Rajesh Bhardwaj 1,2 , Bartłomiej S Augustynek 3,2 , Ebru Ercan-Herbst 4,5 , Palanivel Kandasamy 3,2 , Matthias Seedorf 5 , Christine Peinelt 6 , Matthias A Hediger 7,2 Show Affiliations »
Abstract
BACKGROUND/AIMS: Store-operated Ca2+ entry (SOCE) through plasma membrane Ca2+ channel Orai1 is essential for many cellular processes. SOCE, activated by ER Ca2+ store-depletion, relies on the gating function of STIM1 Orai1-activating region SOAR of the ER-anchored Ca2+-sensing protein STIM1. Electrophysiologically, SOCE is characterized as Ca2+ release-activated Ca2+ current (ICRAC). A major regulatory mechanism that prevents deleterious Ca2+ overload is the slow Ca2+-dependent inactivation (SCDI) of ICRAC. Several studies have suggested a role of Ca2+/calmodulin (Ca2+/CaM) in triggering SCDI. However, a direct contribution of STIM1 in regulating Ca2+/CaM-mediated SCDI of ICRAC is as yet unclear. METHODS: The Ca2+/CaM binding to STIM1 was tested by pulling down recombinant GFP-tagged human STIM1 C-terminal fragments on CaM sepharose beads. STIM1 was knocked out by CRISPR/Cas9 technique in HEK293 cells stably overexpressing human Orai1. Store-operated Ca2+ influx was measured using Fluorometric Imaging Plate Reader and whole-cell patch clamp in cells transfected with STIM1 CaM binding mutants. The involvement of Ca2+/CaM in SCDI was investigated by including recombinant human CaM in patch pipette in electrophysiology. RESULTS: Here we identified residues Leu374/Val375 (H1) and Leu390/Phe391 (H2) within SOAR that serve as hydrophobic anchor sites for Ca2+/CaM binding. The bifunctional H2 site is critical for both Orai1 activation and Ca2+/CaM binding. Single residue mutations of Phe391 to less hydrophobic residues significantly diminished SOCE and ICRAC, independent of Ca2+/CaM. Hence, the role of H2 residues in Ca2+/CaM-mediated SCDI cannot be precisely evaluated. In contrast, the H1 site controls exclusively Ca2+/CaM binding and subsequently SCDI, but not Orai1 activation. V375A but not V375W substitution eliminated SCDI of ICRAC caused by Ca2+/CaM, proving a direct role of STIM1 in coordinating SCDI. CONCLUSION: Taken together, we propose a mechanistic model, wherein binding of Ca2+/CaM to STIM1 hydrophobic anchor residues, H1 and H2, triggers SCDI by disrupting the functional interaction between STIM1 and Orai1. Our findings reveal how STIM1, Orai1, and Ca2+/CaM are functionally coordinated to control ICRAC. © Copyright by the Author(s). Published by Cell Physiol Biochem Press.
BACKGROUND/AIMS: Store-operated Ca2+ entry (SOCE) through plasma membrane Ca2+ channel Orai1 is essential for many cellular processes. SOCE, activated by ER Ca2+ store-depletion, relies on the gating function of STIM1 Orai1 -activating region SOAR of the ER-anchored Ca2+ -sensing protein STIM1 . Electrophysiologically, SOCE is characterized as Ca2+ release-activated Ca2+ current (ICRAC ). A major regulatory mechanism that prevents deleterious Ca2+ overload is the slow Ca2+ -dependent inactivation (SCDI) of ICRAC . Several studies have suggested a role of Ca2+ /calmodulin (Ca2+ /CaM ) in triggering SCDI. However, a direct contribution of STIM1 in regulating Ca2+ /CaM -mediated SCDI of ICRAC is as yet unclear. METHODS: The Ca2+ /CaM binding to STIM1 was tested by pulling down recombinant GFP-tagged human STIM1 C-terminal fragments on CaM sepharose beads. STIM1 was knocked out by CRISPR/Cas9 technique in HEK293 cells stably overexpressing human Orai1 . Store-operated Ca2+ influx was measured using Fluorometric Imaging Plate Reader and whole-cell patch clamp in cells transfected with STIM1 CaM binding mutants. The involvement of Ca2+ /CaM in SCDI was investigated by including recombinant human CaM in patch pipette in electrophysiology. RESULTS: Here we identified residues Leu374 /Val375 (H1) and Leu390 /Phe391 (H2 ) within SOAR that serve as hydrophobic anchor sites for Ca2+ /CaM binding. The bifunctional H2 site is critical for both Orai1 activation and Ca2+ /CaM binding. Single residue mutations of Phe391 to less hydrophobic residues significantly diminished SOCE and ICRAC , independent of Ca2+ /CaM . Hence, the role of H2 residues in Ca2+ /CaM -mediated SCDI cannot be precisely evaluated. In contrast, the H1 site controls exclusively Ca2+ /CaM binding and subsequently SCDI, but not Orai1 activation. V375A but not V375W substitution eliminated SCDI of ICRAC caused by Ca2+ /CaM , proving a direct role of STIM1 in coordinating SCDI. CONCLUSION: Taken together, we propose a mechanistic model, wherein binding of Ca2+ /CaM to STIM1 hydrophobic anchor residues, H1 and H2 , triggers SCDI by disrupting the functional interaction between STIM1 and Orai1 . Our findings reveal how STIM1 , Orai1 , and Ca2+ /CaM are functionally coordinated to control ICRAC . © Copyright by the Author(s). Published by Cell Physiol Biochem Press.
Entities: CellLine
Chemical
Gene
Mutation
Species
Keywords:
STIM1; SOCE; ICRAC; SCDI; Calmodulin; Orai1
Year: 2020
PMID: 32176842 DOI: 10.33594/000000218
Source DB: PubMed Journal: Cell Physiol Biochem ISSN: 1015-8987