Self-translocation of diphtheria toxin across model membranes.

To understand the mechanism of diphtheria toxin membrane translocation, the toxin was entrapped within lipid vesicles, and its low pH-induced translocation across the lipid bilayer was measured. Proteolysis and resistance to guanidinium chloride denaturation were used to demonstrate that the toxin molecules were entrapped. Low pH-induced movement of entrapped toxin to the outer (trans) face of the bilayer was assayed by the binding of external streptavidin to biotin-labeled entrapped toxin. Complete translocation was quantified by the amount of protein released into the external medium. Using whole toxin, it was found that the A fragment was efficiently translocated, but the B fragment was not. This was true both in the low temperature (A domain folded) and high temperature (A domain unfolded) toxin conformations previously identified [Jiang J. X., Abrams, F. S., and London, E. (1991) Biochemistry 30, 3857-3864]. Remarkably, even isolated fragment A appeared to self-translocate under some conditions. Toxin-induced translocation may partly result from formation of a nonspecific toxin-induced pore. This idea is supported by the toxin-induced release of fluorescent dextrans coentrapped within the vesicles. However, low pH-induced exposure of entrapped toxin on the outside of the membrane was conformation dependent. Exposure was greatest for the high temperature conformation. This suggests the existence of a more specific translocation process. The nature and relationship of these processes, and their relative roles in translocation in vivo are discussed.