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Stable carbon isotope ratios of bacterial biomarkers were determined to infer sources of organic carbon used by bacteria in the sediments of three salt marshes. Biomarkers studied were polar lipid-derived fatty acids (PLFA), mainly bacteria- specific, methyl-branched i15:0 and a15:0. Experiments showed that isotopic fractionation between substrate and biomarkers was relatively constant (-4 to -6 parts per thousand, on average) compared to the wide range in C-13/C-12 ratios of carbon sources found in the studied marshes. At the Spartina site of the Waarde Marsh (The Netherlands), biomarker C-13/C-12 ratios were depleted by approximately 6 parts per thousand more than expected for bacteria growing on Spartina litter and were similar to an unvegetated control sediment. This pattern suggested that local macrophyte production was of little importance and that other material (probably of algal origin) was the dominant carbon source for bacterial growth. Spartina contributed about half of the carbon in bacterial PLEA at the Kattendijke Marsh (The Netherlands) and dominated at the Great Marshes (U.S.). The variation in bacterial carbon sources in these marshes was probably related to estimated inputs of nonmacrophyte organic matter to the sediment. At the Waarde Marsh, a clear plant species effect was found as coupling between plant and bacteria was more important in Scirpus maritimus than in Spartina anglica. The contribution of local plant production to bacterial biomass in salt-marsh sediments is highly variable between marshes and depends on the input of nonmacrophyte material by sedimentation in comparison to local plant input, which in turn may differ among plant species. [KEYWORDS: Sulfate reduction; spartina-alterniflora; fatty-acids; bacterial productivity; accretion rates; food webs; fractionation; c-13; georgia; ratios]
Original languageEnglish
Pages (from-to)309-319
JournalLimnology and Oceanography
Issue number2
StatePublished - 1999

ID: 131974