Elucidation of a key mechanism regulating organosulfur cycling in ubiquitous marine bacteria

Hui Hui Fu; Ming-Chen Wang; Zhi-Qing Wang; Yu-Han Sang; Zhen-Kun Li; Fei-Fei Li; Jia-Rong Liu; Qi-Long Qin; Xiao-Yu Zhu; Na Wang; Jin-Jian Wan; Zhao-Jie Teng; Wei-Peng Zhang; Andrew J. Gates; Chun-Yang Li; Jonathan Todd; Yu-Zhong Zhang

Elucidation of a key mechanism regulating organosulfur cycling in ubiquitous marine bacteria

Hui Hui Fu, Ming-Chen Wang, Zhi-Qing Wang, Yu-Han Sang, Zhen-Kun Li, Fei-Fei Li, Jia-Rong Liu, Qi-Long Qin, Xiao-Yu Zhu, Na Wang, Jin-Jian Wan, Zhao-Jie Teng, Wei-Peng Zhang, Andrew J. Gates, Chun-Yang Li, Jonathan Todd, Yu-Zhong Zhang

Research output: Contribution to journal › Article › peer-review

Abstract

Dimethylsulfoniopropionate (DMSP) catabolism by marine Roseobacters is important for global biogeochemical cycling and the climate. Many Roseobacters contain competing DMSP demethylation and cleavage pathways, but only cleavage produces the climate-cooling gas dimethylsulfide. We identify the “switch” regulator in Roseobacters, DmdR, that represses the transcription of DMSP demethylation (dmdA, encoding DMSP demethylase), cleavage (acuI, encoding acryloyl-CoA reductase) and often novel oxidative stress protection (dmdEF, dinB) genes under low intracellular DMSP levels. Increased DMSP levels induce DMSP cleavage and accumulation of cytotoxic acryloyl-CoA. DmdR binds acryloyl-CoA as its effector and derepresses dmdA-acuI transcription to stimulate acryloyl-CoA catabolism and DMSP demethylation. Co-upregulation of the novel peroxidase DmdF and likely DmdE and DinB counteract oxidative stress associated with DMSP demethylation. Thus, DmdR, with DmdR-independent regulation of DMSP cleavage, likely balances cellular DMSP levels to allow its antistress functions, but accelerated demethylation and catabolism of toxic intermediates at higher DMSP levels. In abundant marine bacteria lacking dmdA, DmdR still likely controls acryloyl-CoA catabolism/detoxification. DmdR and DmdEF are widespread in Earth’s oceans and important in biogeochemical cycling and climate-active gas production.

Original language	English
Journal	The EMBO Journal
Publication status	Accepted/In press - 9 Jan 2026

Keywords

DMSP catabolism
coordinated regulation
transcriptional regulator
marine bacteria

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

@article{97dd8e5f07774e5f9ba653c21e48e8a8,

title = "Elucidation of a key mechanism regulating organosulfur cycling in ubiquitous marine bacteria",

abstract = "Dimethylsulfoniopropionate (DMSP) catabolism by marine Roseobacters is important for global biogeochemical cycling and the climate. Many Roseobacters contain competing DMSP demethylation and cleavage pathways, but only cleavage produces the climate-cooling gas dimethylsulfide. We identify the “switch” regulator in Roseobacters, DmdR, that represses the transcription of DMSP demethylation (dmdA, encoding DMSP demethylase), cleavage (acuI, encoding acryloyl-CoA reductase) and often novel oxidative stress protection (dmdEF, dinB) genes under low intracellular DMSP levels. Increased DMSP levels induce DMSP cleavage and accumulation of cytotoxic acryloyl-CoA. DmdR binds acryloyl-CoA as its effector and derepresses dmdA-acuI transcription to stimulate acryloyl-CoA catabolism and DMSP demethylation. Co-upregulation of the novel peroxidase DmdF and likely DmdE and DinB counteract oxidative stress associated with DMSP demethylation. Thus, DmdR, with DmdR-independent regulation of DMSP cleavage, likely balances cellular DMSP levels to allow its antistress functions, but accelerated demethylation and catabolism of toxic intermediates at higher DMSP levels. In abundant marine bacteria lacking dmdA, DmdR still likely controls acryloyl-CoA catabolism/detoxification. DmdR and DmdEF are widespread in Earth{\textquoteright}s oceans and important in biogeochemical cycling and climate-active gas production.",

keywords = "DMSP catabolism, coordinated regulation, transcriptional regulator, marine bacteria",

