309 metagenome assembled microbial genomes from deep sediment samples in the Gulfs of Kathiawar Peninsula

Prokaryoplankton genomes from the deep marine sediments are less explored compared to shallow shore sediments. The Gulfs of Kathiawar peninsula experience varied currents and inputs from different on-shore activities. Any perturbations would directly influence the microbiome and their normal homeostasis. Advancements in reconstructing genomes from metagenomes allows us to understand the role of individual unculturable microbes in ecological niches like the Gulf sediments. Here, we report 309 bacterial and archaeal genomes assembled from metagenomics data of deep sediments from sites in the Gulf of Khambhat and Gulf of Kutch as well as a sample from the Arabian Sea. Phylogenomics classified them into 5 archaeal and 18 bacterial phyla. The genomes will facilitate understanding of the physiology, adaptation and impact of on-shore anthropogenic activities on the deep sediment microbes.

Revealing the full biosphere structure and versatile metabolic functions in the deepest ocean sediment of the Challenger Deep

Background The full biosphere structure and functional exploration of the microbial communities of the Challenger Deep of the Mariana Trench, the deepest known hadal zone on Earth, lag far behind that of other marine realms. Results We adopt a deep metagenomics approach to investigate the microbiome in the sediment of Challenger Deep, Mariana Trench. We construct 178 metagenome-assembled genomes (MAGs) representing 26 phyla, 16 of which are reported from hadal sediment for the first time. Based on the MAGs, we find the microbial community functions are marked by enrichment and prevalence of mixotrophy and facultative anaerobic metabolism. The microeukaryotic community is found to be dominated by six fungal groups that are characterized for the first time in hadal sediment to possess the assimilatory and dissimilatory nitrate/sulfate reduction, and hydrogen sulfide oxidation pathways. By metaviromic analysis, we reveal novel hadal Caudovirales clades, distinctive virus-host interactions, and specialized auxiliary metabolic genes for modulating hosts’ nitrogen/sulfur metabolism. The hadal microbiome is further investigated by large-scale cultivation that cataloged 1070 bacterial and 19 fungal isolates from the Challenger Deep sediment, many of which are found to be new species specialized in the hadal habitat. Conclusion Our hadal MAGs and isolates increase the diversity of the Challenger Deep sediment microbial genomes and isolates present in the public. The deep metagenomics approach fills the knowledge gaps in structure and diversity of the hadal microbiome, and provides novel insight into the ecology and metabolism of eukaryotic and viral components in the deepest biosphere on earth.

Revealing the full biosphere structure and versatile metabolic functions in the deepest ocean sediment of the Challenger Deep

Background: The full biosphere structure and functional exploration of the microbial communities of the Challenger Deep of the Mariana Trench, the deepest known hadal zone on Earth, lag far behind that of other marine realms. Results: We adopt a deep metagenomics approach to investigate the microbiome in the sediment of Challenger Deep, Mariana Trench. We construct 178 metagenome-assembled genomes (MAGs) representing 26 phyla, 16 of which are reported from hadal sediment for the first time. Based on the MAGs, we find the microbial community functions are marked by enrichment and prevalence of mixotrophy and facultative anaerobic metabolism. The microeukaryotic community is found to be dominated by six fungal groups that are characterized for the first time in hadal sediment to possess the assimilatory and dissimilatory nitrate and sulfate reduction, and hydrogen sulfide oxidation pathways. By metaviromic analysis, we reveal novel hadal Caudovirales clades, distinctive virus-host interactions, and specialized auxiliary metabolic genes for modulating hosts' nitrogen/sulfur metabolism. The hadal microbiome is further investigated by large-scale cultivation that cataloged 1070 bacterial and 19 fungal isolates from the Challenger Deep sediment, many of which are found to be new species specialized in the hadal habitat. Conclusion: Our hadal MAGs and isolates increase the diversity of the Challenger Deep sediment microbial genomes and isolates present in the public. The deep metagenomics approach fills the knowledge gaps in structure and diversity of the hadal microbiome, and provides novel insight into the ecology and metabolism of eukaryotic and viral components in the deepest biosphere on earth.

