The protective antigen component of anthrax toxin forms a homoheptameric pore in the endosomal membrane, creating a narrow passageway for the enzymatic components of the toxin to enter the cytosol. We found that, during conversion of the heptameric precursor to the pore, the seven phenylalanine-427 residues converged within the lumen, generating a radially symmetric heptad of solvent-exposed aromatic rings. This "φ-clamp" structure was required for protein translocation and comprised the major conductance-blocking site for hydrophobic drugs and model cations. We conclude that the φ clamp serves a chaperone-like function, interacting with hydrophobic sequences presented by the protein substrate as it unfolds during translocation.Anthrax toxin is composed of three nontoxic proteins, which combine on eukaryotic cell surfaces to form toxic, noncovalent complexes. [See (1) for a review.] Protective antigen (PA), the protein translocase component, binds to a cellular receptor and is activated by a furin-family protease. The resulting 63-kD receptor-bound fragment, PA 63 , self-assembles into the prepore, which is a ring-shaped homoheptamer (Fig. 1A). The prepore then forms complexes with the two ~90-kD enzymatic components, lethal factor (LF) and edema factor (EF). These complexes are endocytosed and delivered to an acidic compartment (2). There, the prepore undergoes an acidic pH-dependent conformational rearrangement (3) to form an ion-conducting, cationselective, transmembrane pore (4), allowing bound LF and EF to translocate into the cytosol.The PA 63 pore (Fig. 1B) is believed to consist of a mushroom-shaped structure, with a globular cap connected to a β-barrel stem that is ~100 Å long (5, 6). A model of the 14-strand β barrel reveals its lumen, which is ~15 Å wide and can only accommodate structure as wide as an α helix (7). The narrow pore creates a structural bottleneck, requiring that the catalytic factors, LF and EF, unfold in order to be translocated (8, 9). The destabilization energy required to unfold the tertiary structure of LF and EF originates partly from the acidic pH in endosomes, which causes their N-terminal domains (LF N and EF N ) to become molten globules (MG) (7). A positive membrane potential [+Δψ (10)], when coupled with these acidic pH conditions, is sufficient to drive LF N through PA 63 pores formed in planar lipid bilayers (9). To enter the narrow confines of the ~15-Å-wide lumen, LF N must shed its residual tertiary structure and convert from the MG form to an extended, "translocatable" conformation (7). How does a solvent-filled pore mediate the disassembly of an MG protein, packed, albeit loosely, with hydrophobically dense stretches of polypeptide? We surmised that an interaction surface inside the pore might facilitate further unfolding of the MG to the extended, translocatable form. †To whom correspondence should be addressed.
