大鼠脑线粒体的代谢。关于钾离子刺激的丙酮酸氧化的研究。
Metabolism of rat brain mitochondria. Studies on the potassium ion-stimulated oxidation of pyruvate.
作者信息
Nicklas W J, Clark J B, Williamson J R
出版信息
Biochem J. 1971 Jun;123(1):83-95. doi: 10.1042/bj1230083.
Abstract
- Rat brain-cortex mitochondria were incubated in media containing 1, 5 or 100mm-K(+) in the presence of ADP, uncoupler (FCCP, carbonyl cyanide p-trifluoro-methoxyphenylhydrazone) or valinomycin while metabolizing pyruvate and malate, or acetylcarnitine and malate or glutamate and malate as substrates. Both the uptake of oxygen and disappearance of substrate were measured under these conditions. 2. With pyruvate and malate as substrate in the presence of both ADP and valinomycin, both the uptake of oxygen and disappearance of pyruvate increased markedly on increasing the K(+) content of the incubation medium from 5 to 100mm-K(+). However, in the presence of uncoupler (FCCP), although the oxygen uptake doubled little change was observed in the rate of disappearance of pyruvate on increasing the K(+) concentration. 3. Only small changes in uptake of substrate and oxygen were observed in the presence of ADP, uncoupler (FCCP) or valinomycin on increasing the K(+) concentration when acetylcarnitine+malate or glutamate+malate were used as substrates by brain mitochondria. 4. Further, increasing the K(+) concentration from 1 to 20mm when rat brain mitochondria were oxidizing a mixture of pyruvate and glutamate in the presence of malate and ADP caused a 30% increase in the respiration rate, 50% increase in the rate of disappearance of pyruvate and an 80% decrease in the rate of disappearance of glutamate. 5. Investigation of the redox state of the cytochromes and the nicotinamide nucleotides in various conditions with either pyruvate or acetylcarnitine as substrates suggested that the specific stimulation of metabolism of pyruvate by K(+) could not be explained by a general stimulation of the electron-transport system. 6. Low-amplitude high-energy swelling of rat brain mitochondria was investigated in both Na(+)- and K(+)-containing media. Swelling of brain mitochondria was much greater in the Na(+)-containing medium and in this medium, the addition of Mg(2+) caused a partial reversal of swelling together with an 85% decrease in the rate of utilization of pyruvate. However, in the K(+)-containing medium, the addition of Mg(2+), although also causing a reversal of swelling, did not affect the rate of disappearance of pyruvate. 7. Measurements of the ATP, NADH/NAD(+) and acetyl-CoA/CoA contents were made under various conditions and no evidence that K(+) concentrations affected these parameters was obtained. 8. The results are discussed in relationship to the physiological significance of the stimulation of pyruvate metabolism by K(+) in rat brain mitochondria. It is proposed that K(+) causes its effects by a direct stimulation of the pyruvate dehydrogenase complex.
摘要
- 将大鼠脑皮质线粒体置于含有1、5或100mM - K⁺的培养基中,在存在ADP、解偶联剂(FCCP,羰基氰对三氟甲氧基苯腙)或缬氨霉素的情况下,以丙酮酸和苹果酸、乙酰肉碱和苹果酸或谷氨酸和苹果酸作为底物进行代谢。在这些条件下测量氧气摄取量和底物消失量。2. 以丙酮酸和苹果酸作为底物,在同时存在ADP和缬氨霉素的情况下,将孵育培养基中的K⁺含量从5mM增加到100mM时,氧气摄取量和丙酮酸消失量均显著增加。然而,在存在解偶联剂(FCCP)的情况下,尽管氧气摄取量翻倍,但在增加K⁺浓度时,丙酮酸消失速率几乎没有变化。3. 当脑线粒体以乙酰肉碱 + 苹果酸或谷氨酸 + 苹果酸作为底物时,在存在ADP、解偶联剂(FCCP)或缬氨霉素的情况下,增加K⁺浓度时,底物摄取量和氧气摄取量仅有微小变化。4. 此外,当大鼠脑线粒体在存在苹果酸和ADP的情况下氧化丙酮酸和谷氨酸的混合物时,将K⁺浓度从1mM增加到20mM会导致呼吸速率增加30%,丙酮酸消失速率增加50%,谷氨酸消失速率降低80%。5. 以丙酮酸或乙酰肉碱作为底物,在各种条件下对细胞色素和烟酰胺核苷酸的氧化还原状态进行研究,结果表明K⁺对丙酮酸代谢的特异性刺激无法通过对电子传递系统的普遍刺激来解释。6. 在含Na⁺和含K⁺的培养基中研究了大鼠脑线粒体的低幅度高能肿胀。脑线粒体在含Na⁺的培养基中肿胀程度大得多,在该培养基中添加Mg²⁺会导致肿胀部分逆转,同时丙酮酸利用速率降低85%。然而,在含K⁺的培养基中,添加Mg²⁺虽然也会导致肿胀逆转,但不影响丙酮酸消失速率。7. 在各种条件下测量了ATP、NADH/NAD⁺和乙酰辅酶A/辅酶A的含量,未获得K⁺浓度影响这些参数的证据。8. 讨论了这些结果与K⁺刺激大鼠脑线粒体丙酮酸代谢的生理意义之间的关系。提出K⁺通过直接刺激丙酮酸脱氢酶复合体发挥作用。
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