Molecular Architecture of a Toxin Pore: a 15-residue Sequence Lines the Transmembrane Channel of Staphylococcal Alpha-toxin

Overview

Journal EMBO J

Specialties Biotechnology
Molecular Biology

Date 1996 Apr 15

PMID 8617232

Citations 24

Authors

A Valeva

A Weisser

B Walker

M Kehoe

H Bayley

S Bhakdi

M Palmer

Affiliations

Soon will be listed here.

Abstract

Staphylococcus aureus alpha-toxin is a hydrophilic polypeptide of 293 amino acids that produces heptameric transmembrane pores. During assembly, the formation of a pre-pore precedes membrane permeabilization; the latter is linked to a conformational change in the oligomer. Here, 41 single-cysteine replacement toxin mutants were thiol-specifically labelled with the polarity-sensitive fluorescent probe acrylodan. After oligomerization on membranes, only the mutants with acrylodan attached to residues in the sequence 118-140 exhibited a marked blue shift in the fluorescence emission maximum, indicative of movement of the fluorophore to a hydrophobic environment. Within this region, two functionally distinct parts could be identified. For mutants at positions 126-140, the shifts were partially reversed after membrane solubilization by detergents, indicating a direct interaction of the label with the membrane lipids. Membrane insertion of this sequence occurred together with the final pre-pore to pore transition of the heptamer. Thus residues 126-140 constitute a transmembrane sequence in the pore. With labelled residues 118-124, pre-pore assembly was the critical event to induce the spectral shifts, which persisted after the removal of membrane lipids and hence probably reflects protomer-protomer contacts within the heptamer. Finally, a derivative of the mutant N121C yielded occluded pores which could be opened by reductive reversal of the modification. Therefore this residue probably lines the lumen of the pore.

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