From Fine-Grain to Coarse-Grain Modeling: Estimating Kinetic Parameters of DNA Molecules

IF 1.4 4区生物学 Q4 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Acta Biotheoretica Pub Date : 2024-11-19 DOI:10.1007/s10441-024-09489-7

Jeremy Curuksu

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引用次数: 0

Abstract

Coarse-grain models are essential to understand the biological function of DNA molecules because the length and time scales of the sequence-dependent physical properties of DNA are often beyond the reach of experimental and all-atom computational methods. Simulating coarse-grain models of DNA, e.g. using Langevin dynamics, requires the parametrization of both potential and kinetic energy functions. Many studies have shown that the flexibility (i.e., potential energy) of a DNA molecule depends on its sequence. In contrast, little is known about the sequence-dependence of DNA mass parameters required to model its kinetic energy. In this paper, an algebraic expression is derived for the kinetic energy as a function of linear and angular velocities of each DNA base parameterized by its mass, center of mass, and rotational inertia tensor. The parameters of this function are then approximated from a set of fine-grain molecular dynamics simulations representing all combinations of the four DNA base pairs AT, TA, GC, and CG, in different sequence contexts. Compatibility conditions associated with the assumption of each base being modeled as a rigid body were verified to be good approximations. The kinetic parameters were found to be significantly different between the four G, C, A, and T bases, and to not be dependent on the sequence context. This suggests that the effective kinetic parameters of a DNA base may depend only on the base itself, not on its neighbors.

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从细粒度建模到粗粒度建模：估算 DNA 分子的动力学参数。

粗粒度模型对于理解 DNA 分子的生物功能至关重要，因为 DNA 与序列相关的物理特性的长度和时间尺度往往超出了实验和全原子计算方法的范围。模拟 DNA 的粗粒度模型，例如使用朗格文动力学，需要对势能和动能函数进行参数化。许多研究表明，DNA 分子的灵活性（即势能）取决于其序列。相比之下，人们对建立 DNA 动能模型所需的 DNA 质量参数的序列依赖性知之甚少。本文导出了动能的代数表达式，它是每个 DNA 碱基的线速度和角速度的函数，由其质量、质心和旋转惯性张量参数化。该函数的参数是通过一组细粒度分子动力学模拟得到的，这些模拟代表了不同序列上下文中 AT、TA、GC 和 CG 四种 DNA 碱基对的所有组合。与每个碱基作为刚体建模的假设相关的相容性条件被证实是良好的近似值。研究发现，G、C、A 和 T 四种碱基的动力学参数有显著差异，且不依赖于序列上下文。这表明 DNA 碱基的有效动力学参数可能只取决于碱基本身，而不取决于其邻近碱基。

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

Acta Biotheoretica 生物-生物学

CiteScore

2.70

自引率

7.70%

发文量

审稿时长

3 months

期刊介绍： Acta Biotheoretica is devoted to the promotion of theoretical biology, encompassing mathematical biology and the philosophy of biology, paying special attention to the methodology of formation of biological theory. Papers on all kind of biological theories are welcome. Interesting subjects include philosophy of biology, biomathematics, computational biology, genetics, ecology and morphology. The process of theory formation can be presented in verbal or mathematical form. Moreover, purely methodological papers can be devoted to the historical origins of the philosophy underlying biological theories and concepts. Papers should contain clear statements of biological assumptions, and where applicable, a justification of their translation into mathematical form and a detailed discussion of the mathematical treatment. The connection to empirical data should be clarified. Acta Biotheoretica also welcomes critical book reviews, short comments on previous papers and short notes directing attention to interesting new theoretical ideas.