Abstract

Background: Although metabolic alterations were observed in heart failure (HF), only recently have the mechanisms underlying these changes been identified. Tumor suppressor p53 responds to metabolic changes thorough several mechanisms. One of the p53 targets, TIGAR (TP53-induced glycolysis and apoptosis regulator) reduces glycolysis and suppresses autophagy, which augments ischemic damage, however its role on HF is unclear. Method and Results: In order to investigate TIGAR’s function in HF, we compared myocardial metabolic and functional outcomes between TIGAR deficient (TIGAR–/–) mice and wild-type (TIGAR+/+) mice subjected to chronic thoracic transverse aortic constriction (TAC), a pressure-overload HF model. In wild-type mice hearts, p53 and TIGAR increased markedly during HF development. Eight weeks after TAC surgery, the left ventricular (LV) dysfunction, fibrosis, oxidative damage, and myocyte apoptosis were significantly advanced in wild-type than in TIGAR–/– mouse heart. Further, myocardial high-energy phosphates in wild-type hearts were significantly decreased compared to those of TIGAR–/– mouse heart. Glucose oxidation and glycolysis rates were also reduced in isolated perfused wild-type hearts following TAC than those in TIGAR–/– hearts, which suggest that the upregulation of TIGAR in HF causes impaired myocardial energetics and function. The effects of TIGAR knockout on LV function were also replicated in tamoxifen (TAM)-inducible cardiac-specific TIGAR knockout mice (TIGARflox/flox/ Tg(Myh6-cre/Esr1) mice). Conclusion: The ablation of TIGAR during pressure-overload HF preserves myocardial function and energetics. Thus, cardiac TIGAR targeted therapy to increase glucose metabolism will be a novel strategy for HF.

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