Holtzman D, Meyers R, O'Gorman E, Khait I, Wallimann T, Allred E, Jensen F
Department of Neurology, Children's Hospital, Boston, Massachusetts, USA.
Am J Physiol. 1997 May;272(5 Pt 1):C1567-77. doi: 10.1152/ajpcell.1997.272.5.C1567.
Mitochondrial and cytosolic creatine kinase (CK) isozymes are active in cells with high and variable ATP metabolic rates. beta-Guanidinopropionic acid (GPA), a competitive inhibitor of creatine transport, was used to study the hypothesis that the creatine-CK-phosphocreatine (PCr) system is important in regulating brain ATP metabolism. The CK-catalyzed reaction rate and reactant concentrations were measured in vivo with 31P nuclear magnetic resonance spectroscopy during energy deficit (hypoxia) or high-energy turnover (seizures) states in urethane-anesthetized mice fed GPA, creatine, or standard chow (controls). Brain phosphagen (i.e., cellular energy reserves) or PCr plus phosphorylated GPA (GPAP) concentrations were equal. The phosphagen-to-NTP ratio was lower than in controls. In vivo CK reaction rate decreased fourfold, whereas ex vivo CK activity that was biochemically measured was doubled. During seizures, CK-catalyzed fluxes increased only in GPA-fed mice. Phosphagen increased in GPA-fed mice, whereas PCr decreased in controls. Survival was higher and brain phosphagen and ATP losses were less for hypoxic GPA-fed mice than for controls. In contrast to mice fed GPA, hypoxic survival and CK reactant concentrations during hypoxia and seizures were the same in creatine-fed mice and controls. Thus GPA, GPAP, or adaptive changes in ATP metabolism stabilize brain ATP and enhance survival during hypoxia in mice.
线粒体和胞质肌酸激酶(CK)同工酶在具有高且可变ATP代谢率的细胞中具有活性。β-胍基丙酸(GPA)是肌酸转运的竞争性抑制剂,用于研究肌酸-CK-磷酸肌酸(PCr)系统在调节脑ATP代谢中起重要作用这一假说。在给喂食GPA、肌酸或标准食物(对照)的氨基甲酸乙酯麻醉小鼠造成能量不足(缺氧)或高能转换(癫痫发作)状态期间,用31P核磁共振波谱法在体内测量CK催化的反应速率和反应物浓度。脑磷酸原(即细胞能量储备)或PCr加磷酸化GPA(GPAP)浓度相等。磷酸原与NTP的比率低于对照组。体内CK反应速率降低了四倍,而生化测量的体外CK活性增加了一倍。在癫痫发作期间,CK催化的通量仅在喂食GPA的小鼠中增加。喂食GPA的小鼠中磷酸原增加,而对照组中PCr减少。缺氧的喂食GPA小鼠的存活率更高,脑磷酸原和ATP损失比对照组少。与喂食GPA的小鼠相反,喂食肌酸的小鼠和对照组在缺氧和癫痫发作期间的缺氧存活率和CK反应物浓度相同。因此,GPA、GPAP或ATP代谢的适应性变化可稳定小鼠脑ATP并提高缺氧期间的存活率。