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引用次数: 0
摘要
人们很早就认识到,蛋白质主链的片段就像机器人操纵器,机器人学中的逆运动学方法已被应用于环路建模,以弥补蛋白质比较建模的不足。具有固定末端的冗余机械手的复杂内部运动称为自运动,其特征由末端的相对位置决定。拓扑上等价(同位)的自运动占据构型空间的同一连续区域。拓扑上不等同(非同向)的区域被同规则表面隔开,穿过同规则表面会导致自运动特性的突然剧变。利用五残基 I 型 β 转折证明,这些概念适用于蛋白质片段,当五残基片段的两端靠得更近时,共规则表面被穿过,结构被锁定为 I 型或 I'型转折。研究还表明,II 型转折在拓扑学上等同于 I'型转折,而不是 I 型转折。这些结果对原生态蛋白质动力学和蛋白质折叠都有影响。
Protein folding, protein dynamics and the topology of self-motions.
It has long been recognized that segments of the protein main chain are like robotic manipulators and inverse kinematics methods from robotics have been applied to model loops to bridge gaps in protein comparative modelling. The complex internal motion of a redundant manipulator with fixed ends is called a self-motion and its character is determined by the relative position of its ends. Self-motions that are topologically equivalent (homotopic) occupy the same continous region of the configuration space. Topologically inequivalent (non-homotopic) regions are separated by co-regular surfaces and crossing a co-regular surface can result in a sudden dramatic change in the character of the self-motion. It is shown, using a five-residue type I β-turn, that these concepts apply to protein segments and that as the ends of the five-residue segment come closer together, a co-regular surface is crossed, and the structure is locked in to becoming either a type I or type I' turn. It is also shown that the type II turn is topologically equivalent to the type I' turn, not the type I turn. These results have implications for both native-state protein dynamics and protein folding.
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