Abstract
The entry of extracellular Ca(2+), which is mediated by Ca(2+) release-activated Ca(2+) (CRAC) channels, is essential for T cell activation and the normal functioning of other immune cells. Although the molecular components of CRAC channels, the Orai1 pore-forming subunit and the STIM1-activating subunit have been recently identified, the gating mechanism by which Orai1 channels conduct Ca(2+) entry upon Orai1-STIM1 interaction following Ca(2+) store release remains elusive. Herein, we show that C-terminal truncations or point mutations prevented Orai1 from binding to STIM1 and subsequent channel opening. In contrast, an Orai1 mutant with an N-terminal truncation interacted with but failed to be activated by STIM1. Moreover, Orai1 channels with C-terminal disruption, but not N-terminal truncation, could be gated by fused functional domains of STIM1. Interestingly, the channel activities of Orai1 mutants carrying either an N-terminal or a C-terminal truncation were restored by a methionine mutation at the putative gating hinge, the conserved Gly-98 site in the first transmembrane segment (TM1) of Orai1. Collectively, these results support a stepwise gating mechanism of STIM1-operated Orai1 channels; the initial binding between STIM1 and the C terminus of Orai1 docks STIM1 onto the N terminus of Orai1 to initiate conformational changes of the pore-lining TM1 helix of Orai1, leading to the opening of the channel.
Highlights
STIM1-operated Orai1 channels mediate Ca2ϩ entry for T cell activation, but the gating mechanism remains elusive
The CAD of STIM1 was not recruited to the peripheral regions of the plasma membrane (PM) by the Orai1-E106A-⌬C1 or ⌬C2 mutants
An understanding of the molecular mechanisms behind ion channel gating provides decisive information that can explain the complexity of ion channel function at the cellular and system levels
Summary
STIM1-operated Orai channels mediate Ca2ϩ entry for T cell activation, but the gating mechanism remains elusive. We differentiated the contributions and roles of the N and C termini of Orai in channel activation and demonstrated the dominance of a methionine mutation at a conserved glycine site (i.e. the putative gating hinge) for channel opening with either full-length or truncated Orai. We differentiated the contributions and roles of the N and C termini of Orai in channel activation and demonstrated the dominance of a methionine mutation at a conserved glycine site (i.e. the putative gating hinge) for channel opening with either full-length or truncated Orai1 Based on these results, we propose a three-step gating model for STIM1-operated Orai channels
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