Fasting/Refeeding Cycles Prevent Myocardial Dysfunction and Morphology Damage in the Spontaneously Hypertensive Rats / Ciclos de Jejum/Realimentação Previnem Disfunção Miocárdica e Danos Morfológicos em Ratos Espontaneamente Hipertensos

Abstract Background: Caloric restriction is known to impair the cardiac function and morphology in hypertrophied hearts of spontaneously hypertensive rats (SHR); however, the influence of fasting/refeeding (RF) is unknown. Objective: To investigate the fasting/refeeding approach on myocardial remodeling and function. In addition, the current study was designed to bring information regarding the mechanisms underlying the participation of Ca2+ handling and b-adrenergic system. Methods: Sixty-day-old male SHR rats were submitted to food ad libitum (C), 50% food restriction (R50) or RF cycles for 90 days. Cardiac remodeling was assessed by ultrastructure analysis and isolated papillary muscle function. The level of significance considered was 5% (a = 0.05). Results: The RF rats presented lower cardiac atrophy than R50 in relation to C rats. The C rats increased weight gain, R50 maintained their initial body weight and RF rats increased and decreased weight during RF. The RF did not cause functional impairment because the isotonic and isometric parameters showed similar behavior to those of C. The isotonic and isometric cardiac parameters were significantly elevated in RF rats compared to R50 rats. In addition, the R50 rats had cardiac damage in relation to C for isotonic and isometric variables. While the R50 rats showed focal changes in many muscle fibers, the RF rats displayed mild alterations, such as loss or disorganization of myofibrils. Conclusion: Fasting/refeeding promotes cardiac beneficial effects and attenuates myocardial injury caused by caloric restriction in SHR rats, contributing to reduce the cardiovascular risk profile and morphological injuries. Furthermore, RF promotes mild improvement in Ca2+ handling and b-adrenergic system.

Resumo Fundamento: A restrição calórica compromete a função e a morfologia cardíacas em corações hipertrofiados de ratos espontaneamente hipertensos (SHR). No entanto, a influência de ciclo de jejum/Realimentação é desconhecida. Objetivo: Investigar o efeito de ciclos de jejum/realimentação sobre a remodelação e função miocárdica. Além disso, o presente estudo foi desenhado para avaliar os mecanismos subjacentes à participação do trânsito de cálcio (Ca+2) e sistema beta-adrenérgico. Métodos: Neste estudo, SHR machos de 60 dias de idade foram submetidos a alimento ad libitum (grupo C), 50% de restrição alimentar (grupo R50) ou ciclos de RF (grupo RF) por 90 dias. A remodelação cardíaca foi avaliada por meio da análise ultraestrutural e função do músculo papilar isolado. Adotou-se o nível de significância de 5% (a = 0,05). Resultados: Os ratos do grupo RF apresentaram menor atrofia cardíaca do que os do grupo R50 em relação aos do grupo C. Os ratos do grupo C aumentaram peso corporal, os ratos do grupo R50 mantiveram seu peso corporal inicial e os ratos do grupo RF aumentaram e reduziram seu peso durante o ciclo RF. O ciclo RF não causou comprometimento funcional, pois os parâmetros isotônicos e isométricos apresentaram comportamento similar aos dos ratos do grupo C. Os parâmetros cardíacos isotônicos e isométricos mostraram-se significativamente elevados nos ratos do grupo RF em comparação aos dos ratos do grupo R50. Além disso, os ratos do grupo R50 apresentaram dano cardíaco em comparação aos ratos do grupo C quanto às variáveis isotônicas e isométricas. Os ratos do grupo R50 apresentaram alterações focais em muitas fibras musculares, enquanto os ratos do grupo RF apresentaram leves alterações, como perda ou desorganização de miofibrilas. Conclusão: Ciclos de Jejum/Realimentação promovem efeitos benéficos cardíacos e atenuam o dano miocárdico causado por restrição calórica em SHR, contribuindo para reduzir o risco cardiovascular e os danos morfológicos. Além disso, o ciclo de jejum/realimentação promove leve melhora do trânsito do Ca2+ e do sistema beta-adrenérgico.

