Shape Correspondence Analysis for Biomolecules Based on Volumetric Eigenfunctions

Q2 Mathematics

Computational and Mathematical Biophysics Pub Date : 2015-10-08 DOI:10.1515/mlbmb-2015-0007

Tao Liao, Hao-Chih Lee, Ge Yang, Y. Zhang

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引用次数: 1

Abstract

Abstract The functionality of biomolecules depends on their flexible structures, which can be characterized by their surface shapes. Tracking the deformation and comparing biomolecular shapes are essential in understanding their mechanisms. In this paper, a new spectral shape correspondence analysis method is introduced for biomolecules based on volumetric eigenfunctions. The eigenfunctions are computed from the joint graph of two given shapes, avoiding the sign flipping and confusion in the order of modes. An initial correspondence is built based on the distribution of a shape diameter, which matches similar surface features in different shapes and guides the eigenfunction computation. A two-step scheme is developed to determine the final correspondence. The first step utilizes volumetric eigenfunctions to correct the assignment of boundary nodes that disobeys the main structures. The second step minimizes the distortion induced by deforming one shape to the other. As a result, a dense point correspondence is constructed between the two given shapes, based on which we approximate and predict the shape deformation, as well as quantitatively measure the detailed shape differences.

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基于体积特征函数的生物分子形状对应分析

生物分子的功能取决于其柔性结构，而柔性结构可以通过其表面形状来表征。跟踪变形和比较生物分子形状对于理解其机制至关重要。本文提出了一种基于体积特征函数的生物分子光谱形状对应分析方法。特征函数由两个给定形状的联合图计算，避免了符号翻转和模态顺序混乱。基于形状直径的分布建立初始对应关系，匹配不同形状的相似表面特征，指导特征函数的计算。提出了一种确定最终对应关系的两步方案。第一步利用体积特征函数修正不服从主结构的边界节点分配。第二步是将一种形状变形为另一种形状所引起的变形最小化。结果，在两个给定形状之间构建密集的点对应关系，在此基础上近似和预测形状变形，并定量测量详细的形状差异。

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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来源期刊

Computational and Mathematical Biophysics Mathematics-Mathematical Physics

CiteScore

2.50

自引率

0.00%

发文量

审稿时长

30 weeks