Genomic evidence for distinct carbon substrate preferences and ecological niches of <scp>B</scp>athyarchaeota in estuarine sediments

Lazar, Cassandre Sara; Baker, Brett J.; Seitz, Kiley W.; Hyde, Andrew S.; Dick, Gregory J.; Hinrichs, Kai‐Uwe; Teske, Andreas

doi:10.1111/1462-2920.13142

Cited by 206 publications

(217 citation statements)

References 71 publications

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“…They are more complete than those typically derived using single-cell genomics 4 and are of similar quality to those reported in other studies considering MAGs 10,11,44 . We have focused on these genomes, which represent only ~12% of the 64,295 recovered bins, as they are of sufficient quality to inform analyses such as resolving phylogenetic relationships 4,30 and comparing inter-and intralineage genomic features [45][46][47] . Importantly, these results demonstrate that a large amount of microbial diversity remains to be genomically described across the tree of life, even within existing metagenomic samples, and that this diversity is readily recovered using current tools and methodologies.…”

Section: Discussionmentioning

confidence: 99%

Recovery of nearly 8,000 metagenome-assembled genomes substantially expands the tree of life

et al. 2017

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Challenges in cultivating microorganisms have limited the phylogenetic diversity of currently available microbial genomes. This is being addressed by advances in sequencing throughput and computational techniques that allow for the cultivation-independent recovery of genomes from metagenomes. Here, we report the reconstruction of 7,903 bacterial and archaeal genomes from > 1,500 public metagenomes. All genomes are estimated to be ≥ 50% complete and nearly half are ≥ 90% complete with ≤ 5% contamination. These genomes increase the phylogenetic diversity of bacterial and archaeal genome trees by > 30% and provide the first representatives of 17 bacterial and three archaeal candidate phyla. We also recovered 245 genomes from the Patescibacteria superphylum (also known as the Candidate Phyla Radiation) and find that the relative diversity of this group varies substantially with different protein marker sets. The scale and quality of this data set demonstrate that recovering genomes from metagenomes provides an expedient path forward to exploring microbial dark matter. Articles NATuRe MiCRobiologyform the UBA data set as they met our filtering criteria of having an estimated quality ≥ 50 (defined as the estimated completeness of a genome minus five times its estimated contamination) and consisting of ≤ 500 scaffolds with an N50 ≥ 10 kb ( Fig. 1 and Supplementary Table 2). Over 93% of the 7,903 UBA genomes have an average coverage of ≥ 10× (5th percentile, 9.2× , 95th percentile, 268× ) and 95.8% have > 5× coverage over 90% of bases, providing assurance of high-quality base-calling across the genomes 3,36 . Among the UBA genomes is a subset of 3,438 near-complete genomes (3,225 bacterial and 213 archaeal) estimated to be ≥ 90% complete with ≤ 5% contamination (Fig. 1a). These genomes consist of ≤ 100 scaffolds in 70.2% of cases (≤ 200 scaffolds in 92.0% genomes) and have an average N50 of 136 kb. Comparison of near-complete UBA genomes that are conspecific strains of complete isolate genomes also suggest that the recovered MAGs have no systematic loss of genomic content, with the exception of extrachromosomal elements such as plasmids (Supplementary Note 1).The UBA data set was also assessed relative to the criteria used by the Human Microbiome Project (HMP) for defining high-quality draft genomes 3,37 . Of the 3,438 UBA genomes we have defined as near complete, 3,201 (93.1%) pass all of the HMP criteria, with the only substantial exception being 4.8% of the genomes having scaffolds with an N50 of < 20 kb (Supplementary Table 3). Nearly half of the remaining 4,465 UBA genomes also pass the HMP criteria for being high quality except that they are estimated to be < 90% complete.The presence of tRNAs for the standard 20 amino acids was examined as a secondary measure of genome quality (Fig. 1c). The 3,438 near-complete UBA genomes have tRNAs that encode for an average of 17.3 ± 2.2 of the 20 amino acids and ≥ 15 amino acids in 90.3% of the genomes. The correlation between estimated genome completeness and identified tRN...

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Section: Discussionmentioning

confidence: 99%

Recovery of nearly 8,000 metagenome-assembled genomes substantially expands the tree of life

et al. 2017

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“…Chemolithoautotrophic microorganisms, i.e., microbes that metabolize CO 2 instead of organic carbon, have been shown to be key players and important primary producers in groundwater microbial communities (Alfreider et al, 2012;Hutchins et al, 2016;Kellermann et al, 2012). A high potential for microbial CO 2 fixation has already been demonstrated in our studied aquifers by molecular analyses (Herrmann et al, 2015;Lazar et al, 2016a;Schwab et al, 2017b). We hypothesized that turnover of OM derived from chemoautotrophic microorganisms should be reflected in DIC isotopes, since OM derived from CO 2 fixation should be isotopically distinct from other sources like surface-derived OM or sedimentary organic matter.…”

Section: Introductionmentioning

confidence: 58%

Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

Nowak

Schwab

Lazar

et al. 2017

Hydrol. Earth Syst. Sci.

