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ABSTRACT
The microbial conversion of petroleum hydrocarbons is increasingly employed in bioremediation efforts. In marine sediments, oxygen levels are characteristically depleted, so anaerobic degradation coupled to sulfate reduction dominates. Prior studies have noted that anaerobic degradation is much reduced in the absence of sediments. In this study, a simple centrifugation protocol was used to extract sediment porewaters to obtain a sediment-free bacterial assemblage capable of anaerobic hydrocarbon degradation. In addition, the factors in sediment that were important to degradation rates were determined. Experiments were designed to differentiate among the effects of increased surface area associated with individual grains in sediments, differing levels of organic constituents in sediments and water, and disparate microbiota within the sedimentary matrix and those free living. Anaerobic alkane degradation, sulfate levels and bacterial community structure were monitored over 90 days in five treatments consisting of Bonny Light crude oil added to (1) intact sediment, (2) sediment-free supernate from centrifuged sediment, (3) supernate plus autoclaved sediment, (4) supernate plus organic-free (combusted) sediment, and (5) a control, with autoclaved supernate plus autoclaved sediment. Lack of surface area associated with sediment grains had little effect on degradation. Separation of porewaters from the sedimentary matrix resulted in loss of bacterial biomass, although this had only a temporary negative effect on degradation rates. Reduction of organic matter due to sediment removal had the largest effect, resulting initially in lower degradation rates. However, sulfate depletion in low organic treatments was also reduced so that long-term loss of alkanes was enhanced.
ACKNOWLEDGEMENTS
This work was made possible through training and use of equipment in the laboratory of Pamela Morris. F. Daniel Bost also provided invaluable training for the GC and molecular work, and Giacomo DiTullio allowed use of his HPCE unit. Research was supported by an American Chemical Society Petroleum Research Summer Faculty Research Fellowship.