Background: Heart failure is a global public health issue that is associated with increasing morbidity and mortality. Previous studies have suggested that mitochondrial dysfunction plays critical roles in the progression of heart failure; however, the underlying mechanisms remain unclear. Since kinases have been reported to modulate mitochondrial function, we investigated the effects of dual-specificity tyrosine-regulated kinase 1B (DYRK1B) on mitochondrial bioenergetics, cardiac hypertrophy, and heart failure. Methods: We engineered DYRK1B transgenic and knock out mice and used transverse aortic constriction (TAC) to produce an in vivo model of cardiac hypertrophy. The effects of DYRK1B and its downstream mediators were subsequently elucidated using RNA-seq analysis and mitochondrial functional analysis. Results: We found that DYRK1B expression was clearly upregulated in failing human myocardium as well as in hypertrophic murine hearts. Cardiac-specific DYRK1B overexpression resulted in cardiac dysfunction accompanied by a decline in the left ventricular ejection fraction, fraction shortening, and increased cardiac fibrosis. In striking contrast to DYRK1B overexpression, the deletion of DYRK1B mitigated TAC-induced cardiac hypertrophy and heart failure. Mechanistically, DYRK1B was positively associated with impaired mitochondrial bioenergetics by directly binding with STAT3 to increase its phosphorylation and nuclear accumulation, ultimately contributing toward the downregulation of PGC-1α. Furthermore, the inhibition of DYRK1B or STAT3 activity using specific inhibitors was able to restore cardiac performance by rejuvenating mitochondrial bioenergetics. Conclusions: Taken together, the findings of this study provide new insights into the previously unrecognized role of DYRK1B in mitochondrial bioenergetics and the progression of cardiac hypertrophy and heart failure. Consequently, these findings may provide new therapeutic options for patients with heart failure.
Navitoclax, which is a type of senolytic drug, selectively eliminates senescent cells. This study aimed to evaluate the therapeutic potential of navitoclax in treatment of angiotensin II (Ang II)-induced heart failure in mice. Navitoclax or vehicle was administrated in mice with Ang II-induced heart failure. Cardiac function and electrophysiology were assessed before and after administration of navitoclax. Cardiac remodeling, including morphological changes, fibrosis, and inflammatory responses, was analyzed in myocardial tissue. Cellular effects of navitoclax were validated in isolated primary cardiomyocytes and cardiac fibroblasts in vitro. Echocardiography of mice showed that navitoclax improved cardiac dysfunction by improving the left ventricular ejection fraction (vehicle: 45.88 ± 2.19%; navitoclax: 54.70 ± 1.65%, P < 0.01). In cardiac electrophysiological testing, navitoclax increased conduction velocity (vehicle: 1.37 ± 0.05 mm/ms; navitoclax: 1.69 ± 0.08 mm/ms, P < 0.05) and decreased susceptibility to ventricular tachyarrhythmia induced by programmed electrical stimulation. Histopathological staining, immunofluorescence, and western blotting examinations showed that navitoclax ameliorated Ang II-induced cardiac fibrosis, hypertrophy, and the inflammatory response. Moreover, navitoclax eliminated senescent cells by inducing apoptosis. Therefore, navitoclax improved cardiac function and electrophysiological characteristics through decreasing cardiac fibrosis, hypertrophy, and inflammation in mice with heart failure. Pharmacological clearance of senescent cells may be a potential therapeutic approach in heart failure with reduced ejection fraction.
Background Myocardial infarction (MI) is characterized by the emergence of dead or dying cardiomyocytes and excessive immune cell infiltration after coronary vessel occlusion. However, the complex transcriptional profile, pathways, cellular interactome, and transcriptional regulators of immune subpopulations after MI remain elusive. Methods and Results Here, male C57BL/6 mice were subjected to MI surgery and monitored for 1 day and 7 days, or sham surgery for 7 days, then cardiac CD45‐positive immune cells were collected for single‐cell RNA sequencing to determine immune heterogeneity. A total of 30 135 CD45 + immune cells were partitioned into macrophages, monocytes, neutrophils, dendritic cells, and T or B cells for further analysis. We showed that macrophages enriched for Olr1 and differentially expressed Gpnmb represented 2 crucial ischemia‐associated macrophages with distinct proinflammatory and prophagocytic capabilities. In contrast to the proinflammatory subset of macrophages enriched for Olr1, Gpnmb‐positive macrophages exhibited higher phagocytosis and fatty acid oxidation preference, which could be abolished by etomoxir treatment. In addition to macrophages, MI triggered prompt recruitment of neutrophils into murine hearts, which constituted the sequential cell‐fate from naïve S100a4‐positive, to activated Sell‐high, to aging Icam1‐high neutrophils. In silico tools predicted that the excessively expanded neutrophils at 1 day were attributed to chemokine C‐C motif ligand/chemokine C‐X‐C motif ligand pathways, whereas CD80/inducible T‐cell costimulator (ICOS) signaling was responsible for the immunosuppressive response at day 7 after MI. Finally, the Fos/AP‐1 (activator protein 1) regulon was identified as the critical regulator of proinflammatory responses, which was significantly activated in patients with dilated cardiomyopathy and ischemic cardiomyopathy. We showed the enriched Fos/AP‐1 target gene loci in genome‐wide association study signals for coronary artery diseases and MI. Targeting Fos/AP‐1 with the selective inhibitor T5224 blunted leukocyte infiltration and alleviated cardiac dysfunction in the preclinical murine MI model. Conclusions Taken together, this single‐cell RNA sequencing data lay the groundwork for the understanding of immune cell heterogeneity and dynamics in murine ischemic hearts. Moreover, Fos/AP‐1 inhibition mitigates inflammatory responses and cardiac dysfunction, which might provide potential therapeutic benefits for heart failure intervention after MI.
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