后负荷诱导的脂肪酸氧化减少与葡萄糖利用增加无关

Hande Piristine, Herman I May, Nan Jiang, Daniel Daou, Francisco Olivares-Silva, Abdallah Elnwasany, Pamela Szweda, Caroline Kinter, Michael Kinter, Gaurav Sharma, Xiaodong Wen, Craig R Malloy, Michael E. Jessen, Thomas G. Gillette, Joseph A Hill
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引用次数: 0

摘要

背景:射血分数保留型心力衰竭(HFpEF)是全球心力衰竭的主要病因,其代谢底物利用是综合征发病机制的关键,但目前仍未明确。在静息状态下,游离脂肪酸(FFA)的氧化是心脏的主要能量来源,支持心脏持续的收缩活动。然而,在与疾病相关的压力下,心脏会更多地依赖葡萄糖。肥胖或糖尿病是导致高频心衰的主要病理生理因素,在肥胖或糖尿病的情况下,代谢底物向葡萄糖的转移会受到影响,这有时可归因于葡萄糖氧化与脂肪代谢相比对氧气的需求更低。但这一观点从未得到证实。此外,虽然在后负荷增加的情况下需氧量会增加,但心肌氧供应仍足以进行脂肪酸氧化(FAO)。因此,有人提出了对葡萄糖的偏好:丙酮酸脱氢酶复合物(PDC)是连接糖酵解和 TCA 循环的限速酶。由于 PDK4(丙酮酸脱氢酶 4)在高密度脂蛋白血症中上调,我们在心肌细胞中过度表达 PDK4,确保 PDC 磷酸化,从而抑制 PDC。这导致丙酮酸作为能量底物的使用减少,模拟了 HFpEF 中葡萄糖氧化的下降。重要的是,与 HFpEF 相关性肥胖不同,该模型使我们能够在没有全身性高脂肪的条件下逆转负荷诱导的葡萄糖利用转变。不出所料,PDK4 转基因小鼠在基线时表现出正常的心脏性能。然而,当L-NAME或手术横主动脉收缩(TAC)导致后负荷适度增加时,它们的收缩性能就会迅速严重下降。这种功能下降并没有伴随着心肌肥厚生长反应的加剧。令人惊讶的是,代谢通量分析表明,在 TAC 之后,即使葡萄糖/丙酮酸的利用被钳制在非常低的水平,部分 FAO 也会下降。此外,参与 FFA 转运和氧化的蛋白质在 TAC 后出现下调,与基因型无关。结论:这些数据表明,心肌细胞在葡萄糖利用率大幅降低且无法增加的情况下,不会通过上调脂肪酸的使用来弥补葡萄糖利用率的不足。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Afterload-induced Decreases in Fatty Acid Oxidation Develop Independently of Increased Glucose Utilization
Background: Metabolic substrate utilization in HFpEF (heart failure with preserved ejection fraction), the leading cause of heart failure worldwide, is pivotal to syndrome pathogenesis and yet remains ill defined. Under resting conditions, oxidation of free fatty acids (FFA) is the predominant energy source of the heart, supporting its unremitting contractile activity. In the context of disease-related stress, however, a shift toward greater reliance on glucose occurs. In the setting of obesity or diabetes, major contributors to HFpEF pathophysiology, the shift in metabolic substrate use toward glucose is impaired, sometimes attributed to the lower oxygen requirement of glucose oxidation versus fat metabolism. This notion, however, has never been tested conclusively. Furthermore, whereas oxygen demand increases in the setting of increased afterload, myocardial oxygen availability remains adequate for fatty acid oxidation (FAO). Therefore, a preference for glucose has been proposed. Methods and Results: Pyruvate dehydrogenase complex (PDC) is the rate-limiting enzyme linking glycolysis to the TCA cycle. As PDK4 (PDC kinase 4) is up-regulated in HFpEF, we over-expressed PDK4 in cardiomyocytes, ensuring that PDC is phosphorylated and thereby inhibited. This leads to diminished use of pyruvate as energy substrate, mimicking the decline in glucose oxidation in HFpEF. Importantly, distinct from HFpEF-associated obesity, this model positioned us to abrogate the load-induced shift to glucose utilization in the absence of systemic high fat conditions. As expected, PDK4 transgenic mice manifested normal cardiac performance at baseline. However, they manifested a rapid and severe decline in contractile performance when challenged with modest increases in afterload triggered either by L-NAME or surgical transverse aortic constriction (TAC). This decline in function was not accompanied by an exacerbation of the myocardial hypertrophic growth response. Surprisingly, metabolic flux analysis revealed that, after TAC, fractional FAO decreased, even when glucose/pyruvate utilization was clamped at very low levels. Additionally, proteins involved in the transport and oxidation of FFA were paradoxically downregulated after TAC regardless of genotype. Conclusions: These data demonstrate that cardiomyocytes in a setting in which glucose utilization is robustly diminished and prevented from increasing do not compensate for the deficit in glucose utilization by up-regulating FFA use.
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