author = "Fu, {Hui Hui} and Ming-Chen Wang and Zhi-Qing Wang and Yu-Han Sang and Zhen-Kun Li and Fei-Fei Li and Jia-Rong Liu and Qi-Long Qin and Xiao-Yu Zhu and Na Wang and Jin-Jian Wan and Zhao-Jie Teng and Wei-Peng Zhang and Gates, {Andrew J.} and Chun-Yang Li and Jonathan Todd and Yu-Zhong Zhang",

year = "2026",

month = jan,

day = "9",

language = "English",

journal = "The EMBO Journal",

issn = "0261-4189",

publisher = "EMBO Press",

}

TY - JOUR

T1 - Elucidation of a key mechanism regulating organosulfur cycling in ubiquitous marine bacteria

AU - Fu, Hui Hui

AU - Wang, Ming-Chen

AU - Wang, Zhi-Qing

AU - Sang, Yu-Han

AU - Li, Zhen-Kun

AU - Li, Fei-Fei

AU - Liu, Jia-Rong

AU - Qin, Qi-Long

AU - Zhu, Xiao-Yu

AU - Wang, Na

AU - Wan, Jin-Jian

AU - Teng, Zhao-Jie

AU - Zhang, Wei-Peng

AU - Gates, Andrew J.

AU - Li, Chun-Yang

AU - Todd, Jonathan

AU - Zhang, Yu-Zhong

PY - 2026/1/9

Y1 - 2026/1/9

N2 - Dimethylsulfoniopropionate (DMSP) catabolism by marine Roseobacters is important for global biogeochemical cycling and the climate. Many Roseobacters contain competing DMSP demethylation and cleavage pathways, but only cleavage produces the climate-cooling gas dimethylsulfide. We identify the “switch” regulator in Roseobacters, DmdR, that represses the transcription of DMSP demethylation (dmdA, encoding DMSP demethylase), cleavage (acuI, encoding acryloyl-CoA reductase) and often novel oxidative stress protection (dmdEF, dinB) genes under low intracellular DMSP levels. Increased DMSP levels induce DMSP cleavage and accumulation of cytotoxic acryloyl-CoA. DmdR binds acryloyl-CoA as its effector and derepresses dmdA-acuI transcription to stimulate acryloyl-CoA catabolism and DMSP demethylation. Co-upregulation of the novel peroxidase DmdF and likely DmdE and DinB counteract oxidative stress associated with DMSP demethylation. Thus, DmdR, with DmdR-independent regulation of DMSP cleavage, likely balances cellular DMSP levels to allow its antistress functions, but accelerated demethylation and catabolism of toxic intermediates at higher DMSP levels. In abundant marine bacteria lacking dmdA, DmdR still likely controls acryloyl-CoA catabolism/detoxification. DmdR and DmdEF are widespread in Earth’s oceans and important in biogeochemical cycling and climate-active gas production.

AB - Dimethylsulfoniopropionate (DMSP) catabolism by marine Roseobacters is important for global biogeochemical cycling and the climate. Many Roseobacters contain competing DMSP demethylation and cleavage pathways, but only cleavage produces the climate-cooling gas dimethylsulfide. We identify the “switch” regulator in Roseobacters, DmdR, that represses the transcription of DMSP demethylation (dmdA, encoding DMSP demethylase), cleavage (acuI, encoding acryloyl-CoA reductase) and often novel oxidative stress protection (dmdEF, dinB) genes under low intracellular DMSP levels. Increased DMSP levels induce DMSP cleavage and accumulation of cytotoxic acryloyl-CoA. DmdR binds acryloyl-CoA as its effector and derepresses dmdA-acuI transcription to stimulate acryloyl-CoA catabolism and DMSP demethylation. Co-upregulation of the novel peroxidase DmdF and likely DmdE and DinB counteract oxidative stress associated with DMSP demethylation. Thus, DmdR, with DmdR-independent regulation of DMSP cleavage, likely balances cellular DMSP levels to allow its antistress functions, but accelerated demethylation and catabolism of toxic intermediates at higher DMSP levels. In abundant marine bacteria lacking dmdA, DmdR still likely controls acryloyl-CoA catabolism/detoxification. DmdR and DmdEF are widespread in Earth’s oceans and important in biogeochemical cycling and climate-active gas production.

KW - DMSP catabolism

KW - coordinated regulation

KW - transcriptional regulator

KW - marine bacteria

M3 - Article

SN - 0261-4189

JO - The EMBO Journal

JF - The EMBO Journal

ER -