Department of Physiology, Anatomy and Genetics, University of Oxford, Oxford, UK.
Buck Institute for Research on Aging, Novato, CA, USA.
J Physiol. 2023 Apr;601(7):1207-1224. doi: 10.1113/JP284270. Epub 2023 Mar 1.
In heart, glucose and glycolysis are important for anaplerosis and potentially therefore for d-β-hydroxybutyrate (βHB) oxidation. As a glucose store, glycogen may also furnish anaplerosis. We determined the effects of glycogen content on βHB oxidation and glycolytic rates, and their downstream effects on energetics, in the isolated rat heart. High glycogen (HG) and low glycogen (LG) containing hearts were perfused with 11 mM [5- H]glucose and/or 4 mM [ C]βHB to measure glycolytic rates or βHB oxidation, respectively, then freeze-clamped for glycogen and metabolomic analyses. Free cytosolic [NAD ]/[NADH] and mitochondrial [Q ]/[QH ] ratios were estimated using the lactate dehydrogenase and succinate dehydrogenase reaction, respectively. Phosphocreatine (PCr) and inorganic phosphate (P ) concentrations were measured using P-nuclear magnetic resonance spectroscopy. Rates of βHB oxidation in LG hearts were half that in HG hearts, with βHB oxidation directly proportional to glycogen content. βHB oxidation decreased glycolysis in all hearts. Glycogenolysis in glycogen-replete hearts perfused with βHB alone was twice that of hearts perfused with βHB and glucose, which had significantly higher levels of the glycolytic intermediates fructose 1,6-bisphosphate and 3-phosphoglycerate, and higher free cytosolic [NAD ]/[NADH]. βHB oxidation increased the Krebs cycle intermediates citrate, 2-oxoglutarate and succinate, the total NADP/H pool, reduced mitochondrial [Q ]/[QH ], and increased the calculated free energy of ATP hydrolysis (∆G ). Although βHB oxidation inhibited glycolysis, glycolytic intermediates were not depleted, and cytosolic free NAD remained oxidised. βHB oxidation alone increased Krebs cycle intermediates, reduced mitochondrial Q and increased ∆G . We conclude that glycogen facilitates cardiac βHB oxidation by anaplerosis. KEY POINTS: Ketone bodies (d-β-hydroxybutyrate, acetoacetate) are increasingly recognised as important cardiac energetic substrates, in both healthy and diseased hearts. As 2-carbon equivalents they are cataplerotic, causing depletion of Krebs cycle intermediates; therefore their utilisation requires anaplerotic supplementation, and intra-myocardial glycogen has been suggested as a potential anaplerotic source during ketone oxidation. It is demonstrated here that cardiac glycogen does indeed provide anaplerotic substrate to facilitate β-hydroxybutyrate oxidation in isolated perfused rat heart, and this contribution was quantified using a novel pulse-chase metabolic approach. Further, using metabolomics and P-MR, it was shown that glycolytic flux from myocardial glycogen increased the heart's ability to oxidise βHB, and βHB oxidation increased the mitochondrial redox potential, ultimately increasing the free energy of ATP hydrolysis.
在心脏中,葡萄糖和糖酵解对于氨甲酰磷酸合成作用(anaplerosis)很重要,因此可能对于 D-β-羟丁酸(βHB)的氧化也是如此。作为葡萄糖的储存库,糖原也可能为氨甲酰磷酸合成作用提供底物。我们在分离的大鼠心脏中确定了糖原含量对 βHB 氧化和糖酵解速率的影响,以及它们对能量学的下游影响。用含有 11mM [5-H]葡萄糖和/或 4mM [C]βHB 的高糖原(HG)和低糖原(LG)心脏进行灌流,分别测量糖酵解速率或 βHB 氧化,然后进行冷冻钳夹以进行糖原和代谢组学分析。使用乳酸脱氢酶和琥珀酸脱氢酶反应分别估计细胞质游离态 [NAD ]/[NADH]和线粒体 [Q ]/[QH ]的比值。使用 31P 核磁共振光谱法测量磷酸肌酸(PCr)和无机磷(P )浓度。LG 心脏的 βHB 氧化速率仅为 HG 心脏的一半,βHB 氧化直接与糖原含量成正比。βHB 氧化降低了所有心脏的糖酵解。仅用 βHB 灌注的糖原充足的心脏中的糖原分解作用是用 βHB 和葡萄糖灌注的心脏的两倍,后者的糖酵解中间产物 1,6-二磷酸果糖和 3-磷酸甘油酸的水平明显更高,并且细胞质游离态 [NAD ]/[NADH]更高。βHB 氧化增加了柠檬酸、2-氧戊二酸和琥珀酸等三羧酸循环中间产物、总 NADPH 池、减少线粒体 [Q ]/[QH ],并增加了计算出的 ATP 水解自由能(∆G )。尽管 βHB 氧化抑制糖酵解,但糖酵解中间产物并未耗尽,细胞质游离态 NAD 仍保持氧化状态。单独的 βHB 氧化增加了三羧酸循环中间产物,减少了线粒体 Q 值并增加了 ∆G 。我们得出结论,糖原通过氨甲酰磷酸合成作用促进心脏的 βHB 氧化。要点:酮体(D-β-羟丁酸、乙酰乙酸盐)越来越被认为是健康和患病心脏中重要的心脏能量底物。作为 2 碳当量,它们是脱碳作用的,导致三羧酸循环中间产物耗竭;因此,它们的利用需要氨甲酰磷酸合成作用的补充,并且心肌内糖原已被提议为酮氧化期间的潜在氨甲酰磷酸合成作用来源。在这里证明,心脏糖原确实为β-羟丁酸在分离的灌注大鼠心脏中的氧化提供了氨甲酰磷酸合成作用底物,并且使用新型脉冲追踪代谢方法对这种贡献进行了量化。此外,通过代谢组学和 31P-MR,表明来自心肌糖原的糖酵解通量增加了心脏氧化βHB 的能力,并且βHB 氧化增加了线粒体氧化还原电位,最终增加了 ATP 水解的自由能。
