Project description:Cardiac metabolic dysfunction is a hallmark of heart failure. Estrogen related receptors ERRalpha and ERRgamma are essential regulators of cardiac metabolism. Therefore, activation of ERR could be a potential theraputic intervention for heart failure. However, in vivo studies demonstrating the potential utility of ERR agonists for heart failure treatment are lacking, as compounds with pharmackinetics appropriate for in vivo use have not been available. Using a structure-based design approach, we designed and synthesized two structurally distinct pan-ERR agonists, SLU-PP-332 (332) and SLU-PP-915 (915), which significantly improved ejection fraction, ameliorated fibrosis and increased survival associated with pressure overload-induced heart failure without affecting cardiac hypertrophy. Mechanistically, a broad spectrum of metabolic genes was transcriptionally activated by ERR agonists, particulary genes involved in fatty acid metabolism and mitochondrial function. Using both in vitro and in vivo genetic dependency experiments, we show that ERRgamma is the main mediatorof ERR agonism-induced transcriptional regulation and cardioprotection and definitively demonstrated target specificity. Additionally, ERR agonism also led to downregulation of cell cycle and development pathways, which was partially mediated by E2F1 in cardiomyocyte. In summary, ERR agonists maintain oxidative metabolism, which confers cardiac protection against pressure overload-induced heart failure in vivo. Our results provide direct pharmacological evidence supporting the further in vivo development of ERR agonists as novel heart failure theraputics.

Project description:Novel pan-ERR agonists ameliorate heart failure through enhancing cardiac fatty acid metabolism and mitochondrial function

Project description:Novel pan-ERR agonists ameliorate heart failure through enhancing cardiac fatty acid metabolism and mitochondrial function

Project description:Heart failure remains a major unmet clinical need and current therapies targeting neurohomonal and hemodynamic regulation have limited efficacy. We report that pharmacological activation of the transcriptional repressor REV-ERBa prevents expression of a pathological gene program and cardiomyocyte hypertrophy. In vivo, REV-ERBa agonism prevents development and halts progression of heart failure in mouse models. Thus, modulation of gene networks by targeting REV-ERBa represents a novel approach to heart failure therapy.

Project description:Heart failure is driven by the interplay between master regulatory transcription factors and dynamic alterations in chromatin structure. Coordinate activation of developmental, inflammatory, fibrotic and growth regulators underlies the hallmark phenotypes of pathologic cardiac hypertrophy and contractile failure. While transactivation in this context is known to be associated with recruitment of histone acetyl-transferase enzymes and local chromatin hyperacetylation, the role of epigenetic reader proteins in cardiac biology is unknown. We therefore undertook a first study of acetyl-lysine reader proteins, or bromodomains, in heart failure. Using a chemical genetic approach, we establish a central role for BET-family bromodomain proteins in gene control during the evolution of heart failure. BET inhibition suppresses cardiomyocyte hypertrophy in a cell-autonomous manner, confirmed by RNA interference in vitro. Following both pressure overload and neurohormonal stimulation, BET inhibition potently attenuates pathologic cardiac remodeling in vivo. Integrative transcriptional and epigenomic analyses reveal that BET proteins function mechanistically as pause-release factors critical to activation of canonical master regulators and effectors that are central to heart failure pathogenesis. Specifically, BET bromodomain inhibition in mice abrogates pathology-associated pause release and transcriptional elongation, thereby preventing activation of cardiac transcriptional pathways relevant to the gene expression profile of failing human hearts. This study implicates epigenetic readers in cardiac biology and identifies BET co-activator proteins as therapeutic targets in heart failure. ChIP-Seq of mouse heart tissues from mice induced with heart failure and treated with JQ1 BET bromodomain inhibitor

