Pangenomics Analysis Reveals Diversification of Enzyme Families and Niche Specialization in Globally Abundant SAR202 Bacteria

Saw, Jimmy H.; Nunoura, Takuro; Hirai, Miho; Takaki, Yoshihiro; Parsons, Rachel; Michelsen, Michelle L.; Longnecker, Krista; Kujawinski, Elizabeth B.; Stepanauskas, Ramunas; Landry, Zachary C.; Carlson, Craig A.; Giovannoni, Stephen J.

doi:10.1128/mbio.02975-19

Cited by 49 publications

(104 citation statements)

References 58 publications

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“…3D). The SAR202 group III has been previously shown to be one of the most dominant Chloro exi in the water column of the global deep ocean [17,28], and our result highlights the signi cance of these bacteria in both pelagic and sedimentary habitats of the deep ocean. Expansion of paralogous enzymes, such as avin-dependent monooxygenases, in SAR202 group III has been suggested to be important for their adaptation in different deep-sea habitats, by diversifying the range of organic molecules that the cells can utilize [16,17].…”

Section: Distribution Of the Reconstructed Mags In Hadal Sediments Ansupporting

confidence: 67%

“…Currently, the knowledge on the metabolism of deep-sea Chloro exi mainly relies on metagenomic or single-cell genomic analysis, due to the lacking of cultivated representatives for dominant deep-sea lineages [15][16][17]. These studies revealed that Chloro exi from deep-sea waters harbor genes involved in organosulfur compounds degradation [8,15], sul te oxidation [8,15], and the metabolisms of recalcitrant compounds such as cyclic alkanes and aromatic compounds [15][16][17]. The analysis of deep-sea Chloro exi from anoxic subsea oor sediments suggest these bacteria have potential for reductive respiration of organohalogen compounds, and for the fermentation of OM combined with CO 2 xation via the Wood-Ljungdahl pathway [9,18].…”

Section: Introductionmentioning

confidence: 99%

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Novel Chloroflexi genomes from the deepest ocean reveal metabolic strategies for the adaptation to deep-sea habitats

Liu¹,

Wang²,

Wang³

et al. 2021

Preprint

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Background: The deep-sea harbors the majority of the microbial biomass on Earth, and is a key site for organic matter (OM) remineralization and storage in the biosphere. Microbial metabolisms in the deep ocean are greatly controlled by the generally depleted but periodically fluctuating supply of OM. Currently, little is known about metabolic potentials of dominant deep-sea microbes to cope with the variable OM inputs, especially for those living in the hadal trenches - the deepest part of the ocean. Results: In this study, we report the first extensive examination of the metabolic potentials of hadal sediment Chloroflexi, a dominant phylum in hadal trenches and the global deep ocean. Sixty-two metagenome-assembled-genomes (MAGs) were reconstructed from nine metagenomic datasets derived from sediments of the Mariana Trench. These MAGs represent six novel species, four novel genera, one novel family and one novel order within the classes Anaerolinea and Dehalococcoidia. Fragment recruitment showed that these MAGs are globally distributed in deep-sea waters and surface sediments, and transcriptomic analysis indicated their in-situ activities. Metabolic reconstruction showed that hadal Chloroflexi mainly have a heterotrophic lifestyle, with the potential to degrade a wide range of organic carbon, sulfur and halogenated compounds. Our results reveal for the first time that hadal Chloroflexi harbor pathways for the complete hydrolytic or oxidative degradation of various recalcitrant OM, including aromatic compounds (e.g. benzoate), polyaromatic hydrocarbons (e.g. fluorene), polychlorobiphenyl (e.g. 4-chlorobiphenyl) and organochlorine compounds (e.g. chloroalkanes, chlorocyclohexane). Moreover, these organisms show the potential to synthesize energy storage compounds (e.g. trehalose), and have regulatory modules to respond to changes in nutrient conditions. These metabolic traits lead us to postulate that the Chloroflexi may follow a “feast and famine” metabolic strategy, which allows them to efficiently consume labile OM and store the energy under rich OM conditions, and to survive under OM limitations by utilizing stored energy and degrading recalcitrant OM. Conclusion: This study expands the knowledge on metabolic processes in deep-ocean Chlorolfexi, and highlights their significance in deep-sea carbon, sulfur and halogen cycles. The metabolic plasticity likely provides Chloroflexi with advantages for the survival under variable and heterogenic OM inputs in the deep ocean.

