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- Coupling Gβγ-Dependent Activation to Channel Opening via Por...Coupling Gβγ-Dependent Activation to Channel Opening via Pore Elements in Inwardly Rectifying Potassium Channels
Neuron, Volume 29, Issue 3, 1 March 2001, Pages 669-680
Rona Sadja, Karine Smadja, Noga Alagem and Eitan Reuveny
SummaryG protein–coupled inwardly rectifying potassium channels, GIRK/Kir3.x, are gated by the Gβγ subunits of the G protein. The molecular mechanism of gating was investigated by employing a novel yeast-based random mutagenesis approach that selected for channel mutants that are active in the absence of Gβγ. Mutations in TM2 were found that mimicked the Gβγ-activated state. The activity of these channel mutants was independent of receptor stimulation and of the availability of heterologously expressed Gβγ subunits but depended on PtdIns(4,5)P. The results suggest that the TM2 region plays a key role in channel gating following Gβγ binding in a phospholipid-dependent manner. This mechanism of gating in inwardly rectifying K channels may be similar to the involvement of the homologous region in prokaryotic KcsA potassium channel and, thus, suggests evolutionary conservation of the gating structure.
Summary | Full Text | PDF (731 kb) - Complex functional interaction between integrin receptors an...Complex functional interaction between integrin receptors and ion channels
Trends in Cell Biology, Volume 16, Issue 12, 1 December 2006, Pages 631-639
Annarosa Arcangeli and Andrea Becchetti
AbstractIntegrin receptors mediate adhesion of the cell to the extracellular matrix and thereby regulate cell motility, proliferation, differentiation and apoptosis. These processes are frequently accompanied by alterations in ion flow. Recent evidence suggests that integrins can regulate ion channels and form macromolecular complexes, thus contributing to the localization of the channel onto the plasma membrane. The integrin–channel complex regulates downstream signaling proteins, such as tyrosine kinases and GTPases. This process could occur in plasma membrane microdomains, such as caveolae. It seems that ion channels sometimes transmit their signals through conformational coupling, instead of change in ion fluxes. Finally, the channel protein is not merely a final target, because it often feeds back by controlling integrin activation and/or expression. These findings have important implications for the physiology of normal and neoplastic cells and suggest interesting perspectives for studies of synaptic plasticity.
Abstract | Full Text | PDF (588 kb) - Potassium-Dependent Slow Inactivation of Kir1.1 (ROMK) Chann...Potassium-Dependent Slow Inactivation of Kir1.1 (ROMK) Channels
Biophysical Journal, Volume 86, Issue 4, 1 April 2004, Pages 2145-2155
H. Sackin, L.G. Palmer and M. Krambis
AbstractThe ROMK (Kir1.1) family of epithelial K channels can be inactivated by a combination of low internal pH and low external K, such that alkalization does not reopen the channels unless external K is elevated. Previous work suggested that this inactivation results from an allosteric interaction between an inner pH gate and an outer K sensor, and could be described by a simple three-state kinetic model. In the present study, we report that a sustained depolarization slowly inactivated (half-time=10–15min) ROMK channels that had been engineered for increased affinity to internal polyamines. Furthermore, this inactivation occurred at external [K] ≤1mM in ROMK mutants whose inner pH gate was constitutively open (ROMK2-K61M mutation). Both pH and voltage inactivation depended on external K in a manner reminiscent of C-type inactivation, but having a much slower time course. Replacement of ROMK extracellular loop residues by Kir2.1 homologous residues attenuated or abolished this inactivation. These results are consistent with the hypothesis that there are (at least) two separate closure processes in these channels: an inner pH-regulated gate, and an outer (inactivation) gate, where the latter is modulated by both voltage and external [K].
Abstract | Full Text | PDF (472 kb) - …more
Copyright © 1996 The Biophysical Society. All rights reserved.
Biophysical Journal, Volume 70, Issue 1, 296-304, 1 January 1996
doi:10.1016/S0006-3495(96)79570-X
Research Article
Beta-amyloid peptide blocks the fast-inactivating K+ current in rat hippocampal neurons
T.A. Good, D.O. Smith and R.M. Murphy
Department of Chemical Engineering, University of Wisconsin, Madison 53706, USA.
Abstract
Deposition of beta-amyloid peptide (A beta) in senile plaques is a hallmark of Alzheimer disease neuropathology. Chronic exposure of neuronal cultures to synthetic A beta is directly toxic, or enhances neuronal susceptibility to excitotoxins. Exposure to A beta may cause a loss of cellular calcium homeostasis, but the mechanism by which this occurs is uncertain. In this work, the acute response of rat hippocampal neurons to applications of synthetic A beta was measured using whole-cell voltage-clamp techniques. Pulse application of A beta caused a reversible voltage-dependent decrease in membrane conductance. A beta selectively blocked the voltage-gated fast-inactivating K+ current, with an estimated KI < 10 microM. A beta also blocked the delayed rectifying current, but only at the highest concentration tested. The response was independent of aggregation state or peptide length. The dynamic response of the fast-inactivating current to a voltage jump was consistent with a model whereby A beta binds reversibly to closed channels and prevents their opening. Blockage of fast-inactivating K+ channels by A beta could lead to prolonged cell depolarization, thereby increasing Ca2+ influx.
