猪心乳酸脱氢酶中一个必需组氨酸残基的离子特性
Ionic properties of an essential histidine residue in pig heart lactate dehydrogenase.
作者信息
Holbrook J J, Ingram V A
出版信息
Biochem J. 1973 Apr;131(4):729-38. doi: 10.1042/bj1310729.
Abstract
- Pig heart lactate dehydrogenase is inhibited by addition of one equivalent of diethyl pyrocarbonate. The inhibition is due to the acylation of a unique histidine residue which is 10-fold more reactive than free histidine. No other amino acid side chains are modified. 2. The carbethoxyhistidine residue slowly decomposes and the enzyme activity reappears. 3. The essential histidine residue is only slightly protected by the presence of NADH but is completely protected when substrate and substrate analogues bind to the enzyme-NADH complex. The protection is interpreted in terms of a model in which substrates can only bind to the enzyme in which the histidine residue is protonated and is thus not available for reaction with the acylating agent. 4. The apparent pK(a) of the histidine residue in the apoenzyme is 6.8+/-0.2. In the enzyme-NADH complex it is 6.7+/-0.2. 5. Acylated enzyme binds NADH with unchanged affinity. The enzyme is inhibited because substrates and substrate analogues cannot bind at the acylated histidine residue in the enzyme-NADH complex.
摘要
- 添加一当量焦碳酸二乙酯可抑制猪心乳酸脱氢酶。这种抑制作用是由于一个独特的组氨酸残基被酰化,该残基的反应活性比游离组氨酸高10倍。没有其他氨基酸侧链被修饰。2. 乙氧羰基组氨酸残基会缓慢分解,酶活性重新出现。3. 必需的组氨酸残基仅受到少量NADH的保护,但当底物和底物类似物与酶 - NADH复合物结合时,它会受到完全保护。这种保护作用可以根据一个模型来解释,在该模型中,底物只能与组氨酸残基质子化的酶结合,因此不能与酰化剂反应。4. 脱辅酶中组氨酸残基的表观pK(a)为6.8±0.2。在酶 - NADH复合物中,它为6.7±0.2。5. 酰化酶以不变的亲和力结合NADH。酶被抑制是因为底物和底物类似物不能在酶 - NADH复合物中酰化的组氨酸残基处结合。
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