Exercício e restrição alimentar aumentam o RNAm de proteínas do trânsito de Ca2+ miocárdico em ratos / Upregulation of mRNA myocardium calcium handling in rats submitted to exercise and food restriction / Ejercicio y restricción alimenticia aumentan el rnam de proteínas del tránsito de Ca2+ miocárdico en ratones

FUNDAMENTO: Treinamento físico (TF) aumenta a sensibilidade dos hormônios tireoidianos (HT) e a expressão gênica de estruturas moleculares envolvidas no movimento intracelular de cálcio do miocárdio, enquanto a restrição alimentar (RIA) promove efeitos contrários ao TF. OBJETIVO: Avaliar os efeitos da associação TF e RIA sobre os níveis plasmáticos dos HT e a produção de mRNA dos receptores HT e estruturas moleculares do movimento de cálcio do miocárdio de ratos. MÉTODOS: Utilizaram-se ratos Wistar Kyoto divididos em: controle (C, n = 7), RIA (R50, n = 7), exercício físico (EX, n = 7) e exercício físico + RIA (EX50, n = 7). A RIA foi de 50 por cento e o TF foi natação (1 hora/dia, cinco sessões/semana, 12 semanas consecutivas). Avaliaram-se as concentrações séricas de triiodotironina (T3), tiroxina (T4) e hormônio tireotrófico (TSH). O mRNA da bomba de cálcio do retículo sarcoplasmático (SERCA2a), fosfolamban (PLB), trocador Na+/Ca+2 (NCX), canal lento de cálcio (canal-L), rianodina (RYR), calsequestrina (CQS) e receptor de HT (TRα1 e TRβ1) do miocárdio foram avaliados por reação em cadeia da polimerase (PCR) em tempo real. RESULTADOS: RIA reduziu o T4, TSH e mRNA do TRα1 e aumentou a expressão da PLB, NCX e canal-L. TF aumentou a expressão do TRβ1, canal-L e NCX. A associação TF e RIA reduziu T4 e TSH e aumentou o mRNA do TRβ1, SERCA2a, NCX, PLB e correlação do TRβ1 com a CQS e NCX. CONCLUSÃO: Associação TF e RIA aumentou o mRNA das estruturas moleculares cálcio transiente, porém o eixo HT-receptor não parece participar da transcrição gênica dessas estruturas.

BACKGROUND: Chronic exercise and food restriction (FR) have directionally opposite changes in transcription of molecular structures of calcium handling and thyroid hormone (TH) status. OBJECTIVE: Evaluate the association of chronic exercise and FR on serum thyroid hormones and gene transcription of molecular structures of intracellular calcium transients and thyroid receptors in myocardium of rats. METHODS: Male Wistar Kyoto rats, divided into two groups: control (C, n = 7), FR (R50, n = 7), chronic exercise (EX, n = 7) and chronic exercise + FR (EX50, n = 7). FR was of 50 percent and exercise was swimming (1 hour/day, 5 days/week, during 12 weeks). Serum concentrations of T3, T4 and TSH were determined. The mRNA gene expression of the sarcoplasmatic reticulum calcium pump (SERCA2a), phospholamban (PLB), Na+/Ca+2 exchanger (NCX), calcium channel L-type (L-channel), ryanodine (RYR), calsequestrin (CQS) and HT receptor (TRα1 and TRβ1) of the myocardium was performed by PCR real-time. RESULTS: FR reduced serum levels of T4 and TSH and TRα1 mRNA and increased the expression of PLB, NCX and L-channel. Exercise increased the TRβ1 receptor, L-channel and NCX. The association of exercise and FR reduced plasma T4 and TSH, TRβ1 mRNA increase, SERCA2a, NCX and PLB, and there was a significant correlation of TRβ1 with CQS and NXC. CONCLUSION: Chronic exercise and food restriction increased the mRNA of transient Ca2+ proteins; however, TH-receptor axis cannot participate in the transcription of mRNA of myocardial calcium transient proteins.

