ABSTRACT
We have examined the rate of gramicidin channel conductance inactivation by ultraviolet photolysis using 0.1 millisecond light flashes. The lower limit on the channel photolysis reaction rate has been reduced by four orders of magnitude over previous observations. Monoolein/hexadecane bilayers formed in 1.0 M KCl were doped with (1-3) x 10(6) gramicidin A' channels and exposed to a broad-spectrum light flash. The flash reduced membrane conductance abruptly by approx. 16%. Following the flash, a further slow reduction of approx. 3% was observed followed by a slow recovery of approx. 4%. The post-flash decay and recovery may be due to slow chemical reactions, conformational relaxations, or changes in the equilibrium between aqueous, lipid-bound, and channel-forming dimerized gramicidin. Under our experimental conditions, gramicidin M was insensitive to light flashes compared to gramicidin A', demonstrating that for gramicidin A' the photolysis mechanism depends specifically on the tryptophan side-chain. Flash photolysis of a membrane containing a small population of channels (approx. 30) indicated that the decay is due to the sudden inactivation of several channels. The recovery appears to result from insertion of normal channels into the membrane. Flash photolysis of single-channel membranes showed that the flash causes abrupt, complete channel inactivation.
Subject(s)
Gramicidin/pharmacology , Lipid Bilayers/radiation effects , Photolysis , Ultraviolet Rays , Electric Conductivity , Ion Channels/metabolism , Lipid Bilayers/metabolismABSTRACT
The decay of gramicidin fluorescence resulting from ultraviolet exposure was compared to the decay of conductance from gramicidin-containing planar bilayer membranes under the same conditions of illumination. The decay rate was the same for both processes. The fluorescence decay was identical whether gramicidin was dissolved in methanol or incorporated into lipid vesicles, indicating that the peptide conformation does not affect the sensitivity of gramicidin to photolysis. The correlation of fluorescence decay and conductance decay imply that conductance loss from gramicidin-doped membranes illuminated with ultraviolet light is due to photochemical modifications of the channel tryptophans rather than simply to disturbance of the conformation of gramicidin channels.
