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Phylogenetic and ecophysiological novelty of subsurface mercury methylators in mangrove sediments

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ISME JOURNAL
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SPRINGERNATURE
DOI: 10.1038/s41396-023-01544-4

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In this study, the authors used MeHg biogeochemical assay and metagenomic sequencing to investigate the microbial community in mangrove sediments and found that subsurface sediments have a higher diversity of Hg methylators compared to superficial sediments. They also identified a novel Hg-methylating microbial lineage called Zixibacteria with unique methionine synthesis capabilities. This study expands our understanding of subsurface Hg methylators and their ecophysiological adaptations in mangrove sediments.
Mangrove sediment is a crucial component in the global mercury (Hg) cycling and acts as a hotspot for methylmercury (MeHg) production. Early evidence has documented the ubiquity of well-studied Hg methylators in mangrove superficial sediments; however, their diversity and metabolic adaptation in the more anoxic and highly reduced subsurface sediments are lacking. Through MeHg biogeochemical assay and metagenomic sequencing, we found that mangrove subsurface sediments (20-100 cm) showed a less hgcA gene abundance but higher diversity of Hg methylators than superficial sediments (0-20 cm). Regional-scale investigation of mangrove subsurface sediments spanning over 1500 km demonstrated a prevalence and family-level novelty of Hg-methylating microbial lineages (i.e., those affiliated to Anaerolineae, Phycisphaerae, and Desulfobacterales). We proposed the candidate phylum Zixibacteria lineage with sulfate-reducing capacity as a currently understudied Hg methylator across anoxic environments. Unlike other Hg methylators, the Zixibacteria lineage does not use the Wood-Ljungdahl pathway but has unique capabilities of performing methionine synthesis to donate methyl groups. The absence of cobalamin biosynthesis pathway suggests that this Hg-methylating lineage may depend on its syntrophic partners (i.e., Syntrophobacterales members) for energy in subsurface sediments. Our results expand the diversity of subsurface Hg methylators and uncover their unique ecophysiological adaptations in mangrove sediments.

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