In-Silico Analyses of Molecular Force Sensors for Mechanical Characterization of Biological Systems.

IF 3.2 3区生物学 Q2 BIOPHYSICS

Biophysical journal Pub Date : 2025-02-03 DOI:10.1016/j.bpj.2025.01.025

Diana M Lopez, Carlos E Castro, Marcos Sotomayor

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Abstract

Mechanical forces play key roles in biological processes such as cell migration and sensory perception. In recent years molecular force sensors have been developed as tools for in situ force measurements. Here we use all-atom steered molecular dynamics simulations to predict and study the relationship between design parameters and mechanical properties for three types of molecular force sensors commonly used in cellular biological research: two peptide- and one DNA-based. The peptide-based sensors consist of a pair of fluorescent proteins, which can undergo Förster resonance energy transfer (FRET), linked by spider silk (GPGGA)_n or synthetic (GGSGGS)_n disordered regions. The DNA-based sensor consists of two fluorophore-labeled strands of DNA that can be unzipped or sheared upon force application with a FRET signal as readout of dissociation. We simulated nine sensors, three of each kind. After equilibration, flexible peptide linkers of three different lengths were stretched by applying forces to their N- and C-terminal Cα atoms in opposite directions. Similarly, we equilibrated a DNA-based sensor and pulled on the phosphate atom of the terminal guanine of one strand and a selected phosphate atom on the other strand for pulling in the opposite direction. These simulations were performed at constant velocity (0.01 nm/ns - 10 nm/ns) and constant force (10 pN - 500 pN) for all versions of the sensors. Our results show how the force response of these sensors depends on their length, sequence, configuration and loading rate. Mechanistic insights gained from simulations analyses indicate that interpretation of experimental results should consider the influence of transient formation of secondary structure in peptide-based sensors and of overstretching in DNA-based sensors. These predictions can guide optimal fluorophore choice and facilitate the rational design of new sensors for use in protein, DNA, hybrid systems, and molecular devices.

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用于生物系统机械特征描述的分子力传感器硅内分析。

机械力在细胞迁移和感官知觉等生物过程中发挥着关键作用。近年来，分子力传感器被开发为原位力测量工具。在此，我们使用全原子导向分子动力学模拟来预测和研究细胞生物学研究中常用的三种分子力传感器的设计参数和机械性能之间的关系：两种基于肽，一种基于 DNA。基于肽的传感器由一对荧光蛋白组成，它们可以进行佛斯特共振能量转移（FRET），并通过蜘蛛丝（GPGGA）n 或合成（GGSGGS）n 无序区连接起来。基于 DNA 的传感器由两条荧光团标记的 DNA 链组成，在施力时可拉开或剪断，并以 FRET 信号作为解离的读数。我们模拟了九种传感器，每种三种。平衡后，通过对其 N 端和 C 端 Cα 原子施加相反方向的力，拉伸三种不同长度的柔性肽链。同样，我们对基于 DNA 的传感器进行了平衡，并对一条链末端鸟嘌呤的磷酸原子和另一条链上选定的磷酸原子进行了反方向拉伸。所有版本的传感器都是在恒速（0.01 nm/ns - 10 nm/ns）和恒力（10 pN - 500 pN）条件下进行模拟的。我们的结果表明，这些传感器的力响应如何取决于其长度、顺序、配置和加载速率。从模拟分析中获得的机理启示表明，在解释实验结果时应考虑到二级结构的瞬时形成对基于肽的传感器和基于 DNA 的传感器的过度拉伸的影响。这些预测可以指导荧光团的最佳选择，并促进用于蛋白质、DNA、混合系统和分子设备的新型传感器的合理设计。

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

Biophysical journal 生物-生物物理

CiteScore

6.10

自引率

5.90%

发文量

3090

审稿时长

2 months

期刊介绍： BJ publishes original articles, letters, and perspectives on important problems in modern biophysics. The papers should be written so as to be of interest to a broad community of biophysicists. BJ welcomes experimental studies that employ quantitative physical approaches for the study of biological systems, including or spanning scales from molecule to whole organism. Experimental studies of a purely descriptive or phenomenological nature, with no theoretical or mechanistic underpinning, are not appropriate for publication in BJ. Theoretical studies should offer new insights into the understanding ofexperimental results or suggest new experimentally testable hypotheses. Articles reporting significant methodological or technological advances, which have potential to open new areas of biophysical investigation, are also suitable for publication in BJ. Papers describing improvements in accuracy or speed of existing methods or extra detail within methods described previously are not suitable for BJ.