A widely conserved bacterial cytoskeletal component influences unique helical shape and motility of the spirochete Leptospira biflexa.
Author | |
---|---|
Abstract | :
Leptospires and other members of the evolutionarily ancient phylum of Spirochaetes are bacteria often characterized by long, highly motile spiral- or wave-shaped cells. Morphology and motility are critical factors in spirochete physiology, contributing to the ability of these bacteria to successfully colonize diverse environments. However, the mechanisms conferring the helical structure of Leptospira spp. have yet to be fully elucidated. We have identified 5 L. biflexa bactofilin proteins, a recently characterized protein family with cytoskeletal properties. These 5 bactofilins are conserved in all species of the Leptospiraceae, indicating that these proteins arose early in the evolution of this family. One member of this protein family, LbbD, confers the optimal pitch distance in the helical structure of L. biflexa. Mutants lacking lbbD display a unique compressed helical morphology, a reduced motility, and a decreased ability to tolerate cell wall stressors. The change in the helical spacing, combined with the motility and cell wall integrity defects, showcases the intimate relationship and coevolution between shape and motility in these spirochetes. This article is protected by copyright. All rights reserved. |
Year of Publication | :
2018
|
Journal | :
Molecular microbiology
|
Date Published | :
2018
|
ISSN Number | :
0950-382X
|
URL | :
http://dx.doi.org/10.1111/mmi.13917
|
DOI | :
10.1111/mmi.13917
|
Short Title | :
Mol Microbiol
|
Download citation |