Manlin Xu’s research while affiliated with Georgia Institute of Technology and other places

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Publications (3)


Molecular basis for inhibition of methane clathrate growth by a deep subsurface bacterial protein
  • Article

February 2024

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21 Reads

Biophysical Journal

Zixing Fan

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Molecular basis for inhibition of methane clathrate growth by a deep subsurface bacterial protein
  • Article
  • Full-text available

August 2023

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101 Reads

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1 Citation

PNAS Nexus

Methane clathrates on continental margins contain the largest stores of hydrocarbons on Earth, yet the role of biomolecules in clathrate formation and stability remains almost completely unknown. Here we report new methane clathrate-binding proteins (CbpAs) of bacterial origin discovered in metagenomes from gas clathrate-bearing ocean sediments. CbpAs show similar suppression of methane clathrate growth as the commercial gas clathrate inhibitor polyvinylpyrrolidone and inhibit clathrate growth at lower concentrations than antifreeze proteins (AFPs) previously tested. Unlike AFPs, CbpAs are selective for clathrate over ice. CbpA3 adopts a non-globular, extended structure with an exposed hydrophobic surface, and, unexpectedly, its TxxxAxxxAxx motif common to AFPs is buried and not involved in clathrate binding. Instead, simulations and mutagenesis suggest a bipartite interaction of CbpAs with methane clathrate, with the pyrrolidine ring of a highly conserved proline residue mediating binding by filling empty clathrate cages. The discovery that CbpAs exert such potent control on methane clathrate properties implies that biomolecules from native sediment bacteria may be important for clathrate stability and habitability.

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Figure S1. Map of Site ODP 1244 (44°35.1784´N; 125°7.1902´W) on Hydrate Ridge, drilled on IODP Leg 204. The site is located 80 km west of
Microbial metabolism and adaptations in Atribacteria-dominated methane hydrate sediments

June 2021

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137 Reads

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23 Citations

Environmental Microbiology

Gas hydrates harbor gigatons of natural gas, yet their microbiomes remain understudied. We bioprospected 16S rRNA amplicons, metagenomes, and metaproteomes from methane hydrate-bearing sediments under Hydrate Ridge (offshore Oregon, USA, ODP Site 1244, 2-69 mbsf) for novel microbial metabolic and biosynthetic potential. Atribacteria sequences generally increased in relative sequence abundance with increasing sediment depth. Most Atribacteria ASVs belonged to JS-1-Genus 1 and clustered with other sequences from gas hydrate-bearing sediments. We recovered 21 metagenome-assembled genomic bins spanning three geochemical zones in the sediment core: the sulfate-methane transition zone, metal (iron/manganese) reduction zone, and gas hydrate stability zone. We found evidence for bacterial fermentation as a source of acetate for aceticlastic methanogenesis and as a driver of iron reduction in the metal reduction zone. In multiple zones, we identified a Ni-Fe hydrogenase-Na+/H+ antiporter supercomplex (Hun) in Atribacteria and Firmicutes bins and in other deep subsurface bacteria and cultured hyperthermophiles from the Thermotogae phylum. Atribacteria expressed tripartite ATP-independent (TRAP) transporters downstream from a novel regulator (AtiR). Atribacteria also possessed adaptations to survive extreme conditions (e.g., high salt brines, high pressure, and cold temperatures) including the ability to synthesize the osmolyte di-myo-inositol-phosphate as well as expression of K+ -stimulated pyrophosphatase and capsule proteins. This article is protected by copyright. All rights reserved.

Citations (1)


... Members of the phylum Atribacterota are found in a broad range of anoxic environments, including oil reservoirs [1] and produced water [2], hot springs [3], marine sediments [4], and methane hydrates [5]. Currently, only one species, Atribacter laminatus RT761 T , has been isolated and characterized [2]. A. laminatus, a glucose fermenter, produced H 2 , acetate, and CO 2 as fermentation products and was stimulated by cocultivation with a hydrogenotrophic methanogen [2]. ...

Reference:

Cultivation of novel Atribacterota from oil well provides new insight into their diversity, ecology, and evolution in anoxic, carbon-rich environments
Microbial metabolism and adaptations in Atribacteria-dominated methane hydrate sediments

Environmental Microbiology