolecules from the toxic effects of high concentrations of metal. | |||
This extremophile is better able to withstand high concentrations of heavy metals than any other well-studied organism. This fact renders it a potential agent of bioremediation as well as an ideal model organism for understanding metal resistance phenotypes. Due to its survival in extreme metal concentrations and genomic sequencing it is thought to be one of the first life forms on earth, existing when there was very little oxygen in the atmosphere some 2.5 billion years ago. | |||
==Genome structure== | ==Genome structure== | ||
Its genome is approximately 6800 kb in size. The heavy-metal resistance found in these bacteia is conferred by two large megaplasmids (pMOL28=180 kbp and pMOL30=240 kbp) carrying gene clusters that encode cation-efflux machinery spanning both bacterial membranes. These low-copy number plasmids are maintained in the presence or absence of selective pressure and are self-transferable at relatively low frequencies. The Minimal Inhibitory Concentration (MIC) for free, non-chelated Ni, Co, Zn and Cd are 2.5, 20, 12 and 2.5 mM, respectively for the reference strain. | |||
The genome of this bacterium contains also 8 P-type ATPase involved in metal efflux specialized in lead, cadmium, thallium and/or copper efflux, and several others mechanisms involved in metal processing. | |||
Scientisist have analysed the genome of Ralstonia metallidurans for genes encoding homologues of established and putative transport proteins; 13% of all genes in Ralstonia metallidurans encode such homologues. Nearly one-third of the transporters identified (32%) appear to function in inorganic ion transport with three-quarters of these acting on cations. Transporters specific for amino acids outnumber sugar transporters nearly 3 : 1, and this fact plus the large number of uptake systems for organic acids indicates the heterotrophic preferences of these bacteria. Putative drug efflux pumps comprise 10% of the encoded transporters, but numerous efflux pumps for heavy metals, metabolites and macromolecules were also identified. | |||
==Cell structure and metabolism== | ==Cell structure and metabolism== | ||
Ralstonia metallidurans uses a variety of substrates as its carbon source or it can grow chemo-lithotropically using molecular hydrogen as the energy source and carbon dioxide as a carbon source. When nitrate is present Ralsonia metallidurans can grow anaerobically. | |||
Its optimal growth temperature is 30 çC. | |||
==Ecology== | ==Ecology== | ||
Due to its ability to withstand high concentrations of heavy metals it renders it as a potential agent of bioremediation of soil and water contaminated with heavy metals or chlorinated organic compounds as well as an ideal model organism for understanding metal resistance phenotypes. | |||
Lead contamination is a serious threat to human health and the environment. Lead levels are typically measured by using atomic absorption spectroscopy or other related instrumental methods. Developent of fluorescent Lead II Probe from Lead II-regulatory protein isolated from Ralstonia Metallidurans could provide rapid, on-site evaluation of the lead content of a sample. | |||
==Pathology== | ==Pathology== | ||
Ralstonia metallidurans is not a pathogen and does not inhabit any host organisms. | |||
==Application to Biotechnology== | ==Application to Biotechnology== | ||
Interestingly, enzymes from Ralstonia metallidurans were used by scientists in constructing a fuel cell. By encasing a pair of electrodes coated with these enzymes from Ralstonia metallidurans which oxidize hydrogen put inside a container filled with air and 3 percent more hydrogen. Trials of the fuel cell produced enough electricity to make a watch work. Larger scale productions are thought to be possible and are in the making. | |||
[[[[Image:060802103513.jpg|thumb|300px|left|''Colored scanning electron image of bacterioform gold on a gold grain from the Hit or Miss Mine in northern Queensland''. [http://images.livescience.com/images/060718_gold_bacteria_01.jpg]]] | |||
==Current Research== | ==Current Research== | ||
It is being researched that Ralstonia metallidurans could be involved in precipitating gold out of solution. It has an ability to survive in gold concentrations that would kill most other organisms.It is possible that the microbe screens out the gold as part of an effort to detoxify its immediate environment. | |||
==References== | ==References== | ||
http://www.livescience.com/othernews/060718_gold_bacteria.html | http://www.livescience.com/othernews/060718_gold_bacteria.html | ||
Edited by | |||
http://www.physorg.com/news94144517.html | |||
http://genamics.com/cgi-bin/genamics/genomes/genomesearch.cgi?field=Relevance&query=Bioremediatio... | |||
http://www.iran-daily.com/1385/2615/html/science.htm | |||
Edited by student of [mailto:ralarsen@ucsd.edu Rachel Larsen] and Kit Pogliano | |||
Revision as of 21:51, 30 May 2007
A Microbial Biorealm page on the genus Ralstonia metallidurans
Classification
Higher order taxa
Kingdom: Bacteria Phylum: Proteobacteria Class: Beta Proteobacteria Order:Burkholderiales Family: Ralstoniaceae Genus: Ralstonia Species: R. metallidurans Strain: CH3
Species
|
NCBI: Taxonomy |
Ralstonia solanacearum Ralstonia oxalatica Ralstonia paucula Ralstonia pickettii
Genus species
Description and significance
Alcaligenes eutrophus CH34, was just recently renamed Ralstonia Metallidurans. It was first isolated in 1976 from the sludge of a zinc decantation tank in Belgium that was polluted with high concentrations of several heavy metals, it and other metal-resistant members of the genus Ralstonia are frequently found in sediments and soils with a high content of heavy metals from diverse geographical locations.
