Cholera remains common in non-industrialized parts of the world today. It persists in part because V. cholera, the bacteria that causes the disease, is able to survive in diverse environments ranging from the intestinal lumen, to fresh water, to estuaries, to the sea. A study in The Journal of General Physiology provides new insights about the membrane components of V. cholera that enable it to withstand otherwise deadly increases in osmotic pressure resulting from changes in its surrounding environment.
Like other bacteria, V. cholera utilizes mechanosensitive channels to respond to rapid shifts in the external osmolarity. But the specific details of how it does so are unclear. Now, researchers from the University of Maryland utilize techniques previously used on E. coli to analyze the functional properties of V. cholera. Sergei Sukharev and colleagues performed the first patch-clamp analysis of channels in the plasma membrane of V. cholera and compared them with those in E. coli. They found that the gating and conductive properties of V. cholerae channels were comparable to those of their E. coli counterparts. A further comparison of the responses of channels in the two species indicated that, whereas small-conductance MscS-like channels were less dense in V. cholerae than in E. coli, large conductance MscL-type channels were present at higher density. Surprisingly, however, V. cholerae was more sensitive than E. coli to abrupt decreases in osmolarity. The findings suggest that the increased number of MscL channels might help compensate for other traits rendering V. cholerae vulnerable to osmotic shock.
About The Journal of General Physiology
Founded in 1918, The Journal of General Physiology (JGP) is published by The Rockefeller University Press. All editorial decisions on manuscripts submitted are made by active scientists in conjunction with our in-house scientific editor. JGP content is posted to PubMed Central, where it is available to the public for free six months after publication. Authors retain copyright of their published works and third parties may reuse the content for non-commercial purposes under a creative commons license. For more information, please visit http://www.jgp.org.
Rowe, I., et al. 2013. J. Gen. Physiol. doi:10.1085/jgp.201310985
Adler, E.M. 2013 J. Gen. Physiol. doi:10.1085/jgp.201311041
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