脑和肝线粒体系统中谷氨酸氧化的调控
CONTROL OF GLUTAMATE OXIDATION IN BRAIN AND LIVER MITOCHONDRIAL SYSTEMS.
作者信息
BALAZS R
出版信息
Biochem J. 1965 May;95(2):497-508. doi: 10.1042/bj0950497.
Abstract
- Glutamate oxidation in brain and liver mitochondrial systems proceeds mainly through transamination with oxaloacetate followed by oxidation of the alpha-oxoglutarate formed. Both in the presence and absence of dinitrophenol in liver mitochondria this pathway accounted for almost 80% of the uptake of glutamate. In brain preparations the transamination pathway accounted for about 90% of the glutamate uptake. 2. The oxidation of [1-(14)C]- and [5-(14)C]-glutamate in brain preparations is compatible with utilization through the tricarboxylic acid cycle, either after the formation of alpha-oxoglutarate or after decarboxylation to form gamma-aminobutyrate. There is no indication of gamma-decarboxylation of glutamate. 3. The high respiratory control ratio obtained with glutamate as substrate in brain mitochondrial preparations is due to the low respiration rate in the absence of ADP: this results from the low rate of formation of oxaloacetate under these conditions. When oxaloacetate is made available by the addition of malate or of NAD(+), the respiration rate is increased to the level obtained with other substrates. 4. When the transamination pathway of glutamate oxidation was blocked with malonate, the uptake of glutamate was inhibited in the presence of ADP or ADP plus dinitrophenol by about 70 and 80% respectively in brain mitochondrial systems, whereas the inhibition was only about 50% in dinitrophenol-stimulated liver preparations. In unstimulated liver mitochondria in the presence of malonate there was a sixfold increase in the oxidation of glutamate by the glutamate-dehydrogenase pathway. Thus the operating activity of glutamate dehydrogenase is much less than the ;free' (non-latent) activity. 5. The following explanation is put forward for the control of glutamate metabolism in liver and brain mitochondrial preparations. The oxidation of glutamate by either pathway yields alpha-oxoglutarate, which is further metabolized. Since aspartate aminotransferase is present in great excess compared with the respiration rate, the oxaloacetate formed is continuously removed by the transamination reaction. Thus alpha-oxoglutarate is formed independently of glutamate dehydrogenation, and the question is how the dehydrogenation of glutamate is influenced by the continuous formation of alpha-oxoglutarate. The results indicate that a competition takes place between the alpha-oxoglutarate-dehydrogenase complex and glutamate dehydrogenase, probably for NAD(+), resulting in preferential oxidation of alpha-oxoglutarate.
摘要
- 脑和肝线粒体系统中的谷氨酸氧化主要通过与草酰乙酸进行转氨作用,随后氧化所形成的α-酮戊二酸来进行。在肝线粒体中,无论有无二硝基苯酚,该途径几乎占谷氨酸摄取量的80%。在脑制剂中,转氨途径约占谷氨酸摄取量的90%。2. 脑制剂中[1-(14)C]-和[5-(14)C]-谷氨酸的氧化与通过三羧酸循环的利用情况相符,这要么是在形成α-酮戊二酸之后,要么是在脱羧形成γ-氨基丁酸之后。没有迹象表明谷氨酸发生γ-脱羧。3. 在脑线粒体制剂中以谷氨酸作为底物获得的高呼吸控制率是由于在没有ADP的情况下呼吸速率较低:这是由于在这些条件下草酰乙酸的形成速率较低所致。当通过添加苹果酸或NAD(+)使草酰乙酸可用时,呼吸速率增加到与其他底物相同的水平。4. 当用丙二酸阻断谷氨酸氧化的转氨途径时,在脑线粒体系统中,在存在ADP或ADP加二硝基苯酚的情况下,谷氨酸的摄取分别被抑制约70%和80%,而在二硝基苯酚刺激的肝制剂中抑制仅约50%。在存在丙二酸的未刺激肝线粒体中,通过谷氨酸脱氢酶途径的谷氨酸氧化增加了六倍。因此,谷氨酸脱氢酶的活性远低于“游离”(非潜伏)活性。5. 针对肝和脑线粒体制剂中谷氨酸代谢的控制提出了以下解释。通过任何一种途径氧化谷氨酸都会产生α-酮戊二酸,其会进一步代谢。由于天冬氨酸转氨酶的存在量与呼吸速率相比大大过量,所形成的草酰乙酸会通过转氨反应不断被清除。因此,α-酮戊二酸的形成独立于谷氨酸脱氢作用,问题在于谷氨酸的脱氢作用如何受到α-酮戊二酸持续形成的影响。结果表明,α-酮戊二酸脱氢酶复合体与谷氨酸脱氢酶之间可能存在竞争,可能是对NAD(+)的竞争,导致α-酮戊二酸优先被氧化。
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