Contribution of STIM-Activated TRPC-ORAI Channels in Pulmonary Hypertension Induced by Chronic Sustained and Intermittent Hypoxia.

Sustained and intermittent hypoxia produce vasoconstriction, arterial remodeling, and hypertension in the lung. Stromal interaction molecule (STIM)-activated transient receptor potential channels (TRPC) and calcium release-activated calcium channel protein (ORAI) channels (STOC) play key roles in the progression of pulmonary hypertension in pre-clinical models of animals subjected to sustained and intermittent hypoxia. The available evidence supports the theory that oxidative stress and hypoxic inducible factors upregulate and activate STIM-activated TRPC-ORAI Ca2+ channels, contributing to the pulmonary remodeling and hypertension induced by sustained hypoxia. However, less is known about the effects of oxidative stress and hypoxic inducible factors on the modulation of STIM-activated TRPC-ORAI channels following chronic intermittent hypoxia. In this review, we examined the emerging evidence supporting the theory that oxidative stress and hypoxic inducible factors induced by intermittent hypoxia upregulate and activate STIM-activated TRPC-ORAI Ca2+ channels. In addition, we used bioinformatics tools to search public databases for the genes involved in the upregulation of STIMactivated TRPC-ORAI Ca2+ channels and compare the differential gene expression and biological processes induced by intermittent and sustained hypoxia in lung cells.

Pharmacological characterization of the calcium influx pathways involved in nitric oxide production by endothelial cells.

OBJECTIVE: To characterize the calcium influx pathways implicated in the sustained elevation of endothelial intracellular calcium concentration, required for the synthesis and release of relaxing factors. METHODS: We evaluated the effect of the newly synthesized pyrazole derivatives, described as selective inhibitors for ORAI (BTP2/Pyr2 and Pyr6) and TRPC3 (Pyr3 and Pyr10) channels, upon endothelium- and extracellular calcium-dependent relaxations stimulated by acetylcholine and thapsigargin, in pre-constricted rat thoracic aortic rings. RESULTS: Acetylcholine and thapsigargin responses were completely reverted by Pyr2 and Pyr6 (1 to 3µM). Pyr3 (0.3 to 3µM) caused a rapid reversal of acetylcholine (6.2±0.08mg.s-1) and thapsigargin (3.9±0.25mg.s-1) relaxations, whereas the more selective TRPC3 blocker Pyr10 (1 to 3µM) had no effect. The recently described TRPC4/5 selective blocker, ML204 (1 to 3µM), reverted completely acetylcholine relaxations, but minimally thapsigargin induced ones. Noteworthy, relaxations elicited by GSK1016790A (TRPV4 agonist) were unaffected by pyrazole compounds or ML204. After Pyr2 and Pyr6 pre-incubation, acetylcholine and thapsigargin evoked transient relaxations similar in magnitude and kinetics to those observed in the absence of extracellular calcium. Sodium nitroprusside relaxations as well as phenylephrine-induced contractions (denuded aorta) were not affected by any of pyrazole compounds (1 to 3µM). CONCLUSION: These observations revealed a previously unrecognized complexity in rat aorta endothelial calcium influx pathways, which result in production and release of nitric oxide. Pharmacologically distinguishable pathways mediate acetylcholine (ORAI/TRPC other than TRPC3/TRPC4 calcium-permeable channels) and thapsigargin (TRPC4 not required) induced calcium influx.

Pharmacological characterization of the calcium influx pathways involved in nitric oxide production by endothelial cells / Caracterização farmacológica das vias de influxo de cálcio envolvidas na produção de óxido nítrico por células endoteliais

