Modulating Lysine Crotonylation in Cardiomyocytes Improves Myocardial Outcomes.

BACKGROUND: Ischemic heart disease is a major global public health challenge, and its functional outcomes remain poor. Lysine crotonylation (Kcr) was recently identified as a post-translational histone modification that robustly indicates active promoters. However, the role of Kcr in myocardial injury is unknown. In this study, we aimed to clarify the pathophysiological significance of Kcr in cardiac injury and explore the underlying mechanism. METHODS: We investigated the dynamic change of both the Kcr sites and protein level in left ventricular tissues at 2 time points following sham or cardiac ischemia-reperfusion injury, followed by liquid chromatography-coupled tandem mass tag mass spectrometry. After validation of the enriched protein Kcr by immunoprecipitation and Western blot, the function and mechanism of specific Kcr sites were further investigated in vitro and in vivo by gain- or loss-of-function mutations targeting Kcr sites of selected proteins. RESULTS: We found that cardiac ischemia-reperfusion injury triggers preferential Kcr of proteins required for cardiomyocyte contractility, including mitochondrial and cytoskeleton proteins, which occurs largely independently of protein-level changes in the same proteins. Those exhibiting Kcr changes were associated not only with disruption of cardiomyocyte mitochondrial, sarcomere architecture, and gap junction but also with cardiomyocyte autophagy and apoptosis. Modulating site-specific Kcr of selected mitochondrial protein IDH3a (isocitrate dehydrogenase 3 [NAD+] alpha) at K199 and cytoskeletal protein TPM1 (tropomyosin alpha-1 chain) at K28/29 or enhancing general Kcr via sodium crotonate provision not only protects cardiomyocyte from apoptosis by inhibiting BNIP3 (Bcl-2 adenovirus E18 19-kDa-interacting protein 3)-mediated mitophagy or cytoskeleton structure rearrangement but also preserves postinjury myocardial function by inhibiting fibrosis and apoptosis. CONCLUSIONS: Our results indicate that Kcr modulation is a key response of cardiomyocytes to ischemia-reperfusion injury and may represent a novel therapeutic target in the context of ischemic heart disease.

Wnt4 is crucial for cardiac repair by regulating mesenchymal-endothelial transition via the phospho-JNK/JNK.

Rational: Wnt4 plays a critical role in development and is reactivated during fibrotic injury; however, the role of Wnt4 in cardiac repair remains unclear. In this study, our aim was to clarify the pathophysiological role and mechanisms of Wnt4 following acute cardiac ischemic reperfusion injury. Methods and results: We investigated the spatio-temporal expression of Wnt4 following acute cardiac ischemic reperfusion injury and found that Wnt4 was upregulated as an early injury response gene in cardiac fibroblasts near the injury border zone and associated with mesenchymal-endothelial transition (MEndoT), a beneficial process for revascularizing the damaged myocardium in cardiac repair. Using ChIP assay and in vitro and in vivo loss- and gain-of-function, we demonstrated that Wnt4 served as a crucial downstream target gene of p53 during MEndoT. Wnt4 knockdown in cardiac fibroblasts led to decreased MEndoT and worsened cardiac function. Conversely, Wnt4 overexpression in cardiac fibroblasts induced MEndoT in these cells via the phospho-JNK/JNK signaling pathway; however, both the p53 and Wnt4 protein levels were dependent on the ß-catenin signaling pathway. JNK activation plays a critical role in the induction of MEndoT and is crucial for Wnt4 regulated MEndoT. Moreover, Wnt4 overexpression specifically in cardiac fibroblasts rescued the cardiac function worsening due to genetic p53 deletion by decreasing fibrosis and increasing MEndoT and vascular density. Conclusion: Our study revealed that Wnt4 plays a pivotal role in cardiac repair with involvement of phospho-JNK mediated MEndoT and is a crucial gene for cardiac fibroblast-targeted therapy in heart disease.