生化网络的层次优化

bioRxiv Pub Date : 2024-08-08 DOI:10.1101/2024.08.06.606818
Nisha A. Viswan, Alexandre Tribut, Manvel Gasparyan, Ovidiu Radulescu, U. Bhalla
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引用次数: 0

摘要

生物信号系统非常复杂,建立机理模型的工作必须面对巨大的参数空间、间接和不完整的数据,并经常遇到多尺度和多物理现象。为了解决这些问题,我们提出了系统模拟分层优化框架 HOSS。HOSS 的工作原理是将广泛的系统模型分解为嵌套层次结构中的各个路径模块。在第一个层次中,依赖关系仅取决于信号输入,而后续层次则仅依赖于前一个层次。我们证明,每个层次中的每个独立通路都可以有效优化。一旦优化完成,其参数将保持不变,同时该路径将作为后续层级的输入。我们开发了一种算法方法,用于确定在任何给定的生化网络中应用 HOSS 所需的嵌套层次。此外,我们还设计了两种可并行化的变体,在优化的初始和中间阶段使用随机扰乱参数生成大量模型实例。我们的研究结果表明,这些变体产生了更优越的模型,并提供了对解决方案退化性的估计。此外,我们还展示了优化方法对基于事件的抽象模拟和基于 ODE 模型的有效性。作者简介 生化通路模型整合了定量和定性数据,用于理解细胞功能、疾病影响以及在硅学中测试治疗方法。由于涉及的变量和参数复杂而繁多,构建和优化这些模型极具挑战性。尽管已开发出数百种生化模型并可从资源库中获取,但这些模型很少被重复使用。为了提高这些模型在生物医学中的利用率,我们提出了一种创新的分层模型优化方法 HOSS。HOSS 利用通路模型的模块化结构,将大型机理计算模型分解为较小的模块。然后从输入模块开始,按照因果关系路径逐步优化这些模块。这种方法大大减轻了计算负担,因为每一步都涉及解决一个更简单的问题。通过使优化过程更易于管理,HOSS 加快了生化模型的生命周期,促进了它们在生物医学研究和应用中的广泛应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hierarchical optimization of biochemical networks
Biological signalling systems are complex, and efforts to build mechanistic models must confront a huge parameter space, indirect and incomplete data, and frequently encounter multiscale and multiphysics phenomena. We present HOSS, a framework for Hierarchical Optimization of Systems Simulations, to address such problems. HOSS operates by breaking down extensive systems models into individual pathway blocks organized in a nested hierarchy. At the first level, dependencies are solely on signalling inputs, and subsequent levels rely only on the preceding ones. We demonstrate that each independent pathway in every level can be efficiently optimized. Once optimized, its parameters are held constant while the pathway serves as input for succeeding levels. We develop an algorithmic approach to identify the necessary nested hierarchies for the application of HOSS in any given biochemical network. Furthermore, we devise two parallelizable variants that generate numerous model instances using stochastic scrambling of parameters during initial and intermediate stages of optimization. Our results indicate that these variants produce superior models and offer an estimate of solution degeneracy. Additionally, we showcase the effectiveness of the optimization methods for both abstracted, event-based simulations and ODE-based models. Author summary Biochemical pathway models integrate quantitative and qualitative data to understand cell functioning, disease effects, and to test treatments in silico. Constructing and optimizing these models is challenging due to the complexity and multitude of variables and parameters involved. Although hundreds of biochemical models have been developed and are available in repositories, they are rarely reused. To enhance the utilization of these models in biomedicine, we propose HOSS, an innovative hierarchical model optimization method. HOSS takes advantage of the modular structure of pathway models by breaking down large mechanistic computational models into smaller modules. These modules are then optimized progressively, starting with input modules and following causality paths. This method significantly reduces the computational burden as each step involves solving a simpler problem. By making the optimization process more manageable, HOSS accelerates the lifecycle of biochemical models and promotes their broader use in biomedical research and applications.
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