Defective branched chain amino acid catabolism contributes to cardiac dysfunction and remodeling following myocardial infarction

W Wang, F Zhang, Y Xia, S Zhao… - American Journal …, 2016 - journals.physiology.org
W Wang, F Zhang, Y Xia, S Zhao, W Yan, H Wang, Y Lee, C Li, L Zhang, K Lian, E Gao
American Journal of Physiology-Heart and Circulatory Physiology, 2016journals.physiology.org
Cardiac metabolic remodeling is a central event during heart failure (HF) development
following myocardial infarction (MI). It is well known that myocardial glucose and fatty acid
dysmetabolism contribute to post-MI cardiac dysfunction and remodeling. However, the role
of amino acid metabolism in post-MI HF remains elusive. Branched chain amino acids
(BCAAs) are an important group of essential amino acids and function as crucial nutrient
signaling in mammalian animals. The present study aimed to determine the role of cardiac …
Cardiac metabolic remodeling is a central event during heart failure (HF) development following myocardial infarction (MI). It is well known that myocardial glucose and fatty acid dysmetabolism contribute to post-MI cardiac dysfunction and remodeling. However, the role of amino acid metabolism in post-MI HF remains elusive. Branched chain amino acids (BCAAs) are an important group of essential amino acids and function as crucial nutrient signaling in mammalian animals. The present study aimed to determine the role of cardiac BCAA metabolism in post-MI HF progression. Utilizing coronary artery ligation-induced murine MI models, we found that myocardial BCAA catabolism was significantly impaired in response to permanent MI, therefore leading to an obvious elevation of myocardial BCAA abundance. In MI-operated mice, oral BCAA administration further increased cardiac BCAA levels, activated the mammalian target of rapamycin (mTOR) signaling, and exacerbated cardiac dysfunction and remodeling. These data demonstrate that BCAAs act as a direct contributor to post-MI cardiac pathologies. Furthermore, these BCAA-mediated deleterious effects were improved by rapamycin cotreatment, revealing an indispensable role of mTOR in BCAA-mediated adverse effects on cardiac function/structure post-MI. Of note, pharmacological inhibition of branched chain ketoacid dehydrogenase kinase (BDK), a negative regulator of myocardial BCAA catabolism, significantly improved cardiac BCAA catabolic disorders, reduced myocardial BCAA levels, and ameliorated post-MI cardiac dysfunction and remodeling. In conclusion, our data provide the evidence that impaired cardiac BCAA catabolism directly contributes to post-MI cardiac dysfunction and remodeling. Moreover, improving cardiac BCAA catabolic defects may be a promising therapeutic strategy against post-MI HF.
American Physiological Society