RESUMEN
The NLRP3 inflammasome is linked to sterile and pathogen-dependent inflammation, and its dysregulation underlies many chronic diseases. Mitochondria have been implicated as regulators of the NLRP3 inflammasome through several mechanisms including generation of mitochondrial reactive oxygen species (ROS). Here, we report that mitochondrial electron transport chain (ETC) complex I, II, III and V inhibitors all prevent NLRP3 inflammasome activation. Ectopic expression of Saccharomyces cerevisiae NADH dehydrogenase (NDI1) or Ciona intestinalis alternative oxidase, which can complement the functional loss of mitochondrial complex I or III, respectively, without generation of ROS, rescued NLRP3 inflammasome activation in the absence of endogenous mitochondrial complex I or complex III function. Metabolomics revealed phosphocreatine (PCr), which can sustain ATP levels, as a common metabolite that is diminished by mitochondrial ETC inhibitors. PCr depletion decreased ATP levels and NLRP3 inflammasome activation. Thus, the mitochondrial ETC sustains NLRP3 inflammasome activation through PCr-dependent generation of ATP, but via a ROS-independent mechanism.
Asunto(s)
Inflamasomas , Proteína con Dominio Pirina 3 de la Familia NLR , Adenosina Trifosfato/metabolismo , Transporte de Electrón , Inflamasomas/metabolismo , Proteína con Dominio Pirina 3 de la Familia NLR/genética , Proteína con Dominio Pirina 3 de la Familia NLR/metabolismo , Especies Reactivas de Oxígeno/metabolismoRESUMEN
Activated macrophages undergo metabolic reprogramming, which drives their pro-inflammatory phenotype, but the mechanistic basis for this remains obscure. Here, we demonstrate that upon lipopolysaccharide (LPS) stimulation, macrophages shift from producing ATP by oxidative phosphorylation to glycolysis while also increasing succinate levels. We show that increased mitochondrial oxidation of succinate via succinate dehydrogenase (SDH) and an elevation of mitochondrial membrane potential combine to drive mitochondrial reactive oxygen species (ROS) production. RNA sequencing reveals that this combination induces a pro-inflammatory gene expression profile, while an inhibitor of succinate oxidation, dimethyl malonate (DMM), promotes an anti-inflammatory outcome. Blocking ROS production with rotenone by uncoupling mitochondria or by expressing the alternative oxidase (AOX) inhibits this inflammatory phenotype, with AOX protecting mice from LPS lethality. The metabolic alterations that occur upon activation of macrophages therefore repurpose mitochondria from ATP synthesis to ROS production in order to promote a pro-inflammatory state.
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Inflamación/inmunología , Activación de Macrófagos , Macrófagos/inmunología , Mitocondrias/enzimología , Succinato Deshidrogenasa/metabolismo , Ácido Succínico/metabolismo , Adenosina Trifosfato/metabolismo , Animales , Carbonil Cianuro m-Clorofenil Hidrazona/farmacología , Ciclo del Ácido Cítrico , Glucólisis , Subunidad alfa del Factor 1 Inducible por Hipoxia/metabolismo , Inflamación/genética , Interleucina-10/metabolismo , Lipopolisacáridos/inmunología , Macrófagos/metabolismo , Malonatos/farmacología , Potencial de la Membrana Mitocondrial , Ratones , Ratones Endogámicos C57BL , Mitocondrias/efectos de los fármacos , Proteínas Mitocondriales/metabolismo , Oxidación-Reducción/efectos de los fármacos , Fosforilación Oxidativa/efectos de los fármacos , Oxidorreductasas/metabolismo , Proteínas de Plantas/metabolismo , Especies Reactivas de Oxígeno/metabolismo , Análisis de Secuencia de ARN , Succinato Deshidrogenasa/genética , TranscriptomaRESUMEN
Bronchioalveolar stem cells (BASCs) are a potential source for lung regeneration, but direct in vivo evidence for a multipotential lineage contribution during homeostasis and disease is critically missing, since specific genetic labeling of BASCs has not been possible. We developed a novel cell tracing approach based on intein-mediated assembly of newly engineered split-effectors, allowing selective targeting of dual-marker expressing BASCs in the mouse lung. RNA sequencing of isolated BASCs demonstrates that BASCs show a distinct transcriptional profile, characterized by co-expression of bronchiolar and alveolar epithelial genes. We found that BASCs generate the majority of distal lung airway cells after bronchiolar damage but only moderately contribute to cellular turnover under homeostatic conditions. Importantly, DTA-mediated ablation of BASCs compromised proper regeneration of distal airways. The study defines BASCs as crucial components of the lung repair machinery and provides a paradigmatic example for the detection and manipulation of stem cells that cannot be recognized by a single marker alone.