Ralstonia metallidurans is gram-negative, non-spore forming bacterium which thrives in the presence of millimolar concentrations of several heavy-metals; Zn, Cd, Co,Pb,Hg, Ni and Cr. Metal resistance functions are mainly encoded on two plasmids, pMOL28 and pMOL30, which produce metal exporters that pump metal ions out of the cell, protecting intracellular macromolecules from the toxic effects of high concentrations of metal.
This extremophile is better able to withstand high concentrations of heavy metals than any other well-studied organism. This fact renders it a potential agent of bioremediation as well as an ideal model organism for understanding metal resistance phenotypes. Due to its survival in extreme metal concentrations and genomic sequencing it is thought to be one of the first life forms on earth, existing when there was very little oxygen in the atmosphere some 2.5 billion years ago.
Genome structure
Its genome is approximately 6800 kb in size. The heavy-metal resistance found in these bacteia is conferred by two large megaplasmids (pMOL28=180 kbp and pMOL30=240 kbp) carrying gene clusters that encode cation-efflux machinery spanning both bacterial membranes. These low-copy number plasmids are maintained in the presence or absence of selective pressure and are self-transferable at relatively low frequencies. The Minimal Inhibitory Concentration (MIC) for free, non-chelated Ni, Co, Zn and Cd are 2.5, 20, 12 and 2.5 mM, respectively for the reference strain.
The genome of this bacterium contains also 8 P-type ATPase involved in metal efflux specialized in lead, cadmium, thallium and/or copper efflux, and several others mechanisms involved in metal processing.
Scientisist have analysed the genome of Ralstonia metallidurans for genes encoding homologues of established and putative transport proteins; 13% of all genes in Ralstonia metallidurans encode such homologues. Nearly one-third of the transporters identified (32%) appear to function in inorganic ion transport with three-quarters of these acting on cations. Transporters specific for amino acids outnumber sugar transporters nearly 3 : 1, and this fact plus the large number of uptake systems for organic acids indicates the heterotrophic preferences of these bacteria. Putative drug efflux pumps comprise 10% of the encoded transporters, but numerous efflux pumps for heavy metals, metabolites and macromolecules were also identified.
Cell structure and metabolism
Ralstonia metallidurans uses a variety of substrates as its carbon source or it can grow chemo-lithotropically using molecular hydrogen as the energy source and carbon dioxide as a carbon source. When nitrate is present Ralsonia metallidurans can grow anaerobically. Its optimal growth temperature is 30 çC.
Ecology
Due to its ability to withstand high concentrations of heavy metals it renders it as a potential agent of bioremediation of soil and water contaminated with heavy metals or chlorinated organic compounds as well as an ideal model organism for understanding metal resistance phenotypes.
Lead contamination is a serious threat to human health and the environment. Lead levels are typically measured by using atomic absorption spectroscopy or other related instrumental methods. Developent of fluorescent Lead II Probe from Lead II-regulatory protein isolated from Ralstonia Metallidurans could provide rapid, on-site evaluation of the lead content of a sample.
Pathology
Ralstonia metallidurans is not a pathogen and does not inhabit any host organisms.
Application to Biotechnology
Interestingly, enzymes from Ralstonia metallidurans were used by scientists in constructing a fuel cell. By encasing a pair of electrodes coated with these enzymes from Ralstonia metallidurans which oxidize hydrogen put inside a container filled with air and 3 percent more hydrogen. Trials of the fuel cell produced enough electricity to make a watch work. Larger scale productions are thought to be possible and are in the making.
[[
Current Research
It is being researched that Ralstonia metallidurans could be involved in precipitating gold out of solution. It has an ability to survive in gold concentrations that would kill most other organisms.It is possible that the microbe screens out the gold as part of an effort to detoxify its immediate environment.
References
http://www.livescience.com/othernews/060718_gold_bacteria.html
http://www.physorg.com/news94144517.html
http://genamics.com/cgi-bin/genamics/genomes/genomesearch.cgi?field=Relevance&query=Bioremediatio...
http://www.iran-daily.com/1385/2615/html/science.htm
Edited by student of Rachel Larsen and Kit Pogliano
![[1]](http://images.livescience.com/images/060718_gold_bacteria_01.jpg){kind=link}