Fractionation of hydrogen isotopes by sulfate- and nitrate-reducing bacteria

Magdalena R. Osburn*, Katherine S. Dawson, Marilyn L. Fogel, Alex L. Sessions

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

16 Scopus citations

Abstract

Hydrogen atoms from water and food are incorporated into biomass during cellular metabolism and biosynthesis, fractionating the isotopes of hydrogen-protium and deuterium-that are recorded in biomolecules. While these fractionations are often relatively constant in plants, large variations in the magnitude of fractionation are observed for many heterotrophic microbes utilizing different central metabolic pathways. The correlation between metabolism and lipid d2H provides a potential basis for reconstructing environmental and ecological parameters, but the calibration dataset has thus far been limited mainly to aerobes. Here we report on the hydrogen isotopic fractionations of lipids produced by nitrate-respiring and sulfate-reducing bacteria. We observe only small differences in fractionation between oxygen- and nitrate-respiring growth conditions, with a typical pattern of variation between substrates that is broadly consistent with previously described trends. In contrast, fractionation by sulfate-reducing bacteria does not vary significantly between different substrates, even when autotrophic and heterotrophic growth conditions are compared. This result is in marked contrast to previously published observations and has significant implications for the interpretation of environmental hydrogen isotope data. We evaluate these trends in light of metabolic gene content of each strain, growth rate, and potential flux and reservoir-size effects of cellular hydrogen, but find no single variable that can account for the differences between nitrate- and sulfate-respiring bacteria. The emerging picture of bacterial hydrogen isotope fractionation is therefore more complex than the simple correspondence between δ2H and metabolic pathway previously understood from aerobes. Despite the complexity, the large signals and rich variability of observed lipid d2H suggest much potential as an environmental recorder of metabolism.

Original languageEnglish (US)
Article number1166
JournalFrontiers in Microbiology
Volume7
Issue numberAUG
DOIs
StatePublished - Aug 2 2016

Keywords

  • Anaerobic microbial metabolism
  • Fatty acids
  • Hydrogen isotopes
  • NAD(P)H
  • Sulfate-reducing bacteria
  • Transhydrogenase

ASJC Scopus subject areas

  • Microbiology
  • Microbiology (medical)

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