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Section: Distribution Of the Reconstructed Mags In Hadal Sediments Ansupporting

confidence: 67%

Section: Introductionmentioning

confidence: 99%

Novel Chloroflexi genomes from the deepest ocean reveal metabolic strategies for the adaptation to deep-sea habitats

Liu¹,

Wang²,

Wang³

et al. 2021

Preprint

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“… 2017 ; Saw et al . 2020 ), peptidases (Mehrshad et al . 2018 ) and potentially haloalkane and haloacetate dehalogenases (Wasmund et al .…”

Section: Discussionmentioning

confidence: 99%

Exploring the abundance, metabolic potential and gene expression of subseafloor Chloroflexi in million-year-old oxic and anoxic abyssal clay

Vuillemin

Kerrigan

Dhondt

et al. 2020

FEMS Microbiology Ecology

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Chloroflexi are widespread in subsurface environments, and recent studies indicate that they represent a major fraction of the communities in subseafloor sediment. Here, we compare the abundance, diversity, metabolic potential, and gene expression of Chloroflexi from three abyssal sediment cores from the western North Atlantic Gyre (water depth >5400 m) covering up to 15 million years of sediment deposition, where Chloroflexi were found to represent major components of the community at all sites. Chloroflexi communities die off in oxic red clay over 10 to 15 million years, and gene expression was below detection. In contrast, Chloroflexi abundance and gene expression at the anoxic abyssal clay site increase below the seafloor and peak in 2 to 3 million-year-old sediment, indicating a comparably higher activity. Metatranscriptomes from the anoxic site reveal increased expression of Chloroflexi genes involved in cell wall biogenesis, protein turnover, inorganic ion transport, defense mechanisms and prophages. Phylogenetic analysis shows that these Chloroflexi are closely related to homoacetogenic subseafloor clades and actively transcribe genes involved in sugar fermentations, gluconeogenesis and Wood-Ljungdahl pathway in the subseafloor. Concomitant expression of cell division genes indicates that these putative homoacetogenic Chloroflexi are actively growing in these million-year-old anoxic abyssal sediments.

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“…For example, a sister clade to the Anaerolineae named WPS-2 (formerly 'subphylum I') contains strains that encode phototrophic machinery but lack carbon fixation machinery (Ward et al, 2019a, b). The non-phototrophic Chloroflexi comprise a larger proportion of the phylum, predominately in the class Anaerolineae that are are widespread in the environment, including strains recovered from activated sludge and wastewater (Nierychlo et al, 2019) and several metagenome assembled genomes from deep ocean environments (Saw et al, 2020), but the ecology of the class remains poorly understood in hot springs.…”

Section: Introductionmentioning

confidence: 99%

Temperature impacts community structure and function of phototrophic Chloroflexi and Cyanobacteria in two alkaline hot springs in Yellowstone National Park

Bennett

Murugapiran

Hamilton

2020

Environ Microbiol Rep

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Summary Photosynthetic bacteria are abundant in alkaline, terrestrial hot springs and there is a long history of research on phototrophs in Yellowstone National Park (YNP). Hot springs provide a framework to examine the ecophysiology of phototrophs in situ because they provide natural gradients of geochemistry, pH and temperature. Phototrophs within the Cyanobacteria and Chloroflexi groups are frequently observed in alkaline hot springs. Decades of research has determined that temperature constrains Cyanobacteria in alkaline hot springs, but factors that constrain the distribution of phototrophic Chloroflexi remain unresolved. Using a combination of 16S rRNA gene sequencing and photoassimilation microcosms, we tested the hypothesis that temperature would constrain the activity and composition of phototrophic Cyanobacteria and Chloroflexi. We expected diversity and rates of photoassimilation to decrease with increasing temperature. We report 16S rRNA amplicon sequencing along with carbon isotope signatures and photoassimilation from 45 to 72°C in two alkaline hot springs. We find that Roseiflexus, Chloroflexus (Chloroflexi) and Leptococcus (Cyanobacteria) operational taxonomic units (OTUs) have distinct distributions with temperature. This distribution suggests that, like phototrophic Cyanobacteria, temperature selects for specific phototrophic Chloroflexi taxa. The richness of phototrophic Cyanobacteria decreased with increasing temperature along with a decrease in oxygenic photosynthesis, whereas Chloroflexi richness and rates of anoxygenic photosynthesis did not decrease with increasing temperature, even at temperatures approaching the upper limit of photosynthesis (~72–73°C). Our carbon isotopic data suggest an increasing prevalence of the 3‐hydroxypropionate pathway with decreasing temperature coincident with photoautotrophic Chloroflexi. Together these results indicate temperature plays a role in defining the niche space of phototrophic Chloroflexi (as has been observed for Cyanobacteria), but other factors such as morphology, geochemistry, or metabolic diversity of Chloroflexi, in addition to temperature, could determine the niche space of this highly versatile group.

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Pangenomics Analysis Reveals Diversification of Enzyme Families and Niche Specialization in Globally Abundant SAR202 Bacteria

Cited by 49 publications

References 58 publications

Novel Chloroflexi genomes from the deepest ocean reveal metabolic strategies for the adaptation to deep-sea habitats

Novel Chloroflexi genomes from the deepest ocean reveal metabolic strategies for the adaptation to deep-sea habitats

Exploring the abundance, metabolic potential and gene expression of subseafloor Chloroflexi in million-year-old oxic and anoxic abyssal clay

Temperature impacts community structure and function of phototrophic Chloroflexi and Cyanobacteria in two alkaline hot springs in Yellowstone National Park

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