Litcius/Paper detail

Key role of <i>Desulfobacteraceae</i> in C/S cycles of marine sediments is based on congeneric catabolic-regulatory networks

Lars Wöhlbrand, Marvin Dörries, Roberto Siani, Arturo Medrano-Soto, Vanessa Schnaars, Julian Schumacher, Christina Hilbers, Daniela Thies, Michael Kube, Richard Reinhardt, Michael Schloter, Milton H. Saier, Michael Winklhofer, Ralf Rabus

2025Science Advances11 citationsDOIOpen Access PDF

Abstract

Marine sediments are highly bioactive habitats, where sulfate-reducing bacteria contribute substantially to seabed carbon cycling by oxidizing ~77 Tmol C org year −1 . This remarkable activity is largely attributable to the deltaproteobacterial family Desulfobacteraceae of complete oxidizers (to CO 2 ), which our biogeography focused meta-analysis verified as cosmopolitan. However, the catabolic/regulatory networks underlying this ecophysiological feat at the thermodynamic limit are essentially unknown. Integrating cultivation-based (80 conditions) proteogenomics of six representative Desulfobacteraceae spp., we identify molecular commonalities explaining the family’s environmental relevance and success. Desulfobacteraceae genomes are specifically enriched in substrate uptake, degradation capacities, and regulatory functions including fine-tuned sulfate uptake. Conserved gene arrangements and shared regulatory patterns translate into strikingly similar (sub-)proteome profiles. From 319 proteins, we constructed a meta-network for catabolizing 35 substrates. Therefrom, we defined a Desulfobacteraceae characteristic gene subset, which we found prevalent in metagenomes of organic-rich, marine sediments. These genes are promising targets to advance our mechanistic understanding of Desulfobacteraceae -driven biogeochemical processes in marine sediments and beyond.

Topics & Concepts

Biogeochemical cycleMarine habitatsProteomeBiologyProteogenomicsGeneMarine bacteriophageGenomeGene regulatory networkComputational biologyEcologyHabitatBacteriaGeneticsGenomicsGene expressionMicrobial Community Ecology and PhysiologyGenomics and Phylogenetic StudiesMethane Hydrates and Related Phenomena