CFTR: A cysteine at position 338 in TM6 senses a positive electrostatic potential in the pore

doi:10.1529/biophysj.104.050534

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CHANNELS, RECEPTORS, AND ELECTRICAL SIGNALING

CFTR: A cysteine at position 338 in TM6 senses a positive electrostatic potential in the pore

Xuehong Liu ¹, Zhi-Ren Zhang ², Matthew D. Fuller ², Joshua Billingsley ¹, Nael A. McCarty ² and David C. Dawson ¹^*

¹ Oregon Health & Science University
² Georgia Institute of Technology

^* To whom correspondence should be addressed. E-mail: dawsonda{at}ohsu.edu.

Submitted on July 27, 2004
Revised on September 1, 2004
Accepted on 3 September 2004

Abstract
We investigated the accessibility to protons and thiol-directedreagents of a cysteine substituted at position 338 in transmembranesegment 6 (TM6) of CFTR to test the hypothesis that T338 residesin the pore. Xenopus oocytes expressing T338C CFTR exhibitedpH-dependent changes in gCl and I-V shape that were specificto the substituted cysteine. The apparent pKa of T338C CFTRwas more acidic than that expected for a cysteine or similarsimple thiols in aqueous solution. The pKa was shifted towardalkaline values when a nearby positive charge (R334) was substitutedwith neutral or negatively charged residues, consistent withthe predicted influence of the positive charge of R334, andperhaps other residues, on the titration of a cysteine at 338. The relative rates of chemical modification of T338C CFTR byMTSET+ and MTSES- were also altered by the charge at 334. Theseobservations support a model for CFTR that places T338 withinthe anion conduction path. The apparent pKa of a cysteine substitutedat 338 and the relative rates of reaction of charged thiol-directedreagents provide a crude measure of a positive electrostaticpotential that may be due to R334 and other residues near thisposition in the pore.

Key Words: MTS reagent, anion channel, electrophysiology, mutagenesis, pKa, thiol

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