Microstructure-based nuclear lamina constitutive model

IF 2.4 4区 生物学 Q4 CELL BIOLOGY
Cytoskeleton Pub Date : 2024-02-12 DOI:10.1002/cm.21835
Nima Mostafazadeh, Zhangli Peng
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Abstract

The nuclear lamina is widely recognized as the most crucial component in providing mechanical stability to the nucleus. However, it is still a significant challenge to model the mechanics of this multilayered protein network. We developed a constitutive model of the nuclear lamina network based on its microstructure, which accounts for the deformation phases at the dimer level, as well as the orientational arrangement and density of lamin filaments. Instead of relying on homology modeling in the previous studies, we conducted molecular simulations to predict the force-extension response of a highly accurate lamin dimer structure obtained through X-ray diffraction crystallography experimentation. Furthermore, we devised a semiflexible worm-like chain extension-force model of lamin dimer as a substitute, incorporating phases of initial stretching, uncoiling of the dimer coiled-coil, and transition of secondary structures. Subsequently, we developed a 2D network continuum model for the nuclear lamina by using our extension-force lamin dimer model and derived stress resultants. By comparing with experimentally measured lamina modulus, we found that the lamina network has sharp initial strain-hardening behavior. This also enabled us to carry out finite element simulations of the entire nucleus with an accurate microstructure-based nuclear lamina model. Finally, we conducted simulations of transendothelial transmigration of a nucleus and investigated the impact of varying network density and uncoiling constants on the critical force required for successful transmigration. The model allows us to incorporate the microstructure characteristics of the nuclear lamina into the nucleus model, thereby gaining insights into how laminopathies and mutations affect nuclear mechanics.

Abstract Image

基于微观结构的核薄层构成模型
核薄层被广泛认为是为细胞核提供机械稳定性的最关键部分。然而,建立这一多层蛋白质网络的力学模型仍是一项重大挑战。我们根据核薄层的微观结构建立了核薄层网络的构成模型,该模型考虑了二聚体水平的变形阶段以及薄层丝的定向排列和密度。我们没有依赖以往研究中的同源建模,而是通过分子模拟来预测通过 X 射线衍射晶体学实验获得的高精度片层二聚体结构的力-拉伸响应。此外,我们还设计了一种片层二聚体的半柔性蚯蚓状链延伸力模型作为替代,其中包含了初始拉伸、二聚体盘绕线圈解卷和二级结构转换等阶段。随后,我们利用延伸力片层二聚体模型建立了核片层的二维网络连续模型,并推导出应力结果。通过与实验测量的层状模量进行比较,我们发现层状网络具有尖锐的初始应变硬化行为。这也使我们能够利用基于微观结构的精确核薄层模型对整个原子核进行有限元模拟。最后,我们对细胞核的跨内皮迁移进行了模拟,并研究了不同的网络密度和解旋常数对成功迁移所需的临界力的影响。该模型使我们能够将核薄层的微观结构特征纳入核模型,从而深入了解薄层病变和突变如何影响核力学。
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来源期刊
Cytoskeleton
Cytoskeleton CELL BIOLOGY-
CiteScore
5.50
自引率
3.40%
发文量
24
审稿时长
6-12 weeks
期刊介绍: Cytoskeleton focuses on all aspects of cytoskeletal research in healthy and diseased states, spanning genetic and cell biological observations, biochemical, biophysical and structural studies, mathematical modeling and theory. This includes, but is certainly not limited to, classic polymer systems of eukaryotic cells and their structural sites of attachment on membranes and organelles, as well as the bacterial cytoskeleton, the nucleoskeleton, and uncoventional polymer systems with structural/organizational roles. Cytoskeleton is published in 12 issues annually, and special issues will be dedicated to especially-active or newly-emerging areas of cytoskeletal research.
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