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An S-methyltransferase that produces the climate-active gas dimethylsulfide is widespread across diverse marine bacteria

Yunhui Zhang, Chuang Sun, Zihua Guo, Liyan Liu, Xiaotong Zhang, Kai Sun, Yanfen Zheng, Andrew J. Gates, Jonathan D. Todd, Xiao‐Hua Zhang, Xiao‐Hua Zhang, Xiao‐Hua Zhang

2024Nature Microbiology14 citationsDOIOpen Access PDF

Abstract

Hydrogen sulfide (H2S), methanethiol (MeSH) and dimethylsulfide (DMS) are abundant sulfur gases with roles in biogeochemical cycling, chemotaxis and/or climate regulation. Catabolism of the marine osmolyte dimethylsulfoniopropionate (DMSP) is a major source of DMS and MeSH, but both also result from S-methylation of H2S via MddA, an H2S and MeSH S-methyltransferase whose gene is abundant in soil but scarce in marine environments. Here we identify the S-adenosine methionine (SAM)-dependent MeSH and H2S S-methyltransferase ‘MddH’, which is widespread in diverse marine bacteria and some freshwater and soil bacteria. mddH is predicted in up to ~5% and ~15% of seawater and coastal sediment bacteria, respectively, which is considerably higher than mddA. Furthermore, marine mddH transcript levels are similar to those for the most abundant DMSP lyase gene dddP. This study implies that the importance of H2S and MeSH S-methylation pathways in marine environments is significantly underestimated. The S-methyltransferase enzyme MddH produces DMS from hydrogen sulfide and methanethiol and its gene abundance rivals that of other known genes whose products generate DMS in marine environments.

Topics & Concepts

MethyltransferaseBacteriaEnvironmental scienceEnvironmental chemistryMarine bacteriophageBiologyEcologyChemistryGeneticsGeneMethylationMicrobial Community Ecology and PhysiologyMarine Bivalve and Aquaculture StudiesMethane Hydrates and Related Phenomena