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Células Madre Adultas/fisiología , Alveolos Pulmonares/citología , Regeneración/fisiología , Mucosa Respiratoria/fisiología , Células Madre Adultas/citología , Animales , Proliferación Celular/fisiología , Células Cultivadas , Embrión de Mamíferos , Células HEK293 , Humanos , Ratones , Ratones de la Cepa 129 , Ratones Endogámicos C57BL , Mucosa Respiratoria/citologíaRESUMEN
Ubiquinol cytochrome c reductase hinge protein (UQCRH) is required for the electron transfer between cytochrome c1 and c of the mitochondrial cytochrome bc1 Complex (CIII). A two-exon deletion in the human UQCRH gene has recently been identified as the cause for a rare familial mitochondrial disorder. Deletion of the corresponding gene in the mouse (Uqcrh-KO) resulted in striking biochemical and clinical similarities including impairment of CIII, failure to thrive, elevated blood glucose levels, and early death. Here, we set out to test how global ablation of the murine Uqcrh affects cardiac morphology and contractility, and bioenergetics. Hearts from Uqcrh-KO mutant mice appeared macroscopically considerably smaller compared to wildtype littermate controls despite similar geometries as confirmed by transthoracic echocardiography (TTE). Relating TTE-assessed heart to body mass revealed the development of subtle cardiac enlargement, but histopathological analysis showed no excess collagen deposition. Nonetheless, Uqcrh-KO hearts developed pronounced contractile dysfunction. To assess mitochondrial functions, we used the high-resolution respirometer NextGen-O2k allowing measurement of mitochondrial respiratory capacity through the electron transfer system (ETS) simultaneously with the redox state of ETS-reactive coenzyme Q (Q), or production of reactive oxygen species (ROS). Compared to wildtype littermate controls, we found decreased mitochondrial respiratory capacity and more reduced Q in Uqcrh-KO, indicative for an impaired ETS. Yet, mitochondrial ROS production was not generally increased. Taken together, our data suggest that Uqcrh-KO leads to cardiac contractile dysfunction at 9 weeks of age, which is associated with impaired bioenergetics but not with mitochondrial ROS production. Global ablation of the Uqcrh gene results in functional impairment of CIII associated with metabolic dysfunction and postnatal developmental arrest immediately after weaning from the mother. Uqcrh-KO mice show dramatically elevated blood glucose levels and decreased ability of isolated cardiac mitochondria to consume oxygen (O2). Impaired development (failure to thrive) after weaning manifests as a deficiency in the gain of body mass and growth of internal organ including the heart. The relative heart mass seemingly increases when organ mass calculated from transthoracic echocardiography (TTE) is normalized to body mass. Notably, the heart shows no signs of collagen deposition, yet does develop a contractile dysfunction reflected by a decrease in ejection fraction and fractional shortening.