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Abstract. Isotopes of dissolved inorganic carbon (DIC) are used to indicate both transit times and biogeochemical evolution of groundwaters. These signals can be complicated in carbonate aquifers, as both abiotic (i.e., carbonate equilibria) and biotic factors influence the δ 13 C and 14 C of DIC. We applied a novel graphical method for tracking changes in the δ 13 C and 14 C of DIC in two distinct aquifer complexes identified in the Hainich Critical Zone Exploratory (CZE), a platform to study how water transport links surface and shallow groundwaters in limestone and marlstone rocks in central Germany. For more quantitative estimates of contributions of different biotic and abiotic carbon sources to the DIC pool, we used the NETPATH geochemical modeling program, which accounts for changes in dissolved ions in addition to C isotopes.Although water residence times in the Hainich CZE aquifers based on hydrogeology are relatively short (years or less), DIC isotopes in the shallow, mostly anoxic, aquifer assemblage (HTU) were depleted in 14 C compared to a deeper, oxic, aquifer complex (HTL). Carbon isotopes and chemical changes in the deeper HTL wells could be explained by interaction of recharge waters equilibrated with post-bomb 14 C sources with carbonates. However, oxygen depletion and δ 13 C and 14 C values of DIC below those expected from the processes of carbonate equilibrium alone indicate considerably different biogeochemical evolution of waters in the upper aquifer assemblage (HTU wells). Changes in 14 C and 13 C in the upper aquifer complexes result from a number of biotic and abiotic processes, including oxidation of 14 C-depleted OM derived from recycled microbial carbon and sedimentary organic matter as well as water-rock interactions. The microbial pathways inferred from DIC isotope shifts and changes in water chemistry in the HTU wells were supported by comparison with in situ microbial community structure based on 16S rRNA analyses.Our findings demonstrate the large variation in the importance of biotic as well as abiotic controls on 13 C and 14 C of DIC in closely related aquifer assemblages. Further, they support the importance of subsurface-derived carbon sources like DIC for chemolithoautotrophic microorganisms as well as rock-derived organic matter for supporting heterotrophic groundwater microbial communities and indicate that even shallow aquifers have microbial communities that use a variety of subsurface-derived carbon sources.

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“…The 16S rRNA genes identified in V1-V5 and Bathyarchaeota genomes 12,27 were aligned with full-length 16S rRNA sequences in the GreenGenes database 43 classified as Crenarchaeota, Bathyarchaeota (former Miscellaneous Crenarchaeota Group), Terrestrial Hot Spring Crenarchaeota Group (THSCG) and Aigarchaeota. The multiple sequence alignment from SSU-ALIGN (ref.…”

Section: Methodsmentioning

confidence: 99%

“…3b). The presence of multiple genes encoding peptide and amino-acid transporters suggests that the Verstraetearchaeota are capable of importing these compounds, which can then be degraded to keto-acids by various endopeptidases (PepB, PepD, PepP and PepT), glutamate dehydrogenase (Gdh) and aminotransferases (AspB, ArgD, GabT, IlvE, GlmS and HisC) 26,27 . The ketoacids could be converted to acetyl-CoA by 2-oxoacid: ferredoxin oxidoreductases (Kor, Ior, Por and Vor) and aldehydeferredoxin oxidoreductases (Aor) 12,26 (Fig.…”

Section: Fermentative Metabolismmentioning

confidence: 99%

Methylotrophic methanogenesis discovered in the archaeal phylum Verstraetearchaeota

et al. 2016

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Methanogenesis is the primary biogenic source of methane in the atmosphere and a key contributor to climate change. The long-standing dogma that methanogenesis originated within the Euryarchaeota was recently challenged by the discovery of putative methane-metabolizing genes in members of the Bathyarchaeota, suggesting that methanogenesis may be more phylogenetically widespread than currently appreciated. Here, we present the discovery of divergent methylcoenzyme M reductase genes in population genomes recovered from anoxic environments with high methane flux that belong to a new archaeal phylum, the Verstraetearchaeota. These archaea encode the genes required for methylotrophic methanogenesis, and may conserve energy using a mechanism similar to that proposed for the obligate H 2 -dependent methylotrophic Methanomassiliicoccales and recently described Candidatus 'Methanofastidiosa'. Our findings indicate that we are only beginning to understand methanogen diversity and support an ancient origin for methane metabolism in the Archaea, which is changing our understanding of the global carbon cycle.

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Genomic evidence for distinct carbon substrate preferences and ecological niches of Bathyarchaeota in estuarine sediments

Cited by 206 publications

References 71 publications

Recovery of nearly 8,000 metagenome-assembled genomes substantially expands the tree of life

Recovery of nearly 8,000 metagenome-assembled genomes substantially expands the tree of life

Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

Methylotrophic methanogenesis discovered in the archaeal phylum Verstraetearchaeota

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