Gottfried-Schatz Research Center (Biophysics), Medical University of Graz, Austria.
Institute of Chemistry, University of Graz, Austria.
Cell Calcium. 2019 May;79:27-34. doi: 10.1016/j.ceca.2019.02.007. Epub 2019 Feb 16.
Mutation of a single residue within the recently identified lipid (diacylglycerol) recognition window of TRPC3 (G652A) was found to abolish channel activation via endogenous lipid mediators while retaining sensitivity to the non-lipid activator GSK1702934A (abb. GSK). The mechanism of this change in chemical sensing by TRPC3 was analysed by whole-cell and single channel electrophysiology as well as Ca imaging. Currents initiated by GSK or the structural (benzimidazole) analog BI-2 were significantly larger in cells expressing the G652A mutant as compared to wild type (WT) channels. Whole cell patch-clamp experiments revealed that enhanced sensitivity to benzimidazoles was not due to augmented potency but reflected enhanced efficacy of benzimidazoles. Single channel analysis demonstrated that neither unitary conductance nor I-V characteristics were altered by the G652A mutation, precluding altered pore architecture as the basis of enhanced efficacy. These experiments uncovered a distinct gating pattern of BI-2-activated G652A mutant channels, featuring a unique, long-lived open state. Moreover, G652A mutant channels lacked PLC/diacylglycerol mediated cross-desensitization for GSK activation as typically observed for TRPC3. Lack of desensitization in G652A channels enabled large GSK/BI-2-induced Ca signals in conditions that fully desensitized TRPC3 WT channels. We demonstrate that the lipid-recognition window of TRPC3 determines both sensitivity to lipid mediators and chemical gating by benzimidazoles. TRPC3 mutations within this lipid interaction site are suggested as a basis for chemogenetic targeting of TRPC3-signaling.
在最近鉴定的 TRPC3(G652A)的脂质(二酰基甘油)识别窗口内的单个残基的突变被发现消除了通过内源性脂质介体的通道激活,同时保留了对非脂质激活剂 GSK1702934A(简称 GSK)的敏感性。通过全细胞和单通道电生理学以及 Ca 成像分析了 TRPC3 化学感应中这种变化的机制。与野生型(WT)通道相比,表达 G652A 突变体的细胞中由 GSK 或结构(苯并咪唑)类似物 BI-2 引发的电流明显更大。全细胞贴片钳实验表明,对苯并咪唑的敏感性增强不是由于效力增强,而是反映了苯并咪唑的效力增强。单通道分析表明,G652A 突变既没有改变单位电导也没有改变 I-V 特性,排除了改变孔结构作为效力增强的基础。这些实验揭示了 BI-2 激活的 G652A 突变体通道的独特门控模式,其特征是独特的、长寿命的开放状态。此外,G652A 突变体通道缺乏 PLC/二酰基甘油介导的 GSK 激活的交叉脱敏作用,这是通常观察到的 TRPC3 的特征。G652A 通道中没有脱敏作用,使得在完全脱敏 TRPC3 WT 通道的条件下,产生了大的 GSK/BI-2 诱导的 Ca 信号。我们证明,TRPC3 的脂质识别窗口决定了对脂质介体的敏感性和苯并咪唑的化学门控。TRPC3 中脂质相互作用位点的突变被认为是 TRPC3 信号化学遗传靶向的基础。
