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KChIP 调节 Kv4.2 功能表达的功能计量学基础。

Functional stoichiometry underlying KChIP regulation of Kv4.2 functional expression.

机构信息

Department of Neuroscience, Baylor College of Medicine, Houston, Texas 77030, USA.

出版信息

J Neurochem. 2013 Aug;126(4):462-72. doi: 10.1111/jnc.12309. Epub 2013 Jun 10.

DOI:10.1111/jnc.12309
PMID:23692269
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3737270/
Abstract

K channel-interacting proteins (KChIPs) enhance functional expression of Kv4 channels by binding to an N-terminal regulatory region located in the first 40 amino acids of Kv4.2 that we call the functional expression regulating N-terminal (FERN) domain. Mutating two residues in the FERN domain to alanines, W8A and F11A, disrupts KChIP binding and regulation of Kv4.2 without eliminating the FERN domain's control of basal expression level or regulation by DPP6. When Kv4.2(W8A,F11A) is co-expressed with wild type Kv4.2 and KChIP3 subunits, a dominant negative effect is seen where the current expression is reduced to levels normally seen without KChIP addition. The dominant negative effect correlates with heteromultimeric channels remaining on intracellular membranes despite KChIP binding to non-mutant Kv4.2 subunits. In contrast, the deletion mutant Kv4.2(Δ1-40), eliminating both KChIP binding and the FERN domain, has no dominant negative effect even though the maximal conductance level is 5x lower than seen with KChIP3. The 5x increased expression seen with KChIP integration into the channel is fully apparent even when a reduced number of KChIP subunits are incorporated as long as all FERN domains are bound. Our results support the hypothesis that KChIPs enhances Kv4.2 functional expression by a 1 : 1 suppression of the N-terminal FERN domain and by producing additional positive regulatory effects on functional channel expression.

摘要

K 通道相互作用蛋白(KChIPs)通过与 Kv4.2 第一个 40 个氨基酸的 N 端调节区结合,增强 Kv4 通道的功能性表达,我们称之为功能性表达调节 N 端(FERN)结构域。将 FERN 结构域中的两个残基突变为丙氨酸(W8A 和 F11A),可破坏 KChIP 与 Kv4.2 的结合和调节,而不会消除 FERN 结构域对基础表达水平的控制或 DPP6 的调节。当 Kv4.2(W8A,F11A)与野生型 Kv4.2 和 KChIP3 亚基共同表达时,会出现显性负效应,即电流表达水平降低至没有 KChIP 加入时的正常水平。显性负效应与异源多聚体通道尽管与非突变 Kv4.2 亚基结合,但仍保留在细胞内膜上有关。相比之下,缺失突变体 Kv4.2(Δ1-40),消除了 KChIP 结合和 FERN 结构域,即使最大电导水平比与 KChIP3 结合时低 5 倍,也没有显性负效应。即使整合到通道中的 KChIP 亚基数量减少,只要所有的 FERN 结构域都被结合,通过 KChIP 整合到通道中观察到的 5 倍增加的表达水平仍然完全明显。我们的结果支持这样的假设,即 KChIPs 通过 1:1 抑制 N 端 FERN 结构域和对功能性通道表达产生额外的正向调节作用来增强 Kv4.2 的功能性表达。

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