Membrane vesicles of Shewanella oneidensis MR-1 enhance denitrification growth in a species-specific manner

Denitrification, a fundamental bacterial respiratory process that occurs in anoxic environments, plays a pivotal role in energy synthesis and the global nitrogen cycle. Although the significance of this process is well-recognized, its regulation within polymicrobial communities remains poorly understood, particularly concerning interspecies interactions. In this study, we investigated the role that bacterial membrane vesicles (MV) play in modulating denitrification across bacterial species. MV is known to carry specific biomolecules such as secondary metabolites, proteins, and nucleic acids, therefore considered to be a secretion pathway. We found that MV produced by Shewanella oneidensis enhanced denitrification in a species-specific manner. Bacteria with highly hydrophobic surfaces tended to respond to denitrification enhancement, suggesting that the MV–bacteria attachment process is the key to generating species specificity. Transcriptome analysis and isotopic metabolite tracking indicated that the MV influenced denitrifying activities, rather than the transcription of denitrification-related genes. We further demonstrated that c -type cytochromes in MV act as key components that enhance denitrification. These insights expand our understanding of bacterial ecology, highlighting the role of membrane vesicles in facilitating respiratory competition and cooperation in polymicrobial communities.