胰岛素浓度和自缔合对其A-21环酐中间体向脱酰胺胰岛素和共价二聚体分配的影响。

Effects of insulin concentration and self-association on the partitioning of its A-21 cyclic anhydride intermediate to desamido insulin and covalent dimer.

作者信息

Darrington R T, Anderson B D

机构信息

Department of Pharmaceutics and Pharmaceutical Chemistry, College of Pharmacy, University of Utah, Salt Lake City 84112, USA.

出版信息

Pharm Res. 1995 Jul;12(7):1077-84. doi: 10.1023/a:1016231019677.

DOI:10.1023/a:1016231019677

PMID:7494806

Abstract

PURPOSE

In the pH range 2-5, human insulin degrades via deamidation at the A-21 asn and covalent dimerization. Both products form via a common cyclic anhydride intermediate, a product of intramolecular neucleophilic attack by the A-21 carboxyl terminus. This study examines the influence of [insulin] and self-association on the partitioning of the intermediate to products.

METHODS

Insulin self-association was characterized (pH 2-4) by concentration difference spectroscopy. Deamination rates (pH 2-4) and concurrent rates of covalent dimer formation (pH 4) were determined versus [insulin] at 35 degrees C by initial rates. A mathematical model was developed to account for the overall rate and product composition profile versus pH and [insulin].

RESULTS

Between pH 2-4, insulin self-associates to form non-covalent dimers with a pH independent association constant of 1.8 x 10(4) M-1. The overall rate of degradation is governed by intermediate formation, while product distribution is determined by competition between water and the phe B-1 amino group of insulin for the anhydride. In dilute solutions, deamidation is first-order in [insulin] while covalent dimerization is second-order. Thus, deamidation predominates in dilute solutions but the fraction of covalent dimer formed increases with [insulin]. At high [insulin], self-association inhibits covalent dimer formation, preventing exclusive degradation via this pathway. The model accurately predicts a maximum in covalent dimer formation near pH 4.

CONCLUSIONS

A mechanism is described which accounts for the complex dependence of insulin's degradation rate and product distribution profile on pH (between 2-5) and [insulin]. If these results can be generalized, they suggest that covalent aggregation in proteins may be inhibited by self-association.

摘要

目的

在pH值2 - 5范围内，人胰岛素通过A - 21天冬酰胺处的脱酰胺作用和共价二聚化进行降解。这两种产物均通过一个共同的环状酸酐中间体形成，该中间体是A - 21羧基末端分子内亲核攻击的产物。本研究考察了胰岛素浓度和自缔合对中间体向产物分配的影响。

方法

通过浓度差光谱法表征胰岛素在pH值2 - 4时的自缔合情况。在35℃下，通过初始速率法测定脱氨速率（pH值2 - 4）和共价二聚体形成的同时速率（pH值4）与胰岛素浓度的关系。建立了一个数学模型来解释总体速率和产物组成随pH值和胰岛素浓度的变化情况。

结果

在pH值2 - 4之间，胰岛素自缔合形成非共价二聚体，其缔合常数为1.8×10⁴ M⁻¹，与pH值无关。降解的总体速率由中间体的形成决定，而产物分布则由水和胰岛素的苯丙氨酸B - 1氨基对酸酐的竞争决定。在稀溶液中，脱酰胺反应对胰岛素浓度呈一级反应，而共价二聚化反应呈二级反应。因此，脱酰胺反应在稀溶液中占主导，但形成的共价二聚体的比例随胰岛素浓度增加而增加。在高胰岛素浓度下，自缔合抑制共价二聚体的形成，从而防止通过该途径的唯一降解。该模型准确预测了在pH值接近4时共价二聚体形成的最大值。

结论

描述了一种机制，该机制解释了胰岛素降解速率和产物分布随pH值（2 - 5之间）和胰岛素浓度的复杂依赖性。如果这些结果能够推广，它们表明蛋白质中的共价聚集可能会受到自缔合的抑制。

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胰岛素浓度和自缔合对其A-21环酐中间体向脱酰胺胰岛素和共价二聚体分配的影响。

Effects of insulin concentration and self-association on the partitioning of its A-21 cyclic anhydride intermediate to desamido insulin and covalent dimer.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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