Anharmonic activations in proteins and peptide model systemsand their connection with supercooled water thermodynamics

Il Nuovo cimento della Societa italiana di fisica. C Pub Date : 2016-07-19 DOI:10.1393/NCC/I2016-16305-Y

A. Cupane, null Schirò

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引用次数: 3

Abstract

Summary. — Proteins, the nano-machines of living systems, are highly dynamic molecules. The time-scale of functionally relevant motions spans over a very broad range, from femtoseconds to several seconds. In particular, the pico-to nanoseconds region is characterized by side-chain and backbone anharmonic ﬂuctuations that are responsible for many biological tasks like ligand binding, substrate recognition and enzymatic activity. Neutron scattering on hydrated protein powders reveals two main activations of anharmonic dynamics, characterized by diﬀerent onset temperature and amplitude. Here we review our work on synthetic polypeptides, native proteins, and single amino acids to identify the physical origin of the two onsets —one involving water-independent local dynamics of methyl groups and, to a minor extent, of aromatic side-chains, and the other one, known as “protein dynamical transition”, concerning large scale functional protein ﬂuctuations, most likely induced by a crossover in the structure and dynamics of hydration water connected with the second critical point hypothesis.

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蛋白质和肽模型系统中的非调和活化及其与过冷水热力学的关系

总结。蛋白质是生命系统的纳米机器，是高度动态的分子。功能相关运动的时间尺度跨度非常大，从飞秒到几秒。特别是，皮到纳秒区域的特征是侧链和主链的非调和波动，这些波动负责许多生物任务，如配体结合、底物识别和酶活性。水合蛋白粉上的中子散射表现出两种主要的非调和动力学激活，它们具有不同的起始温度和振幅。在这里，我们回顾了我们在合成多肽、天然蛋白质和单氨基酸方面的工作，以确定这两种启动的物理起源——一种涉及甲基不依赖水的局部动力学，在较小程度上涉及芳香侧链，另一种被称为“蛋白质动态过渡”，涉及大规模的功能蛋白质波动。这很可能是由水合水的结构和动力学的交叉引起的，与第二个临界点假设有关。

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Il Nuovo cimento della Societa italiana di fisica. C

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