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Glucemia , Insuficiencia de Crecimiento , Humanos , Ratones , Animales , Especies Reactivas de Oxígeno/metabolismo , Complejo III de Transporte de Electrones/genética , Complejo III de Transporte de Electrones/metabolismo , Ratones Noqueados , Metabolismo Energético/genética , Factores de Transcripción/metabolismoRESUMEN
Some of the most threatening human diseases are due to a blockage of the mitochondrial electron transport chain (ETC). In a variety of plants, fungi, and prokaryotes, there is a naturally evolved mechanism for such threats to viability, namely a bypassing of the blocked portion of the ETC by alternative enzymes of the respiratory chain. One such enzyme is the alternative oxidase (AOX). When AOX is expressed, it enables its host to survive life-threatening conditions or, as in parasites, to evade host defenses. In vertebrates, this mechanism has been lost during evolution. However, we and others have shown that transfer of AOX into the genome of the fruit fly and mouse results in a catalytically engaged AOX. This implies that not only is the AOX a promising target for combating human or agricultural pathogens but also a novel approach to elucidate disease mechanisms or, in several cases, potentially a therapeutic cure for human diseases. In this review, we highlight the varying functions of AOX in their natural hosts and upon xenotopic expression, and discuss the resulting need to develop species-specific AOX inhibitors.
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Agroquímicos , Proteínas Mitocondriales , Agroquímicos/farmacología , Animales , Drosophila/metabolismo , Seguridad Alimentaria , Humanos , Ratones , Proteínas Mitocondriales/genética , Proteínas Mitocondriales/metabolismo , Oxidorreductasas , Preparaciones Farmacéuticas , Proteínas de Plantas/genética , Proteínas de Plantas/metabolismoRESUMEN
Plants and other organisms, but not insects or vertebrates, express the auxiliary respiratory enzyme alternative oxidase (AOX) that bypasses mitochondrial respiratory complexes III and/or IV when impaired. Persistent expression of AOX from Ciona intestinalis in mammalian models has previously been shown to be effective in alleviating some metabolic stresses produced by respiratory chain inhibition while exacerbating others. This implies that chronic AOX expression may modify or disrupt metabolic signaling processes necessary to orchestrate adaptive remodeling, suggesting that its potential therapeutic use may be confined to acute pathologies, where a single course of treatment would suffice. One possible route for administering AOX transiently is AOX-encoding nucleic acid constructs. Here we demonstrate that AOX-encoding chemically-modified RNA (cmRNA), sequence-optimized for expression in mammalian cells, was able to support AOX expression in immortalized mouse embryonic fibroblasts (iMEFs), human lung carcinoma cells (A549) and primary mouse pulmonary arterial smooth muscle cells (PASMCs). AOX protein was detectable as early as 3 h after transfection, had a half-life of ~4 days and was catalytically active, thus supporting respiration and protecting against respiratory inhibition. Our data demonstrate that AOX-encoding cmRNA optimized for use in mammalian cells represents a viable route to investigate and possibly treat mitochondrial respiratory disorders.
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Mitocondrias , ARN , Animales , Humanos , Ratones , Fibroblastos/metabolismo , Mitocondrias/genética , Mitocondrias/metabolismo , Proteínas Mitocondriales/genética , Proteínas Mitocondriales/metabolismo , ARN/metabolismo , Células A549 , TransfecciónRESUMEN
Mitochondrial oxidative phosphorylation (OXPHOS) and cellular workload are tightly balanced by the key cellular regulator, calcium (Ca2+). Current models assume that cytosolic Ca2+ regulates workload and that mitochondrial Ca2+ uptake precedes activation of matrix dehydrogenases, thereby matching OXPHOS substrate supply to ATP demand. Surprisingly, knockout (KO) of the mitochondrial Ca2+ uniporter (MCU) in mice results in only minimal phenotypic changes and does not alter OXPHOS. This implies that adaptive activation of mitochondrial dehydrogenases by intramitochondrial Ca2+ cannot be the exclusive mechanism for OXPHOS control. We hypothesized that cytosolic Ca2+, but not mitochondrial matrix Ca2+, may adapt OXPHOS to workload by adjusting the rate of pyruvate supply from the cytosol to the mitochondria. Here, we studied the role of malate-aspartate shuttle (MAS)-dependent substrate supply in OXPHOS responses to changing Ca2+ concentrations in isolated brain and heart mitochondria, synaptosomes, fibroblasts, and thymocytes from WT and MCU KO mice and the isolated working rat heart. Our results indicate that extramitochondrial Ca2+ controls up to 85% of maximal pyruvate-driven OXPHOS rates, mediated by the activity of the complete MAS, and that intramitochondrial Ca2+ accounts for the remaining 15%. Of note, the complete MAS, as applied here, included besides its classical NADH oxidation reaction the generation of cytosolic pyruvate. Part of this largely neglected mechanism has previously been described as the "mitochondrial gas pedal." Its implementation into OXPHOS control models integrates seemingly contradictory results and warrants a critical reappraisal of metabolic control mechanisms in health and disease.
