Expanding anaerobic alkane metabolism in the domain of Archaea

Wang, Yinzhao; Wegener, Gunter; Hou, Jialin; Wang, Fengping; Xiao, Xiang

doi:10.1038/s41564-019-0364-2

Cited by 154 publications

(244 citation statements)

References 53 publications

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“…Newly assembled Archaeoglobi MAGs, including MAGs of "Ca. Polytropus marinifundus" (Juan de Fuca Ridge, Northeast Pacific Ocean), Archaeoglobi WYZ-LMO1 (Washburn Spring, WY, USA), WYZ-LMO2 (Obsidian Pool, WY, USA), and WYZ-LMO3 (Obsidian Pool, WY, USA), were retrieved from previous studies (7,17).…”

Section: Methodsmentioning

confidence: 99%

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Genomic and Transcriptomic Evidence Supports Methane Metabolism in Archaeoglobi

et al. 2020

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Euryarchaeal lineages have been believed to have a methanogenic last common ancestor. However, members of euryarchaeal Archaeoglobi have long been considered nonmethanogenic and their evolutionary history remains elusive. Here, three high-quality metagenomic-assembled genomes (MAGs) retrieved from high-temperature oil reservoir and hot springs, together with three newly assembled Archaeoglobi MAGs from previously reported hot spring metagenomes, are demonstrated to represent a novel genus of Archaeoglobaceae, “Candidatus Methanomixophus.” All “Ca. Methanomixophus” MAGs encode an M methyltransferase (MTR) complex and a traditional type of methyl-coenzyme M reductase (MCR) complex, which is different from the divergent MCR complexes found in “Ca. Polytropus marinifundus.” In addition, “Ca. Methanomixophus dualitatem” MAGs preserve the genomic capacity for dissimilatory sulfate reduction. Comparative phylogenetic analysis supports a laterally transferred origin for an MCR complex and vertical heritage of the MTR complex in this lineage. Metatranscriptomic analysis revealed concomitant in situ activity of hydrogen-dependent methylotrophic methanogenesis and heterotrophic fermentation within populations of “Ca. Methanomixophus hydrogenotrophicum” in a high-temperature oil reservoir. IMPORTANCE Current understanding of the diversity, biology, and ecology of Archaea is very limited, especially considering how few of the known phyla have been cultured or genomically explored. The reconstruction of “Ca. Methanomixophus” MAGs not only expands the known range of metabolic versatility of the members of Archaeoglobi but also suggests that the phylogenetic distribution of MCR and MTR complexes is even wider than previously anticipated.

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Section: Methodsmentioning

confidence: 99%

“…1; see also Fig. 2A and C), were downloaded from the NCBI database and included into this study (7).…”

Section: Anme-2dmentioning

confidence: 99%

Genomic and Transcriptomic Evidence Supports Methane Metabolism in Archaeoglobi

et al. 2020

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“…In particular, it has been found that archaea are functionally diverse, being capable of ammonia oxidation, methane metabolism, and organic matter degradation [6][7][8]. Novel archaeal phyla with unusual metabolic potentials are still being discovered, for example, Nezhaarchaeota and Helarchaeota, two new archaeal phyla identified in 2019, were found to possess the potential for anaerobic short-chain hydrocarbon cycling [9,10]. In contrast to the increasing knowledge gleaned from archaeal community composition and metabolic capacity characterization, much less is known about the spatiotemporal dynamics of archaeal community distribution, their assembly mechanism, and inter taxa association in sediments [11,12].…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal dynamics of the archaeal community in coastal sediments: assembly process and co-occurrence relationship

et al. 2020

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Studies of marine benthic archaeal communities are updating our view of their taxonomic composition and metabolic versatility. However, large knowledge gaps remain with regard to community assembly processes and inter taxa associations. Here, using 16S rRNA gene amplicon sequencing and qPCR, we investigated the spatiotemporal dynamics, assembly processes, and co-occurrence relationships of the archaeal community in 58 surface sediment samples collected in both summer and winter from across~1500 km of the eastern Chinese marginal seas. Clear patterns in spatiotemporal dynamics in the archaeal community structure were observed, with a more pronounced spatial rather than seasonal variation. Accompanying the geographic variation was a significant distance-decay pattern with varying contributions from different archaeal clades, determined by their relative abundance. In both seasons, dispersal limitation was the most important process, explaining~40% of the community variation, followed by homogeneous selection and ecological drift, that made an approximately equal contribution (~30%). This meant that stochasticity rather than determinism had a greater impact on the archaeal community assembly. Furthermore, we observed seasonality in archaeal co-occurrence patterns: closer inter-taxa connections in winter than in summer, and unmatched geographic patterns between community composition and co-occurrence relationship. These results demonstrate that the benthic archaeal community was assembled under a seasonalconsistent mechanism but the co-occurrence relationships changed over the seasons, indicating complex archaeal dynamic patterns in coastal sediments of the eastern Chinese marginal seas.

