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Simulations suggest a constrictive force is required for Gram-negative bacterial cell division.


ABSTRACT: To divide, Gram-negative bacterial cells must remodel cell wall at the division site. It remains debated, however, whether this cell wall remodeling alone can drive membrane constriction, or if a constrictive force from the tubulin homolog FtsZ is required. Previously, we constructed software (REMODELER 1) to simulate cell wall remodeling during growth. Here, we expanded this software to explore cell wall division (REMODELER 2). We found that simply organizing cell wall synthesis complexes at the midcell is not sufficient to cause invagination, even with the implementation of a make-before-break mechanism, in which new hoops of cell wall are made inside the existing hoops before bonds are cleaved. Division can occur, however, when a constrictive force brings the midcell into a compressed state before new hoops of relaxed cell wall are incorporated between existing hoops. Adding a make-before-break mechanism drives division with a smaller constrictive force sufficient to bring the midcell into a relaxed, but not necessarily compressed, state.

SUBMITTER: Nguyen LT 

PROVIDER: S-EPMC6425016 | biostudies-literature | 2019 Mar

REPOSITORIES: biostudies-literature

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Simulations suggest a constrictive force is required for Gram-negative bacterial cell division.

Nguyen Lam T LT   Oikonomou Catherine M CM   Ding H Jane HJ   Kaplan Mohammed M   Yao Qing Q   Chang Yi-Wei YW   Beeby Morgan M   Jensen Grant J GJ  

Nature communications 20190319 1


To divide, Gram-negative bacterial cells must remodel cell wall at the division site. It remains debated, however, whether this cell wall remodeling alone can drive membrane constriction, or if a constrictive force from the tubulin homolog FtsZ is required. Previously, we constructed software (REMODELER 1) to simulate cell wall remodeling during growth. Here, we expanded this software to explore cell wall division (REMODELER 2). We found that simply organizing cell wall synthesis complexes at th  ...[more]

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