RESUMEN
Redox signaling and cardiac function are tightly linked. However, it is largely unknown which protein targets are affected by hydrogen peroxide (H2O2) in cardiomyocytes that underly impaired inotropic effects during oxidative stress. Here, we combine a chemogenetic mouse model (HyPer-DAO mice) and a redox-proteomics approach to identify redox sensitive proteins. Using the HyPer-DAO mice, we demonstrate that increased endogenous production of H2O2 in cardiomyocytes leads to a reversible impairment of cardiac contractility in vivo. Notably, we identify the γ-subunit of the TCA cycle enzyme isocitrate dehydrogenase (IDH)3 as a redox switch, linking its modification to altered mitochondrial metabolism. Using microsecond molecular dynamics simulations and experiments using cysteine-gene-edited cells reveal that IDH3γ Cys148 and 284 are critically involved in the H2O2-dependent regulation of IDH3 activity. Our findings provide an unexpected mechanism by which mitochondrial metabolism can be modulated through redox signaling processes.
Asunto(s)
Peróxido de Hidrógeno , Mitocondrias , Ratones , Animales , Peróxido de Hidrógeno/metabolismo , Mitocondrias/metabolismo , Oxidación-Reducción , Metabolismo Energético , Miocitos Cardíacos/metabolismo , Estrés OxidativoRESUMEN
Mitochondria have originated in eukaryotic cells by endosymbiosis of a specialized prokaryote approximately 2 billion years ago. They are essential for normal cell function by providing energy through their role in oxidizing carbon substrates. Glutathione (GSH) is a major thiol-disulfide redox buffer of the cell including the mitochondrial matrix and intermembrane space. We have generated cardiomyocyte-specific Grx1-roGFP2 GSH redox potential (EGSH) biosensor mice in the past, in which the sensor is targeted to the mitochondrial matrix. Using this mouse model a distinct EGSH of the mitochondrial matrix (-278.9⯱â¯0.4â¯mV) in isolated cardiomyocytes is observed. When analyzing the EGSH in isolated mitochondria from the transgenic hearts, however, the EGSH in the mitochondrial matrix is significantly oxidized (-247.7⯱â¯8.7â¯mV). This is prevented by adding N-Ethylmaleimide during the mitochondria isolation procedure, which precludes disulfide bond formation. A similar reducing effect is observed by isolating mitochondria in hypoxic (0.1-3% O2) conditions that mimics mitochondrial pO2 levels in cellulo. The reduced EGSH is accompanied by lower ROS production, reduced complex III activity but increased ATP levels produced at baseline and after stimulation with succinate/ADP. Altogether, we demonstrate that oxygenation is an essential factor that needs to be considered when analyzing mitochondrial function ex vivo.
Asunto(s)
Mitocondrias/metabolismo , Oxígeno/metabolismo , Adenosina Trifosfato/metabolismo , Animales , Complejo III de Transporte de Electrones/metabolismo , Peróxido de Hidrógeno/metabolismo , Hiperoxia/metabolismo , Ratones , Mitocondrias Cardíacas/metabolismo , Miocitos Cardíacos/metabolismo , Oxidación-Reducción , Superóxidos/metabolismoRESUMEN
SIGNIFICANCE: Redox signaling is a common mechanism in the cellular response toward a variety of stimuli. For analyzing redox-dependent specific alterations in a cell, genetically encoded biosensors were highly instrumental in the past. To advance the knowledge about the importance of this signaling mechanism in vivo, models that are as close as possible to physiology are needed. Recent Advances: The development of transgenic (tg) redox biosensor animal models has enhanced the knowledge of redox signaling under patho(physio)logical conditions. So far, commonly used small animal models, that is, Caenorhabditis elegans, Drosophila melanogaster, and Danio rerio, and genetically modified mice were employed for redox biosensor transgenesis. However, especially the available mouse models are still limited. CRITICAL ISSUES: The analysis of redox biosensor responses in vivo at the tissue level, especially for internal organs, is hampered by the detection limit of the available redox biosensors and microscopy techniques. Recent technical developments such as redox histology and the analysis of cell-type-specific biosensor responses need to be further refined and followed up in a systematic manner. FUTURE DIRECTIONS: The usage of tg animal models in the field of redox signaling has helped to answer open questions. Application of the already established models and consequent development of more defined tg models will enable this research area to define the role of redox signaling in (patho)physiology in further depth. Antioxid. Redox Signal. 29, 603-612.
Asunto(s)
Técnicas Biosensibles , Imagen Molecular , Oxidación-Reducción , Animales , Animales Modificados Genéticamente , Caenorhabditis elegans , Drosophila melanogaster , Expresión Génica , Genes Reporteros , Ratones , Imagen Molecular/métodos , Especificidad de Órganos/genética , Organismos Modificados Genéticamente , Plantas/metabolismo , Regiones Promotoras Genéticas , Transducción de SeñalRESUMEN
RATIONALE: Changes in redox potentials of cardiac myocytes are linked to several cardiovascular diseases. Redox alterations are currently mostly described qualitatively using chemical sensors, which however do not allow quantifying redox potentials, lack specificity, and the possibility to analyze subcellular domains. Recent advances to quantitatively describe defined redox changes include the application of genetically encoded redox biosensors. OBJECTIVE: Establishment of mouse models, which allow the quantification of the glutathione redox potential (EGSH) in the cytoplasm and the mitochondrial matrix of isolated cardiac myocytes and in Langendorff-perfused hearts based on the use of the redox-sensitive green fluorescent protein 2, coupled to the glutaredoxin 1 (Grx1-roGFP2). METHODS AND RESULTS: We generated transgenic mice with cardiac myocyte-restricted expression of Grx1-roGFP2 targeted either to the mitochondrial matrix or to the cytoplasm. The response of the roGFP2 toward H2O2, diamide, and dithiothreitol was titrated and used to determine the EGSH in isolated cardiac myocytes and in Langendorff-perfused hearts. Distinct EGSH were observed in the cytoplasm and the mitochondrial matrix. Stimulation of the cardiac myocytes with isoprenaline, angiotensin II, or exposure to hypoxia/reoxygenation additionally underscored that these compartments responded independently. A compartment-specific response was also observed 3 to 14 days after myocardial infarction. CONCLUSIONS: We introduce redox biosensor mice as a new tool, which allows quantification of defined alterations of EGSH in the cytoplasm and the mitochondrial matrix in cardiac myocytes and can be exploited to answer questions in basic and translational cardiovascular research.