Bakken I J, White L R, Unsgård G, Aasly J, Sonnewald U
Department of Physics, Norwegian University of Science and Technology (NTNU), Trondheim.
J Neurosci Res. 1998 Mar 1;51(5):636-45. doi: 10.1002/(SICI)1097-4547(19980301)51:5<636::AID-JNR11>3.0.CO;2-0.
The ability of cultured astrocytes to metabolize [U-13C]glutamate in the absence of glucose was investigated by utilizing 13C nuclear magnetic resonance spectroscopy to identify 13C-labeled metabolites. Control cultures (3 mM glucose), hypoglycemic cultures (glucose-deprived), severe hypoglycemic cultures (glucose-deprived, 0.5 mM iodoacetate as an inhibitor of glycolysis), hypoglycemic/hypoxic cultures, and cultures deprived of all additional substrates were incubated for 2 hr in medium containing 0.5 mM glutamate (50% [U-13C]glutamate). Glucose deprivation alone had little effect on removal of glutamate from the culture medium, but the presence of iodoacetate or incubating cultures in a low-oxygen atmosphere decreased glutamate clearance. Only the withdrawal of all substrates other than glutamate decreased glutamine synthesis. Metabolism of glutamate through the tricarboxylic acid (TCA) cycle was evident by the appearance of [1,2,3-13C]glutamate and [U-13C]aspartate in cell extracts and [U-13C]lactate in cell media. Lactate derived from TCA cycle intermediates was significantly reduced after glucose deprivation and even more so after severe hypoglycemia. Release of glutamate from astrocytes was observed under all incubation conditions. [U-13C]Aspartate was not detected in control media but was released from glucose-deprived cells when oxygen was available. Increased release was observed in the presence of iodoacetate. After withdrawal of all substrates other than glutamate, [U-13C]aspartate was the only metabolite observed intracellularly, whereas aspartate, glutamine, and 5-oxoproline were detected in the incubation medium. The present results indicate that glutamate-to-aspartate conversion is preferentially utilized by astrocytes when oxygen is available but glycolysis is impaired.
利用13C核磁共振波谱法鉴定13C标记的代谢物,研究了培养的星形胶质细胞在无葡萄糖情况下代谢[U-13C]谷氨酸的能力。对照培养物(3 mM葡萄糖)、低血糖培养物(葡萄糖剥夺)、严重低血糖培养物(葡萄糖剥夺,0.5 mM碘乙酸作为糖酵解抑制剂)、低血糖/低氧培养物以及剥夺所有其他底物的培养物,在含有0.5 mM谷氨酸(50%[U-13C]谷氨酸)的培养基中孵育2小时(应为2小时)。单独的葡萄糖剥夺对从培养基中去除谷氨酸的影响很小,但碘乙酸的存在或在低氧气氛中孵育培养物会降低谷氨酸清除率。只有去除谷氨酸以外的所有底物才会降低谷氨酰胺的合成。通过细胞提取物中[1,2,3-13C]谷氨酸和[U-13C]天冬氨酸以及细胞培养基中[U-13C]乳酸的出现,表明谷氨酸通过三羧酸(TCA)循环进行代谢。葡萄糖剥夺后,源自TCA循环中间体的乳酸显著减少,严重低血糖后更是如此。在所有孵育条件下均观察到星形胶质细胞释放谷氨酸。对照培养基中未检测到[U-13C]天冬氨酸,但在有氧气时,葡萄糖剥夺的细胞会释放[U-13C]天冬氨酸。在碘乙酸存在下观察到释放增加。去除谷氨酸以外的所有底物后,[U-13C]天冬氨酸是细胞内观察到的唯一代谢物,而在孵育培养基中检测到天冬氨酸、谷氨酰胺和5-氧代脯氨酸。目前的结果表明,当有氧气但糖酵解受损时,星形胶质细胞优先利用谷氨酸向天冬氨酸的转化。 (注:原文中“incubated for 2 hr”翻译时少了个“2”,已补充完整)
