Professor Stephen Tucker

De novo point mutations in patients diagnosed with ataxic cerebral palsy

Brain Oxford University Press 138:7 (2015) 1817-1832

Authors:

Ricardo Parolin Schnekenberg, Emma M Perkins, Jack W Miller, Wayne IL Davies, Maria Cristina D'Adamo, Mauro Pessia, Katherine A Fawcett, David Sims, Elodie Gillard, Karl Hudspith, Paul Skehel, Jonathan Williams, Mary O'Regan, Sandeep Jayawant, Rosalind Jefferson, Sarah Hughes, Andrea Lustenberger, Jiannis Ragoussis, Mandy Jackson, Stephen Tucker, Andrea Németh

Abstract:

Cerebral palsy is a sporadic disorder with multiple likely aetiologies, but frequently considered to be caused by birth asphyxia. Genetic investigations are rarely performed in patients with cerebral palsy and there is little proven evidence of genetic causes. As part of a large project investigating children with ataxia, we identified four patients in our cohort with a diagnosis of ataxic cerebral palsy. They were investigated using either targeted next generation sequencing or trio-based exome sequencing and were found to have mutations in three different genes, KCNC3, ITPR1 and SPTBN2. All the mutations were de novo and associated with increased paternal age. The mutations were shown to be pathogenic using a combination of bioinformatics analysis and in vitro model systems. This work is the first to report that the ataxic subtype of cerebral palsy can be caused by de novo dominant point mutations, which explains the sporadic nature of these cases. We conclude that at least some subtypes of cerebral palsy may be caused by de novo genetic mutations and patients with a clinical diagnosis of cerebral palsy should be genetically investigated before causation is ascribed to perinatal asphyxia or other aetiologies.

Molecular simulation studies of hydrophobic gating in nanopores and ion channels.

Biochemical Society Transactions Portland Press 43:2 (2015) 146-150

Authors:

Jemma L Trick, Prafulla Aryal, Stephen J Tucker, Mark SP Sansom

K2P channel gating mechanisms revealed by structures of TREK-2 and a complex with Prozac

Science American Association for the Advancement of Science 347:6227 (2015) 1256-1259

Authors:

YY Dong, Ashley Pike, A Mackenzie, C McClenaghan, P Aryal, L Dong, A Quigley, M Grieben, S Goubin, S Mukhopadhyay, Gian Ruda, MV Clausen, L Cao, Paul Brennan, Nicola Burgess-Brown, Mark Sansom, Stephen Tucker, Elizabeth Carpenter

Abstract:

TREK-2 (KCNK10/K2P10), a two-pore domain potassium (K2P) channel, is gated by multiple stimuli such as stretch, fatty acids, and pH and by several drugs. However, the mechanisms that control channel gating are unclear. Here we present crystal structures of the human TREK-2 channel (up to 3.4 angstrom resolution) in two conformations and in complex with norfluoxetine, the active metabolite of fluoxetine (Prozac) and a state-dependent blocker of TREK channels. Norfluoxetine binds within intramembrane fenestrations found in only one of these two conformations. Channel activation by arachidonic acid and mechanical stretch involves conversion between these states through movement of the pore-lining helices. These results provide an explanation for TREK channel mechanosensitivity, regulation by diverse stimuli, and possible off-target effects of the serotonin reuptake inhibitor Prozac.

Novel phenotype associated with a mutation in the KCNA1(Kv1.1) gene

Frontiers in Physiology Frontiers 5 (2015) 525

Authors:

Maria C D'Adamo, Constanze Gallenmüller, Ilenio Servettini, Elisabeth Hartl, Stephen J Tucker, Larissa Arning, Saskia Biskup, Alessandro Grottesi, Luca Guglielmi, Paola Imbrici, Pia Bernasconi, Giuseppe Di Giovanni, Fabio Franciolini, Luigi Catacuzzeno, Mauro Pessia, Thomas Klopstock

Hydrophobic Gating in Ion Channels

Journal of Molecular Biology Elsevier 427:1 (2015) 121-130

Authors:

Prafulla Aryal, Mark SP Sansom, Stephen J Tucker

Abstract:

Biological ion channels are nanoscale transmembrane pores. When water and ions are enclosed within the narrow confines of a sub-nanometer hydrophobic pore, they exhibit behavior not evident from macroscopic descriptions. At this nanoscopic level, the unfavorable interaction between the lining of a hydrophobic pore and water may lead to stochastic liquid-vapor transitions. These transient vapor states are "dewetted", i.e. effectively devoid of water molecules within all or part of the pore, thus leading to an energetic barrier to ion conduction. This process, termed "hydrophobic gating", was first observed in molecular dynamics simulations of model nanopores, where the principles underlying hydrophobic gating (i.e., changes in diameter, polarity, or transmembrane voltage) have now been extensively validated. Computational, structural, and functional studies now indicate that biological ion channels may also exploit hydrophobic gating to regulate ion flow within their pores. Here we review the evidence for this process and propose that this unusual behavior of water represents an increasingly important element in understanding the relationship between ion channel structure and function.