The T domain of diphtheria toxin is known to participate in the pH-dependent translocation of the catalytic C domain of the toxin across the endosomal membrane, but how it does so, and whether cellular proteins are also required for this process, remain unknown. Here, we report results showing that the T domain alone is capable of translocating the entire C domain across model, planar phospholipid bilayers in the absence of other proteins. The T domain therefore contains the entire molecular machinery for mediating transfer of the catalytic domain of diphtheria toxin across membranes.Many toxic proteins of bacterial and plant origin are known to act by enzymically modifying substrates within the cytosol of mammalian cells, but the mechanism by which any of these toxins crosses a membrane to gain access to its substrates is not yet understood. These intracellularly acting toxins are generally bipartite proteins, containing the enzymic and receptorbinding functions on separate polypeptides, designated A and B, respectively (1). In some toxins, the B moiety also serves a second function, in mediating translocation of the A moiety across membranes.Diphtheria toxin (DT), the earliest example of an AB toxin, is a single, 535-residue polypeptide containing three folding domains: the amino-terminal C, or catalytic, domain (residues 1-185); the intermediate T, or transmembrane, domain (residues 202-378); and the carboxyl-terminal R, or receptorbinding, domain (residues 386-535) (Fig. 1). The catalytic domain is connected to the T domain by an arginine-rich loop and a readily reducible disulfide bridge (linking C186 to C201).After binding to its cell-surface receptor via the R domain, DT is proteolytically cleaved within the arginine-rich loop, yielding two disulfide-linked fragments: fragment A (corresponding to domain C) and fragment B (corresponding to domains T and R). The receptor-bound toxin is endocytosed and trafficked to an acidic vesicular compartment, where it undergoes a conformational change that allows the T domain to insert into the membrane and the catalytic domain to be translocated to the cytosol. The C186-C201 disulfide is reduced at some stage in this process, allowing the catalytic domain to be released into the cytosol. There, it catalyzes the ADP-ribosylation of elongation factor 2, causing inhibition of protein synthesis and cell death. (For a general review of diphtheria toxin, see ref. 2.)The crystallographic structure (3, 4) of native DT shows the T domain to consist of a bundle of 10 ␣-helices, which resembles the channel-forming domains of certain colicins (5-8) and ␣-helical domains found in certain mammalian proteins involved in regulation of apoptosis (9). Studies in planar lipid bilayers have shown that under low pH conditions (pH Յ 6) in the cis compartment (the compartment to which protein is added), the isolated T domain is able to form cation-selective channels in the membrane (10); similar channels are formed by whole DT and by a truncated mutant, DT(CϩT), lacking the R domain...
