Younes Bouchiba, Juan Cortés, Thomas Schiex, Sophie Barbe
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引用次数: 4
Abstract
Computational protein design (CPD) is a powerful technique for engineering new proteins, with both great fundamental implications and diverse practical interests. However, the approximations usually made for computational efficiency, using a single fixed backbone and a discrete set of side chain rotamers, tend to produce rigid and hyper-stable folds that may lack functionality. These approximations contrast with the demonstrated importance of molecular flexibility and motions in a wide range of protein functions. The integration of backbone flexibility and multiple conformational states in CPD, in order to relieve the inaccuracies resulting from these simplifications and to improve design reliability, are attracting increased attention. However, the greatly increased search space that needs to be explored in these extensions defines extremely challenging computational problems. In this review, we outline the principles of CPD and discuss recent effort in algorithmic developments for incorporating molecular flexibility in the design process.
计算蛋白设计(Computational protein design, CPD)是一种强大的蛋白质工程技术,具有重要的基础意义和广泛的应用价值。然而,通常为了计算效率而进行的近似,使用单个固定主干和一组离散的侧链转子,往往会产生刚性和超稳定的折叠,可能缺乏功能。这些近似与已证明的分子柔韧性和运动在广泛的蛋白质功能中的重要性形成对比。在CPD中集成骨干柔韧性和多种构象状态,以减轻这些简化带来的不准确性,提高设计的可靠性,正受到越来越多的关注。然而,在这些扩展中需要探索的大大增加的搜索空间定义了极具挑战性的计算问题。在这篇综述中,我们概述了CPD的原理,并讨论了在设计过程中结合分子灵活性的算法发展的最新努力。
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