High-conductance calcium-activated potassium channels; structure, pharmacology, and function.
about
Molecular mechanisms of large-conductance ca (2+) -activated potassium channel activation by ginseng gintoninCharacterization and gene expression of high conductance calcium-activated potassium channels displaying mechanosensitivity in human odontoblastsStructure of the human BK channel Ca2+-activation apparatus at 3.0 A resolutionStructure of the gating ring from the human large-conductance Ca(2+)-gated K(+) channelOpen structure of the Ca2+ gating ring in the high-conductance Ca2+-activated K+ channel.The beta subunit increases the Ca2+ sensitivity of large conductance Ca2+-activated potassium channels by retaining the gating in the bursting statesGating mechanism of BK (Slo1) channels: so near, yet so farHow neutrophils kill microbesAnalysis of Maxi-K alpha subunit splice variants in human myometriumPeptide toxins and small-molecule blockers of BK channelsOn benzofuroindole analogues as smooth muscle relaxantsRelaxation to authentic nitric oxide and SIN-1 in rat isolated mesenteric arteries: variable role for smooth muscle hyperpolarizationFunctional effects of auxiliary beta4-subunit on rat large-conductance Ca(2+)-activated K(+) channelHabituation of reflexive and motivated behavior in mice with deficient BK channel function.Upregulation of STREX splice variant of the large conductance Ca2+-activated potassium (BK) channel in a rat model of mesial temporal lobe epilepsyRenin-angiotensin system expression and secretory function in cultured human ciliary body non-pigmented epithelium.Global cDNA amplification combined with real-time RT-PCR: accurate quantification of multiple human potassium channel genes at the single cell level.Number of K(Ca) channels underlying spontaneous miniature outward currents (SMOCs) in mudpuppy cardiac neurons.Down-regulation of BK channel expression in the pilocarpine model of temporal lobe epilepsy.Molecular and cellular basis of small--and intermediate-conductance, calcium-activated potassium channel function in the brain.Properties and physiological function of Ca2+-dependent K+ currents in uniglomerular olfactory projection neurons.Morphine induces preconditioning via activation of mitochondrial K(Ca) channelsStepwise contribution of each subunit to the cooperative activation of BK channels by Ca2+.Is there a role for potassium channel openers in neuronal ion channel disorders?Ca(2+) influx and opening of Ca(2+)-activated K(+) channels in muscle fibers from control and mdx mice.The large-conductance Ca2+-activated K+ channel is essential for innate immunity.Antecedent hydrogen sulfide elicits an anti-inflammatory phenotype in postischemic murine small intestine: role of BK channels.Synthesis of an iberiotoxin derivative by chemical ligation: a method for improved yields of cysteine-rich scorpion toxin peptides.Peripheral channelopathies as targets for potassium channel openers.Reverse electron flow-induced ROS production is attenuated by activation of mitochondrial Ca2+-sensitive K+ channels.KCa1.1 inhibition attenuates fibroblast-like synoviocyte invasiveness and ameliorates disease in rat models of rheumatoid arthritis.Ability of naringenin, a bioflavonoid, to activate M-type potassium current in motor neuron-like cells and to increase BKCa-channel activity in HEK293T cells transfected with α-hSlo subunit.Role of gap junctions and EETs in endothelium-dependent hyperpolarization of porcine coronary arteryWNK4 kinase inhibits Maxi K channel activity by a kinase-dependent mechanism.WNK1 activates large-conductance Ca2+-activated K+ channels through modulation of ERK1/2 signaling.Stimulation of the BK(Ca) channel in cultured smooth muscle cells of human trachea by magnolol.Elevated subsarcolemmal Ca2+ in mdx mouse skeletal muscle fibers detected with Ca2+-activated K+ channels.The NADPH oxidase of professional phagocytes--prototype of the NOX electron transport chain systems.Large conductance, calcium- and voltage-gated potassium (BK) channels: regulation by cholesterol.The beta subunit of the high-conductance calcium-activated potassium channel contributes to the high-affinity receptor for charybdotoxin.
