AI Article Synopsis
- Biofilms are communities of bacteria that attach to surfaces and are held together by a matrix, but how this matrix interacts with the cells is not fully understood.
- The study focuses on *Vibrio cholerae*, the bacteria responsible for cholera, and reveals that the main matrix component, Vibrio polysaccharide (VPS), does not attract the cells, but a protein called Bap1 helps link the cells together.
- As biofilms age, changes in VPS levels and a process called surface trimming lead to a shift in cell-matrix interactions from attractive to repulsive, promoting cell dispersal and potentially enriching our understanding of biofilm growth dynamics in other microorganisms.
Article Abstract
Biofilms are ubiquitous surface-associated bacterial communities embedded in an extracellular matrix. While it is commonly assumed that biofilm-dwelling cells are glued together by the matrix, how the cell-matrix interaction depends on the specific biochemistry of the matrix components and how this interaction varies during biofilm growth remains unclear. Here, we investigated cell-matrix interactions in ( ), the causative agent of cholera. We combine genetics, microscopy, simulation, and biochemical tools to show that cells are not attractive to V ibrio p oly s accharide (VPS), the main matrix component, but they can be bridged with each other and to the VPS network through crosslinking by Bap1. Downregulation of VPS and surface trimming by the polysaccharide lyase RbmB cause surface remodeling as biofilms age, shifting the nature of cell-matrix interactions from attractive to repulsive and facilitating cell dispersal as aggregated groups. Our results suggest a new conceptual model in understanding the intricate cell-matrix interaction as the major driver for biofilm development, which is potentially generalizable to certain other biofilm-forming species and exopolysaccharides.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11601406 | PMC |
| http://dx.doi.org/10.1101/2024.11.11.623042 | DOI Listing |
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