Oxidation Driven Reversal of PIP₂-dependent Gating in GIRK2 Channels.

IF 5.1 Q2 CELL BIOLOGY Function (Oxford, England) Pub Date : 2023-04-10 eCollection Date: 2023-01-01 DOI:10.1093/function/zqad016

Sun-Joo Lee, Shoji Maeda, Jian Gao, Colin G Nichols

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Abstract

Physiological activity of G protein gated inward rectifier K⁺ (GIRK, Kir3) channel, dynamically regulated by three key ligands, phosphoinositol-4,5-bisphosphate (PIP₂), Gβγ, and Na⁺, underlies cellular electrical response to multiple hormones and neurotransmitters in myocytes and neurons. In a reducing environment, matching that inside cells, purified GIRK2 (Kir3.2) channels demonstrate low basal activity, and expected sensitivity to the above ligands. However, under oxidizing conditions, anomalous behavior emerges, including rapid loss of PIP₂ and Na⁺-dependent activation and a high basal activity in the absence of any agonists, that is now paradoxically inhibited by PIP₂. Mutagenesis identifies two cysteine residues (C65 and C190) as being responsible for the loss of PIP₂ and Na⁺-dependent activity and the elevated basal activity, respectively. The results explain anomalous findings from earlier studies and illustrate the potential pathophysiologic consequences of oxidation on GIRK channel function, as well as providing insight to reversed ligand-dependence of Kir and KirBac channels.

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氧化驱动 GIRK2 通道中 PIP2 依赖性门控的逆转

G 蛋白门控内向整流 K+（GIRK，Kir3）通道的生理活性受磷酸肌醇-4,5-二磷酸（PIP2）、Gβγ 和 Na+ 三种关键配体的动态调节，是肌细胞和神经元对多种激素和神经递质做出细胞电反应的基础。在与细胞内相匹配的还原环境中，纯化的 GIRK2（Kir3.2）通道表现出较低的基础活性，并对上述配体具有预期的敏感性。然而，在氧化条件下，出现了异常行为，包括 PIP2 和 Na+ 依赖性激活的快速丧失，以及在没有任何激动剂的情况下的高基础活性，而这种活性现在却被 PIP2 所抑制。基因突变确定了两个半胱氨酸残基（C65 和 C190）分别是导致 PIP2 和 Na+ 依赖性活性丧失以及基础活性升高的原因。这些结果解释了早期研究中的异常发现，说明了氧化对 GIRK 通道功能的潜在病理生理后果，并为 Kir 和 KirBac 通道的反向配体依赖性提供了见解。

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