Cardiac, Metabolic and Molecular Profiles of Sedentary Rats in the Initial Moment of Obesity / Perfis Cardíaco, Metabólico e Molecular de Ratos Sedentários no Momento Inicial da Obesidade

Abstract Background: Different types of high-fat and/or high-energy diets have been used to induce obesity in rodents. However, few studies have reported on the effects observed at the initial stage of obesity induced by high-fat feeding on cardiac functional and structural remodelling. Objective: To characterize the initial moment of obesity and investigate both metabolic and cardiac parameters. In addition, the role of Ca2+ handling in short-term exposure to obesity was verified. Methods: Thirty-day-old male Wistar rats were randomized into two groups (n = 19 each): control (C; standard diet) and high-fat diet (HF, unsaturated high-fat diet). The initial moment of obesity was defined by weekly measurement of body weight (BW) complemented by adiposity index (AI). Cardiac remodelling was assessed by morphological, histological, echocardiographic and papillary muscle analysis. Ca2+ handling proteins were determined by Western Blot. Results: The initial moment of obesity occurred at the 3rd week. Compared with C rats, the HF rats had higher final BW (4%), body fat (20%), AI (14.5%), insulin levels (39.7%), leptin (62.4%) and low-density lipoprotein cholesterol (15.5%) but did not exhibit alterations in systolic blood pressure. Echocardiographic evaluation did not show alterations in cardiac parameters. In the HF group, muscles were observed to increase their +dT/dt (C: 52.6 ± 9.0 g/mm2/s and HF: 68.0 ± 17.0 g/mm2/s; p < 0.05). In addition, there was no changes in the cardiac expression of Ca2+ handling proteins. Conclusion: The initial moment of obesity promotes alterations to hormonal and lipid profiles without cardiac damage or changes in Ca2+ handling.

Resumo Fundamentos: Diferentes tipos de dietas hiperlipídicas e/ou hipercalóricas têm sido usados para induzir obesidade em roedores. No entanto, poucos estudos relataram os efeitos da obesidade induzida por dieta hiperlipídica em sua fase inicial sobre a remodelação cardíaca funcional e estrutural. Objetivo: Caracterizar o momento inicial da obesidade e investigar parâmetros metabólicos e cardíacos. Além disso, analisar o papel do trânsito de Ca+2 em curtos períodos de exposição à obesidade. Métodos: Ratos Wistar com idade de 30 dias foram distribuídos aleatoriamente em dois grupos (n = 19 em cada grupo): controle (C, dieta padrão) e dieta hiperlipídica (HL, dieta rica em gordura insaturada). O momento inicial da obesidade foi definido por medidas semanais do peso corporal, complementadas pelo índice de adiposidade (IA). A remodelação cardíaca foi avaliada por análise morfológica, histológica, ecocardiográfica e funcional dos músculos papilares. Proteínas envolvidas no trânsito de Ca2+ foram determinadas por Western Blot. Resultados: O momento inicial da obesidade ocorreu na terceira semana. Em comparação aos ratos C, os animais HL apresentaram maior peso corporal final (4%), gordura corporal (20%), IA (14,5%), níveis de insulina (39,7%), leptina (62,4%) e lipoproteína de baixa densidade (15,5%), mas não apresentaram alterações na pressão sistólica. A avaliação ecocardiográfica não mostrou alterações nos parâmetros cardíacos. No grupo HL, observou-se um aumento no +dT/dt (C: 52,6 ± 9,0 g/mm2/s e HL: 68,0 ± 17,0 g/mm2/s; p < 0,05) muscular. Além disso, não houve alterações na expressão cardíaca de proteínas envolvidas no trânsito de Ca2+. Conclusão: O momento inicial da obesidade promove alterações nos perfis hormonais e lipídicos sem causar danos cardíacos ou mudanças no trânsito de Ca2+.

Remodelamento miocárdico após grandes infartos converte potenciação pós-pausa em decaimento da força em ratos / Myocardial remodeling after large infarcts in rat converts post rest-potentiation in force decay / Miocárdio remodelado después de grandes infartos en ratas convierte potenciación post-pausa en disminucion de la fuerza

FUNDAMENTO: A Contração Pós-Repouso (CPR) do músculo cardíaco fornece informações indiretas sobre a manipulação de cálcio intracelular. OBJETIVO: Nosso objetivo foi estudar o comportamento da CPR e seus mecanismos subjacentes em camundongos com infarto do miocárdio. MÉTODOS: Seis semanas após a oclusão coronariana, a contratilidade dos Músculos Papilares (MP) obtidos a partir de camundongos submetidos à cirurgia sham (C, n = 17), com infarto moderado (MMI, n = 10) e grande infarto (LMI, n = 14), foi avaliada após intervalos de repouso de 10 a 60 segundos antes e depois da incubação com cloreto de lítio (Li+) em substituição ao cloreto de sódio ou rianodina (Ry). A expressão proteica de SR Ca(2+)-ATPase (SERCA2), trocador Na+/Ca2+ (NCX), fosfolambam (PLB) e fosfo-Ser (16)-PLB foi analisada por Western blotting. RESULTADOS: Os camundongos MMI apresentaram potenciação de CPR reduzida em comparação aos camundongos C. Em oposição à potenciação normal para camundongos C, foram observadas degradações de força pós-repouso nos músculos de camundongos LMI. Além disso, a Ry bloqueou a degradação ou potenciação de PRC observada em camundongos LMI e C; o Li+ inibiu o NCX e converteu a degradação em potenciação de CPR em camundongos LMI. Embora os camundongos MMI e LMI tenham apresentado diminuição no SERCA2 (72 ± 7% e 47 ± 9% de camundongos controle, respectivamente) e expressão protéica de fosfo-Ser16-PLB (75 ± 5% e 46 ± 11%, respectivamente), a superexpressão do NCX (175 ± 20%) só foi observada nos músculos de camundongos LMI. CONCLUSÃO: Nossos resultados mostraram, pela primeira vez, que a remodelação miocárdica pós-IAM em camundongos pode mudar a potenciação regular para degradação pós-repouso, afetando as proteínas de manipulação de Ca(2+) em miócitos.

