果糖负荷后肝脏中三磷酸腺苷耗竭的机制。肝脏腺苷酸脱氨酶的动力学研究。
The mechanism of adenosine triphosphate depletion in the liver after a load of fructose. A kinetic study of liver adenylate deaminase.
作者信息
van den Berghe G, Bronfman M, Vanneste R, Hers H G
出版信息
Biochem J. 1977 Mar 15;162(3):601-9. doi: 10.1042/bj1620601.
Abstract
- The hepatic concentration of several nucleotides and metabolites was measured during the first few minutes after an intravenous load of fructose to mice. The first changes, observed at 30s, were a decrease in the concentration of Pi and a simultaneous accumulation of fructose 1-phosphate. The decrease in the concentrations of ATP and GTP proceeded more slowly. An increase in the concentration of IMP was detected only after 1 min and could therefore not be considered to be the cause of the accumulation of fructose 1-phosphate. 2. To explain the temporary burst of adenine nucleotide breakdown that occurs after a load of fructose, the kinetics of AMP deaminase (EC 3.5.4.6) from rat liver were reinvestigated at physiological (0.2 mM) concentration of substrate. For this purpose, a new radiochemical-assay procedure was developed. At 0.2mM-AMP a low activity could be measured, which was more than 90% inhibited by 5mM-Pi. ATP (3MM) increased the enzyme activity over 200-fold. Pi alone did not influence the ATP-activated enzyme, but 0.5mM-GTP caused a 60% inhibition. The combined effect of both inhibitors at their physiological concentrations reached 95%. 3. It is proposed that the rapid degradation of adenine nucleotides that occurs after a load of fructose is caused by a decrease in the concentration of both inhibitors, Pi and GTP, soon counteracted by the decrease in the concentration of ATP. 4. Some of the kinetic parameters of liver AMP deaminase were computed in terms of the concerted transition theory of Monod, Wyman & Changeux (1965) (J. Mol. Biol. 12, 88-118).
摘要
- 在给小鼠静脉注射果糖后的最初几分钟内,测量了几种核苷酸和代谢物的肝脏浓度。在30秒时观察到的最初变化是无机磷酸(Pi)浓度降低,同时1-磷酸果糖积累。三磷酸腺苷(ATP)和三磷酸鸟苷(GTP)浓度的降低进展较为缓慢。仅在1分钟后才检测到次黄嘌呤核苷酸(IMP)浓度增加,因此不能认为它是1-磷酸果糖积累的原因。2. 为了解释果糖负荷后发生的腺嘌呤核苷酸分解的短暂爆发,在底物生理浓度(0.2 mM)下重新研究了大鼠肝脏中AMP脱氨酶(EC 3.5.4.6)的动力学。为此,开发了一种新的放射化学测定方法。在0.2 mM-AMP时可测量到低活性,5 mM-Pi可抑制该活性的90%以上。3 mM-ATP使酶活性增加了200倍以上。单独的Pi不影响ATP激活的酶,但0.5 mM-GTP会导致60%的抑制。两种抑制剂在其生理浓度下的联合作用达到95%。3. 有人提出,果糖负荷后腺嘌呤核苷酸的快速降解是由两种抑制剂Pi和GTP浓度降低引起的,而ATP浓度的降低很快抵消了这种作用。4. 根据莫诺德、怀曼和尚热(1965年)(《分子生物学杂志》12卷,88 - 118页)的协同转变理论计算了肝脏AMP脱氨酶的一些动力学参数。
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