Abstract
Abstract. Microbial methane oxidation is the primary control on the emission of the greenhouse gas methane into the atmosphere. In terrestrial environments, aerobic methanotrophic bacteria are largely responsible for this process. In marine sediments, a coupling of anaerobic oxidation of methane (AOM) with sulfate reduction, often carried out by a consortium of anaerobic methanotrophic archaea (ANME) and sulfate-reducing bacteria, consumes almost all methane produced within those sediments. Motivated by recent evidence for AOM with iron(III) in Lake Kinneret sediments, the goal of the present study was to link the geochemical gradients in the lake porewater to the microbial community structure. Screening of archaeal 16S rRNA gene sequences revealed a shift from hydrogenotrophic to acetoclastic methanogens with depth. The observed changes in microbial community structure suggest possible direct and indirect mechanisms for the AOM coupled to iron reduction in deep sediments. The percentage of members of the Nitrospirales order increased with depth, suggesting their involvement in iron reduction together with Geobacter genus and "reverse methanogenesis". An indirect mechanism through sulfate and ANME seems less probable due to the absence of ANME sequences. This is despite the abundant sequences related to sulfate-reducing bacteria (Deltaproteobacteria) together with the occurrence of dsrA in the deep sediment that could indicate the production of sulfate (disproportionation) from S0 for sulfate-driven AOM. The presence of the functional gene pmoA in the deep anoxic sediment together with sequences related to Methylococcales suggests the existence of a second unexpected indirect pathway – aerobic methane oxidation pathway in an anaerobic environment.
Highlights
Chemical profiles in the porewater of aquatic sediments reflect the sequence of microbially mediated redox reactions that are driven by the availability of both electron donors and of suitable electron acceptors
In our recent study (Sivan et al, 2011), we provided in situ geochemical evidence for anaerobic oxidation of methane (AOM) coupled to microbial iron reduction below the main methanogenesis zone in Lake Kinneret (LK) sediments, where dissolved sulfate and nitrate are absent
This study focused on microbial community shifts along the porewater profiles of electron acceptor gradients related to www.biogeosciences.net/12/2847/2015/
Summary
Chemical profiles in the porewater of aquatic sediments reflect the sequence of microbially mediated redox reactions that are driven by the availability of both electron donors and of suitable electron acceptors. The latter are depleted in the order of decreasing chemical potential, beginning with oxygen and proceeding through nitrate, manganese and iron oxides, and sulfate. When the produced methane diffuses into a zone with a suitable electron acceptor, it can be consumed by microbial oxidation (methanotrophy), the main process by which the important greenhouse methane is prevented from escaping into the atmosphere. While in the terrestrial environment, aerobic methanotrophy is the dominant process (Chistoserdova et al, 2005), in anaerobic marine sediments, archaea are found to consume the majority of upward-diffusing methane coupled to sulfate reduction (Knittel and Boetius, 2009; Thauer, 2010; Valentine, 2002)
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