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Clifford L. Slayman
Researcher at Yale University
Publications - 71
Citations - 4201
Clifford L. Slayman is an academic researcher from Yale University. The author has contributed to research in topics: Membrane potential & Depolarization. The author has an hindex of 38, co-authored 71 publications receiving 4097 citations.
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Journal ArticleDOI
The relationship between ATP and an electrogenic pump in the plasma membrane of Neurospora crassa
TL;DR: The data strongly suggest that an electrogenic ion pump in the plasma membrane of Neurospora is fueled by ATP; comparison of the measured membrane potentials with the energy available from hydrolysis of ATP indicates that two ions could be pumped for each molecule of ATP split.
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Depolarization of the Plasma Membrane of Neurospora During Active Transport of Glucose: Evidence for a Proton-Dependent Cotransport System
TL;DR: The data support Mitchell's notion that sugar and hydrogen ions are contransported under the influence of the membrane potential, and lead to values for H(+):glucose stoichiometry of 0.8 to 1.4.
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Interpretation of current-voltage relationships for "active" ion transport systems: I. Steady-state reaction-kinetic analysis of class-I mechanisms.
TL;DR: A simple reaction-kinetic model to describe electrogenic pumping and co- (or counter-) transport of ions, which accommodates many known properties of proton-transport systems, particularly as observed in “chemiosmotic” or energy-coupling membranes.
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Electrical Measurements on Endomembranes
Adam Bertl,Eduardo Blumwald,Roberto Coronado,Robert S. Eisenberg,Goeff Findlay,Dietrich Gradmann,Bertil Hille,Kurt Köhler,Hans Albert Kolb,Enid A. C. MacRobbie,Gerhard Meissner,Christopher Miller,Erwin Neher,Philip Palade,Omar Pantoja,Dale Sanders,Julian I. Schroeder,Clifford L. Slayman,Roger M. Spanswick,Alan R. Walker,Alan J. Williams +20 more
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A potassium-proton symport in Neurospora crassa.
TL;DR: A potassium-proton symport mechanism is competent to sustain the largest stable K+ gradients that have been measured in Neurospora, with no direct contribution from phosphate hydrolysis or redox processes.