Chemotactically induced increase in the membrane potential of spheroplasts of Rhodopseudomonas sphaeroides

Photosensory behavior in procaryotes

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A voltage clamp inhibits chemotaxis of Spirochaeta aurantia

Anaerobic conditions were employed to study the relationship between membrane potential and chemotaxis in Spirochaeta aurantia. When cells were grown anaerobically and suspended in anaerobic potassium phosphate buffer (pH 5.5), membranes did not appear to be polarized. Nevertheless, motility was supported by a transmembrane pH gradient, and the anaerobic cells exhibited D-xylose taxis. Introduction of trace amounts of air into anaerobic cell suspensions resulted in a transient membrane polarization. The addition of valinomycin to cells suspended under anaerobic conditions did not alter the steady-state value of membrane potential appreciably but served to clamp membrane potential at the preset level. Although there was no detectable effect of valinomycin on the motility of anaerobic cells in potassium phosphate buffer, D-xylose taxis was completely inhibited by this treatment. These data indicate the the action of valinomycin as a voltage clamp serves to inhibit the chemotaxis of S. aurantia and provide evidence to support the suggestion that the mechanism of chemotaxis in this organism involves the transduction of sensory signals in the form of membrane potential fluctuations.

Chemotaxis of Spirochaeta aurantia: involvement of membrane potential in chemosensory signal transduction

The effects of valinomycin and nigericin on sugar chemotaxis in Spirochaeta aurantia were investigated by using a quantitative capillary assay, and the fluorescent cation, 3,3'-dipropyl-2,2'-thiodicarbocyanine iodide was used as a probe to study effects of chemoattractants on membrane potential. Addition of a chemoattractant, D-xylose, to cells in either potassium or sodium phosphate buffer resulted in a transient membrane depolarization. In the presence of valinomycin, the membrane potential of cells in potassium phosphate buffer was reduced, and the transient membrane depolarization that resulted from the addition of D-xylose was eliminated. Although there was no detectable effect of valinomycin on motility, D-xylose taxis of cells in potassium phosphate buffer was completely inhibited by valinomycin. In sodium phosphate buffer, valinomycin had little effect on membrane potential or D-xylose taxis. Nigericin is known to dissipate the transmembrane pH gradient of S. aurantia in potassium phosphate buffer. This compound did not dissipate the membrane potential or the transient membrane depolarization observed upon addition of D-xylose to cells in either potassium or sodium phosphate buffer. Nigericin did not inhibit D-xylose taxis in either potassium or sodium phosphate buffer. This study indicates that the membrane potential but not the transmembrane pH gradient of S. aurantia is somehow involved in chemosensory signal transduction.