Intracellular Ca2+ signalling evoked by Ca2+ mobilizing agonists, like angiotensin II in the adrenal gland, involves the activation of inositol(1,4,5)trisphosphate(InsP3)‐mediated Ca2+ release from internal stores followed by activation of a Ca2+ influx termed capacitative calcium entry. Here we report the amino acid sequence of a functional capacitative Ca2+ entry (CCE) channel that supports inward Ca2+ currents in the range of the cell resting potential. The expressed CCE channel opens upon depletion of Ca2+ stores by InsP3 or thapsigargin, suggesting that the newly identified channel supports the CCE coupled to InsP3 signalling.
Dihydropyridines (DHPs) block the vascular smooth muscle L-type Ca2+ channel at lower concentrations than the cardiac Ca2+ channel, although their alpha 1 subunit, which binds the DHPs, is derived from the same gene. This alpha 1C gene gives rise to several splice variants, among which the alpha 1C-b variant is affected by lower concentrations of nisoldipine than the alpha 1C-a variant. Functional expression of chimeras of alpha 1C-a and alpha 1C-b subunits demonstrated that the transmembrane segment IS6 is responsible for the different dihydropyridine sensitivity. Northern blot analysis showed that transcripts coding for the IS6 segment of the alpha 1C-a subunit were expressed in heart but not in aorta, whereas the IS6 segment of the alpha 1C-b subunit was expressed predominantly in vascular smooth muscle. In situ hybridization of rat heart sections confirmed this expression pattern of IS6 alpha 1C-a and IS6 alpha 1C-b in ventricular and smooth muscle myocytes, respectively. These results suggest that the different dihydropyridine sensitivities of cardiac and vascular L-type Ca2+ channels are caused at least partially by the tissue-specific expression of alternatively spliced IS6 segments of the alpha 1C gene.
Genes related to trp (transient receptor potential) are proposed to encode store‐operated channels. We examined the ionic permeation of recombinant channels formed by stable and transient expression of the TRP homologue bCCE1 in Chinese hamster ovary (CHO) cells (CHO(CCE1)) and rat basophilic leukaemia (RBL) cells, respectively. Store‐operated currents were activated in CHO(CCE1) cells by internal dialysis of IP3 under strong buffering of intracellular Ca2+. The action of IP3 was mimicked by thapsigargin but not by IP4. With extracellular Ca2+, Na+ and Mg2+, the store‐operated currents of CHO(CCE1) rectified inwardly in the presence of internal Cs+. Outward currents were not detected below +80 mV. Identical currents were recorded with external Ba2+ and also with no external Na+ and Mg2+. In the absence of external Mg2+, the inward currents showed an anomalous mole fraction behaviour between Ca2+ and Na+. Half‐maximal inhibition of Na+ currents was observed with ≈100 nM and full block with 2‐5 μM external Ca2+. In the parental CHO(‐) cells, IP3 dialysis evoked inward currents that also displayed anomalous mole fraction behaviour between Ca2+ and Na+. However, half‐maximal block of Na+ currents required 5 times higher Ca2+ concentrations in CHO(‐) cells. Additionally, the density of Ca2+ and Na+ currents at ‐80 mV was 5 and 2 times larger in CHO(CCE1) cells, respectively. In RBL cells, dialysis of IP3 evoked store‐operated currents that showed 1.4‐fold larger densities at ‐80 mV in cells expressing bCCE1. The enhanced density of store‐operated currents in CHO(CCE1) cells and in bCCE1‐transfected RBL cells probably reflects the phenotype of CCE1. These results suggest a highly selective permeation of Ca2+ through recombinant channels formed by CCE1 either alone or in combination with endogenous channel proteins.
Summary Genomic studies have repeatedly associated variants in the gene encoding microRNA miR-137 with increased schizophrenia risk. Bioinformatic predictions suggest that miR-137 regulates schizophrenia-associated signaling pathways critical to neural development, but these predictions remain largely unvalidated. In the present study, we demonstrate that miR-137 regulates neuronal levels of p55γ, PTEN, Akt2, GSK3β, mTOR, and rictor. All are key proteins within the PI3K-Akt-mTOR pathway and act downstream of neuregulin (Nrg)/ErbB and BDNF signaling. Inhibition of miR-137 ablates Nrg1α-induced increases in dendritic protein synthesis, phosphorylated S6, AMPA receptor subunits, and outgrowth. Inhibition of miR-137 also blocks mTORC1-dependent responses to BDNF, including increased mRNA translation and dendritic outgrowth, while leaving mTORC1-independent S6 phosphorylation intact. We conclude that miR-137 regulates neuronal responses to Nrg1α and BDNF through convergent mechanisms, which might contribute to schizophrenia risk by altering neural development.
Whole-cell current recordings were used to examine the involvement of intracellular Ca2+ in the modulation of recombinant transient-receptor-potential like (TRPL) channels of Drosophila photoreceptor cells. TRPL was stably transfected in Chinese hamster ovary (CHO) cells and the expression of a calmodulin-binding protein with a molecular mass that corresponded to TRPL was demonstrated using calmodulin overlays. In cells expressing TRPL, ionic currents that were prominently outwardly rectifying were detected prior to activation of intracellular signalling pathways. The outwardly rectifying currents reversed close to 0 mV and did not occur after removal of permeant cations from the intracellular space. This suggests that TRPL forms non-selective cationic channels that appear to be constitutively active in mammalian cell lines. The TRPL channel currents were enhanced by manoeuvres that activate the phospholipase C (PLC) signalling pathway. These included activation of membrane receptors by thrombin, activation of G proteins by cell dialysis with guanosine 5'-O-(3-thiotriphosphate) (GTP[gamma-S]) and release of Ca2+ from intracellular stores by dialysis with inositol 1,4,5-trisphosphate (IP3). After complete depletion of Ca2+ stores, IP3 had no effect on TRPL currents, suggesting that IP3 does not activate recombinant TRPL channels directly. However, thapsigargin, which induces a rise of cytosolic Ca2+, increased TRPL channel currents. Cell dialysis with solutions containing various concentrations of Ca2+ enhanced TRPL currents in a dose-dependent manner (EC50=450 nM Ca2+). Conversely, chelation of cytosolic Ca2+ abolished TRPL channel currents. The present results indicate that the activity of recombinant TRPL channels expressed in mammalian cell lines is up-regulated by a rise of cytosolic Ca2+.
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