A DNA damage checkpoint in Caulobacter crescentus inhibits cell division through a direct interaction with FtsW

Author(s)

Modell, Joshua W.; Hopkins, Alexander C.; Laub, Michael T.

Abstract

Following DNA damage, cells typically delay cell cycle progression and inhibit cell division until their chromosomes have been repaired. The bacterial checkpoint systems responsible for these DNA damage responses are incompletely understood. Here, we show that Caulobacter crescentus responds to DNA damage by coordinately inducing an SOS regulon and inhibiting the master regulator CtrA. Included in the SOS regulon is sidA (SOS-induced inhibitor of cell division A), a membrane protein of only 29 amino acids that helps to delay cell division following DNA damage, but is dispensable in undamaged cells. SidA is sufficient, when overproduced, to block cell division. However, unlike many other regulators of bacterial cell division, SidA does not directly disrupt the assembly or stability of the cytokinetic ring protein FtsZ, nor does it affect the recruitment of other components of the cell division machinery. Instead, we provide evidence that SidA inhibits division by binding directly to FtsW to prevent the final constriction of the cytokinetic ring.

Date issued

2011-05

URI

http://hdl.handle.net/1721.1/70050

Department

Massachusetts Institute of Technology. Department of Biology

Journal

Genes and Development

Publisher

Cold Spring Harbor Laboratory

Citation

Modell, J. W., A. C. Hopkins, and M. T. Laub. “A DNA Damage Checkpoint in Caulobacter Crescentus Inhibits Cell Division Through a Direct Interaction with FtsW.” Genes & Development 25.12 (2011): 1328–1343. Web.

Version: Author's final manuscript

ISSN

0890-9369

1549-5477