Anaerobic Degradation of Non-Methane Alkanes by " Methanoliparia" in Hydrocarbon Seeps of the Gulf of Mexico

Overview

Journal mBio

Publisher American Society for Microbiology

Specialty Microbiology

Date 2019 Aug 22

PMID 31431553

Citations 31

Authors

Rafael Laso-Perez

Cedric Hahn

Daan M van Vliet

Halina E Tegetmeyer

Florence Schubotz

Nadine T Smit

Thomas Pape

Heiko Sahling

Gerhard Bohrmann

Antje Boetius

Katrin Knittel

Gunter Wegener

Affiliations

Soon will be listed here.

Abstract

Crude oil and gases in the seabed provide an important energy source for subsurface microorganisms. We investigated the role of archaea in the anaerobic degradation of non-methane alkanes in deep-sea oil seeps from the Gulf of Mexico. We identified microscopically the ethane and short-chain alkane oxidizers " Argoarchaeum" and " Syntrophoarchaeum" forming consortia with bacteria. Moreover, we found that the sediments contain large numbers of cells from the archaeal clade " Methanoliparia," which was previously proposed to perform methanogenic alkane degradation. " Methanoliparia" occurred abundantly as single cells attached to oil droplets in sediments without apparent bacterial or archaeal partners. Metagenome-assembled genomes of " Methanoliparia" encode a complete methanogenesis pathway including a canonical methyl-coenzyme M reductase (MCR) but also a highly divergent MCR related to those of alkane-degrading archaea and pathways for the oxidation of long-chain alkyl units. Its metabolic genomic potential and its global detection in hydrocarbon reservoirs suggest that " Methanoliparia" is an important methanogenic alkane degrader in subsurface environments, producing methane by alkane disproportionation as a single organism. Oil-rich sediments from the Gulf of Mexico were found to contain diverse alkane-degrading groups of archaea. The symbiotic, consortium-forming " Argoarchaeum" and " Syntrophoarchaeum" are likely responsible for the degradation of ethane and short-chain alkanes, with the help of sulfate-reducing bacteria. " Methanoliparia" occurs as single cells associated with oil droplets. These archaea encode two phylogenetically different methyl-coenzyme M reductases that may allow this organism to thrive as a methanogen on a substrate of long-chain alkanes. Based on a library survey, we show that "" is frequently detected in oil reservoirs and may be a key agent in the transformation of long-chain alkanes to methane. Our findings provide evidence for the important and diverse roles of archaea in alkane-rich marine habitats and support the notion of a significant functional versatility of the methyl coenzyme M reductase.

Citing Articles

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A comprehensive genomic catalog from global cold seeps.

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