Mem3DG:用离散微分几何在三维建模膜力学化学动力学。

IF 2.4 Q3 BIOPHYSICS Biophysical reports Pub Date : 2022-09-14 Epub Date: 2022-06-15 DOI:10.1016/j.bpr.2022.100062
Cuncheng Zhu, Christopher T Lee, Padmini Rangamani
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引用次数: 11

摘要

生物膜采用对细胞功能至关重要的不同形态。许多研究使用计算建模来了解各种机械化学因素如何促进膜形状转变。与基于近似的方法(例如,有限元法[FEM])相比,这类离散网格模型在三维模拟复杂物理和形状方面提供了更大的灵活性;它的公式产生了一个有效的算法,同时保持了无坐标的几何描述。然而,离散背景下几何定义的模糊性导致了对哪种离散网格模型在理论和数值上是最优的缺乏共识;离散和光滑几何理论中对能量和力都有贡献的项之间的双射关系仍有待建立。我们解决了这一问题,并提出了一个可扩展的框架Mem3DG,用于在三角网格上基于离散微分几何(DDG)建模膜的三维机械化学动力学。DDG的形式主义解决了这种不一致性,并为如何将平滑和离散的能量和力联系起来提供了一个统一的视角。为了证明这一点,Mem3DG被用于对一系列机械化学复杂性不断增加的例子进行建模:恢复经典的形状转换,如1)双凹面圆盘、哑铃和unduloid;和2)球形芽在球形、扁平的补片膜上;研究了膜力学与蛋白质迁移率的耦合如何共同影响相和形状的转变。随着膜超微结构的高分辨率3D成像变得越来越容易,我们设想将Mem3DG作为一种端到端的工具,在用户指定的机械化学条件下模拟真实的细胞几何形状。
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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Mem3DG: Modeling membrane mechanochemical dynamics in 3D using discrete differential geometry.

Biomembranes adopt varying morphologies that are vital to cellular functions. Many studies use computational modeling to understand how various mechanochemical factors contribute to membrane shape transformations. Compared with approximation-based methods (e.g., finite element method [FEM]), the class of discrete mesh models offers greater flexibility to simulate complex physics and shapes in three dimensions; its formulation produces an efficient algorithm while maintaining coordinate-free geometric descriptions. However, ambiguities in geometric definitions in the discrete context have led to a lack of consensus on which discrete mesh model is theoretically and numerically optimal; a bijective relationship between the terms contributing to both the energy and forces from the discrete and smooth geometric theories remains to be established. We address this and present an extensible framework, Mem3DG, for modeling 3D mechanochemical dynamics of membranes based on discrete differential geometry (DDG) on triangulated meshes. The formalism of DDG resolves the inconsistency and provides a unifying perspective on how to relate the smooth and discrete energy and forces. To demonstrate, Mem3DG is used to model a sequence of examples with increasing mechanochemical complexity: recovering classical shape transformations such as 1) biconcave disk, dumbbell, and unduloid; and 2) spherical bud on spherical, flat-patch membrane; investigating how the coupling of membrane mechanics with protein mobility jointly affects phase and shape transformation. As high-resolution 3D imaging of membrane ultrastructure becomes more readily available, we envision Mem3DG to be applied as an end-to-end tool to simulate realistic cell geometry under user-specified mechanochemical conditions.

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来源期刊
Biophysical reports
Biophysical reports Biophysics
CiteScore
2.40
自引率
0.00%
发文量
0
审稿时长
75 days
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