FUNDAMENTO: Entrenamiento físico (EF) aumenta la sensibilidad de las hormonas tiroideas (HT) y la expresión génica de estructuras moleculares envueltas en el movimiento intracelular de calcio del miocardio, mientras que la restricción alimenticia (RA) promueve efectos contrarios al EF. OBJETIVO: Evaluar los efectos de la asociación EF y RA sobre los niveles plasmáticos de los HT y la producción de ARNm de los receptores HT y estructuras moleculares del movimiento de calcio del miocardio de ratones. MÉTODOS: Se utilizaron ratones Wistar Kyoto divididos en: control (C, n = 7), RA (R50, n = 7), ejercicio físico (EX, n = 7) y ejercicio físico + RA (EX50, n = 7). La RA fue de 50 por ciento y el EF fue natación (1 hora/día, cinco sesiones/semana, 12 semanas consecutivas). Se evaluaron las concentraciones séricas de triyodotironina (T3), tiroxina (T4) y hormona tireotrófico (TSH). El ARNm de la bomba de calcio del retículo sarcoplasmático (SERCA2a), fosfolamban (PLB), intercambiador Na+/Ca+2 (NCX), canal lento de calcio (canal-L), rianodina (RYR), calsequestrina (CQS) y receptor de HT (TRα1 y TRβ1) del miocardio fueron evaluados por reacción en cadena de la polimerasa (PCR) en tiempo real. RESULTADOS: RA redujo el T4, TSH y ARNm del TRα1 y aumentó la expresión de la PLB, NCX y canal-L. EF aumentó la expresión del TRβ1, canal-L y NCX. La asociación EF y RA redujo T4 y TSH y aumentó el ARNm del TRβ1, SERCA2a, NCX, PLB y correlación del TRβ1 con la CQS y NCX. CONCLUSIÓN: Asociación EF y RA aumentó el ARNm de las estructuras moleculares calcio transiente, sin embargo el eje HT-receptor no parece participar de la transcripción génica de esas estructuras.

Calcium Uptake and Release through Sarcoplasmic Reticulum in the Inferior Oblique Muscles of Patients with Inferior Oblique Overaction

We characterized and compared the characteristics of Ca2+ movements through the sarcoplasmic reticulum of inferior oblique muscles in the various conditions including primary inferior oblique overaction (IOOA), secondary IOOA, and controls, so as to further understand the pathogenesis of primary IOOA. Of 15 specimens obtained through inferior oblique myectomy, six were from primary IOOA, 6 from secondary IOOA, and the remaining 3 were controls from enucleated eyes. Ryanodine binding assays were performed, and Ca2+ uptake rates, calsequestrins and SERCA levels were determined. Ryanodine bindings and sarcoplasmic reticulum Ca2+ uptake rates were significantly decreased in primary IOOA (p < 0.05). Western blot analysis conducted to quantify calsequestrins and SERCA, found no significant difference between primary IOOA, secondary IOOA, and the controls. Increased intracellular Ca2+ concentration due to reduced sarcoplasmic reticulum Ca2+ uptake may play a role in primary IOOA.

The interaction of ryanoids with individual ryanodine receptor channels

Ryanodine binds with high affinity and specificity to a class of Ca2+-release channels known as ryanodine receptors (RyR). The interaction with RyR results in a dramatic alteration in function with open probability (Po) increasing markedly and rates of ion translocation modified. We have investigated the features of ryanodine that govern the interaction of the ligand with RyR and the mechanisms underlying the subsequent alterations in function by monitoring the effects of congeners and derivatives of ryanodine (ryanoids) on individual RyR2 channels. While the interaction of all tested ryanoids results in an increased Po, the amplitude of the modified conductance state depends upon the structure of the ryanoid. We propose that different rates of cation translocation observed in the various RyR-ryanoid complexes represent different conformations of the channel stabilized by specific conformers of the ligand. On the time scale of a single channel experiment ryanodine binds irreversibly to the channel. However, alterations in structure yield some ryanoids with dissociation rate constants orders of magnitude greater than ryanodine. The probability of occurrence of the RyR-ryanoid complex is sensitive to trans-membrane voltage, with the vast majority of the influence of potential arising from a voltage-driven alteration in the affinity of the ryanoid-binding site.

Caffeine causes glycerophosphorylcholine accumulation through ryanodine-inhibitable increase of cellular calcium and activation of phospholipase A2 in cultured MDCK cells

Glycerophosphrylocholine (GPC) is a renal medullary compatible organic osmolyte that is derived from choline via phosphatidylcholine, which is catalyzed in part by phospholipase A2 (PLA2) and its degradation by GPC: choline phosphodiesterase (GPC: choline PDE). We found that caffeine elevated intracellular free calcium ([Ca2+]i) and GPC level in cultured MDCK cells, canine kidney epithelial cells, and propose a possible biochemical mechanism. When MDCK cells were incubated for 3 h with 1 to 10 mM caffeine, cellular GPC was elevated in a dose-dependent manner, and this occurred independently of the extracellular osmolality. Caffeine stimulated the rate of [14C]choline incorporation into [14C]GPC and PLA2 activity. Whereas, GPC: choline PDE activity was accompanied by less of increase. These enzyme changes demonstrate the increased net synthesis of MDCK GPC. In order to identify what triggers the PLA2 activation, [Ca2+]i was measured by using a fluorescence dye, Fura-2. Caffeine (10 mM) resulted in a typical transient increase in MDCK [Ca2+]i concentration, and this increase was greatly inhibited by pretreatment of MDCK cells with 10 mM ryanodine for 5 min. Ryanodine (10 mM) also inhibited the caffeine-induced stimulation of PLA2 activity. These findings provide the first evidence that caffeine in MDCK cells causes a ryanodine-inhibitable increase of [Ca2+]i and PLA2 activity, resulting in cellular GPC accumulation.