Project description:Immune checkpoint therapeutics including CD40 agonists have tremendous promise to elicit antitumor responses in patients resistant to current therapies. Conventional immune checkpoint inhibitors (PD-1/PD-L1, CTLA-4 antagonists) are associated with serious adverse cardiac events including life-threatening myocarditis. However, little is known regarding the potential for CD40 agonists to trigger myocardial inflammation or myocarditis. Here, we leverage genetic mouse models, single cell sequencing, and cell depletion studies to demonstrate that an anti-CD40 agonist antibody reshapes the cardiac immune landscape through activation of CCR2+ macrophages and subsequent recruitment of effector memory CD8 T-cells. We identify a positive feedback loop between CCR2+ macrophages and CD8 T-cells driven by IL12b, TNF, and IFN-γ signaling that promotes myocardial inflammation and show that prior exposure to CD40 agonists sensitizes the heart to secondary insults and accelerates LV remodeling. Collectively, these findings highlight the potential for CD40 agonists to promote myocardial inflammation and potentiate heart failure pathogenesis.

Project description:Cardiac fibrosis is a common feature of ischemic heart disease and cardiac fibroblasts (CF) are key players in cardiac remodeling of the injured heart after myocardial infarction (MI). Fibrosis increases myocardial stiffness, thereby impairing cardiac function, which ultimately progresses to end-stage heart failure. Little is known, however, on the secretome of CF and cell-to-cell communication of CF is only incompletely understood. Here, we in vivo labeled secreted proteins by expressing TurboID under control of the POSTN promotor in cardiac fibroblasts of mouse with myocardial infarction, enriched biotinylated proteins and analyzed them using LC-MS.

Project description:Cardiac β3-adrenergic receptors (β3AR) are upregulated in diseased hearts and mediate antithetic effects to those of β1AR and β2AR. β3AR agonists were recently shown to protect from myocardial remodeling in preclinical studies and to improve systolic function in patients with severe heart failure. The mechanisms involved, however, remain elusive. Here we used a transgenic mouse model with moderate, cardiac-specific expression of the human β3AR (β3AR-Tg) (with levels similiar to those observed in human cardiac bisopsies) to dissect downstream effects after transaortic constriction (TAC)

Project description:Functional oncogenic links between ErbB2 and ERR⍺ in HER2+ breast cancer patients support a therapeutic benefit of co-targeted therapies. However, ErbB2 and ERR⍺ also play key roles in heart physiology, and this approach could pose a potential liability to cardiovascular health. Using integrated phosphoproteomic, transcriptomic and metabolic profiling, we uncovered molecular mechanisms associated with the adverse remodeling of cardiac functions in mice with combined attenuation of ErbB2 and ERR⍺ activity. Genetic disruption of both effectors results in profound effects on cardiomyocyte architecture, inflammatory response and metabolism, the latter leading to a decrease in fatty acyl-carnitine species further increasing the reliance on glucose as a metabolic fuel, a hallmark of failing hearts. Furthermore, integrated omics signatures of ERR⍺ loss-of-function and doxorubicin treatment exhibit reciprocal features of chemotherapeutic cardiotoxicity. These findings thus reveal potential cardiovascular risks in discrete combination therapies in the treatment of breast and other cancers.

Project description:Cardiac-specific PPARalpha transgenic (Tg-PPARalpha) mice show mild cardiac hypertrophy and systolic dysfunction. The failing heart phenotypes observed in Tg-PPARalpha are exacerbated by crossing with cardiac-specific Sirt1 transgenic (Tg-Sirt1) mice, whereas Tg-Sirt1 mice themselves do not show any cardiac hypertrophy or systolic dysfunction. To investigate the mechanism leading to the failing heart phenotypes in TgPPARalpha/Tg-Sirt1 bigenic mice, microarray analyses were performed. The microarray analyses revealed that many ERR target genes were downregulated in Tg-PPARalpha and in Tg-Sirt1, and they were further downregulated in the Tg-PPARalpha/Tg-Sirt1 bigenic mice. Four groups of cardiac-specific transgenic mice were used for the study, i.e., control, PPARalpha, Sirt1 and PPARalpha/Sirt1. Hearts were dissected after 10-11 weeks of male FVB background transgenic mice. Total RNA was prepared from the hearts to conduct the microarray analyses.