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Identifying labile DOM components in a coastal ocean through depleted bacterial transcripts and chemical signals

Abstract : Understanding which compounds comprising the complex and dynamic marine dissolved organic matter (DOM) pool are important in supporting heterotrophic bacterial production remains a major challenge. We eliminated sources of labile phytoplankton products, advected terrestrial material and photodegradation products to coastal microbial communities by enclosing water samples in situ for 24 h in the dark. Bacterial genes for which expression decreased between the beginning and end of the incubation and chemical formulae that were depleted over this same time frame were used as indicators of bioavailable compounds, an approach that avoids augmenting or modifying the natural DOM pool. Transport- and metabolism-related genes whose relative expression decreased implicated osmolytes, carboxylic acids, fatty acids, sugars and organic sulfur compounds as candidate bioreactive molecules. FT-ICR MS analysis of depleted molecular formulae implicated functional groups similar to 30-40 Da in size cleaved from semi-polar components of DOM as bioreactive components. Both gene expression and FT-ICR MS analyses indicated higher lability of compounds with sulfur and nitrogen heteroatoms. Untargeted methodologies able to integrate biological and chemical perspectives can be effective strategies for characterizing the labile microbial metabolites participating in carbon flux.
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https://hal-cea.archives-ouvertes.fr/cea-02291363
Contributor : Marianne Leriche <>
Submitted on : Wednesday, September 18, 2019 - 4:21:38 PM
Last modification on : Wednesday, June 17, 2020 - 3:42:03 PM

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Alexey Vorobev, Shalabh Sharma, Mengyun Yu, Juhyung Lee, Benjamin J. Washington, et al.. Identifying labile DOM components in a coastal ocean through depleted bacterial transcripts and chemical signals. Environmental Microbiology, Wiley-Blackwell, 2018, 20 (8), pp.3012-3030. ⟨10.1111/1462-2920.14344⟩. ⟨cea-02291363⟩

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