Professor Stephen Tucker

Random mutagenesis screening indicates the absence of a separate H(+)-sensor in the pH-sensitive Kir channels.

Channels (Austin, Tex.) 4:5 (2010) 390-397

Authors:

JJ Paynter, L Shang, MK Bollepalli, T Baukrowitz, SJ Tucker

Abstract:

Several inwardly-rectifying (Kir) potassium channels (Kir1.1, Kir4.1 and Kir4.2) are characterised by their sensitivity to inhibition by intracellular H(+) within the physiological range. The mechanism by which these channels are regulated by intracellular pH has been the subject of intense scrutiny for over a decade, yet the molecular identity of the titratable pH-sensor remains elusive. In this study we have taken advantage of the acidic intracellular environment of S. cerevisiae and used a K(+) -auxotrophic strain to screen for mutants of Kir1.1 with impaired pH-sensitivity. In addition to the previously identified K80M mutation, this unbiased screening approach identified a novel mutation (S172T) in the second transmembrane domain (TM2) that also produces a marked reduction in pH-sensitivity through destabilization of the closed-state. However, despite this extensive mutagenic approach, no mutations could be identified which removed channel pH-sensitivity or which were likely to act as a separate H(+) -sensor unique to the pH-sensitive Kir channels. In order to explain these results we propose a model in which the pH-sensing mechanism is part of an intrinsic gating mechanism common to all Kir channels, not just the pH-sensitive Kir channels. In this model, mutations which disrupt this pH-sensor would result in an increase, not reduction, in pH-sensitivity. This has major implications for any future studies of Kir channel pH-sensitivity and explains why formal identification of these pH-sensing residues still represents a major challenge.

TREK Channel Pore Probed by Cysteine Scanning Mutagenesis and Structural Modelling

Biophysical Journal Elsevier 98:3 (2010) 327a

Authors:

Paula L Piechotta, Phill J Stansfeld, Murali K Bollepalli, Markus Rapedius, Isabelle Andres-Enguix, Lijun Shang, Hariolf Fritzenschaft, Mark SP Sansom, Stephen Tucker, Thomas Baukrowitz

A Structural Model of a Kir Channel in the Open State Derived from Mutagenic Scanning of the Pore Gating Energetics

BIOPHYSICAL JOURNAL 98:3 (2010) 697A-697A

Authors:

Murali K Bollepalli, Philip Fowler, Markus Rapedius, Man-Jiang Xie, Lijun Shang, Hariolf Fritzenschaft, Mark Sansom, Stephen J Tucker, Thomas Baukrowitz

Radiolytic Footprinting Reveals Conformational Changes During Potassium Channel Gating

BIOPHYSICAL JOURNAL 98:3 (2010) 696A-696A

Authors:

Sayan Gupta, Rhijuta D'Mello, Mark R Chance, Vassiliy N Bavro, Catherine Venien-Bryan, Stephen J Tucker

Random mutagenesis screening indicates the absence of a separate H(+)-sensor in the pH-sensitive Kir channels.

Channels (Austin) 4:5 (2010) 390-397

Authors:

Jennifer J Paynter, Lijun Shang, Murali K Bollepalli, Thomas Baukrowitz, Stephen J Tucker

Abstract:

Several inwardly-rectifying (Kir) potassium channels (Kir1.1, Kir4.1 and Kir4.2) are characterised by their sensitivity to inhibition by intracellular H(+) within the physiological range. The mechanism by which these channels are regulated by intracellular pH has been the subject of intense scrutiny for over a decade, yet the molecular identity of the titratable pH-sensor remains elusive. In this study we have taken advantage of the acidic intracellular environment of S. cerevisiae and used a K(+) -auxotrophic strain to screen for mutants of Kir1.1 with impaired pH-sensitivity. In addition to the previously identified K80M mutation, this unbiased screening approach identified a novel mutation (S172T) in the second transmembrane domain (TM2) that also produces a marked reduction in pH-sensitivity through destabilization of the closed-state. However, despite this extensive mutagenic approach, no mutations could be identified which removed channel pH-sensitivity or which were likely to act as a separate H(+) -sensor unique to the pH-sensitive Kir channels. In order to explain these results we propose a model in which the pH-sensing mechanism is part of an intrinsic gating mechanism common to all Kir channels, not just the pH-sensitive Kir channels. In this model, mutations which disrupt this pH-sensor would result in an increase, not reduction, in pH-sensitivity. This has major implications for any future studies of Kir channel pH-sensitivity and explains why formal identification of these pH-sensing residues still represents a major challenge.