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Calcio/metabolismo , Citosol/metabolismo , Mitocondrias/metabolismo , Ácido Pirúvico/metabolismo , Animales , Ácido Aspártico/metabolismo , Encéfalo/metabolismo , Canales de Calcio/deficiencia , Canales de Calcio/genética , Ácido Glutámico/química , Ácido Glutámico/metabolismo , Corazón/fisiología , Malatos/química , Malatos/metabolismo , Potencial de la Membrana Mitocondrial , Ratones , Ratones Endogámicos C57BL , Ratones Noqueados , Miocardio/metabolismo , Fosforilación Oxidativa , Ratas , Especificidad por Sustrato , Sinaptosomas/metabolismoRESUMEN
Cardiac ischaemia-reperfusion (I/R) injury has been attributed to stress signals arising from an impaired mitochondrial electron transport chain (ETC), which include redox imbalance, metabolic stalling and excessive production of reactive oxygen species (ROS). The alternative oxidase (AOX) is a respiratory enzyme, absent in mammals, that accepts electrons from a reduced quinone pool to reduce oxygen to water, thereby restoring electron flux when impaired and, in the process, blunting ROS production. Hence, AOX represents a natural rescue mechanism from respiratory stress. This study aimed to determine how respiratory restoration through xenotopically expressed AOX affects the re-perfused post-ischaemic mouse heart. As expected, AOX supports ETC function and attenuates the ROS load in post-anoxic heart mitochondria. However, post-ischaemic cardiac remodelling over 3 and 9 weeks was not improved. AOX blunted transcript levels of factors known to be up-regulated upon I/R such as the atrial natriuretic peptide (Anp) whilst expression of pro-fibrotic and pro-apoptotic transcripts were increased. Ex vivo analysis revealed contractile failure at nine but not 3 weeks after ischaemia whilst label-free quantitative proteomics identified an increase in proteins promoting adverse extracellular matrix remodelling. Together, this indicates an essential role for ETC-derived signals during cardiac adaptive remodelling and identified ROS as a possible effector.
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Isquemia Miocárdica/metabolismo , Isquemia Miocárdica/fisiopatología , Transducción de Señal , Remodelación Ventricular , Animales , Biocatálisis , Transporte de Electrón , Matriz Extracelular/metabolismo , Masculino , Ratones , Mitocondrias Cardíacas/metabolismo , Proteínas Mitocondriales/metabolismo , Contracción Miocárdica , Isquemia Miocárdica/complicaciones , Isquemia Miocárdica/genética , Daño por Reperfusión Miocárdica/complicaciones , Daño por Reperfusión Miocárdica/genética , Daño por Reperfusión Miocárdica/patología , Daño por Reperfusión Miocárdica/fisiopatología , Miocardio/patología , Miocardio/ultraestructura , Oxidorreductasas/metabolismo , Proteínas de Plantas/metabolismo , ARN Mensajero/genética , ARN Mensajero/metabolismoRESUMEN
Cigarette smoke (CS) exposure is the predominant risk factor for the development of chronic obstructive pulmonary disease (COPD) and the third leading cause of death worldwide. We aimed to elucidate whether mitochondrial respiratory inhibition and oxidative stress are triggers in its etiology. In different models of CS exposure, we investigated the effect on lung remodeling and cell signaling of restoring mitochondrial respiratory electron flow using alternative oxidase (AOX), which bypasses the cytochrome segment of the respiratory chain. AOX attenuated CS-induced lung tissue destruction and loss of function in mice exposed chronically to CS for 9 months. It preserved the cell viability of isolated mouse embryonic fibroblasts treated with CS condensate, limited the induction of apoptosis, and decreased the production of reactive oxygen species (ROS). In contrast, the early-phase inflammatory response induced by acute CS exposure of mouse lung, i.e., infiltration by macrophages and neutrophils and adverse signaling, was unaffected. The use of AOX allowed us to obtain novel pathomechanistic insights into CS-induced cell damage, mitochondrial ROS production, and lung remodeling. Our findings implicate mitochondrial respiratory inhibition as a key pathogenic mechanism of CS toxicity in the lung. We propose AOX as a novel tool to study CS-related lung remodeling and potentially to counteract CS-induced ROS production and cell damage.
