Probing the Structure of the Diphtheria Toxin Channel: Reactivity in Planar Lipid Bilayer Membranes of Cysteine-substituted  Mutant Channels with Methanethiosulfonate Derivatives

doi:10.1085/jgp.110.3.229

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Article

Probing the Structure of the Diphtheria Toxin Channel

Reactivity in Planar Lipid Bilayer Membranes of Cysteine-substituted Mutant Channels with Methanethiosulfonate Derivatives

Paul D. Huynh^*^,, Can Cui, Hangjun Zhan, Kyoung Joon Oh, R. John Collier, and Alan Finkelstein^*^,

From the ^* Department of Physiology & Biophysics, and Department of Neuroscience, Albert Einstein College of Medicine, Bronx, New York 10461; and Department of Microbiology and Molecular Genetics, Harvard Medical School, Boston, Massachusetts 02115

Previous work has established that the 61 amino acid stretchfrom residue 322 to 382 in the T-domain of diphtheria toxinforms channels indistinguishable in ion-conducting propertiesfrom those formed by the entire T-domain. In the crystal structureof the toxin's water-soluble form, the bulk of this stretchis an ${alpha}$ -helical hairpin, designated TH8-9. The present studywas directed at determining which residues in TH8-9 line theion-conducting pathway of the channel; i.e., its lumen or entrances.To this end, we singly mutated 49 of TH8-9's 51 residues (328–376)to cysteines, formed channels with the mutant T-domain proteinsin planar lipid bilayers, and then determined whether theyreacted with small, charged, lipid-insoluble, sulfhydryl-specificmethanethiosulfonate (MTS) derivatives added to the bathingsolutions. The indication of a reaction, and that the residuelined the ion-conducting pathway, was a sudden change in single-channelconductance and/or flickering behavior. The results of thisstudy were surprising in two respects. First, of the 49 cysteine-substitutedresidues in TH8-9 tested, 23 reacted with MTS derivatives ina most unusual pattern consisting of two segments: one extendingfrom 329 to 341 (11 of 13 reacted), and the other from 347to 359 (12 of 13 reacted); none of the residues outside of thesetwo segments appeared to react. Second, in every cysteine mutantchannel manifesting an MTS effect, only one transition in single-channelconductance (or flickering behavior) occurred, not the severalexpected for a multimeric channel. Our results are not consistentwith an ${alpha}$ -helical or β-strand model for the channel, butinstead suggest an open, flexible structure. Moreover, contraryto common sense, they indicate that the channel is not multimeric but is formed from only one TH8-9 unit of the T-domain.

Key Words: helical hairpin • streptavidin • subunits • channel conductance • channel flickering

Address correspondence to Alan Finkelstein, Department of Physiology& Biophysics, Albert Einstein College of Medicine, 1300Morris Park Ave. Bronx, New York 10461. FAX: 718-430-8819.E-mail: finkelst @aecom.yu.edu

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