P2860
Q21285088-F31B1AAF-EA08-4D5A-A510-E3C4C1657EB0Q22254206-AC22585A-8D0A-48CF-9277-6BE2D6169358Q24595712-FDC266F8-8949-4144-BBC6-0ADB556AC87DQ24602501-03062935-6FE5-4888-9A3A-A08D1A1D7374Q24605639-F18DA58C-D369-4E59-B213-7CC6B88A8793Q24642378-6F765F02-982C-4550-B6B8-D3865A52B0CCQ24644547-26317669-3FA0-4FCA-BCAD-2E2D7E9A855AQ24672245-60137943-5BEC-4CD6-BD6A-FF097ED5D534Q24803979-C2066665-0ABD-45B0-9556-AC302B4706BDQ26771356-3C793B6A-0D87-4A37-AE45-382A07B5BA3FQ27001453-46B6433E-19BA-4F43-B556-10BA07BCCB11Q28367873-9A4CDF62-285C-424C-A7C6-75864ECDACE7Q28566676-209F49B8-E5C5-4A3A-ABCC-1582531E4758Q30446199-EEBFE37D-4CFB-43DF-9A23-3CA5E13844B3Q30497593-CF338C5A-5A04-4FC3-8766-582143C67886Q30695093-2DE7A0BB-75DF-4C3F-ABEB-B52CAE390A79Q30939795-0C3488D7-F74C-49A9-9C3C-0155B6F034ACQ31816717-C7A819D8-00BD-4779-9691-BE7FF3769563Q33320921-BFF55488-FC2B-489D-AA28-DDC05CA8A1B3Q33560844-8BF8871B-CA84-4BDE-8582-BB82171F6E76Q33573030-FD972383-ECF1-44D0-97D5-CAAF5CEE04FDQ33970045-F58C1C4B-89B8-480A-B9B9-A90C25240D7AQ34038735-AC7D1ABB-6015-4553-8CFA-E1958694FFC3Q34075106-A67C9DB2-F92C-4109-8632-B4B4C4879C6BQ34178063-57C95AFE-D5BE-4501-A921-462FF196F5A0Q34301370-3E752C5C-59D8-4DF8-A9BA-15F31C4917A7Q34357787-E2FEF1C3-46AF-43DA-B363-D712C950C625Q34387133-B8D11E43-8498-4971-8CD5-CE9B2C820F3CQ34481593-44F59B87-CBDB-4CA2-99D8-9C46B439505AQ34579660-81763E9E-0961-46B1-8D0D-1FAE35D43163Q34791066-9F1B2B00-04FC-4671-AF65-03F2F665F659Q34886666-02F5B726-9E45-4B00-AEFA-D5C58CCFB54EQ35042052-60ADAD5C-1117-489E-A7AD-19FAD55E8C3BQ35159554-3081385B-B0F6-4B5D-AE0E-8FF25403C186Q35228556-991F8E9D-712D-4A04-B269-33C15D8ACB45Q35534801-B8F3E739-8991-44E1-B093-DBBD4D6C5A00Q35700706-2DB7EE57-EF4A-4847-964F-DD6F9FCB50E0Q35828194-5A0A3A3B-12AD-409A-8910-20AC1874942AQ36059310-08EF6F98-59E8-4C92-93EF-4CF526B2F100Q36071684-B0D993F9-ADEA-4B6F-A314-22D248282253
P2860
High-conductance calcium-activated potassium channels; structure, pharmacology, and function.
description
1996 nî lūn-bûn
@nan
1996 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
1996 թվականի հունիսին հրատարակված գիտական հոդված
@hy
1996年の論文
@ja
1996年論文
@yue
1996年論文
@zh-hant
1996年論文
@zh-hk
1996年論文
@zh-mo
1996年論文
@zh-tw
1996年论文
@wuu
name
High-conductance calcium-activ ...... e, pharmacology, and function.
@ast
High-conductance calcium-activ ...... e, pharmacology, and function.
@en
High-conductance calcium-activ ...... e, pharmacology, and function.
@nl
type
label
High-conductance calcium-activ ...... e, pharmacology, and function.
@ast
High-conductance calcium-activ ...... e, pharmacology, and function.
@en
High-conductance calcium-activ ...... e, pharmacology, and function.
@nl
prefLabel
High-conductance calcium-activ ...... e, pharmacology, and function.
@ast
High-conductance calcium-activ ...... e, pharmacology, and function.
@en
High-conductance calcium-activ ...... e, pharmacology, and function.
@nl
P2093
P356
P1476
High-conductance calcium-activ ...... e, pharmacology, and function.
@en
P2093
G J Kaczorowski
M L Garcia
O B McManus
R J Leonard
P2860
P2888
P304
P356
10.1007/BF02110699
P577
1996-06-01T00:00:00Z
P6179
1023493066