[Mechanisms regulating citric acid metabolism in the brain].

Voprosy biokhimii mozga Pub Date : 1976-01-01

N D Eshchenko, M I Prokhorova

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Abstract

The changes in the rates of citrate biosynthesis and utilization in rat brain, liver, kidney and heart, produced by hypoxia, action of 2,4-DNP and thyreotoxicosis, were compared with changes of some regulatory parameters under the same conditions. The comparison of citrate-synthase activities, citrate levels in tissues and 14C-incorporation from different precursors into citric acid permitted us to establish that the biosynthesis of citrate in brain was more intensive than in other tissues studied. The main source of acetyl-CoA for citrate-synthase reaction in brain is the oxidation of pyruvate. The ratio of adenine nucleotides plays an important role in the control of citrate-synthase activity in brain, where the oxaloacetate control is not as significant as in liver. NAD-specific isocitrate dehydrogenase reaction was found to be the dominant pathway for citrate oxidation in brain: more than 60 percent of brain citrate were oxidized by NAD-ICDH, while less than 10 percent of citric acid were utilized by this enzyme in other tissues studied. The existance of an adenine nucleotide control of NAD-ICDH activity in brain may be an additional mechanism for the regulation of the first steps of energy metabolism in brain.

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[调节大脑中柠檬酸代谢的机制]。

比较了缺氧、2,4- dnp作用和甲状腺中毒对大鼠脑、肝、肾和心脏中柠檬酸盐生物合成和利用速率的变化，以及相同条件下一些调节参数的变化。通过比较柠檬酸合酶活性、组织中柠檬酸水平和不同前体向柠檬酸中掺入14c的情况，我们可以确定，大脑中柠檬酸的生物合成比研究的其他组织更强烈。脑内柠檬酸合酶反应中乙酰辅酶a的主要来源是丙酮酸的氧化。在大脑中，腺嘌呤核苷酸的比例在控制柠檬酸合酶活性方面起着重要作用，而草酰乙酸的控制作用不如肝脏那么显著。研究发现，nad特异性异柠檬酸脱氢酶反应是大脑中柠檬酸氧化的主要途径:超过60%的脑柠檬酸被NAD-ICDH氧化，而在研究的其他组织中，只有不到10%的柠檬酸被该酶利用。脑内腺嘌呤核苷酸控制nad1 - icdh活性的存在可能是脑内能量代谢第一步调节的另一种机制。

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Voprosy biokhimii mozga

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