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Metabolic versatility of aerobic methane‐oxidizing bacteria under anoxia in aquatic ecosystems

Biao Li, Zhendu Mao, Jingya Xue, Peng Xing, Qinglong L. Wu

2024Environmental Microbiology Reports11 citationsDOIOpen Access PDF

Abstract

Abstract The potential positive feedback between global aquatic deoxygenation and methane (CH 4 ) emission emphasizes the importance of understanding CH 4 cycling under O 2 ‐limited conditions. Increasing observations for aerobic CH 4 ‐oxidizing bacteria (MOB) under anoxia have updated the prevailing paradigm that MOB are O 2 ‐dependent; thus, clarification on the metabolic mechanisms of MOB under anoxia is critical and timely. Here, we mapped the global distribution of MOB under anoxic aquatic zones and summarized four underlying metabolic strategies for MOB under anoxia: (a) forming a consortium with oxygenic microorganisms; (b) self‐generation/storage of O 2 by MOB; (c) forming a consortium with non‐oxygenic heterotrophic bacteria that use other electron acceptors; and (d) utilizing alternative electron acceptors other than O 2 . Finally, we proposed directions for future research. This study calls for improved understanding of MOB under anoxia, and underscores the importance of this overlooked CH 4 sink amidst global aquatic deoxygenation.

Topics & Concepts

DeoxygenationAnoxic watersAquatic ecosystemBacteriaEnvironmental chemistryHeterotrophMicroorganismEcosystemOxidizing agentBiologyEcologyEnvironmental scienceChemistryBiochemistryGeneticsCatalysisOrganic chemistryMethane Hydrates and Related PhenomenaMicrobial Community Ecology and PhysiologyCerebrospinal fluid and hydrocephalus