Geological processes mediate a microbial dispersal loop in the deep biosphere

Gittins, Daniel A.; Desiage, Pierre‐Arnaud; Morrison, Natasha; Rattray, Jayne E.; Bhatnagar, Srijak; Chakraborty, Anirban; Zorz, Jackie; Li, Carmen; Horanszky, Oliver; Cramm, Margaret; Bisiach, Francesco; Bennett, R; Webb, Jamie; MacDonald, Adam; Fowler, Martin; Campbell, D C; Hubert, Claude

doi:10.1126/sciadv.abn3485

Cited by 20 publications

(14 citation statements)

References 90 publications

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“…Heuer et al (2020) postulated that vegetative cells and endospores that are deposited in surface sediments and undergo burial over geological timescales can then be revived under the right selective conditions. This is consistent with recent observations in a 1,180 m sediment core sampled during IODP Expedition 370 (Beulig et al 2022), and the concept of a microbial dispersal loop proposed for understanding the interplay of ecological principles of selection and migration in the subsurface (Mestre and Höfer et al 2020;Gittins et al 2022). Aside from geological processes such as sedimentation and petroleum fluid migration, natural dispersal vectors in the deep biosphere are limited (Stetter et al 1993).…”

Section: Provenance Of the Oil Reservoir Microbiomesupporting

confidence: 88%

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Environmental selection influences the microbiome of subsurface petroleum reservoirs

Gittins

Bhatnagar

Hubert

2022

Preprint

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Petroleum reservoirs within the deep biosphere are extreme environments inhabited by diverse microbial communities creating biogeochemical hotspots in the subsurface. Despite their ecological and industrial importance, systematic studies of core microbial taxa and associated genomic attributes of the oil reservoir microbiome are limited. This study compiles and compares 343 16S rRNA gene amplicon libraries and 25 shotgun metagenomic libraries from oil reservoirs in different parts of the world. Taxonomic composition varies among reservoirs with different physicochemical characteristics, and with geographic distance. Despite oil reservoirs lacking a taxonomic core microbiome in these datasets, gene-centric metagenomic analysis reveals a functional core featuring carbon acquisition and energy conservation strategies consistent with other deep biosphere environments. Genes for anaerobic hydrocarbon degradation are observed in a subset of the samples and are therefore not considered to represent core biogeochemical functions in oil reservoirs. Metabolic redundancy within the petroleum reservoir microbiome reveals these to be deep biosphere systems poised to respond to changes in redox biogeochemistry. This highlights the potential to use microbial genomics for predicting microbial responses to (bio)engineering perturbations to these subsurface habitats.

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Section: Provenance Of the Oil Reservoir Microbiomesupporting

confidence: 88%

“…2022), and the concept of a microbial dispersal loop proposed for understanding the interplay of ecological principles of selection and migration in the subsurface (Mestre and Höfer et al . 2020; Gittins et al . 2022).…”

Section: Discussionmentioning

confidence: 99%

Environmental selection influences the microbiome of subsurface petroleum reservoirs

Gittins

Bhatnagar

Hubert

2022

Preprint

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“…The mud volcano fluids and subsurface sediment microbial communities resemble each other in the presence of gram-positive, sometimes thermophilic, and presumably spore-forming genera and families within the phylum Firmicutes. Thus, the Urania Basin sediment microbiota provide an illustrative example for a “firmicute hotspot,” the previously postulated point sources that distribute endospore-forming, moderately thermophilic Firmicutes across cold marine sediments world-wide ( Hubert et al, 2009 ; Müller et al, 2014 ; Gittins et al, 2022 ). These spore-forming bacteria require a certain minimum temperature but cannot grow in deep-sea surficial sediments that are permanently cold.…”

