Gating of ion channels made by a diphtheria toxin fragment in phospholipid bilayer membranes.

Abstract

B45, a fragment containing the major hydrophobic region of diphtheria toxin, increases the conductance of thin lipid membranes by forming ion-conducting channels that are gated by transmembrane voltage, Vm and the bath pH. Single-channel currents show bursting behavior in the form of rapid transitions between a closed and an open conductance level. The average duration of a current burst, as well as the total time a channel is actually open within a burst, decreases with increasing Vm. Analysis of these data suggests that, over a range of Vm, increases in the rate constants for transitions from the open to the closed states largely account for the decline in macroscopic conductance with increasing Vm. Increases in rate constants for transitions from a closed to an open conductance state are more likely to account for the increase in macroscopic conductance with increasing bath pH. Since several diphtheria toxin fragments and mutants are currently available, each containing various portions of the B-45 region, it may be possible to study the relationship of the structure of these complex proteins to the detailed gating properties of the ion channels that they form.