Peptide- and proton-driven allosteric clamps catalyze anthrax toxin translocation across membranes

Anthrax toxin is an intracellularly acting toxin in which sufficient information is available regarding the structure of its transmembrane channel, allowing for detailed investigation of models of translocation. Anthrax toxin, comprising three proteins—protective antigen (PA), lethal factor (LF), an...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 113; no. 34; pp. 9611 - 9616
Main Authors Das, Debasis, Krantz, Bryan A.
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 23.08.2016
Subjects
Allosteric Regulation
Anthrax
Antigens
Antigens, Bacterial - metabolism
Bacterial Toxins - metabolism
Biological Sciences
Hydrogen-Ion Concentration
Kinetics
Lipid Bilayers - chemistry
Lipid Bilayers - metabolism
Peptides
Phenylalanine - metabolism
Phosphatidylcholines - chemistry
Phosphatidylcholines - metabolism
Protein Binding
Protein Structure, Secondary
Protein Transport
Proteins
Protons
Stereoisomerism
Thermodynamics
anthrax toxin
helix-compression model
planar bilayer electrophysiology
Brownian ratchet
allostery
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Summary:Anthrax toxin is an intracellularly acting toxin in which sufficient information is available regarding the structure of its transmembrane channel, allowing for detailed investigation of models of translocation. Anthrax toxin, comprising three proteins—protective antigen (PA), lethal factor (LF), and edema factor—translocates large proteins across membranes. Here we show that the PA translocase channel has a transport function in which its catalytic active sites operate allosterically. We find that the phenylalanine clamp (ϕ-clamp), the known conductance bottleneck in the PA translocase, gates as either a more closed state or a more dilated state. Thermodynamically, the two channel states have >300-fold different binding affinities for an LF-derived peptide. The change in clamp thermodynamics requires distant α-clamp and ϕ-clamp sites. Clamp allostery and translocation are more optimal for LF peptides with uniform stereochemistry, where the least allosteric and least efficiently translocated peptide had a mixed stereochemistry. Overall, the kinetic results are in less agreement with an extended-chain Brownian ratchet model but, instead, are more consistent with an allosteric helix-compression model that is dependent also on substrate peptide coil-to-helix/helix-to-coil cooperativity.
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Edited by Hagan Bayley, University of Oxford, Oxford, United Kingdom, and accepted by Editorial Board Member R. J. Collier July 1, 2016 (received for review January 13, 2016)
Author contributions: D.D. and B.A.K. designed research; B.A.K. and D.D. designed and guided the experiments; D.D. performed research; D.D. mutagenized and purified the anthrax toxin proteins and performed the electrophysiological studies; D.D. and B.A.K. analyzed data; and D.D. and B.A.K. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1600624113