AI Article Synopsis

  • - The study investigates microbial communities in petroleum reservoirs under high-pressure conditions, focusing on methanogenic and sulfate-reducing environments using production water from the Jilin Oilfield in China.
  • - A 90-day incubation revealed key microbial groups, with methanogenic conditions dominated by Firmicutes and unique methanogens, while sulfate-reducing communities were mostly Firmicutes and other candidate taxa important for nutrient exchange.
  • - The research highlights the importance of microbial interactions and metabolic roles in petroleum degradation, suggesting that high-pressure conditions can uncover previously overlooked microbial functions, often referred to as "microbial dark matter."

Article Abstract

While pressure is a significant characteristic of petroleum reservoirs, it is often overlooked in laboratory studies. To clarify the composition and metabolic properties of microbial communities under high-pressure conditions, we established methanogenic and sulfate-reducing enrichment cultures under high-pressure conditions using production water from the Jilin Oilfield in China. We utilized a metagenomics approach to analyze the microbial community after a 90-day incubation period. Under methanogenic conditions, Firmicutes, Deferribacteres, Ignavibacteriae, Thermotogae, and Nitrospirae, in association with the hydrogenotrophic methanogen Archaeoglobaceae and acetoclastic , were highly represented. Genomes for . Odinarchaeota and the hydrogen-dependent methylotrophic . Methanosuratus were also recovered from the methanogenic culture. The sulfate-reducing community was dominated by Firmicutes, Thermotogae, Nitrospirae, , and several candidate taxa including . Bipolaricaulota, . Aminicenantes, and Candidate division WOR-3. These candidate taxa were key pantothenate producers for other community members. The study expands present knowledge of the metabolic roles of petroleum-degrading microbial communities under high-pressure conditions. Our results also indicate that microbial community interactions were shaped by syntrophic metabolism and the exchange of amino acids and cofactors among members. Furthermore, incubation under pressure conditions has the potential to reveal the roles of microbial dark matter.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10766756PMC
http://dx.doi.org/10.3389/fmicb.2023.1305731DOI Listing

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