Abstract
STIM1 has been recently identified as a Ca(2+) sensor in endoplasmic reticulum (ER) and an initiator of the store-operated Ca(2+) entry (SOCE) pathway, but the mechanism of SOCE activation remains controversial. Here we focus on the early ER-delimited steps of the SOCE pathway and demonstrate that STIM1 is critically involved in initiating of production of calcium influx factor (CIF), a diffusible messenger that can deliver the signal from the stores to plasma membrane and activate SOCE. We discovered that CIF production is tightly coupled with STIM1 expression and requires functional integrity of its intraluminal sterile alpha-motif (SAM) domain. We demonstrate that 1) molecular knockdown or overexpression of STIM1 results in corresponding impairment or amplification of CIF production and 2) inherent deficiency in the ER-delimited CIF production and SOCE activation in some cell types can be a result of their deficiency in STIM1 protein; expression of a wild-type STIM1 in such cells was sufficient to fully rescue their ability to produce CIF and SOCE. We found that glycosylation sites in the ER-resident SAM domain of STIM1 are essential for initiation of CIF production. We propose that after STIM1 loses Ca(2+) from EF hand, its intraluminal SAM domain may change conformation, and via glycosylation sites it can interact with and activate CIF-producing machinery. Thus, CIF production appears to be one of the earliest STIM1-dependent events in the ER lumen, and impairment of this process results in impaired SOCE response.
Highlights
Very little is known about the molecular mechanism of Calcium influx factor (CIF) production in the stores, but the mechanism of CIF-induced activation of SOCE has been identified [32]; when released from the stores, CIF was shown to trigger a plasma membrane-delimited cascade of reactions that start with CIF-induced displacement of inhibitory calmodulin from a plasma membrane variant of Ca2ϩ-independent phospholipase A2, which transduces the signal to storeoperated channels leading to their opening and activation of SOCE
Neuronal cell lines, vascular SMC, and X. laevis oocytes were used as complementary models for a wide range of experimental approaches [32, 33], which allowed us to carefully assess the initial steps in the SOCE pathway and the impact of molecular manipulation with STIM1 on CIF production and SOCE activation
Molecular down-regulation of STIM1 resulted in significant reduction in the amount of STIM1 protein and caused inhibition of TG-induced Ca2ϩ influx in SMC (Figs. 1 and 2b). This result is fully consistent with reports in nonexcitable cell types [14, 16], in which the presence of STIM1 is thought to be absolutely required for its conformational coupling with and activation of plasma membrane channels
Summary
Molecular Down-regulation of Endogenous STIM1—Primary SMC were used for studies of the role of endogenous STIM1 on SOCE (Ca2ϩ entry) and CIF production, showed the highest transfection rate (above 90%), and provided a well described native cell model of SOCE. Neuronal cell lines, vascular SMC, and X. laevis oocytes were used as complementary models for a wide range of experimental approaches [32, 33], which allowed us to carefully assess the initial steps in the SOCE pathway and the impact of molecular manipulation with STIM1 on CIF production and SOCE activation.
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