Metagenomic Insights Into Ecological and Phylogenetic Significances of Candidatus Natranaeroarchaeales, a Novel Abundant Archaeal Order in Soda Lake Sediment

BackgroundArchaea were originally discovered in extreme environments, and thrive in many extreme habitats including soda lakes with high pH and salinity. Characteristic and diverse archaeal community played a significant role in biogeochemical cycles; however, the archaeal community and their functions are still less-studied in the intricate sediment of soda lakes. ResultsIn this article, the archaeal community of the deep sediment (40-50 cm depth) of five artificially-separated ponds with a salinity range from 7.0% to 33.0% in a soda saline lake was systematically surveyed using culture-independent metagenomics combined with the next-generation sequencing of the archaeal 16S rRNA amplicons. Nine archaeal phyla were detected, which accounted for 2.2% to 35.73% of microbial community in the five deep sediments. Besides the well-known class Halobacteria, one novel archaeal order (Candidatus Natranaeroarchaeales) of the class Thermoplasmata was even more abundant than Halobacteria in some deep sediment samples. Of 69 dereplicated archaeal metagenome-assembled genomes (MAGs), 30 MAGs belonged to Ca. Natranaeroarchaeales. Different genera of the Ca. Natranaeroarchaeales preferred to inhabit in the different salinities, and the divergent halophilic adaptation strategies (salt-out or salt-in) suggested the fast evolution adaptation within this lineage. Most high-quality MAGs had the genes of Wood-Ljungdahl pathway, organic acid fermentation and sulfur respiration, suggesting the putative functions in carbon fixation and sulfur reduction. Interestingly, heterodisulfide reductase and F420-non-reducing hydrogenase complex HdrABC-MvhADG were widely distributed in Ca. Natranaeroarchaeales and may play the core roles in energy metabolism from hydrogen. The regeneration of CoM-S-S-CoB was coupled to succinate or 2-oxoglutarate production in Ca. Natranaeroarchaeales instead of methanogenesis in the close related Methanomassiliicoccales. It suggested that methyl-coenzyme M reductase in Methanomassiliicoccales may be laterally transferred from other methanogens. ConclusionA novel archaeal order Ca. Natranaeroarchaeales of Thermoplasmata was found by culture-independent approaches. This order was the most abundant archaeal lineage in the deep sediment of soda lakes, with the characteristic environmental adaptation and biogeochemical potentials in carbon fixation and sulfur reduction. The difference in fermentation products coupled to energy metabolism between methanogens and Ca. Natranaeroarchaeales provided additional insights into the origination of methanogenesis in Thermoplasmata from the energy metabolism perspective.

“Sifarchaeota” a novel Asgard phylum capable of polysaccharide degradation and anaerobic methylotrophy

The Asgard superphylum is a deeply branching monophyletic group of Archaea, recently described as some of the closest relatives of the eukaryotic ancestor. The wide application of genomic analyses from metagenome sequencing has established six distinct phyla, whose genomes encode for diverse metabolic capacities and play important biogeochemical and ecological roles in marine sediments. Here, we describe two metagenome-assembled genomes (MAGs) recovered from deep marine sediments off Costa Rica margin, defining a novel lineage phylogenetically married to Thorarchaeota, as such we propose the name “Sifarchaeota” for this phylum. The two “Sifarchaeota” MAGs encode for an anaerobic methylotrophy pathway enabling the utilization of C1-C3 compounds (methanol and methylamines) to synthesize acetyl CoA. Also, the MAGs showed a remarkable saccharolytic capabilities compared to other Asgard lineages and encoded for diverse classes of carbohydrate active enzymes (CAZymes) targeting different mono-, di- and oligosaccharides. Comparative genomic analysis based on the full metabolic profiles of Asgard lineages revealed the close relation between “Sifarchaeota” and Odinarchaeota MAGs, which suggested a similar metabolic potentials and ecological roles. Furthermore, we identified multiple potential horizontal gene transfer (HGT) events from different bacterial donors within “Sifarchaetoa” MAGs, which hypothetically expanded “Sifarchaeota” capacities for substrate utilization, energy production and niche adaptation.ImportanceDeep marine sediments are the home of multiple poorly described archaeal lineages, many of which have ecological and evolutionary importance. We recovered metagenome-assembled genomes (MAGs) belonging to a novel Asgard phylum from the deep sediment of the Costa Rica margin. We proposed the name “Sifarchaeota” to describe the members of this phylum. Representative genomes of the “Sifarchaeota” showed remarkable saccharolytic capacities extending the known metabolic features encoded by the Asgard lineages. We attribute its ability to survive under the deep sediment conditions to its putative capacities to utilize different (C1-C3) compounds commonly encountered in deep sediment environments via anaerobic methylotrophy pathway. Also, we showed the importance of horizontal gene transfer in enhancing the “Sifarchaeota” collective adaptation strategies.