Abstract
The binary Clostridium botulinum C2 toxin consists of two individual proteins, the transport component C2II (80 kDa) and the enzyme component C2I, which ADP-ribosylates G-actin in the cytosol of cells. Trypsin-activated C2II (C2IIa) forms heptamers that bind to the cell receptor and mediate translocation of C2I from acidic endosomes into the cytosol of target cells. Here, we report that translocation of C2I across cell membranes is accompanied by pore formation of C2IIa. We used a radioactive rubidium release assay to detect C2IIa pores in the membranes of Chinese hamster ovary cells. Pore formation by C2IIa was dependent on the cellular C2 toxin receptor and an acidic pulse. Pores were formed when C2IIa was bound to cells at neutral pH and when cells were subsequently shifted to acidic medium (pH < 5.5), but no pores were detected when C2IIa was added to cells directly in acidic medium. Most likely, acidification induces a change from "pre-pore" to "pore" conformation of C2IIa, and formation of the pore conformation before membrane binding precludes insertion into membranes. When C2I was present during binding of C2IIa to cells prior to the acidification step, C2IIa-mediated rubidium release was decreased, suggesting that C2I interacted with the lumen of the C2IIa pore. A decrease of rubidium efflux was also detected when C2I was added to C2IIa-treated cells after the acidification step, suggesting that C2I interacted with C2IIa in its pore conformation. Moreover, C2I also interacted with C2IIa channels in artificial lipid membranes and blocked them partially. C2I was only translocated across the cell membrane when C2IIa plus C2I were bound to cells at neutral pH and subsequently shifted to acidic pH. When cell-bound C2IIa was exposed to acidic pH prior to C2I addition, only residual intoxication of cells was observed at high toxin concentrations, and binding of C2I to C2IIa was slightly decreased. Overall, C2IIa pores were essential but not sufficient for translocation of C2I. Intoxication of target cells with C2 toxin requires a strictly coordinated pH-dependent sequence of binding, pore formation by C2IIa, and translocation of C2I.
Highlights
Bacterial protein toxins, which target substrates in the cytosol of eukaryotic cells, have developed sophisticated delivery mechanisms to transport their active components across lipid membranes into the cytosol
Like protective antigen (PA), C2II has to be activated by proteolytic cleavage [18], and the resulting C2IIa forms ring-shaped heptamers (ϳ420 kDa), which have an outer diameter of ϳ15 nm and an inner diameter of ϳ1–2 nm [15]
C2I translocates from early acidic endosomes into the cytosol, a process that can be blocked by bafilomycin A1, a specific inhibitor of the vesicular Hϩ-ATPase [15]
Summary
Bacterial protein toxins, which target substrates in the cytosol of eukaryotic cells, have developed sophisticated delivery mechanisms to transport their active components across lipid membranes into the cytosol. Trypsin-activated C2II (C2IIa) forms heptamers that bind to the cell receptor and mediate translocation of C2I from acidic endosomes into the cytosol of target cells. Translocation of C2I into the cytosol was only observed under conditions that induced pore formation of C2IIa in cell membranes and when both C2I and C2IIa were already bound to cells at the time of acidification.
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