复杂生化系统的混合确定性/随机模拟

IF 3.743 Q2 Biochemistry, Genetics and Molecular Biology Molecular BioSystems Pub Date : 2017-09-29 DOI:10.1039/C7MB00426E
Paola Lecca, Fabio Bagagiolo and Marina Scarpa
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引用次数: 9

摘要

在生物细胞中,细胞功能和遗传调控装置是由涉及基因、蛋白质和酶的复杂化学反应网络来实现和控制的。精确的计算模型是理解复杂系统进化背后的机制不可或缺的手段,并不总是用湿实验室实验来探索。然而,为了达到目的,计算模型应该能够描述和模拟生物系统在许多方面的复杂性。此外,它应该通过高效的算法来实现,需要尽可能短的执行时间,以避免过度扩大数据分析和任何后续实验之间的时间间隔。生物网络的复杂性除了表现在其拓扑结构上外,还表现在其动态特性上,通常是非线性的和僵硬的。这种刚度是由于分子种类的存在,其丰度波动了许多数量级。刚性系统的完全随机模拟在计算上耗费大量时间。另一方面,连续模型成本较低,但它们无法捕捉到分子物种小种群的随机行为。我们介绍了一种新的高效的混合随机-确定性计算模型和软件工具MoBioS(分子生物学模拟器)实现它。MoBioS的数学模型用连续微分方程来描述确定性反应,用类似gillespie的算法来描述随机反应。与目前大多数混合方法不同,MoBioS算法将反应集合分为快速反应、中等反应和慢速反应,并实现了随机模型和确定性模型之间的滞后切换。快速反应近似为连续确定性过程,并由确定性速率方程建模。中等反应是指反应等待时间大于快速反应等待时间但小于慢速反应等待时间的反应。如果一个中等反应在超过低(高)等待时间阈值时被归类为随机(确定性)过程,则它近似为随机(确定性)过程。采用吉莱斯皮第一反应法选择并执行慢反应。MoBios的性能在杂交动力学的一个典型例子上进行了测试:DNA转录调控。利用模拟的试剂丰度动态分布和完全确定性方法引入的误差估计来评估计算模型与软件工具的一致性。
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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Hybrid deterministic/stochastic simulation of complex biochemical systems

In a biological cell, cellular functions and the genetic regulatory apparatus are implemented and controlled by complex networks of chemical reactions involving genes, proteins, and enzymes. Accurate computational models are indispensable means for understanding the mechanisms behind the evolution of a complex system, not always explored with wet lab experiments. To serve their purpose, computational models, however, should be able to describe and simulate the complexity of a biological system in many of its aspects. Moreover, it should be implemented by efficient algorithms requiring the shortest possible execution time, to avoid enlarging excessively the time elapsing between data analysis and any subsequent experiment. Besides the features of their topological structure, the complexity of biological networks also refers to their dynamics, that is often non-linear and stiff. The stiffness is due to the presence of molecular species whose abundance fluctuates by many orders of magnitude. A fully stochastic simulation of a stiff system is computationally time-expensive. On the other hand, continuous models are less costly, but they fail to capture the stochastic behaviour of small populations of molecular species. We introduce a new efficient hybrid stochastic–deterministic computational model and the software tool MoBioS (MOlecular Biology Simulator) implementing it. The mathematical model of MoBioS uses continuous differential equations to describe the deterministic reactions and a Gillespie-like algorithm to describe the stochastic ones. Unlike the majority of current hybrid methods, the MoBioS algorithm divides the reactions' set into fast reactions, moderate reactions, and slow reactions and implements a hysteresis switching between the stochastic model and the deterministic model. Fast reactions are approximated as continuous-deterministic processes and modelled by deterministic rate equations. Moderate reactions are those whose reaction waiting time is greater than the fast reaction waiting time but smaller than the slow reaction waiting time. A moderate reaction is approximated as a stochastic (deterministic) process if it was classified as a stochastic (deterministic) process at the time at which it crosses the threshold of low (high) waiting time. A Gillespie First Reaction Method is implemented to select and execute the slow reactions. The performances of MoBios were tested on a typical example of hybrid dynamics: that is the DNA transcription regulation. The simulated dynamic profile of the reagents’ abundance and the estimate of the error introduced by the fully deterministic approach were used to evaluate the consistency of the computational model and that of the software tool.

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来源期刊
Molecular BioSystems
Molecular BioSystems 生物-生化与分子生物学
CiteScore
2.94
自引率
0.00%
发文量
0
审稿时长
2.6 months
期刊介绍: Molecular Omics publishes molecular level experimental and bioinformatics research in the -omics sciences, including genomics, proteomics, transcriptomics and metabolomics. We will also welcome multidisciplinary papers presenting studies combining different types of omics, or the interface of omics and other fields such as systems biology or chemical biology.
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