灌注大鼠心脏中三磷酸腺苷耗竭后糖酵解受损的一种可能机制。
A possible mechanism of glycolytic impairment after adenosine triphosphate deplection in the perfused rat heart.
作者信息
Grinwald P M, Hearse D J, Segal M B
出版信息
J Physiol. 1980 Apr;301:337-47. doi: 10.1113/jphysiol.1980.sp013209.
Abstract
- When the heart is deprived of substrate and O2 for a long period, the ATP content falls to very low levels, with associated changes in ADP and AMP content, and a fall in intracellular pH. 2. These changes appear sufficient to block the hexokinase reaction, outweighing the normal mechanisms controlling this enzyme. Anaerobic glycolysis then remains blocked, even when glucose supply is restored. The block in anaerobic glycolysis can be overcome, however, by a brief period of oxidative metabolism, apparently because the improvement in adenine nucleotide levels serves to 're-prime' the system. 3. When the cell is severely depleted of ATP, the resulting impairment of glycolysis tends to reinforce the low ATP content, establishing a vicious cycle. Metabolic effects of this kind may cause irreversible loss of function, and may contribute to the mechanism of cell death.
摘要
- 当心脏长期缺乏底物和氧气时,ATP含量降至极低水平,同时伴随着ADP和AMP含量的变化以及细胞内pH值下降。2. 这些变化似乎足以阻断己糖激酶反应,其作用超过了控制该酶的正常机制。即使恢复葡萄糖供应,无氧糖酵解仍会受阻。然而,短暂的氧化代谢可克服无氧糖酵解的阻断,这显然是因为腺嘌呤核苷酸水平的改善有助于“重新启动”该系统。3. 当细胞的ATP严重耗竭时,由此导致的糖酵解受损往往会加剧ATP含量的降低,从而形成恶性循环。这种代谢效应可能导致不可逆转的功能丧失,并可能参与细胞死亡机制。
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