肌红蛋白、溶菌酶、核糖核酸酶A、凝乳胰蛋白酶、细胞色素c和羧肽酶A1折叠漏斗的“刚性”经典或崎岖底部的灵活性。

Intrinsically disordered proteins Pub Date : 2017-10-16 eCollection Date: 2017-01-01 DOI:10.1080/21690707.2017.1355205

Vladimir N Uversky

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引用次数: 1

摘要

球形蛋白质的结晶能力和解决其晶体结构的能力似乎代表了蛋白质功能的锁与钥匙模型的胜利，其中独特的3D结构类似于非周期晶体的存在被认为是给定蛋白质具有特定生物活性的先决条件。蛋白质晶体学的历史可以追溯到50多年前首次发现的肌红蛋白、溶菌酶、rna酶A、胰凝乳酶、细胞色素c和羧肽酶A1的晶体结构。本文简要地考虑了目前可获得的这些蛋白质的广泛结构信息，并表明它们折叠漏斗的底部(即它们势能景观的最低部分)不是光滑的，而是崎岖的。换句话说，这些结晶经典具有显著的构象灵活性，而不是刚性(不可移动)的晶体状实体。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Flexibility of the "rigid" classics or rugged bottom of the folding funnels of myoglobin, lysozyme, RNase A, chymotrypsin, cytochrome c, and carboxypeptidase A1.

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Flexibility of the "rigid" classics or rugged bottom of the folding funnels of myoglobin, lysozyme, RNase A, chymotrypsin, cytochrome c, and carboxypeptidase A1.

The abilities to crystalize of a globular protein and to solve its crystal structure seem to represent triumph of the lock-and-key model of protein functionality, where the presence of unique 3D structure resembling aperiodic crystal is considered as a prerequisite for a given protein to possess specific biologic activity. The history of protein crystallography has its roots in first crystal structures of myoglobin, lysozyme, RNase A, chymotrypsin, cytochrome c, and carboxypeptidase A1 solved more than 50 y ago. This article briefly considers extensive structural information currently available for these proteins and shows that the bottoms of their folding funnels (i.e., the lowest parts of their potential energy landscapes) are not smoothed but rugged. In other words, these crystallization classics are characterized by significant conformational flexibility and are not rigid (immobile) crystal-like entities.

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Intrinsically disordered proteins

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