Asunto(s)
Fumar Cigarrillos/efectos adversos , Mitocondrias/metabolismo , Proteínas Mitocondriales/genética , Nicotiana/efectos adversos , Oxidorreductasas/genética , Proteínas de Plantas/genética , Enfermedad Pulmonar Obstructiva Crónica/genética , Animales , Apoptosis/efectos de los fármacos , Movimiento Celular/efectos de los fármacos , Mezclas Complejas/farmacología , Modelos Animales de Enfermedad , Proteínas del Complejo de Cadena de Transporte de Electrón/genética , Proteínas del Complejo de Cadena de Transporte de Electrón/metabolismo , Embrión de Mamíferos , Femenino , Fibroblastos/citología , Fibroblastos/efectos de los fármacos , Fibroblastos/enzimología , Expresión Génica , Pulmón/efectos de los fármacos , Pulmón/enzimología , Pulmón/fisiopatología , Macrófagos/efectos de los fármacos , Macrófagos/metabolismo , Macrófagos/patología , Ratones , Ratones Transgénicos , Mitocondrias/efectos de los fármacos , Mitocondrias/patología , Proteínas Mitocondriales/metabolismo , Neutrófilos/efectos de los fármacos , Neutrófilos/metabolismo , Neutrófilos/patología , Estrés Oxidativo , Oxidorreductasas/metabolismo , Proteínas de Plantas/metabolismo , Cultivo Primario de Células , Enfermedad Pulmonar Obstructiva Crónica/inducido químicamente , Enfermedad Pulmonar Obstructiva Crónica/enzimología , Enfermedad Pulmonar Obstructiva Crónica/fisiopatología , Especies Reactivas de Oxígeno/agonistas , Especies Reactivas de Oxígeno/antagonistas & inhibidores , Especies Reactivas de Oxígeno/metabolismo , Transducción de Señal , Nicotiana/químicaRESUMEN
The generation of mitochondrial superoxide (O2ÌÌ) by reverse electron transport (RET) at complex I causes oxidative damage in pathologies such as ischemia reperfusion injury, but also provides the precursor to H2O2 production in physiological mitochondrial redox signaling. Here, we quantified the factors that determine mitochondrial O2ÌÌ production by RET in isolated heart mitochondria. Measuring mitochondrial H2O2 production at a range of proton-motive force (Δp) values and for several coenzyme Q (CoQ) and NADH pool redox states obtained with the uncoupler p-trifluoromethoxyphenylhydrazone, we show that O2ÌÌ production by RET responds to changes in O2 concentration, the magnitude of Δp, and the redox states of the CoQ and NADH pools. Moreover, we determined how expressing the alternative oxidase from the tunicate Ciona intestinalis to oxidize the CoQ pool affected RET-mediated O2ÌÌ production at complex I, underscoring the importance of the CoQ pool for mitochondrial O2ÌÌ production by RET. An analysis of O2ÌÌ production at complex I as a function of the thermodynamic forces driving RET at complex I revealed that many molecules that affect mitochondrial reactive oxygen species production do so by altering the overall thermodynamic driving forces of RET, rather than by directly acting on complex I. These findings clarify the factors controlling RET-mediated mitochondrial O2ÌÌ production in both pathological and physiological conditions. We conclude that O2ÌÌ production by RET is highly responsive to small changes in Δp and the CoQ redox state, indicating that complex I RET represents a major mode of mitochondrial redox signaling.