BACKGROUND: Post-rest contraction (PRC) of cardiac muscle provides indirect information about the intracellular calcium handling. OBJECTIVE: Our aim was to study the behavior of PRC, and its underlying mechanisms, in rats with myocardial infarction. METHODS: Six weeks after coronary occlusion, the contractility of papillary muscles (PM) obtained from sham-operated (C, n=17), moderate infarcted (MMI, n=10) and large infarcted (LMI, n=14) rats was evaluated, following rest intervals of 10 to 60 seconds before and after incubation with lithium chloride (Li+) substituting sodium chloride or ryanodine (Ry). Protein expression of SR Ca(2+)-ATPase (SERCA2), Na+/Ca2+ exchanger (NCX), phospholamban (PLB) and phospho-Ser(16)-PLB were analyzed by Western blotting. RESULTS: MMI exhibited reduced PRC potentiation when compared to C. Opposing the normal potentiation for C, post-rest decays of force were observed in LMI muscles. In addition, Ry blocked PRC decay or potentiation observed in LMI and C; Li+ inhibited NCX and converted PRC decay to potentiation in LMI. Although MMI and LMI presented decreased SERCA2 (72±7% and 47±9% of Control, respectively) and phospho-Ser16-PLB (75±5% and 46±11%, respectively) protein expression, overexpression of NCX (175±20%) was only observed in LMI muscles. CONCLUSION: Our results showed, for the first time ever, that myocardial remodeling after MI in rats may change the regular potentiation to post-rest decay by affecting myocyte Ca(2+) handling proteins.

FUNDAMENTO: La Contracción pos pausa (CPP) del músculo cardíaco provee informaciones indirectas sobre la manejo del calcio intracelular. OBJETIVO: Nuestro objetivo fue estudiar el comportamiento de la CPP y sus mecanismos subyacentes en Ratas con infarto de miocardio. MÉTODOS: Seis semanas después de la oclusión coronaria, la contractilidad de los Músculos Papilares (MP) obtenidos a partir de Ratas sometidos a falsa cirurgia (C, n = 17), con infarto moderado (MMI, n = 10) y gran infarto (LMI, n = 14), fue evaluada después de pausas de estímulos de 10 a 60 segundos antes y después de la incubación con cloruro de litio (Li+) en substitución del cloruro de sodio o rianodina (Ry). La expresión proteica de SR Ca(2+)-ATPasa (SERCA2), intercambiador Na+/Ca2+ (NCX), fosfolamban (PLB) y fosfo-Ser (16)-PLB fue analizada por Western blotting. RESULTADOS: Los Ratas MMI presentaron potenciación de CPP reducida en comparación a los Ratas C. En oposición a la potenciación normal para Ratas C, fueron observadas decaimientos de fuerza post-reposo en los músculos de Ratas LMI. Además de eso, la Ry bloqueó la decaimiento o potenciación de PRC observada en Ratas LMI y C; el Li+ inhibió el NCX y convirtió la decaimiento en potenciación de CPP en Ratas LMI. Aunque los Ratas MMI y LMI hayan presentado disminución en el SERCA2 (72 ± 7% y 47 ± 9% de Ratas control, respectivamente) y expresión proteica de fosfo-Ser16-PLB (75 ± 5% y 46 ± 11%, respectivamente), la superexpresión del NCX (175 ± 20%) sólo fue observada en los músculos de Ratas LMI. CONCLUSIÓN: Nuestros resultados mostraron, por primera vez, que el remodelado miocárdico post-IAM en Ratas puede cambiar la potenciación regular para decaimiento post-reposo, afectando las proteínas de manejo del Ca(2+) en miocitos.

