about
Muscle channelopathies and critical points in functional and genetic studies.ClC chloride channelsDiversity of Cl(-) channelsThe functional unit of the renal type IIa Na+/Pi cotransporter is a monomerAnion transport in heartHigh-affinity Zn block in recombinant N-methyl-D-aspartate receptors with cysteine substitutions at the Q/R/N site.Oxidation and reduction control of the inactivation gating of Torpedo ClC-0 chloride channels.Ion permeation and selectivity in ClC-type chloride channels.Bacterial ion channels and their eukaryotic homologues.Genetic disorders of neuromuscular ion channels.Chloride channels in the kidney: lessons learned from knockout animals.Amazing chloride channels: an overview.Modulation of the slow/common gating of CLC channels by intracellular cadmium.Cysteine modification of a putative pore residue in ClC-0: implication for the pore stoichiometry of ClC chloride channels.Fast and slow gating relaxations in the muscle chloride channel CLC-1.CLC-0 and CFTR: chloride channels evolved from transporters.In the beginning: a personal reminiscence on the origin and legacy of ClC-0, the 'Torpedo Cl(-) channel'.Activation of the MEF2 transcription factor in skeletal muscles from myotonic mice.CLC chloride channels in Caenorhabditis elegans.Identification of three cysteines as targets for the Zn2+ blockade of the human skeletal muscle chloride channel.The muscle chloride channel ClC-1 has a double-barreled appearance that is differentially affected in dominant and recessive myotonia.Mechanism of block of single protopores of the Torpedo chloride channel ClC-0 by 2-(p-chlorophenoxy)butyric acid (CPB).Residues lining the inner pore vestibule of human muscle chloride channels.Characterization of two new dominant ClC-1 channel mutations associated with myotonia.Functional and structural analysis of ClC-K chloride channels involved in renal disease.Chloride dependence of hyperpolarization-activated chloride channel gates.Mapping ligand binding pockets in chloride ClC-1 channels through an integrated in silico and experimental approach using anthracene-9-carboxylic acid and niflumic acid.Pores Formed by Single Subunits in Mixed Dimers of Different CLC Chloride Channels
P2860
Q24532297-99F664A3-5558-425A-AE0A-6B7911355046Q24542504-4F309024-88AC-4246-A892-23A2DD43176BQ24642246-72E8DDB9-2C29-4E8C-BBB7-16380F27E986Q28138657-4AC97E7B-1A21-4685-8BE4-D5D115A38B63Q28141703-2BB0EBF5-9831-4F90-A2BB-0E49BB61E9C2Q28367644-0DEC4273-13D0-40DA-935F-3C19D90E6D6AQ34190624-476CCD32-79C2-482F-823F-56C6CFB15799Q34211948-BB87AC7C-6A07-47F6-832A-D29C4EFCB8B8Q34464686-DA8A681E-5E23-46F6-AD87-043FBDB4352CQ34811193-30140E23-C026-438F-BC32-5D504FE0F587Q34993939-53FD919F-AA7A-476C-86E9-5C71E3B964CFQ35056777-73A548FF-70E3-49DD-8C38-F68C86F63773Q36333197-77567D8C-0763-452D-91AD-DB91FB649777Q36438872-02CD6086-EE1C-465C-96DD-5ACE7B6F5EEBQ36444711-137F49A3-954B-487C-90E8-F639F1AE8925Q37129332-D0DBF32F-7113-4493-B51E-95EF3972830AQ38272578-AAED01C1-E917-4C43-9F99-5F529A2BE323Q39737926-D4081F6C-2791-42F7-A9BF-A495BBD5EB12Q40917330-B95F34D8-5B25-4F11-B107-0C58B6680E2AQ40960206-71015E2F-E496-45F5-B317-945F6B492F2FQ41910206-C540E779-FAD1-48EB-9423-AA94644DFDA7Q41952375-0C97535B-FFE7-4644-93BA-7F6D3AAC3EAAQ43508362-710B5EF8-FEA1-4A69-ABFA-1A1949151EF5Q48818477-9C7BB45D-1CD2-4B84-A1A2-7C54D8282B7BQ48889584-EFEB04B2-2DB5-46AB-A642-870B5729DA72Q48923241-0B152B63-E38C-422A-9158-3F0886AED4E8Q52676150-C7E60D2C-E81F-41EA-B659-57DA6866EF20Q56974970-80110AD3-4542-42AD-BDD6-B2638CD6B278
P2860
description
1998 nî lūn-bûn
@nan
1998年の論文
@ja
1998年論文
@yue
1998年論文
@zh-hant
1998年論文
@zh-hk
1998年論文
@zh-mo
1998年論文
@zh-tw
1998年论文
@wuu
1998年论文
@zh
1998年论文
@zh-cn
name
Pore stoichiometry of a voltage-gated chloride channel.
@en
type
label
Pore stoichiometry of a voltage-gated chloride channel.
@en
prefLabel
Pore stoichiometry of a voltage-gated chloride channel.
@en
P2093
P2860
P356
P1433
P1476
Pore stoichiometry of a voltage-gated chloride channel.
@en
P2093
P2860
P2888
P304
P356
10.1038/29319
P407
P577
1998-08-01T00:00:00Z
P5875
P6179
1019602118