RESUMO
RESUMEN Introducción: Resultados de nuestro laboratorio sugieren que la disfunción mitocondrial en el corazón precede a la falla miocárdica asociada a la hiperglucemia sostenida. Objetivo: Estudiar los eventos tempranos que ocurren en las mitocondrias de corazón en un modelo de diabetes mellitus tipo 1. Materiales y métodos: Ratas Wistar macho fueron inyectadas con estreptozotocina (STZ; 60 mg/kg, ip) y sacrificadas 10 o 14 días posinyección. Se obtuvo la fracción mitocondrial de corazón. Resultados: El consumo de O2 en estado 3 en presencia de malato-glutamato (21%) o succinato (16%) y las actividades de los complejos I-III (27%), II-III (24%) y IV (22%) fueron menores en los animales diabéticos a los 14 días posinyección. Cuando los animales se sacrificaron al día 10, solo el consumo de O2 en estado 3 en presencia de sustratos del complejo I (23%) y su control respiratorio (30%) fueron menores en las ratas inyectadas con STZ, de acuerdo con una reducción en la actividad del complejo I-III (17%). Estos cambios se acompañaron de un aumento en las velocidades de producción de H2O2 (117%), NO (30%) y ONOO- (∼225%), en la expresión de mtNOS (29%) y en la [O2 -]ss (∼150%) y [NO]ss (∼30%), junto con una disminución de la actividad de la Mn-SOD (15%) y la [GSSG+GSH]mitocondrial (28%), sin cambios en la expresión de PGC-1α. Conclusión: La disfunción del complejo I y el aumento en la generación de H2O2, NO y ONOO- pueden considerarse señales subcelulares prodrómicas del deterioro de la función mitocondrial que precede a la disfunción cardíaca en la diabetes.
ABSTRACT Background: Previous results from our laboratory suggest that heart mitochondrial dysfunction precedes myocardial failure associated with sustained hyperglycemia. Purpose: The aim of this study was to analyze the early events that take place in heart mitochondria in a type 1 diabetes mellitus (DM) model. Methods: Male Wistar rats were injected with streptozotocin (STZ; 60 mg/kg, ip.) to induce DM. They were euthanized 10 or 14 days later and the heart mitochondrial fraction was obtained. Results: State 3 O2 consumption in the presence of malate-glutamate (21%) or succinate (16%), and complex I-III (27%), II-III (24%) and IV (22%) activities were lower in diabetic animals 14 days after STZ injection. When animals were euthanized at day 10, only state 3 O2 consumption sustained by complex I substrates (23%) and its corresponding respiratory control (30%) were lower in rats injected with STZ, in agreement with reduced complex I-III activity (17%). These changes were accompanied by increased H2O2 (117%), NO (30%) and ONOO- (~225%) production rates, mtNOS expression (29%) and O2 - (~150%) and NO (~30%) steady-state concentrations, together with a decrease in Mn-SOD activity (15%) and mitochondrial [GSSG+GSH] (28%), without changes in PGC-1α expression. Conclusion: Complex I dysfunction and increased H2O2, NO and ONOO- production rates can be considered subcellular prodromal signals of the mitochondrial damage that precedes myocardial dysfunction in diabetes.
RESUMO
This study, in an experimental model of type I Diabetes Mellitus in rats, deals with the mitochondrial production rates and steady-state concentrations of H2O2 and NO, and ATP levels as part of a network of signaling molecules involved in heart mitochondrial biogenesis. Sustained hyperglycemia leads to a cardiac compromise against a work overload, in the absence of changes in resting cardiac performance and of heart hypertrophy. Diabetes was induced in male Wistar rats by a single dose of Streptozotocin (STZ, 60mg × kg-1, ip.). After 28 days of STZ-injection, rats were sacrificed and hearts were isolated. The mitochondrial mass (mg mitochondrial protein × g heart-1), determined through cytochrome oxidase activity ratio, was 47% higher in heart from diabetic than from control animals. Stereological analysis of cardiac tissue microphotographs showed an increase in the cytosolic volume occupied by mitochondria (30%) and in the number of mitochondria per unit area (52%), and a decrease in the mean area of each mitochondrion (23%) in diabetic respect to control rats. Additionally, an enhancement (76%) in PGC-1α expression was observed in cardiac tissue of diabetic animals. Moreover, heart mitochondrial H2O2 (127%) and NO (23%) productions and mtNOS expression (132%) were higher, while mitochondrial ATP production rate was lower (~ 40%), concomitantly with a partial-mitochondrial depolarization, in diabetic than in control rats. Changes in mitochondrial H2O2 and NO steady-state concentrations and an imbalance between cellular energy demand and mitochondrial energy transduction could be involved in the signaling pathways that lead to the novo synthesis of mitochondria. However, this compensatory mechanism triggered to restore the mitochondrial and tissue normal activities, did not lead to competent mitochondria capable of supplying the energetic demands in diabetic pathological conditions.