K(ir)1.1通道的钾离子依赖性门控通过孔道的构象变化与pH门控相关联。

K(+)-dependent gating of K(ir)1.1 channels is linked to pH gating through a conformational change in the pore.

作者信息

Schulte U, Weidemann S, Ludwig J, Ruppersberg J, Fakler B

机构信息

Department of Physiology II, University of Tübingen, Ob dem Himmelreich 7, 72074 Tübingen, Germany.

出版信息

J Physiol. 2001 Jul 1;534(Pt 1):49-58. doi: 10.1111/j.1469-7793.2001.t01-1-00049.x.

DOI:10.1111/j.1469-7793.2001.t01-1-00049.x

PMID:11432991

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2278684/

Abstract

We have used giant patch-clamp recording to investigate the interaction between pH gating and K(+)-dependent gating in rat K(ir)1.1 (ROMK) channels heterologously expressed in Xenopus oocytes. 2. Gating by intracellular protons (pH gating) and extracellular K(+) ions (K(+)-dependent gating) is a hallmark of K(ir)1.1 channels that mediate K(+) secretion and control NaCl reabsorption in the kidney. pH gating is driven by protonation of an intracellular lysine residue (K80 in K(ir)1.1). K(+)-dependent gating occurs upon withdrawal of K(+) ions from the extracellular side of the channel. Both gating mechanisms are thought to interact allosterically. 3. K(+)-dependent gating was shown to be strictly coupled to pH gating; it only occurred when channels were in the pH-inactivated closed state, but not in the open state. Moreover, K(+)-dependent gating was absent in the non-pH-gated mutant K(ir)1.1(K80 M). 4. Channels inactivated by K(+)-dependent gating were reactivated upon addition of permeant ions to the extracellular side of the membrane, while impermeant ions failed to induce channel reactivation. Moreover, mutagenesis identified two residues in the P-helix (L136 and V140 in K(ir)1.1) that are crucial for K(+)-dependent gating. Replacement of these residues with the ones present in the non-K(+)-gated K(ir)2.1 abolished K(+)-dependent gating of K(ir)1.1 channels without affecting pH gating. 5. The results indicate that pH gating and K(+)-dependent gating are coupled to each other via structural rearrangements in the inner pore involving the P-helix.

摘要

我们运用巨膜片钳记录技术，研究了非洲爪蟾卵母细胞中异源表达的大鼠K(ir)1.1（ROMK）通道的pH门控与钾离子依赖性门控之间的相互作用。2. 细胞内质子（pH门控）和细胞外钾离子（钾离子依赖性门控）介导的门控是K(ir)1.1通道的一个标志，该通道介导肾脏中的钾离子分泌并控制氯化钠重吸收。pH门控由细胞内赖氨酸残基（K(ir)1.1中的K80）的质子化驱动。钾离子依赖性门控在钾离子从通道细胞外侧撤离时发生。两种门控机制被认为通过变构相互作用。3. 钾离子依赖性门控被证明与pH门控严格偶联；它仅在通道处于pH失活的关闭状态时发生，而在开放状态下不发生。此外，在非pH门控突变体K(ir)1.1(K80 M)中不存在钾离子依赖性门控。4. 由钾离子依赖性门控失活的通道在向膜的细胞外侧添加通透离子后重新激活，而不通透离子未能诱导通道重新激活。此外，诱变鉴定出P螺旋中的两个残基（K(ir)1.1中的L136和V140）对钾离子依赖性门控至关重要。用非钾离子门控的K(ir)2.1中存在的残基替换这些残基，消除了K(ir)1.1通道的钾离子依赖性门控而不影响pH门控。5. 结果表明，pH门控和钾离子依赖性门控通过涉及P螺旋的内孔结构重排相互偶联。

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pH gating of ROMK (K(ir)1.1) channels: control by an Arg-Lys-Arg triad disrupted in antenatal Bartter syndrome.

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pH-dependent gating of ROMK (Kir1.1) channels involves conformational changes in both N and C termini.

J Biol Chem. 1998 Dec 18;273(51):34575-9. doi: 10.1074/jbc.273.51.34575.