Asunto(s)
Complejo I de Transporte de Electrón/metabolismo , Peróxido de Hidrógeno/metabolismo , Mitocondrias Cardíacas/metabolismo , Superóxidos/metabolismo , Ubiquinona/metabolismo , Animales , Transporte de Electrón , Femenino , Masculino , Ratones , Ratones Endogámicos C57BL , Fosforilación Oxidativa , Ratas , Ratas Wistar , Transducción de SeñalRESUMEN
Pulmonary diseases such as chronic obstructive pulmonary disease, lung fibrosis, and bronchopulmonary dysplasia are characterized by the destruction or malformation of the alveolar regions of the lung. The underlying pathomechanisms at play are an area of intense interest since these mechanisms may reveal pathways suitable for interventions to drive reparative processes. Lipid-laden fibroblasts (lipofibroblasts) express the Perilipin 2 (Plin2) gene-product, PLIN2, commonly called adipose-differentiation related protein (ADRP). These cells are also thought to play a role in alveolarization and repair after injury to the alveolus. Progress in defining the functional contribution of lipofibroblasts to alveolar generation and repair is hampered by a lack of in vivo tools. The present study reports the generation of an inducible mouse Cre-driver line to target cells of the ADRP lineage. Robust Cre-mediated recombination in this mouse line was detected in mesenchymal cells of the postnatal lung, and in additional organs including the heart, liver, and spleen. The generation and validation of this valuable new tool to genetically target, manipulate, and trace cells of the ADRP lineage is critical for assessing the functional contribution of lipofibroblasts to lung development and repair.
Asunto(s)
Diferenciación Celular/genética , Integrasas/genética , Organogénesis/genética , Perilipina-2/genética , Animales , Células Epiteliales/metabolismo , Fibroblastos/metabolismo , Pulmón/crecimiento & desarrollo , Pulmón/metabolismo , Pulmón/patología , Ratones , Alveolos Pulmonares/crecimiento & desarrollo , Alveolos Pulmonares/metabolismo , Alveolos Pulmonares/patologíaRESUMEN
A reduced number of alveoli is the structural hallmark of diseases of the neonatal and adult lung, where alveoli either fail to develop (as in bronchopulmonary dysplasia), or are progressively destroyed (as in chronic obstructive pulmonary disease). To correct the loss of alveolar septa through therapeutic regeneration, the mechanisms of septa formation must first be understood. The present study characterized platelet-derived growth factor receptor-α-positive (PDGFRα(+)) cell populations during late lung development in mice. PDGFRα(+) cells (detected using a PDGFRα(GFP) reporter line) were noted around the proximal airways during the pseudoglandular stage. In the canalicular stage, PDGFRα(+) cells appeared in the more distal mesenchyme, and labeled α-smooth muscle actin-positive tip cells in the secondary crests and lipofibroblasts in the primary septa during alveolarization. Some PDGFRα(+) cells appeared in the mesenchyme of the adult lung. Over the course of late lung development, PDGFRα(+) cells consistently expressed collagen I, and transiently expressed markers of mesenchymal stem cells. With the use of both, a constitutive and a conditional PDGFRα(Cre) line, it was observed that PDGFRα(+) cells generated alveolar myofibroblasts including tip cells of the secondary crests, and lipofibroblasts. These lineages were committed before secondary septation. The present study provides new insights into the time-dependent commitment of the PDGFRα(+) cell lineage to lipofibroblasts and myofibroblasts during late lung development that is needed to better understand the cellular contribution to the process of alveolarization.