ABSTRACT Objective: To characterize the calcium influx pathways implicated in the sustained elevation of endothelial intracellular calcium concentration, required for the synthesis and release of relaxing factors. Methods: We evaluated the effect of the newly synthesized pyrazole derivatives, described as selective inhibitors for ORAI (BTP2/Pyr2 and Pyr6) and TRPC3 (Pyr3 and Pyr10) channels, upon endothelium- and extracellular calcium-dependent relaxations stimulated by acetylcholine and thapsigargin, in pre-constricted rat thoracic aortic rings. Results: Acetylcholine and thapsigargin responses were completely reverted by Pyr2 and Pyr6 (1 to 3μM). Pyr3 (0.3 to 3μM) caused a rapid reversal of acetylcholine (6.2±0.08mg.s−1) and thapsigargin (3.9±0.25mg.s−1) relaxations, whereas the more selective TRPC3 blocker Pyr10 (1 to 3μM) had no effect. The recently described TRPC4/5 selective blocker, ML204 (1 to 3μM), reverted completely acetylcholine relaxations, but minimally thapsigargin induced ones. Noteworthy, relaxations elicited by GSK1016790A (TRPV4 agonist) were unaffected by pyrazole compounds or ML204. After Pyr2 and Pyr6 pre-incubation, acetylcholine and thapsigargin evoked transient relaxations similar in magnitude and kinetics to those observed in the absence of extracellular calcium. Sodium nitroprusside relaxations as well as phenylephrine-induced contractions (denuded aorta) were not affected by any of pyrazole compounds (1 to 3μM). Conclusion: These observations revealed a previously unrecognized complexity in rat aorta endothelial calcium influx pathways, which result in production and release of nitric oxide. Pharmacologically distinguishable pathways mediate acetylcholine (ORAI/TRPC other than TRPC3/TRPC4 calcium-permeable channels) and thapsigargin (TRPC4 not required) induced calcium influx.

RESUMO Objetivo: Caracterizar as vias do influxo de cálcio envolvidas no aumento sustentado da concentração intracelular de cálcio na célula endotelial, essencial para a síntese e a liberação de fatores relaxantes. Métodos: Analisamos o efeito de derivados pirazólicos sintetizados recentemente, descritos como inibidores seletivos para canais ORAI (BTP2/Pyr2 e Pyr6) e TRPC3 (Pyr3 e Pyr10), nos relaxamentos dependentes de endotélio e cálcio extracelular, produzidos por acetilcolina e tapsigargina, em anéis pré-contraídos da aorta torácica de rato. Resultados: As respostas de acetilcolina e tapsigargina foram completamente revertidas por Pyr2 e Pyr6 (1 a 3μM). Pyr3 (0,3 a 3μM) produziu reversão rápida dos relaxamentos de acetilcolina (6,2±0,08mg.s−1) e tapsigargina (3,9±0,25mg.s−1), enquanto o bloqueador mais seletivo para TRPC3, Pyr10 (1 a 3μM), não apresentou efeito. ML204 (1 a 3μM), bloqueador seletivo de TRPC4, descrito há pouco tempo, reverteu os relaxamentos induzidos por acetilcolina de forma completa, mas afetou minimamente aqueles produzidos por tapsigargina. Os derivados pirazólicos ou ML204 não afetaram os relaxamentos estimulados com GSK1016790A (TRPV4-agonista). Ainda, após pré-incubação com Pyr2 e Pyr6, acetilcolina e tapsigargina provocaram relaxamentos transitórios semelhantes em magnitude e cinética àqueles observados na ausência de cálcio extracelular. Os relaxamentos do nitroprussiato de sódio e as contrações induzidas pela fenilefrina (aorta sem endotélio) não foram afetados pelos compostos pirazólicos (1 a 3μM). Conclusão: Essas observações revelaram uma complexidade desconhecida das vias de influxo de cálcio no endotélio da aorta de rato, que resultam na produção e na liberação de óxido nítrico. Vias distinguíveis farmacologicamente medeiam o influxo estimulado por acetilcolina (ORAI TRPC, diferentes de TRPC3 TRPC4) e tapsigargina (TRPC4 não requerido).

STIM-TRP Pathways and Microdomain Organization: Auxiliary Proteins of the STIM/Orai Complex.

The basic paradigm of a mechanism for calcium influx triggered after a reduction on calcium store content implies a sensor of calcium concentration on the endoplasmic reticulum (the stores) and a calcium channel immersed on the plasma membrane. These two basic components are STIM and Orai, the most fundamental and minimal molecular constituents of the store-operated calcium entry mechanism. However, even when minimal components can be reduced to these two proteins, the intricate process involved in approximating two cellular membranes (endoplasmic reticulum, ER and plasma membrane, PM) require the participation of several other components, many of which remain unidentified to this date. Here we review several of the proteins identified as constituents of the so-called store-operated calcium influx complex (SOCIC) and discuss their role in modulating this complex phenomenon.