The electron transfer system of syntrophically grown Desulfovibrio vulgaris

Interspecies hydrogen transfer between organisms producing and consuming hydrogen promotes the decomposition of organic matter in most anoxic environments. Although syntrophic couplings between hydrogen producers and consumers are a major feature of the carbon cycle, mechanisms for energy recovery a...

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Bibliographic Details
Published inJournal of bacteriology no. 2009
Main Authors Walker, C.B., He, Z., Yang, Z.K., Ringbauer, Jr., J.A., He, Q., Zhou, J., Voordouw, G., Wall, J.D., Arkin, A.P., Hazen, T.C., Stolyar, S., Stahl, D.A.
Format Journal Article
LanguageEnglish
Published United States 01.05.2009
Subjects
CARBON CYCLE
COMMUNITIES
CYTOCHROMES
DESULFOVIBRIO
ELECTRON TRANSFER
ELECTRONS
ENERGY RECOVERY
ENVIRONMENTAL SCIENCES
GENES
GEOSCIENCES
HYDROGEN
HYDROGEN TRANSFER
HYDROGENASES
LACTATES
MUTATIONS
NUTRIENTS
ORGANIC MATTER
OXIDATION
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Summary:Interspecies hydrogen transfer between organisms producing and consuming hydrogen promotes the decomposition of organic matter in most anoxic environments. Although syntrophic couplings between hydrogen producers and consumers are a major feature of the carbon cycle, mechanisms for energy recovery at the extremely low free energies of reactions typical of these anaerobic communities have not been established. In this study, comparative transcriptional analysis of a model sulfate-reducing microbe, Desulfovibrio vulgaris Hildenborough, suggested the use of alternative electron transfer systems dependent upon growth modality. During syntrophic growth on lactate with a hydrogenotrophic methanogen, D. vulgaris up-regulated numerous genes involved in electron transfer and energy generation when compared with sulfate-limited monocultures. In particular, genes coding for the putative membrane-bound Coo hydrogenase, two periplasmic hydrogenases (Hyd and Hyn) and the well-characterized high-molecular weight cytochrome (Hmc) were among the most highly expressed and up-regulated. Additionally, a predicted operon coding for genes involved in lactate transport and oxidation exhibited up-regulation, further suggesting an alternative pathway for electrons derived from lactate oxidation during syntrophic growth. Mutations in a subset of genes coding for Coo, Hmc, Hyd and Hyn impaired or severely limited syntrophic growth but had little affect on growth via sulfate-respiration. These results demonstrate that syntrophic growth and sulfate-respiration use largely independent energy generation pathways and imply that understanding of microbial processes sustaining nutrient cycling must consider lifestyles not captured in pure culture.
Bibliography:Earth Sciences Division
DE-AC02-05CH11231
LBNL-2246E
ISSN:0021-9193
1098-5530
DOI:10.1128/JB.00356-09