Enzyme kinetics simulation at the scale of individual particles.

IF 3.1 2区 化学 Q3 CHEMISTRY, PHYSICAL
Taylor Kearney, Mark B Flegg
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引用次数: 0

Abstract

Enzyme-catalyzed reactions involve two distinct timescales: a short timescale on which enzymes bind to substrate molecules to produce bound complexes and a comparatively long timescale on which the molecules of the complex are transformed into products. The uptake of the substrate in these reactions is the rate at which the product is made on the long timescale. Models often only consider the uptake to reduce the number of chemical species that need to be modeled and to avoid explicitly treating multiple timescales. Typically, the uptake rates cannot be described by mass action kinetics and are traditionally derived by applying singular perturbation theory to the system's governing differential equations. This analysis ignores short timescales by assuming that a pseudo-equilibrium between the enzyme and the enzyme-bound complex is maintained at all times. This assumption cannot be incorporated into current particle-based simulations of reaction-diffusion systems because they utilize proximity-based conditions to govern the instances of reactions that cannot maintain this pseudo-equilibrium for infinitely fast reactions. Instead, these methods must directly simulate the dynamics on the short timescale to accurately model the system. Due to the disparate timescales, such simulations require excessive amounts of computational time before the behavior on the long timescale can be observed. To resolve this problem, we use singular perturbation theory to develop a proximity-based reaction condition that enables us to ignore all fast reactions and directly reproduce non-mass action kinetics at long timescales. To demonstrate our approach, we implement simulations of a specific third order reaction with kinetics reminiscent of the prototypical Michaelis-Menten system.

单个粒子尺度的酶动力学模拟。
酶催化反应涉及两个不同的时间尺度:酶与底物分子结合产生结合复合物的时间尺度较短,复合物分子转化为产物的时间尺度相对较长。在这些反应中,底物的吸收是在长时间尺度上生成产物的速度。模型通常只考虑吸收,以减少需要建模的化学物种数量,并避免明确处理多个时间尺度。通常情况下,吸收速率无法用质量作用动力学来描述,传统的方法是将奇异扰动理论应用于系统的控制微分方程。这种分析假设酶和酶结合复合物之间始终保持假平衡,从而忽略了短时标。目前基于粒子的反应扩散系统模拟无法采用这一假设,因为它们利用基于邻近性的条件来控制反应实例,而这种条件无法维持无限快反应的伪平衡。相反,这些方法必须直接模拟短时间尺度上的动力学,才能准确模拟系统。由于时间尺度不同,这种模拟需要过多的计算时间才能观察到长时间尺度上的行为。为了解决这个问题,我们利用奇异扰动理论开发了一种基于邻近性的反应条件,使我们能够忽略所有快速反应,直接再现长时间尺度上的非质量作用动力学。为了演示我们的方法,我们对一个特定的三阶反应进行了模拟,该反应的动力学与典型的 Michaelis-Menten 系统相似。
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
Journal of Chemical Physics
Journal of Chemical Physics 物理-物理:原子、分子和化学物理
CiteScore
7.40
自引率
15.90%
发文量
1615
审稿时长
2 months
期刊介绍: The Journal of Chemical Physics publishes quantitative and rigorous science of long-lasting value in methods and applications of chemical physics. The Journal also publishes brief Communications of significant new findings, Perspectives on the latest advances in the field, and Special Topic issues. The Journal focuses on innovative research in experimental and theoretical areas of chemical physics, including spectroscopy, dynamics, kinetics, statistical mechanics, and quantum mechanics. In addition, topical areas such as polymers, soft matter, materials, surfaces/interfaces, and systems of biological relevance are of increasing importance. Topical coverage includes: Theoretical Methods and Algorithms Advanced Experimental Techniques Atoms, Molecules, and Clusters Liquids, Glasses, and Crystals Surfaces, Interfaces, and Materials Polymers and Soft Matter Biological Molecules and Networks.
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