Liberacion de endotelina-1 por angiotensina ii en miocitos cardiacos aislados / Angiotensin II-induced endothelin-1 release in cardiac myocytes

Muchos de los efectos de la angiotensina II (Ang II) son mediados en realidad por la acción de endotelina (ET) endógena liberada y/o producida en respuesta a la Ang II. En este trabajo evaluamos la interacción Ang II/ET-1, sus consecuencias en la contractilidad cardíaca y el papel de las especies reactivas del oxígeno (EROs). Se usaron cardiomiocitos aislados de gato. La Ang II, 1 nM, produjo un efecto inotrópico positivo (EIP) de 31.8±3.8% que fue cancelado por inhibición de los receptores AT1, de los receptores de ET, del intercambiador Na+/H+ (NHE), del modo inverso del intercambiador Na+/Ca2+ (NCX) o por el secuestro de EROs. La Ang II, 100 nM, produjo un EIP de 70.5±7.6% que fue cancelado por inhibición de los receptores AT1y bloqueado en parte por inhibición de los receptores de ET, del NHE, del modo inverso del NCX o por el secuestro de EROs. La Ang II, 1 nM, incrementó el ARNm de la preproET-1 lo cual fue anulado por el bloqueo de los receptores AT1. Los resultados permiten concluir que el EIP de la Ang II es debido a la acción de la ET-1 endógena liberada/formada por la Ang II. La ET-1 produce: estimulación del NHE, activación del modo inverso del NCX y un consecuente EIP. Dentro de esta cascada también participarían los EROs.

Many of the effects thought to be due to angiotensin II (Ang II) are due to the release/formation of endothelin (ET). We tested whether Ang II elicits its positive inotropic effect (PIE) by the action of endogenous ET-1 and the role played by the reactive oxygen species (ROS) in this mechanism. Experiments were performed in cat isolated ventricular myocytes in which sarcomere shortening (SS) was measured to asses contractility after pharmacological interventions and the effect of Ang II on inotropism were analyzed. Ang II 1 nM increased SS by 31.8±3.8% (p<0.05). This PIE was cancelled by AT1 receptor blockade, by ET-1 receptors blockade, by Na+/H+ exchanger (NHE) inhibition, by reverse mode Na+/Ca2+ exchanger (NCX) blockade or by ROS scavenging. Ang II 100 nM increases SS by 70.5±7.6% (p<0.05). This PIE was completely abolished by AT1 receptors blockade and were partially bocked by ET-1 receptors blockade, by NHE inhibition, by reverse mode NCX blockade or by ROS scavenging. Ang II increased preproET-1 mRNA, effect that was blunted by AT1 receptors blockade. We conclude that Ang II induces (through its AT1 receptor) release/formation of ET-1, which acting in autocrine fashion on ET receptors of the isolated myocytes increases inotropism through NHE stimulation and NCX reverse mode activation. The participation of ROS is involved is this chain of events.

pH-dependent modulation of intracellular free magnesium ions with ionselective electrodes in papillary muscle of guinea pig

A change in pH can alter the intracellular concentration of electrolytes such as intracellular Ca2+ and Na+ ([Na+]i) that are important for the cardiac function. For the determination of the role of pH in the cardiac magnesium homeostasis, the intracellular Mg2+ concentration ([Mg2+]i), membrane potential and contraction in the papillary muscle of guinea pigs using ion-selective electrodes changing extracellular pH ([pH]o) or intracellular pH ([pH]i) were measured in this study. A high CO2-induced low [pH]o causes a significant increase in the [Mg2+]i and [Na+]i, which was accompanied by a decrease in the membrane potential and twitch force. The high [pH]o had the opposite effect. These effects were reversible in both the beating and quiescent muscles. The low [pH]o-induced increase in [Mg2+]i occurred in the absence of [Mg2+]o. The [Mg2+]i was increased by the low [pH]i induced by propionate. The [Mg2+]i was increased by the low [pH]i induced by NH4Cl-prepulse and decreased by the recovery of [pH]i induced by the removal of NH4Cl. These results suggest that the pH can modulate [Mg2+]i with a reverse relationship in heart, probably by affecting the intracellular Mg2+ homeostasis, but not by Mg2+ transport across the sarcolemma.

Control of rest potentiation in ventricular myocardium by the Na-Ca exchange mechanism

To reinvestigate the possible regulating activity of the Na-Ca exchange mechanism on the rest potentiation phenomenon post rest contraction force development was studied in isometrically contracting rat papillary muscles, stimulated at a rate of 30/min and submitted to pauses varying from 5 to 60 seconds. The Na-Ca exchange activity was analysed using the relationship between the amplitude of the first post rest contractions and the steady state control contractions (relative potentiation) and by the changes of internal Na that are known to affect the Na-Ca exchange activity. Maneuvers that increased the internal Na concentration as high rate of stimulation and high external Na produced an increase of the relative potentiation. This was seen when stimulation rate was changed from 30/min to 60/min, even in low extracellular. Na concentration. On the other hand, the blockade of the fast Na channel by propafenone and the reduction of the external Na concentration, that are known to reduce internal Na, diminished the relative potentiation. These results suggest that the activity of the Na/Ca exchange mechanism might control the rest potentiation effects in cardiac muscle