Evolutionary homology on coupled dynamical systems with applications to protein flexibility analysis.

Zixuan Cang, Elizabeth Munch, Guo-Wei Wei
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引用次数: 11

Abstract

While the spatial topological persistence is naturally constructed from a radius-based filtration, it has hardly been derived from a temporal filtration. Most topological models are designed for the global topology of a given object as a whole. There is no method reported in the literature for the topology of an individual component in an object to the best of our knowledge. For many problems in science and engineering, the topology of an individual component is important for describing its properties. We propose evolutionary homology (EH) constructed via a time evolution-based filtration and topological persistence. Our approach couples a set of dynamical systems or chaotic oscillators by the interactions of a physical system, such as a macromolecule. The interactions are approximated by weighted graph Laplacians. Simplices, simplicial complexes, algebraic groups and topological persistence are defined on the coupled trajectories of the chaotic oscillators. The resulting EH gives rise to time-dependent topological invariants or evolutionary barcodes for an individual component of the physical system, revealing its topology-function relationship. In conjunction with Wasserstein metrics, the proposed EH is applied to protein flexibility analysis, an important problem in computational biophysics. Numerical results for the B-factor prediction of a benchmark set of 364 proteins indicate that the proposed EH outperforms all the other state-of-the-art methods in the field.

耦合动力系统的进化同源性及其在蛋白质柔韧性分析中的应用。
虽然空间拓扑持久性是由基于半径的过滤自然构建的,但它几乎没有从时间过滤中得到。大多数拓扑模型是为给定对象的整体拓扑而设计的。据我们所知,文献中没有关于对象中单个组件拓扑的方法报告。对于科学和工程中的许多问题,单个组件的拓扑结构对于描述其性质非常重要。我们提出了一种基于时间进化的过滤和拓扑持久性的进化同源性(EH)。我们的方法通过物理系统(如大分子)的相互作用耦合一组动态系统或混沌振荡器。相互作用用加权图拉普拉斯算子逼近。在混沌振子的耦合轨迹上定义了简单、简单复形、代数群和拓扑持久性。由此产生的EH产生了物理系统单个组件的随时间变化的拓扑不变量或进化条形码,揭示了其拓扑-功能关系。与Wasserstein度量相结合,提出的EH应用于蛋白质柔韧性分析,这是计算生物物理学中的一个重要问题。对364个蛋白质的基准集进行b因子预测的数值结果表明,所提出的EH优于该领域所有其他最先进的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
3.40
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