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dc.contributor.authorAston, John E.
dc.contributor.authorApel, William A.
dc.contributor.authorLee, Brady D.
dc.contributor.authorPeyton, Brent M.
dc.date.accessioned2017-02-07T15:39:51Z
dc.date.available2017-02-07T15:39:51Z
dc.date.issued2011-01
dc.identifier.citationAston JE, Apel WA, Lee BD, Peyton BM, "Growth effects and assimilation of organic acids in chemostat and batch cultures of Acidithiobacillus caldus," World Journal of Microbiology and Biotechnology, January 2011 27(1):153–161en_US
dc.identifier.issn0959-3993
dc.identifier.urihttps://scholarworks.montana.edu/xmlui/handle/1/12569
dc.description.abstractThe ability of Acidithiobacillus caldus to grow aerobically using pyruvate, acetate, citrate, 2-ketoglutarate, succinate, and malate as either an electron donor and carbon source (heterotrophic growth), or as a carbon source when potassium tetrathionate was added as an electron donor (mixotrophic growth), was tested in chemostat cultures. Under both heterotrophic and mixotrophic conditions, organic acids were added to a sub-lethal concentration (50 μM). Under mixotrophic conditions, potassium tetrathionate was added to an excess concentration (10 mM). No cell growth was observed under heterotrophic conditions; however, effluent cell concentrations increased over threefold when pyruvate was coupled with potassium tetrathionate. Under these conditions, the effluent pyruvate concentration was reduced to below the detection limit (2 μM), and oxygen consumption increased by approximately 100%. Although pyruvate provided a carbon source in these experiments, ambient carbon dioxide was also available to the cells. To test whether At. caldus could grow mixotrophically using pyruvate as a sole carbon source and potassium tetrathionate as an electron donor, cells were batch cultured in a medium free of dissolved inorganic carbon, and with no carbon dioxide in the headspace. These experiments showed that At. caldus was able to convert between 65 ± 8 and 82 ± 15% of the pyruvate carbon to cellular biomass, depending on the initial pyruvate concentrations. This work is the first to identify a defined organic-carbon source, other than glucose, that At. caldus can assimilate. This has important implications, as mixotrophic and heterotrophic activity has been shown to increase mineral leaching in acidic systems.en_US
dc.titleGrowth effects and assimilation of organic acids in chemostat and batch cultures of Acidithiobacillus caldusen_US
dc.typeArticleen_US
mus.citation.extentfirstpage153en_US
mus.citation.extentlastpage161en_US
mus.citation.issue1en_US
mus.citation.journaltitleWorld Journal of Microbiology and Biotechnologyen_US
mus.citation.volume27en_US
mus.identifier.categoryChemical & Material Sciencesen_US
mus.identifier.categoryEngineering & Computer Scienceen_US
mus.identifier.categoryLife Sciences & Earth Sciencesen_US
mus.identifier.doi10.1007/s11274-010-0441-4en_US
mus.relation.collegeCollege of Agricultureen_US
mus.relation.collegeCollege of Engineeringen_US
mus.relation.collegeCollege of Letters & Scienceen_US
mus.relation.departmentCenter for Biofilm Engineering.en_US
mus.relation.departmentChemical & Biological Engineering.en_US
mus.relation.departmentChemical Engineering.en_US
mus.relation.departmentChemistry & Biochemistry.en_US
mus.relation.departmentEcology.en_US
mus.relation.departmentMicrobiology & Immunology.en_US
mus.relation.universityMontana State University - Bozemanen_US
mus.relation.researchgroupCenter for Biofilm Engineering.en_US
mus.data.thumbpage5en_US
mus.contributor.orcidPeyton, Brent M.|0000-0003-0033-0651en_US


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