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Miofibroblastos/citología , Miofibroblastos/metabolismo , Alveolos Pulmonares/citología , Alveolos Pulmonares/embriología , Receptor alfa de Factor de Crecimiento Derivado de Plaquetas/metabolismo , Actinas/genética , Actinas/metabolismo , Animales , Linaje de la Célula , Colágeno Tipo I/biosíntesis , Colágeno Tipo I/genética , Mesodermo/citología , Mesodermo/embriología , Ratones , Ratones Transgénicos , Receptor alfa de Factor de Crecimiento Derivado de Plaquetas/genéticaRESUMEN
Cardiomyocytes continuously generate the contractile force to circulate blood through the body. Imbalances in contractile performance or energy supply cause adaptive responses of the heart resulting in adverse rearrangement of regular structures, which in turn might lead to heart failure. At the cellular level, cardiomyocyte remodeling includes (1) restructuring of the contractile apparatus; (2) rearrangement of the cytoskeleton; and (3) changes in energy metabolism. Dedifferentiation represents a key feature of cardiomyocyte remodeling. It is characterized by reciprocal changes in the expression pattern of "mature" and "immature" cardiomyocyte-specific genes. Dedifferentiation may enable cardiomyocytes to cope with hypoxic stress by disassembly of the energy demanding contractile machinery and by reduction of the cellular energy demand. Dedifferentiation during myocardial repair might provide cardiomyocytes with additional plasticity, enabling survival under hypoxic conditions and increasing the propensity to enter the cell cycle. Although dedifferentiation of cardiomyocytes has been described during tissue regeneration in zebrafish and newts, little is known about corresponding mechanisms and regulatory circuits in mammals. The recent finding that the cytokine oncostatin M (OSM) is pivotal for cardiomyocyte dedifferentiation and exerts strong protective effects during myocardial infarction highlights the role of cytokines as potent stimulators of cardiac remodeling. Here, we summarize the current knowledge about transient dedifferentiation of cardiomyocytes in the context of myocardial remodeling, and propose a model for the role of OSM in this process.
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Corazón/fisiología , Miocitos Cardíacos/citología , Animales , Cardiomiopatía Dilatada/metabolismo , Cardiomiopatía Dilatada/patología , Desdiferenciación Celular , Humanos , Miocitos Cardíacos/metabolismo , Oncostatina M/metabolismo , Receptores de Oncostatina M/antagonistas & inhibidores , Receptores de Oncostatina M/genética , Receptores de Oncostatina M/metabolismo , Regeneración , Remodelación VentricularRESUMEN
NOA1 is an evolutionary conserved, nuclear encoded GTPase essential for mitochondrial function and cellular survival. The function of NOA1 for assembly of mitochondrial ribosomes and regulation of OXPHOS activity depends on its GTPase activity, but so far no ligands have been identified that regulate the GTPase activity of NOA1. To identify nucleic acids that bind to the RNA-binding domain of NOA1 we employed SELEX (Systemic Evolution of Ligands by EXponential Enrichment) using recombinant mouse wildtype NOA1 and the GTPase mutant NOA1-K353R. We found that NOA1 binds specifically to oligonucleotides that fold into guanine tetrads (G-quadruplexes). Binding of G-quadruplex oligonucleotides stimulated the GTPase activity of NOA1 suggesting a regulatory link between G-quadruplex containing RNAs, NOA1 function and assembly of mitochondrial ribosomes.
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G-Cuádruplex , GTP Fosfohidrolasas/metabolismo , Mitocondrias/enzimología , ARN/química , ARN/metabolismo , Animales , Arginina/metabolismo , Secuencia de Bases , Activación Enzimática , GTP Fosfohidrolasas/aislamiento & purificación , Hidrólisis , Lisina/metabolismo , Ratones , Proteínas Mutantes/aislamiento & purificación , Proteínas Mutantes/metabolismo , Unión Proteica , ARN Ribosómico/metabolismo , Proteínas Recombinantes/metabolismo , Técnica SELEX de Producción de Aptámeros , Especificidad por SustratoRESUMEN
Cardiomyocyte development in mammals is characterized by a transition from hyperplastic to hypertrophic growth soon after birth. The rise of cardiomyocyte cell mass in postnatal life goes along with a proportionally bigger increase in the mitochondrial mass in response to growing energy requirements. Relatively little is known about the molecular processes regulating mitochondrial biogenesis and mitochondrial DNA (mtDNA) maintenance during developmental cardiac hypertrophy. Genome-wide transcriptional profiling revealed the activation of transcriptional regulatory circuits controlling mitochondrial biogenesis in growing rat hearts. In particular, we detected a specific upregulation of factors involved in mtDNA expression and translation. More surprisingly, we found a specific upregulation of DNA repair proteins directly linked to increased oxidative damage during heart mitochondrial biogenesis, but only relatively minor changes in the mtDNA replication machinery. Our study paves the way for improved understanding of mitochondrial biogenesis, mtDNA maintenance and physiological adaptation processes in the heart and provides the first evidence for the recruitment of nucleotide excision repair proteins to mtDNA in cardiomyocytes upon DNA damage.