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K(ir)1.1通道的钾离子依赖性门控通过孔道的构象变化与pH门控相关联。

K(+)-dependent gating of K(ir)1.1 channels is linked to pH gating through a conformational change in the pore.

作者信息

Schulte U, Weidemann S, Ludwig J, Ruppersberg J, Fakler B

机构信息

Department of Physiology II, University of Tübingen, Ob dem Himmelreich 7, 72074 Tübingen, Germany.

出版信息

J Physiol. 2001 Jul 1;534(Pt 1):49-58. doi: 10.1111/j.1469-7793.2001.t01-1-00049.x.

DOI:10.1111/j.1469-7793.2001.t01-1-00049.x

PMID:11432991

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2278684/

Abstract

We have used giant patch-clamp recording to investigate the interaction between pH gating and K(+)-dependent gating in rat K(ir)1.1 (ROMK) channels heterologously expressed in Xenopus oocytes. 2. Gating by intracellular protons (pH gating) and extracellular K(+) ions (K(+)-dependent gating) is a hallmark of K(ir)1.1 channels that mediate K(+) secretion and control NaCl reabsorption in the kidney. pH gating is driven by protonation of an intracellular lysine residue (K80 in K(ir)1.1). K(+)-dependent gating occurs upon withdrawal of K(+) ions from the extracellular side of the channel. Both gating mechanisms are thought to interact allosterically. 3. K(+)-dependent gating was shown to be strictly coupled to pH gating; it only occurred when channels were in the pH-inactivated closed state, but not in the open state. Moreover, K(+)-dependent gating was absent in the non-pH-gated mutant K(ir)1.1(K80 M). 4. Channels inactivated by K(+)-dependent gating were reactivated upon addition of permeant ions to the extracellular side of the membrane, while impermeant ions failed to induce channel reactivation. Moreover, mutagenesis identified two residues in the P-helix (L136 and V140 in K(ir)1.1) that are crucial for K(+)-dependent gating. Replacement of these residues with the ones present in the non-K(+)-gated K(ir)2.1 abolished K(+)-dependent gating of K(ir)1.1 channels without affecting pH gating. 5. The results indicate that pH gating and K(+)-dependent gating are coupled to each other via structural rearrangements in the inner pore involving the P-helix.

摘要

我们运用巨膜片钳记录技术，研究了非洲爪蟾卵母细胞中异源表达的大鼠K(ir)1.1（ROMK）通道的pH门控与钾离子依赖性门控之间的相互作用。2. 细胞内质子（pH门控）和细胞外钾离子（钾离子依赖性门控）介导的门控是K(ir)1.1通道的一个标志，该通道介导肾脏中的钾离子分泌并控制氯化钠重吸收。pH门控由细胞内赖氨酸残基（K(ir)1.1中的K80）的质子化驱动。钾离子依赖性门控在钾离子从通道细胞外侧撤离时发生。两种门控机制被认为通过变构相互作用。3. 钾离子依赖性门控被证明与pH门控严格偶联；它仅在通道处于pH失活的关闭状态时发生，而在开放状态下不发生。此外，在非pH门控突变体K(ir)1.1(K80 M)中不存在钾离子依赖性门控。4. 由钾离子依赖性门控失活的通道在向膜的细胞外侧添加通透离子后重新激活，而不通透离子未能诱导通道重新激活。此外，诱变鉴定出P螺旋中的两个残基（K(ir)1.1中的L136和V140）对钾离子依赖性门控至关重要。用非钾离子门控的K(ir)2.1中存在的残基替换这些残基，消除了K(ir)1.1通道的钾离子依赖性门控而不影响pH门控。5. 结果表明，pH门控和钾离子依赖性门控通过涉及P螺旋的内孔结构重排相互偶联。

K(ir)1.1通道的钾离子依赖性门控通过孔道的构象变化与pH门控相关联。

K(+)-dependent gating of K(ir)1.1 channels is linked to pH gating through a conformational change in the pore.

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K(ir)1.1通道的钾离子依赖性门控通过孔道的构象变化与pH门控相关联。

K(+)-dependent gating of K(ir)1.1 channels is linked to pH gating through a conformational change in the pore.

作者信息

机构信息

出版信息