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Isolation of the cDNA for erythrocyte integral membrane protein of 28 kilodaltons: member of an ancient channel familyThe uncoupling protein homologues: UCP1, UCP2, UCP3, StUCP and AtUCPMolecular basis of functional diversity of voltage-gated potassium channels in mammalian brainInfluenza A virus M2 ion channel protein: a structure-function analysisThe Caenorhabditis elegans unc-93 gene encodes a putative transmembrane protein that regulates muscle contraction.Rat brain expresses an alternatively spliced form of the dihydropyridine-sensitive L-type calcium channel alpha 2 subunit.Structure-activity relationships of the Kvbeta1 inactivation domain and its putative receptor probed using peptide analogs of voltage-gated potassium channel alpha- and beta-subunits.Molecular diversity and regulation of renal potassium channels.Do voltage-dependent K+ channels require Ca2+? A critical test employing a heterologous expression system.Atomic distance estimates from disulfides and high-affinity metal-binding sites in a K+ channel pore.Protein sequence and structure relationship ARMA spectral analysis: application to membrane proteinsEffects of ethanol on calcium channels, potassium channels, and vasopressin release.Mast cell degranulating peptide: a multi-functional neurotoxin.Evolutionary origins of ion channels.CFTR!Stress-induced corneal epithelial apoptosis mediated by K+ channel activationMotoneurones "learn" and "forget" physical activity.Release of amyloid beta-protein precursor derivatives by electrical depolarization of rat hippocampal slicesMechanism of gating of T-type calcium channels.Sodium channel activation gating is affected by substitutions of voltage sensor positive charges in all four domainsPotent synergistic in vitro interaction between nonantimicrobial membrane-active compounds and itraconazole against clinical isolates of Aspergillus fumigatus resistant to itraconazoleFunctional expression of a probable Arabidopsis thaliana potassium channel in Saccharomyces cerevisiae.Targeting voltage-gated calcium channels for neuropathic pain management.Uncultured lobster muscle, cultured neurons and brain slices: the neurophysiology of zinc.Cloning and expression of the delayed-rectifier IsK channel from neonatal rat heart and diethylstilbestrol-primed rat uterusOmega-conotoxins as experimental tools and therapeutics in pain management.Long-range interactions, voltage sensitivity, and ion conduction in S4 segments of excitable channels.Shaker-related potassium channel, Kv1.4, mRNA regulation in cultured rat heart myocytes and differential expression of Kv1.4 and Kv1.5 genes in myocardial development and hypertrophy.Concomitant acceleration of the activation and inactivation kinetics of the human delayed rectifier K+ channel (Kv1.1) by Ca(2+)-independent phospholipase A2.Mechanisms of action of antiarrhythmic drugs: from ion channel blockage to arrhythmia termination.Assembly of potassium channels.Conservation of Ca2+/calmodulin regulation across Na and Ca2+ channels.Fatty acid ethyl esters, nonoxidative metabolites of ethanol, accelerate the kinetics of activation of the human brain delayed rectifier K+ channel, Kv1.1.Biophysics of a trespasser, Na+ block of Ca2+ channels.Habit, prejudice, power and politics: issues in the conversion of H2-receptor antagonists to over-the-counter use.Immunoisolation of a K+ channel from basolateral membranes of Necturus enterocytes.Expression of ion channel genes in Drosophila.Intrinsic excitability of cholinergic neurons in the rat parabigeminal nucleus.Increase in cell size underlies neuron-specific temperature acclimation in Aplysia.Modulation of vertebrate brain Na+ and K+ channels by subtypes of protein kinase C.
P2860
Q24293104-D3ED2005-C4BB-4B2F-84CB-1B8D1F2F0BA6Q24531899-2543A587-6031-4FE0-A039-5DC3B14186EBQ28254761-3C5BF313-7665-442D-A357-AD864416E08DQ28285692-553C9F91-AA1E-45AE-A0C6-CE8525791471Q30982840-058F429F-93FF-49F9-A7CA-05EAC6D491F5Q30982932-9184635C-FE5B-4457-BC9A-DA19C6440ED9Q31980386-597C59C2-1A27-4DD8-865B-DE9230DBDE93Q33728388-0B994F9E-3028-4C17-9182-C98F2C24A201Q33820577-E2028658-B0B1-4536-BC06-CA97D8B2D0BAQ33915081-6A61B598-5266-488F-A1A7-A83ED1512000Q34115497-EBA56F73-7975-4C97-9A8A-0A55CFDE40A1Q34494370-A504F671-1923-4D0C-88CF-2CEF0260E53EQ34572975-27284A7E-5BA2-46D6-B209-B74E3C4B642FQ35179221-4D0D95CA-2E53-4551-9FF0-0CCF65184C4AQ35334619-149D92F4-339F-46EC-839A-42062B98DC75Q36015695-E40D28E5-0476-4E29-8C4F-B803DEBC82EBQ36243931-68813A98-5DE2-42B9-8780-AEA1E0E84E02Q36342500-0FFB0722-18A5-4C2F-AB42-1A97325B954AQ36434614-FAA6898C-C2C9-4669-B180-78B254E85D3DQ36435921-1C4F14B3-8415-49B4-8A89-EE0F9BB871AEQ37119654-04391489-3195-4E14-94E9-EEE212F3B67EQ37599088-CB5F219A-3774-4309-A8C1-39C6A28B9323Q37605352-7256120E-916E-4A19-BE6A-FA8E509114E5Q37606529-53A6587E-E87F-41E1-A7B8-DCE11960803CQ37738600-5767FAEC-82EC-47B5-83CA-13B174C04916Q38087443-567F5B44-8868-454C-AA32-5BF37B984EB7Q39453706-A4532D72-69F7-4526-82F9-FA46D6230A0EQ40305219-77EF23AB-F805-4D42-AF1A-FD8754D8EB33Q41368862-399FB0B8-0E93-4CE8-81C2-1528EA097DB8Q41372287-2D684D9B-476F-4664-9EDA-06EA9885E52AQ41460038-22729566-B916-42A8-870A-72AB5813423CQ42035315-7B287655-00DF-4172-89FF-901A08C4773DQ42063193-2D251CB7-7263-443C-B6F6-7F0662F48794Q42088803-D6BA881E-7CE9-40A7-8373-939B50DFF976Q42378720-6D2166E3-2A8E-4519-A589-F5E0BA800997Q42615022-9B54874A-5ADB-4576-8ABB-726948A8F7C0Q46596550-A8C32D0B-578E-4FBD-93B8-F1C9EA508866Q46980014-FBC64EF9-6456-436A-9BC0-CDB0CECC4B61Q47396208-377E36C0-D22B-4118-AB7B-FE2158AEC47CQ48934881-A04866FB-BBCD-496A-9CEE-38D42E38DBA7
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Voltage-sensitive ion channels.
@en
type
label
Voltage-sensitive ion channels.
@en
prefLabel
Voltage-sensitive ion channels.
@en
P1433
P1476
Voltage-sensitive ion channels.
@en
P356
10.1016/0092-8674(89)90979-3
P407
P577
1989-01-01T00:00:00Z