Richards Mark W, Leroy Jerôme, Pratt Wendy S, Dolphin Annette C
Laboratory of Cellular and Molecular Neuroscience, Department of Pharmacology, University College London, London, UK.
Channels (Austin). 2007 Mar-Apr;1(2):92-101. doi: 10.4161/chan.4145. Epub 2007 Mar 15.
Ca(v)beta subunits of voltage-gated calcium channels contain two conserved domains, a src-homology-3 (SH3)-domain and a guanylate kinase-like (GK)-domain. The SH3-domain is split, with its final (fifth) beta-strand separated from the rest of the domain by an intervening sequence termed the HOOK-domain, whose sequence varies between Ca(v)beta subunits. Here we have been guided by the recent structural studies of Ca(v)beta subunits in the design of specific truncated constructs, with the goal of investigating the role of the HOOK-domain of Ca(v)beta subunits in the modulation of inactivation of N-type calcium channels. We have coexpressed the beta subunit constructs with Ca(v)2.2 and alpha(2)delta-2, using the N-terminally palmitoylated beta(2a) subunit, because it supports very little voltage-dependent inactivation, and made comparisons with beta(1b) domains. Deletion of the variable region of the beta(2a) HOOK-domain resulted in currents with a rapidly inactivating component, and additional mutation of the beta(2a) palmitoylation motif further enhanced inactivation. The isolated GK-domain of beta(2a) alone enhanced current amplitude, but the currents were rapidly and completely inactivating. When the beta(2a)-GK-domain construct was extended proximally, by including the HOOK-domain and the epsilon-strand of the SH3-domain, inactivation was about four-fold slower than in the absence of the HOOK domain. When the SH3-domain of beta(2a) truncated prior to the HOOK-domain was coexpressed with the (HOOK+epsilonSH3+GK)-domain of beta(2a), all the properties of beta(2a) were restored, in terms of loss of inactivation. Furthermore, removal of the HOOK sequence from the (HOOK+epsilonSH3+GK)-beta(2a) construct increased inactivation. Together, these results provide evidence that the HOOK domain is an important determinant of inactivation.
电压门控钙通道的Ca(v)β亚基包含两个保守结构域,一个src同源3(SH3)结构域和一个鸟苷酸激酶样(GK)结构域。SH3结构域是分裂的,其最后的(第五个)β链通过一个称为HOOK结构域的中间序列与该结构域的其余部分分开,HOOK结构域的序列在Ca(v)β亚基之间有所不同。在这里,我们在设计特定的截短构建体时受到了Ca(v)β亚基近期结构研究的指导,目的是研究Ca(v)β亚基的HOOK结构域在调节N型钙通道失活中的作用。我们使用N端棕榈酰化的β(2a)亚基将β亚基构建体与Ca(v)2.2和α(2)δ-2共表达,因为它几乎不支持电压依赖性失活,并与β(1b)结构域进行了比较。删除β(2a) HOOK结构域的可变区导致电流具有快速失活成分,并且β(2a)棕榈酰化基序的额外突变进一步增强了失活。单独的β(2a)分离的GK结构域增强了电流幅度,但电流快速且完全失活。当β(2a)-GK结构域构建体向近端延伸,包括HOOK结构域和SH3结构域的ε链时,失活速度比没有HOOK结构域时慢约四倍。当在HOOK结构域之前截短的β(2a)的SH3结构域与β(2a)的(HOOK+εSH3+GK)结构域共表达时,就失活丧失而言,β(2a)的所有特性都恢复了。此外,从(HOOK+εSH3+GK)-β(2a)构建体中去除HOOK序列增加了失活。总之,这些结果提供了证据表明HOOK结构域是失活的重要决定因素。
