Cluntun Ahmad A, Visker Joseph R, Velasco-Silva Jesse N, Lang Marisa J, Cedeño-Rosario Luis, Shankar Thirupura S, Hamouche Rana, Ling Jing, Kim Ji Eon, Toshniwal Ashish G, Low Hayden K, Cunningham Corey N, Carrington James, Catrow Jonathan Leon, Pearce Quentinn, Jeong Mi-Young, Bott Alex J, Narbona-Pérez Álvaro J, Stanley Claire E, Li Qing, Eberhardt David R, Morgan Jeffrey T, Yadav Tarun, Wells Chloe E, Ramadurai Dinesh K A, Swiatek Wojciech I, Chaudhuri Dipayan, Rothstein Jeffery D, Muoio Deborah M, Paulo Joao A, Gygi Steven P, Baker Steven A, Navankasattusas Sutip, Cox James E, Funai Katsuhiko, Drakos Stavros G, Rutter Jared, Ducker Gregory S
Department of Biochemistry, University of Utah, Salt Lake City, UT 84112, USA.
Nora Eccles Harrison Cardiovascular Research and Training Institute, University of Utah, Salt Lake City, UT 84112, USA.
bioRxiv. 2024 Oct 8:2024.10.07.617073. doi: 10.1101/2024.10.07.617073.
Lactate is the highest turnover circulating metabolite in mammals. While traditionally viewed as a waste product, lactate is an important energy source for many organs, but first must be oxidized to pyruvate for entry into the tricarboxylic acid cycle (TCA cycle). This reaction is thought to occur in the cytosol, with pyruvate subsequently transported into mitochondria via the mitochondrial pyruvate carrier (MPC). Using C stable isotope tracing, we demonstrated that lactate is oxidized in the myocardial tissue of mice even when the MPC is genetically deleted. This MPC-independent lactate import and mitochondrial oxidation is dependent upon the monocarboxylate transporter 1 (MCT1/). Mitochondria isolated from the myocardium without MCT1 exhibit a specific defect in mitochondrial lactate, but not pyruvate, metabolism. The import and subsequent mitochondrial oxidation of lactate by mitochondrial lactate dehydrogenase (LDH) acts as an electron shuttle, generating sufficient NADH to support respiration even when the TCA cycle is disrupted. In response to diverse cardiac insults, animals with hearts lacking MCT1 undergo rapid progression to heart failure with reduced ejection fraction. Thus, the mitochondrial import and oxidation of lactate enables carbohydrate entry into the TCA cycle to sustain cardiac energetics and maintain myocardial structure and function under stress conditions.
乳酸是哺乳动物中循环代谢物周转率最高的物质。虽然传统上被视为一种废物,但乳酸是许多器官的重要能量来源,但首先必须氧化为丙酮酸才能进入三羧酸循环(TCA循环)。该反应被认为发生在细胞质中,随后丙酮酸通过线粒体丙酮酸载体(MPC)转运到线粒体中。使用碳稳定同位素示踪法,我们证明即使MPC基因缺失,乳酸仍能在小鼠心肌组织中被氧化。这种不依赖MPC的乳酸导入和线粒体氧化依赖于单羧酸转运蛋白1(MCT1)。从没有MCT1的心肌中分离出的线粒体在线粒体乳酸而非丙酮酸代谢方面表现出特定缺陷。线粒体乳酸脱氢酶(LDH)对乳酸的导入及随后的线粒体氧化起到电子穿梭的作用,即使在TCA循环中断时也能产生足够的NADH来支持呼吸作用。在应对各种心脏损伤时,缺乏MCT1的动物心脏会迅速发展为心力衰竭,射血分数降低。因此,乳酸的线粒体导入和氧化使碳水化合物能够进入TCA循环,以在应激条件下维持心脏能量代谢并保持心肌结构和功能。
