The Third Transmembrane Segment of Orai1 Protein Modulates Ca2+ Release-activated Ca2+ (CRAC) Channel Gating and Permeation Properties

Ma-Khin Win Yee,Bernard Ribalet,Sonal Srikanth,Yousang Gwack

doi:10.1074/jbc.m111.265884

Ma-Khin Win Yee, Bernard Ribalet + Show 2 more

Open Access

https://doi.org/10.1074/jbc.m111.265884

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Abstract

Orai1, the pore subunit of Ca(2+) release-activated Ca(2+) channels, has four transmembrane segments (TMs). The first segment, TMI, lines the pore and plays an important role in channel activation and ion permeation. TMIII, on the other hand, does not line the pore but still regulates channel gating and permeation properties. To understand the role of TMIII, we have mutated and characterized several residues in this domain. Mutation of Trp-176 to Cys (W176C) and Gly-183 to Ala (G183A) had dramatic effects. Unlike wild-type channels, which exhibit little outward current and are activated by STIM1, W176C mutant channels exhibited a large outward current at positive potentials and were constitutively active in the absence of STIM1. G183A mutant channels also exhibited substantial outward currents but were active only in the presence of 2-aminoethoxydiphenyl borate (2-APB), irrespective of STIM1. With W176C mutant channels inward, monovalent currents were blocked by Ca(2+) with a high affinity similar to the wild type, but the Ca(2+)-dependent blocking of outward currents differed in the two cases. Although a 50% block of the WT outward current required 250 μm Ca(2+), more than 6 mm was necessary to have the same effect on W176C mutant channels. In the presence of extracellular Ca(2+), W176C and G183A outward currents developed slowly in a voltage-dependent manner, whereas they developed almost instantaneously in the absence of Ca(2+). These changes in permeation and gating properties mimic the changes induced by mutations of Glu-190 in TMIII and Asp-110/Asp-112 in the TMI/TMII loop. On the basis of these data, we propose that TMIII maintains negatively charged residues at or near the selectivity filter in a conformation that facilitates Ca(2+) inward currents and prevents outward currents of monovalent cations. In addition, to controlling selectivity, TMIII may also stabilize channel gating in a closed state in the absence of STIM1 in a Trp-176-dependent manner.

Highlights

Store-operated Ca2ϩ entry (SOCE)3 via the Ca2ϩ releaseactivated-Ca2ϩ (CRAC) channels requires interaction of the pore-forming Orai1 protein with the endoplasmic reticulum (ER) -membrane bound luminal Ca2ϩ sensor, STIM1
Analysis of TMIII Mutants of Orai1 for Store-operated Ca2ϩ Entry—To determine the role of TMIII in the permeation properties of CRAC channels, we mutated a series of residues in TMIII and examined their properties (Fig. 1, A and B)
All the mutants showed comparable expression levels as judged by immunoblotting (Fig. 1C) and showed plasma membrane localization similar to wild-type Orai1 (Fig. 1D and supplemental Fig. 1). These studies suggested that the Ser-179 and Gly-183 residues play an important role in channel gating and that the W176C mutant may be constitutively active and independent from store-depletion

Summary

Introduction

Store-operated Ca2ϩ entry (SOCE)3 via the Ca2ϩ releaseactivated-Ca2ϩ (CRAC) channels requires interaction of the pore-forming Orai1 protein with the endoplasmic reticulum (ER) -membrane bound luminal Ca2ϩ sensor, STIM1. Together these data suggest that large outward currents observed with W176C mutant channels may result from a change in CRAC channel pore affinity for extracellular Ca2ϩ.

Results

Conclusion