Histone deacetylases (HDACs) regulate cardiac plasticity; however, their molecular targets are unknown. As autophagy contributes to pathological cardiac remodeling, we hypothesized that HDAC inhibitors target autophagy. The prototypical HDAC inhibitor (HDACi), trichostatin A (TSA), attenuated both load-and agonistinduced hypertrophic growth and abolished the associated activation of autophagy. Phenylephrine (PE)-triggered hypertrophy and autophagy in cultured cardiomyocytes were each blocked by a panel of structurally distinct HDAC inhibitors. RNAi-mediated knockdown of either Atg5 or Beclin 1, two essential autophagy effectors, was similarly capable of suppressing ligand-induced autophagy and myocyte growth. RNAi experiments uncovered the class I isoforms HDAC1 and HDAC2 as required for the autophagic response. To test the functional requirement of autophagic activation, we studied mice that overexpress Beclin 1 in cardiomyocytes. In these animals with a fourfold amplified autophagic response to TAC, TSA abolished TAC-induced increases in autophagy and blunted load-induced hypertrophy. Finally, we subjected animals with preexisting hypertrophy to HDACi, finding that ventricular mass reverted to nearnormal levels and ventricular function normalized completely. Together, these data implicate autophagy as an obligatory element in pathological cardiac remodeling and point to HDAC1/2 as required effectors. Also, these data reveal autophagy as a previously unknown target of HDAC inhibitor therapy.
Cardiovascular disease (CVD) is the leading cause of morbidity and mortality worldwide. Although treatments have improved, development of novel therapies for patients with CVD remains a major research goal. Apoptosis, necrosis, and autophagy occur in cardiac myocytes, and both gradual and acute cell death are hallmarks of cardiac pathology, including heart failure, myocardial infarction, and ischemia/reperfusion. Pharmacological and genetic inhibition of autophagy, apoptosis, or necrosis diminishes infarct size and improves cardiac function in these disorders. Here, we review recent progress in the fields of autophagy, apoptosis, and necrosis. In addition, we highlight the involvement of these mechanisms in cardiac pathology and discuss potential translational implications.
Insulin resistance and metabolic syndrome are rapidly expanding public health problems. Acting through the PI3K/Akt pathway, insulin and insulin-like growth factor-1 (IGF-1) inactivate FoxO transcription factors, a class of highly conserved proteins important in numerous physiological functions. However, even as FoxO is a downstream target of insulin, FoxO factors also control upstream signaling elements governing insulin sensitivity and glucose metabolism. Here, we report that sustained activation of either FoxO1 or FoxO3 in cardiac myocytes increases basal levels of Akt phosphorylation and kinase activity. FoxO-activated Akt directly interacts with and phosphorylates FoxO, providing feedback inhibition. We reported previously that FoxO factors attenuate cardiomyocyte calcineurin (PP2B) activity. We now show that calcineurin forms a complex with Akt and inhibition of calcineurin enhances Akt phosphorylation. In addition, FoxO activity suppresses protein phosphatase 2A (PP2A) and disrupts Akt-PP2A and Akt-calcineurin interactions. Repression of Akt-PP2A/B interactions and phosphatase activities contributes, at least in part, to FoxO-dependent increases in Akt phosphorylation and kinase activity. Resveratrol, an activator of Sirt1, increases the transcriptional activity of FoxO1 and triggers Akt phosphorylation in heart. Importantly, FoxO-mediated increases in Akt activity diminish insulin signaling, as manifested by reduced Akt phosphorylation, reduced membrane translocation of Glut4, and decreased insulintriggered glucose uptake. Also, inactivation of the gene coding for FoxO3 enhances insulin-dependent Akt phosphorylation. Taken together, this study demonstrates that changes in FoxO activity have a dose-responsive repressive effect on insulin signaling in cardiomyocytes through inhibition of protein phosphatases, which leads to altered Akt activation, reduced insulin sensitivity, and impaired glucose metabolism.cardiomyocyte ͉ calcineurin ͉ insulin resistance ͉ cardiomyopathy
Background Myocardium irreversibly injured by ischemic stress must be efficiently repaired to maintain tissue integrity and contractile performance. Macrophages play critical roles in this process. These cells transform across a spectrum of phenotypes to accomplish diverse functions ranging from mediating the initial inflammatory responses that clear damaged tissue to subsequent reparative functions that help rebuild replacement tissue. Although macrophage transformation is crucial to myocardial repair, events governing this transformation are poorly understood. Methods Here, we set out to determine whether innate immune responses triggered by cytoplasmic DNA play a role. Results We report that ischemic myocardial injury, and the resulting release of nucleic acids, activates the recently described cGAS (GMP-AMP synthase)-STING (stimulator of interferon genes) pathway. Animals lacking cGAS display significantly improved early survival post-MI, diminished pathological remodeling including ventricular rupture, enhanced angiogenesis, and preserved ventricular contractile function. Furthermore, cGAS loss-of-function abolishes the induction of key inflammatory programs such as iNOS and promotes the transformation of macrophages to a reparative phenotype, which results in enhanced repair and improved hemodynamic performance. Conclusions These results reveal, for the first time, that the cytosolic DNA receptor cGAS functions during cardiac ischemia as a pattern recognition receptor in the sterile immune response. Further, we report that this pathway governs macrophage transformation, thereby regulating post-injury cardiac repair. As modulators of this pathway are currently in clinical use, our findings raise the prospect of new treatment options to combat ischemic heart disease and its progression to heart failure.
BackgroundMechanical assist device therapy has emerged recently as an important and rapidly expanding therapy in advanced heart failure, triggering in some patients a beneficial reverse remodeling response. However, mechanisms underlying this benefit are unclear.Methods and ResultsIn a model of mechanical unloading of the left ventricle, we observed progressive myocyte atrophy, autophagy, and robust activation of the transcription factor FoxO3, an established regulator of catabolic processes in other cell types. Evidence for FoxO3 activation was similarly detected in unloaded failing human myocardium. To determine the role of FoxO3 activation in cardiac muscle in vivo, we engineered transgenic mice harboring a cardiomyocyte‐specific constitutively active FoxO3 mutant (caFoxO3flox;αMHC‐Mer‐Cre‐Mer). Expression of caFoxO3 triggered dramatic and progressive loss of cardiac mass, robust increases in cardiomyocyte autophagy, declines in mitochondrial biomass and function, and early mortality. Whereas increases in cardiomyocyte apoptosis were not apparent, we detected robust increases in Bnip3 (Bcl2/adenovirus E1B 19‐kDa interacting protein 3), an established downstream target of FoxO3. To test the role of Bnip3, we crossed the caFoxO3flox;αMHC‐Mer‐Cre‐Mer mice with Bnip3‐null animals. Remarkably, the atrophy and autophagy phenotypes were significantly blunted, yet the early mortality triggered by FoxO3 activation persisted. Rather, declines in cardiac performance were attenuated by proteasome inhibitors. Consistent with involvement of FoxO3‐driven activation of the ubiquitin‐proteasome system, we detected time‐dependent activation of the atrogenes program and sarcomere protein breakdown.ConclusionsIn aggregate, these data point to FoxO3, a protein activated by mechanical unloading, as a master regulator that governs both the autophagy‐lysosomal and ubiquitin‐proteasomal pathways to orchestrate cardiac muscle atrophy.
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