Journal
NATURE COMMUNICATIONS
Volume 13, Issue 1, Pages -Publisher
NATURE PORTFOLIO
DOI: 10.1038/s41467-022-31378-1
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Funding
- UTS Microbial Imaging Facility (MIF)
- UTS infrastructure grant
- University of Technology Sydney
- Australian Research Council Future Fellowship [FT1601000010]
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During infection, some uropathogenic Escherichia coli exhibit filamentation, a stress response that promotes bacterial dispersal and survival. This process involves dynamic repositioning of FtsZ division rings and the distribution of DamX protein throughout the cell envelope.
During infection of bladder epithelial cells, uropathogenic Escherichia coli (UPEC) can stop dividing and grow into highly filamentous forms. Here, we find that some filaments of E. coli UTI89 released from infected cells grow very rapidly and by more than 100 mu m before initiating division, whereas others do not survive, suggesting that infection-related filamentation (IRF) is a stress response that promotes bacterial dispersal. IRF is accompanied by unstable, dynamic repositioning of FtsZ division rings. In contrast, DamX, which is associated with normal cell division and is also essential for IRF, is distributed uniformly around the cell envelope during filamentation. When filaments initiate division to regenerate rod cells, DamX condenses into stable rings prior to division. The DamX rings maintain consistent thickness during constriction and remain at the septum until after membrane fusion. Deletion of damX affects vegetative cell division in UTI89 (but not in the model E. coli K-12), and, during infection, blocks filamentation and reduces bacterial cell integrity. IRF therefore involves DamX distribution throughout the membrane and prevention of FtsZ ring stabilization, leading to cell division arrest. DamX then reassembles into stable division rings for filament division, promoting dispersal and survival during infection. A subset of uropathogenic Escherichia coli are able to halt division and grow into highly filamentous cells during infection of bladder epithelial cells. Here, authors aim to determine the mechanism, and understand the dynamics of cell division machinery during infection-related filamentation.
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