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Reparación del ADN , ADN Mitocondrial/metabolismo , Corazón/crecimiento & desarrollo , Mitocondrias Cardíacas/genética , Estrés Oxidativo , Envejecimiento/genética , Animales , Aumento de la Célula , Daño del ADN , ADN Mitocondrial/química , Regulación de la Expresión Génica , Corazón/embriología , Mitocondrias Cardíacas/metabolismo , Mitocondrias Cardíacas/fisiología , Proteínas Mitocondriales/genética , Proteínas Mitocondriales/metabolismo , Miocardio/citología , Miocardio/metabolismo , Ratas , Ratas Sprague-Dawley , Ratas Wistar , Regulación hacia ArribaRESUMEN
T cell activation, proliferation, and differentiation are fundamentally driven by shifts in cellular metabolism, with mitochondria playing a central role. Cytochrome c oxidase (COX, complex IV) is a key player in this process, as its activity is crucial for apoptosis, mtDNA maintenance, mitochondrial transcription, and mitochondrial respiration (MR), all of which influence T cell fate and function. Despite its known roles, the specific functions of COX required for T cell activity in vivo remain unclear. To isolate the role of MR in T cell function, we reintroduced this capability in COX-deficient T cells using an alternative oxidase (AOX) from Ciona intestinalis. Our findings demonstrate that MR is vital for maintaining metabolic balance during T cell activation by alleviating electron pressure from metabolic reprogramming and preserving redox homeostasis. We further showed that AOX mitigates apoptosis, prevents metabolic disruptions in glycolysis and the tricarboxylic acid cycle, and improves mtDNA maintenance and transcription, indicating that these disturbances are secondary to impaired MR in the absence of COX. Most importantly, the introduction of AOX restored robust effector and memory T cell generation and function in COX-deficient cells. These results highlight the essential role of COX-dependent MR in ensuring cellular health and underscore its pivotal role in T cell proliferation and differentiation.
RESUMEN
Mitochondrial disorders are hallmarked by the dysfunction of oxidative phosphorylation (OXPHOS) yet are highly heterogeneous at the clinical and genetic levels. Striking tissue-specific pathological manifestations are a poorly understood feature of these conditions, even if the disease-causing genes are ubiquitously expressed. To investigate the functional basis of this phenomenon, we analyzed several OXPHOS-related bioenergetic parameters, including oxygen consumption rates, electron transfer system (ETS)-related coenzyme Q (mtCoQ) redox state and production of reactive oxygen species (ROS) in mouse brain and liver mitochondria fueled by different substrates. In addition, we determined how these functional parameters are affected by ETS impairment in a tissue-specific manner using pathologically relevant mouse models lacking either Ndufs4 or Ttc19, leading to Complex I (CI) or Complex III (CIII) deficiency, respectively. Detailed OXPHOS analysis revealed striking differences between brain and liver mitochondria in the capacity of the different metabolic substrates to fuel the ETS, reduce the ETS-related mtCoQ, and to induce ROS production. In addition, ETS deficiency due to either CI or CIII dysfunction had a much greater impact on the intrinsic bioenergetic parameters of brain compared with liver mitochondria. These findings are discussed in terms of the still rather mysterious tissue-specific manifestations of mitochondrial disease.