Characterization of Membrane Translocation by Anthrax Protective Antigen

Abstract

Solving the crystallographic structure of the ring-shaped heptamer formed by protective antigen (PA), the B moiety of anthrax toxin, has focused attention on understanding how this oligomer mediates membrane translocation of the toxin's A moieties. We have developed an assay for translocation in which radiolabeled ligands are bound to proteolytically activated PA (PA₆₃) at the surface of CHO or L6 cells, and translocation across the plasma membrane is induced by lowering the pH. The cells are then treated with Pronase E to degrade residual surface-bound material, and protected ligands are quantified after fractionation by SDS−PAGE. Translocation was most efficient (35%−50%) with LF_N, the N-terminal PA binding domain of the anthrax lethal factor (LF). Intact LF, edema factor (EF), or fusion proteins containing LF_N fused to certain heterologous proteins [the diphtheria toxin A chain (DTA) or dihydrofolate reductase (DHFR)] were less efficiently translocated (15%−20%); and LF_N fusions to several other proteins were not translocated at all. LF_N with different N-terminal residues was found to be degraded according to the N-end rule by the proteasome, and translocation of LF_N fused to a mutant form of DHFR with a low affinity for methotrexate (MTX) protected cells from the effects of MTX. Both results are consistent with a cytosolic location of protected proteins. Evidence that a protein must unfold to be translocated was obtained in experiments showing that (i) translocation of LF_NDTA was blocked by introduction of an artificial disulfide into the DTA moiety, and (ii) translocation of LF_NDHFR and LF_NDTA was blocked by their ligands (MTX and adenine, respectively). These results demonstrate that the acid-induced translocation by anthrax toxin closely resembles that of diphtheria toxin, despite the fact that these two toxins are unrelated and form pores by different mechanisms.