还原型烟酰胺腺嘌呤二核苷酸(磷酸)对大鼠肝脏色氨酸吡咯酶活性的调节。葡萄糖和烟酰胺的实验。
The regulation of rat liver tryptophan pyrrolase activity by reduced nicotinamide-adenine dinucleotide (phosphate). Experiments with glucose and nicotinamide.
作者信息
Badawy A A, Evans M
出版信息
Biochem J. 1976 May 15;156(2):381-90. doi: 10.1042/bj1560381.
Abstract
- Chronic administration of glucose or nicotinamide in drinking water inhibits the activity of rat liver tryptophan pyrrolase, and subsequent withdrawal causes an enhancement. The enzyme activity is also inhibited by administration in drinking water of sucrose, but not fructose, which is capable of preventing the glucose effect. 2. The inhibition by glucose or nictinamide is not due to a defective apoenzyme synthesis nor a decreased cofactor availability. 3. The inhibition by nicotinamide is reversed by regeneration of liver NAD+ and NADP+ in vivo by administration of fructose, pyruvate or phenazine methosulphate. Inhibition by glucose is also reversed by the above agents and by NH4Cl. Reversal of inhibition by glucose or nicotinamide is also achieved in vitro by addition of NAD+ or NADP+. 4. Glucose or nicotinamide increases liver [NADPH]. [NADP+] is also increased by nicotinamide. [NADPH] is also increased by sucrose, but not by fructose, which prevents the glucose effect. Phenazine methosulphate prevents the increase in [NADPH] caused by both glucose and nicotinamide. 5. It is suggested that the inhibition of tryptophan pyrrolase activity by glucose or nicotinamide is mediated by both NADPH and NADH.
摘要
- 长期在饮水中给予葡萄糖或烟酰胺会抑制大鼠肝脏色氨酸吡咯酶的活性,随后停用则会使其活性增强。蔗糖(而非果糖)在饮水中的给予也会抑制该酶活性,果糖能够防止葡萄糖的这种作用。2. 葡萄糖或烟酰胺的抑制作用并非由于脱辅基酶合成缺陷或辅因子可用性降低所致。3. 通过在体内给予果糖、丙酮酸或吩嗪甲硫酸盐使肝脏NAD⁺和NADP⁺再生,可逆转烟酰胺的抑制作用。上述试剂以及NH₄Cl也可逆转葡萄糖的抑制作用。在体外添加NAD⁺或NADP⁺也可实现葡萄糖或烟酰胺抑制作用的逆转。4. 葡萄糖或烟酰胺会增加肝脏[NADPH]。烟酰胺也会使[NADP⁺]增加。蔗糖也会使[NADPH]增加,但果糖不会,果糖可防止葡萄糖的这种作用。吩嗪甲硫酸盐可防止葡萄糖和烟酰胺引起的[NADPH]增加。5. 有人提出,葡萄糖或烟酰胺对色氨酸吡咯酶活性的抑制作用是由NADPH和NADH共同介导的。
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