Catherine Berrier scite author profile

Mechanosensitive ion channels from Escherichia coli were studied in giant proteoliposomes reconstituted from an inner membrane fraction, or in giant round cells in which the outer membrane and the cell wall had been disrupted by a lysozyme-EDTA treatment and a mild osmotic shock. Patch-clamp experiments revealed the presence in these two preparations of an array of different conductances (100 to 2,300 pS in 0.1 M KCl) activated by stretch. The electrical activity induced by stretch in the native membrane was complex, due to the activation of several different conductances. In contrast, patches of proteoliposomes generally contained clusters of identical conductances, which differed from patch to patch. These experiments are consistent with the notion that these different conductances correspond to different proteins in the plasma membrane of E. coli, which segregate into clusters of identical channels on dilution involved in reconstitution in proteoliposomes. These conductances could be grouped into three subfamilies of poorly selective channels. In both preparations, the higher the conductance, the higher was the negative pressure needed for activation. We discuss the putative role of these channels as parts of a multicomponent osmoregulatory system.

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Gadolinium ion inhibits loss of metabolites induced by osmotic shock and large stretch‐activated channels in bacteria

Berrier

Coulombe

Szabó

et al. 1992

European Journal of Biochemistry

200

183

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Bacteria subjected to a hypotonic osmotic shock lose internal ions and also metabolites, without lysis of the cells. We show that the presence in the shock medium, at submillimolar concentrations, of the ion gadolinium, recently shown to block stretch-activated channels in Xenopus oocytes [Yang, X.-C. & Sachs, F. (1989) Science 243,1068 -10711, was sufficient to inhibit shock-induced release of metabolites such as lactose and ATP in Escherichia coli and ATP in Streptococcus faecalis. Moreover, gadolinium was observed, in patch-clamp experiments, to inhibit the giant stretch-activated channels of E. coli , S. faecalis. and Bacillus subtilis. Taken together, these data suggest that stretch-activated channels are localized in the cytoplasmic membrane of Gram-negative and Gram-positive bacteria, where they control the efflux of osmotic solutes, thus probably playing a major role in the response to hypotonic osmotic shock.

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Release of Thioredoxin via the Mechanosensitive Channel MscL during Osmotic Downshock of Escherichia coli Cells

Ajouz

Berrier

Garrigues

et al. 1998

Journal of Biological Chemistry

148

126

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Escherichia coli cells possess several mechanosensitive ion channels but only MscL, the channel with the highest conductance, which is activated at the highest membrane tension, has been cloned. We investigated the putative involvement of MscL in the effluxes caused by osmotic downshock. Osmotic shock caused the release of potassium glutamate, trehalose, and glycine betaine from wild type cells and cells lacking MscL. There was no difference between the two strains, but the extreme rapidity of the efflux process, as shown herein for glycine betaine, suggests that it is channel-mediated. Osmotic downshock also induces the release of some cytosolic proteins from EDTA-treated cells. We investigated the release of thioredoxin. This protein was totally released from wild type cells but was retained by MscL

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