Huang Guo N, Zeng Weizhong, Kim Joo Young, Yuan Joseph P, Han Linhuang, Muallem Shmuel, Worley Paul F
Department of Neuroscience, The Johns Hopkins University School of Medicine, Baltimore, MD 21205, USA.
Nat Cell Biol. 2006 Sep;8(9):1003-10. doi: 10.1038/ncb1454. Epub 2006 Aug 13.
Receptor-evoked Ca2+ signalling involves Ca2+ release from the endoplasmic reticulum, followed by Ca2+ influx across the plasma membrane. Ca2+ influx is essential for many cellular functions, from secretion to transcription, and is mediated by Ca2+-release activated Ca2+ (I(crac)) channels and store-operated calcium entry (SOC) channels. Although the molecular identity and regulation of I(crac) and SOC channels have not been precisely determined, notable recent findings are the identification of STIM1, which has been indicated to regulate SOC and I(crac) channels by functioning as an endoplasmic reticulum Ca2+ sensor, and ORAI1 (ref. 7) or CRACM1 (ref. 8)--both of which may function as I(crac) channels or as an I(crac) subunit. How STIM1 activates the Ca2+ influx channels and whether STIM1 contributes to the channel pore remains unknown. Here, we identify the structural features that are essential for STIM1-dependent activation of SOC and I(crac) channels, and demonstrate that they are identical to those involved in the binding and activation of TRPC1. Notably, the cytosolic carboxyl terminus of STIM1 is sufficient to activate SOC, I(crac) and TRPC1 channels even when native STIM1 is depleted by small interfering RNA. Activity of STIM1 requires an ERM domain, which mediates the selective binding of STIM1 to TRPC1, 2 and 4, but not to TRPC3, 6 or 7, and a cationic lysine-rich region, which is essential for gating of TRPC1. Deletion of either region in the constitutively active STIM1(D76A) yields dominant-negative mutants that block native SOC channels, expressed TRPC1 in HEK293 cells and I(crac) in Jurkat cells. These observations implicate STIM1 as a key regulator of activity rather than a channel component, and reveal similar regulation of SOC, I(crac) and TRPC channel activation by STIM1.
受体诱发的Ca2+信号传导涉及内质网释放Ca2+,随后Ca2+跨质膜内流。Ca2+内流对于从分泌到转录的许多细胞功能至关重要,它由Ca2+释放激活的Ca2+(I(crac))通道和储存操纵性钙内流(SOC)通道介导。尽管I(crac)和SOC通道的分子身份及调控尚未精确确定,但最近的显著发现是鉴定出了STIM1,它被认为通过作为内质网Ca2+传感器来调控SOC和I(crac)通道,以及ORAI1(参考文献7)或CRACM1(参考文献8)——这两者都可能作为I(crac)通道或I(crac)亚基发挥作用。STIM1如何激活Ca2+内流通道以及STIM1是否构成通道孔仍然未知。在此,我们确定了STIM1依赖性激活SOC和I(crac)通道所必需的结构特征,并证明它们与参与TRPC1结合和激活的特征相同。值得注意的是,即使天然STIM1被小干扰RNA耗尽,STIM1的胞质羧基末端也足以激活SOC、I(crac)和TRPC1通道。STIM1的活性需要一个ERM结构域,该结构域介导STIM1与TRPC1、2和4的选择性结合,但不与TRPC3、6或7结合,还需要一个富含阳离子赖氨酸的区域,这对于TRPC1的门控至关重要。在组成型活性STIM1(D76A)中删除这两个区域之一会产生显性负性突变体,它们会阻断天然SOC通道、在HEK293细胞中表达的TRPC1以及在Jurkat细胞中的I(crac)。这些观察结果表明STIM1是活性的关键调节因子而非通道成分,并揭示了STIM1对SOC、I(crac)和TRPC通道激活的类似调控。
