厌氧大鼠心脏。葡萄糖和三羧酸循环代谢产物对代谢和生理性能的影响。
Anaerobic rat heart. Effects of glucose and tricarboxylic acid-cycle metabolites on metabolism and physiological performance.
作者信息
Penney D G, Cascarano J
出版信息
Biochem J. 1970 Jun;118(2):221-7. doi: 10.1042/bj1180221.
Abstract
- The ability of tricarboxylic acid-cycle metabolites to influence the physiological performance of the perfused anaerobic rat heart was investigated. Energy expenditure/h [(beats/min)x60xsystolic pressure/g of protein] for various anoxic conditions compared with oxygenated control hearts were: 5mm-glucose, 4.5%; 20mm- or 40mm-glucose, 10%; 20mm-glucose plus fumerate+malate+glutamate, 29%; 20mm-glucose plus oxaloacetate and alpha-oxoglutarate, 31%. 2. The energy expenditure/lactate production ratio was increased by the tricarboxylic acid-cycle metabolites, indicating that alterations in anaerobic physiological performance did not result from changes in glycolysis. 3. Analysis of tissue constituents provided further indication of an enhanced energy status for fumarate+malate+glutamate- and oxaloacetate+alpha-oxoglutarate-perfused hearts; tissue concentrations of both glycogen and ATP were higher than in the 20mm-glucose-perfused groups. 4. A marked increase in the accumulation of succinate in tissues perfused with oxaloacetate+alpha-oxoglutarate or fumarate+malate+glutamate provided further evidence that these metabolites were stimulating mitochondrial energy production under anoxia. 5. These studies indicate that mitochondrial ATP production can be stimulated in an isolated mammalian tissue perfused under anaerobiosis with a resulting enhancement of cell function.
摘要
- 研究了三羧酸循环代谢产物对灌注的无氧大鼠心脏生理性能的影响。与有氧对照心脏相比,各种缺氧条件下的能量消耗/小时[(心跳/分钟)×60×收缩压/克蛋白质]为:5毫摩尔葡萄糖,4.5%;20毫摩尔或40毫摩尔葡萄糖,10%;20毫摩尔葡萄糖加延胡索酸+苹果酸+谷氨酸,29%;20毫摩尔葡萄糖加草酰乙酸和α-酮戊二酸,31%。2. 三羧酸循环代谢产物提高了能量消耗/乳酸生成比,表明无氧生理性能的改变并非由糖酵解变化引起。3. 组织成分分析进一步表明,灌注延胡索酸+苹果酸+谷氨酸和草酰乙酸+α-酮戊二酸的心脏能量状态增强;糖原和ATP的组织浓度均高于灌注20毫摩尔葡萄糖的组。4. 灌注草酰乙酸+α-酮戊二酸或延胡索酸+苹果酸+谷氨酸的组织中琥珀酸积累显著增加,进一步证明这些代谢产物在缺氧条件下刺激线粒体能量产生。5. 这些研究表明,在无氧条件下灌注的分离哺乳动物组织中,线粒体ATP生成可被刺激,从而增强细胞功能。
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