Staphylococcal alpha-toxin: a study of membrane penetration and pore formation.

Cell lysis by staphylococcal alpha-toxin, a potent virulence factor of most pathogenic strains of Staphylococcus aureus, follows a three-step sequence: binding of toxin to the membrane, leaking of ions caused by membrane injury, and rupturing of the membrane caused by osmotic swelling. The membrane injury step is composed of two separate events, membrane penetration and membrane perturbation. The membrane penetration event involves conversion of the soluble toxin monomer into an amphipathic molecule, which inserts into the lipid bilayer of the membrane. The membrane perturbation event involves association of the toxin monomers, in the plane of the membrane, to form hexameric transmembrane pores. In this study, we demonstrate that, in an asolectin liposome system, controlling the pH of the external buffer permits these two events to be temporally resolved. Using Controlled-Pore Glass bead-purified alpha-toxin, four events are measured as a function of pH: (a) release of potassium from prelabeled asolectin vesicles, (b) conversion of the toxin to a globally hydrophobic molecule, (c) binding of detergent by the toxin, and (d) labeling of the toxin with photoactivable, radiolabeled, hydrophobic probes. Two of these events, potassium release and conversion to a net hydrophobic state, are paired in that, for the event to occur, each requires a pH of 4.6 or less. In contrast, photolabeling with the membrane probes PC I and PC II (where PC represents phosphatidylcholine) is easily detectable at pH values as high as 5.0 and 6.0. These results demonstrate that, as the pH is lowered, two distinct changes in the physical properties of alpha-toxin occur. The first, which occurs under mild acidic conditions, converts the toxin from a water-soluble molecule into an amphipathic molecule. The second, requiring relatively more acidic conditions, converts the amphipathic toxin molecule into a globally hydrophobic molecule. Correlated with these physical changes in the alpha-toxin molecule is the acquisition of two new biological properties. The conversion of alpha-toxin into an amphipathic conformation correlates with the acquisition of the biological property of the reversible penetration into the bilayer of the asolectin liposome membrane, as evidenced by labeling with the photoactivable probes. At lower pH, the conversion of the toxin into a globally hydrophobic molecule correlates with the biological property of causing damage to the cell membrane, as measured by the release of internal potassium ions, presumably by the formation of transmembrane hexamer pores.(ABSTRACT TRUNCATED AT 400 WORDS)