Waagepetersen Helle S, Qu Hong, Hertz Leif, Sonnewald Ursula, Schousboe Arne
Department of Pharmacology, Neuroscience PharmaBiotec Research Center, Royal Danish School of Pharmacy, DK-2100 Copenhagen, Denmark.
Neurochem Res. 2002 Nov;27(11):1431-7. doi: 10.1023/a:1021636102735.
Pyruvate recycling was studied in primary cultures of mouse cerebrocortical astrocytes, GABAergic cerebrocortical interneurons, and co-cultures consisting of both cell types by measuring production of [4-(13)C]glutamate from [3-(13)C]glutamate by aid of nuclear magnetic resonance spectroscopy. This change in the position of the label can only occur by entry of [3-(13)C]glutamate into the tricarboxylic acid (TCA) cycle, conversion of labeled alpha-ketoglutarate to malate or oxaloacetate, malic enzyme-mediated decarboxylation of malate to pyruvate or phosphoenolpyruvate carboxykinase-mediated conversion of oxaloacetate to phosphoenolpyruvate and subsequent hydrolysis of the latter to pyruvate, and introduction of the labeled pyruvate into the TCA cycle, i.e., after exit of the carbon skeleton of pyruvate from the TCA cycle followed by re-entry of the same pyruvate molecules via acetyl CoA. In agreement with earlier observations, pyruvate recycling was demonstrated in astrocytes, indicating the ability of these cells to undertake complete oxidative degradation of glutamate. The recycled [4-(13)C]glutamate was not further converted to glutamine, showing compartmentation of astrocytic metabolism. Thus, absence of recycling into glutamine in the brain in vivo cannot be taken as indication that pyruvate recycling is absent in astrocytes. No recycling could be demonstrated in the cerebrocortical neurons. This is consistent with a previously demonstrated lack of incorporation of label from glutamate into lactate, and it also indicates that mitochondrial malic enzyme is not operational. Nor was there any indication of pyruvate recycling in the co-cultures. Although this may partly be due to more rapid depletion of glutamate in the co-cultures, this observation at the very least indicates that pyruvate recycling is not up-regulated in the neuronal-astrocytic co-cultures.
通过借助核磁共振波谱法测量[3-(13)C]谷氨酸生成[4-(13)C]谷氨酸的量,在小鼠大脑皮质星形胶质细胞、γ-氨基丁酸能大脑皮质中间神经元的原代培养物以及由这两种细胞类型组成的共培养物中研究了丙酮酸循环。标记位置的这种变化仅能通过[3-(13)C]谷氨酸进入三羧酸(TCA)循环、标记的α-酮戊二酸转化为苹果酸或草酰乙酸、苹果酸酶介导的苹果酸脱羧生成丙酮酸或磷酸烯醇式丙酮酸羧激酶介导的草酰乙酸转化为磷酸烯醇式丙酮酸以及后者随后水解为丙酮酸,以及将标记的丙酮酸引入TCA循环来发生,即丙酮酸的碳骨架从TCA循环中退出后,相同的丙酮酸分子通过乙酰辅酶A重新进入。与早期观察结果一致,在星形胶质细胞中证实了丙酮酸循环,表明这些细胞有能力对谷氨酸进行完全的氧化降解。循环利用的[4-(13)C]谷氨酸没有进一步转化为谷氨酰胺,这表明星形胶质细胞代谢存在区室化。因此,体内大脑中不存在向谷氨酰胺的循环利用不能被视为星形胶质细胞中不存在丙酮酸循环的迹象。在大脑皮质神经元中未证实有循环利用。这与先前证明的谷氨酸中的标记物未掺入乳酸一致,也表明线粒体苹果酸酶不起作用。在共培养物中也没有丙酮酸循环的迹象。虽然这可能部分是由于共培养物中谷氨酸更快耗尽,但这一观察结果至少表明在神经元-星形胶质细胞共培养物中丙酮酸循环没有上调。