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“…Notably, the recently described process of multi-carbon alkane oxidation by archaea co-occurs with anaerobic methane oxidation by ANME archaea. Previous observations of these phenomena have mainly featured hydrothermal vent environments 15, 22, 38 whereas this deep sea setting experiences permanently low temperatures. Methane oxidizers are most abundant, in agreement with the high concentration of methane; however, by investigating an environment that also has relatively high concentrations of C 2+ gases, the potential and importance of both GoM-Arc1- and Syntrophoarchaeaum - like archaea degrading thermogenic hydrocarbons in cold seep sediments is shown for the first time.…”

Section: Discussionmentioning

confidence: 99%

“…Numerous studies have focused on anaerobic oxidation of methane, since methane generally is the dominant hydrocarbon in cold seep fluids. This process is mediated by anaerobic methanotrophic archaea (ANME) through the reverse methanogenesis pathway, typically in syntrophy with bacteria that can reduce electron acceptors such as sulfate, nitrate, and metal oxides 8, 15, 16 . Investigations of enrichment cultures have also revealed anaerobic bacterial or archaeal oxidation of non-methane alkanes and aromatic hydrocarbons, including ethane (e.g.…”

Section: Introductionmentioning

confidence: 99%

Thermogenic hydrocarbons fuel a redox stratified subseafloor microbiome in deep sea cold seep sediments

Dong

Rattray

Campbell

et al. 2020

Preprint

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20At marine cold seeps, gaseous and liquid hydrocarbons migrate from deep subsurface 21 origins to the sediment-water interface. Cold seep sediments are known to host 22CoM reductase pathway), longer-chain alkanes (fumarate addition pathway), and 35 aromatic hydrocarbons (fumarate addition and subsequent benzoyl-CoA pathways), 36 including novel lineages within Methanosarcinales and Chloroflexi. Geochemical 37 profiling demonstrated that hydrocarbon substrates are abundant in this location, 38 thermogenic in origin, and subject to biodegradation. The detection of alkyl-39 /arylalkylsuccinate metabolites, together with carbon isotopic signatures of ethane, 40propane and carbon dioxide, support that microorganisms are actively degrading 41 hydrocarbons in these sediments. Capacities for reductive dehalogenation, sulfide 42 oxidation, hydrogen oxidation, carbon fixation, and fermentation are also widespread. 43Most community members may indirectly benefit from thermogenic hydrocarbons 44 through interspecies transfer of electrons and metabolites, and degradation of 45 necromass. Thus, we conclude that upward migrated thermogenic hydrocarbons are 46 important carbon and energy sources that sustain diverse subseafloor microbial 47 communities at permanently cold hydrocarbon seeps. 48 3 Introduction 49 Marine cold seeps are characterised by the migration of gas and oil from deep 50 subsurface sources to the sediment-water interface 1, 2 . This seepage often contains 51 gaseous short-chain alkanes, as well as heavier liquid alkanes and aromatic 52 compounds 3 , that originate from deep thermogenic petroleum deposits. Migrated 53 hydrocarbons can serve as an abundant source of carbon and energy for 54 microorganisms in these ecosystems, either via their direct utilization or indirectly 55 through metabolizing by-products of hydrocarbon biodegradation 4 . Multiple 16S rRNA 56 gene surveys have revealed that cold seep sediments at or near the sediment-water 57 interface host an extensive diversity of archaeal and bacterial lineages 5-9 . However, 58 much less is known about metabolic versatility of this diverse microbiome, and how 59 surface and subsurface populations are connected and differentiated in different redox 60 zones within the sediment column 10, 11 . Most seep-associated microorganisms lack 61 sequenced genomes, precluding meaningful predictions of relationships between 62 microbial lineages and their biogeochemical functions 4, 8, 10-13 . 63 Geochemical studies have provided evidence that microorganisms in deep seafloor 64 sediments, including cold seeps, mediate anaerobic hydrocarbon oxidation 2, 3 . A range 65 of efforts have been undertaken to enrich and isolate anaerobic hydrocarbon-oxidizing 66 microorganisms from cold seep sediments and other ecosystems rich in hydrocarbons 67 (e.g. marine hydrothermal vents) [5][6][7][8][9] 14 . Numerous studies have focused on anaerobic 68 oxidation of methane, since methane generally is the dominant hydrocarbon in cold 69 seep fluids. This process is mediated by...

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Expanding anaerobic alkane metabolism in the domain of Archaea

Cited by 154 publications

References 53 publications

Genomic and Transcriptomic Evidence Supports Methane Metabolism in Archaeoglobi

Genomic and Transcriptomic Evidence Supports Methane Metabolism in Archaeoglobi

Spatiotemporal dynamics of the archaeal community in coastal sediments: assembly process and co-occurrence relationship

Thermogenic hydrocarbons fuel a redox stratified subseafloor microbiome in deep sea cold seep sediments

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