Section: Discussionmentioning

confidence: 99%

Microbial diversity gradients in the geothermal mud volcano underlying the hypersaline Urania Basin

et al. 2022

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Mud volcanoes transport deep fluidized sediment and their microbial communities and thus provide a window into the deep biosphere. However, mud volcanoes are commonly sampled at the surface and not probed at greater depths, with the consequence that their internal geochemistry and microbiology remain hidden from view. Urania Basin, a hypersaline seafloor basin in the Mediterranean, harbors a mud volcano that erupts fluidized mud into the brine. The vertical mud pipe was amenable to shipboard Niskin bottle and multicorer sampling and provided an opportunity to investigate the downward sequence of bacterial and archaeal communities of the Urania Basin brine, fluid mud layers and consolidated subsurface sediments using 16S rRNA gene sequencing. These microbial communities show characteristic, habitat-related trends as they change throughout the sample series, from extremely halophilic bacteria (KB1) and archaea (Halodesulfoarchaeum spp.) in the brine, toward moderately halophilic and thermophilic endospore-forming bacteria and uncultured archaeal lineages in the mud fluid, and finally ending in aromatics-oxidizing bacteria, uncultured spore formers, and heterotrophic subsurface archaea (Thermoplasmatales, Bathyarchaeota, and Lokiarcheota) in the deep subsurface sediment at the bottom of the mud volcano. Since these bacterial and archaeal lineages are mostly anaerobic heterotrophic fermenters, the microbial ecosystem in the brine and fluidized mud functions as a layered fermenter for the degradation of sedimentary biomass and hydrocarbons. By spreading spore-forming, thermophilic Firmicutes during eruptions, the Urania Basin mud volcano likely functions as a source of endospores that occur widely in cold seafloor sediments.

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“…This mechanism has been shown to affect metacommunity structure by dampening distance-decay relationships and maintaining local diversity (69, 74, 75). Many prokaryotes reach the deep ocean from the surface through vertical dispersal (76) or disperse as endospores from sediments (77). However, DNA-based community composition data includes non-active bacterial cells (78), likely in dormancy state, to survive the very different conditions of the dark and cold deep ocean (77).…”

Section: Discussionmentioning

confidence: 99%

“…Many prokaryotes reach the deep ocean from the surface through vertical dispersal (76) or disperse as endospores from sediments (77). However, DNA-based community composition data includes non-active bacterial cells (78), likely in dormancy state, to survive the very different conditions of the dark and cold deep ocean (77). Therefore, a relatively higher proportion of dormant bacteria can create an apparent ‘homogenization’ of prokaryotic communities in deep zones.…”

Section: Discussionmentioning

confidence: 99%

Global biogeography of the smallest plankton across ocean depths

Junger

Sarmento²,

Giner

et al. 2023

Preprint

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Tiny ocean plankton (picoplankton) are fundamental for the functioning of the biosphere, but the ecological mechanisms shaping their biogeography are partially understood. Comprehending whether these microorganisms are structured by niche vs. neutral processes is highly relevant in the context of global change. The ecological drivers structuring picoplankton communities differ between prokaryotes and minute eukaryotes (picoeukaryotes) in the global surface ocean: while prokaryotic communities are shaped by a balanced combination of dispersal, selection, and drift, picoeukaryotic communities are mainly shaped by dispersal limitation. Yet, whether or not the relative importance of these processes in structuring picoplankton varies as we dive into the deep ocean was unknown. Here we investigate the mechanisms structuring picoplanktonic communities inhabiting different ocean depths. We analyzed 451 samples from the tropical and subtropical global ocean and the Mediterranean Sea covering the epi- (0-200m), meso- (200-1,000m), and bathypelagic (1,000-4,000m) depth zones. We found that selection decreased with depth possibly due to lower habitat heterogeneity. In turn, dispersal limitation increased with depth, possibly due to dispersal barriers such as water masses and bottom topography. Picoplankton β-diversity positively correlated with environmental heterogeneity and water mass variability in both the open-ocean and the Mediterranean Sea. However, this relationship tended to be weaker for picoeukaryotes than for prokaryotes. Community patterns were generally more pronounced in the Mediterranean Sea, probably because of its substantial cross-basin environmental heterogeneity and deep-water isolation. Altogether, we found that different combinations of ecological mechanisms shape the biogeography of the smallest members of the ocean microbiome across ocean depths.

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Geological processes mediate a microbial dispersal loop in the deep biosphere

Cited by 20 publications

References 90 publications

Environmental selection influences the microbiome of subsurface petroleum reservoirs

Environmental selection influences the microbiome of subsurface petroleum reservoirs

Microbial diversity gradients in the geothermal mud volcano underlying the hypersaline Urania Basin

Global biogeography of the smallest plankton across ocean depths

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