Dynamic modelling of signalling pathways when ODEs are not feasible.

Bioinformatics (Oxford, England) Pub Date : 2024-11-18 DOI:10.1093/bioinformatics/btae683

Timo Rachel, Eva Brombacher, Svenja Wöhrle, Olaf Groß, Clemens Kreutz

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Abstract

Motivation: Mathematical modelling plays a crucial role in understanding inter- and intracellular signalling processes. Currently, ordinary differential equations (ODEs) are the predominant approach in systems biology for modelling such pathways. While ODE models offer mechanistic interpretability, they also suffer from limitations, including the need to consider all relevant compounds, resulting in large models difficult to handle numerically and requiring extensive data.

Results: In previous work, we introduced the retarded transient function (RTF) as an alternative method for modelling temporal responses of signalling pathways. Here, we extend the RTF approach to integrate concentration or dose-dependencies into the modelling of dynamics. With this advancement, RTF modelling now fully encompasses the application range of ordinary differential equation (ODE) models, which comprises predictions in both time and concentration domains. Moreover, characterizing dose-dependencies provides an intuitive way to investigate and characterize signalling differences between biological conditions or cell-types based on their response to stimulating inputs. To demonstrate the applicability of our extended approach, we employ data from time- and dose-dependent inflammasome activation in bone-marrow derived macrophages (BMDMs) treated with nigericin sodium salt. Our results show the effectiveness of the extended RTF approach as a generic framework for modelling dose-dependent kinetics in cellular signalling. The approach results in intuitively interpretable parameters that describe signal dynamics and enables predictive modelling of time- and dose-dependencies even if only individual cellular components are quantified.

Availability: The presented approach is available within the MATLAB-based Data2Dynamics modelling toolbox at https://github.com/Data2Dynamics and https://zenodo.org/records/14008247 and as R code at https://github.com/kreutz-lab/RTF.

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当 ODEs 不可行时，信号通路的动态建模。

动机数学建模在理解细胞间和细胞内信号传递过程中起着至关重要的作用。目前，常微分方程（ODE）是系统生物学中模拟此类通路的主要方法。虽然常微分方程模型提供了机理上的可解释性，但它们也有局限性，包括需要考虑所有相关化合物，导致大型模型难以数值处理，并且需要大量数据：在之前的工作中，我们介绍了迟滞瞬态函数（RTF）作为信号通路时间反应建模的替代方法。在此，我们扩展了 RTF 方法，将浓度或剂量依赖性纳入动态建模。有了这一进步，RTF建模现在完全涵盖了常微分方程（ODE）模型的应用范围，其中包括时域和浓度域的预测。此外，描述剂量依赖性为研究和描述不同生物条件或细胞类型对刺激输入的反应的信号差异提供了一种直观的方法。为了证明我们的扩展方法的适用性，我们使用了经尼格列汀钠盐处理的骨髓衍生巨噬细胞（BMDMs）中时间和剂量依赖性炎性体激活的数据。我们的研究结果表明，作为一种通用框架，扩展的 RTF 方法可以有效地模拟细胞信号的剂量依赖性动力学。该方法可获得直观易懂的参数，用于描述信号动态，即使只对单个细胞成分进行量化，也能对时间和剂量依赖性进行预测建模：所介绍的方法可从基于 MATLAB 的 Data2Dynamics 建模工具箱中获取，网址为 https://github.com/Data2Dynamics 和 https://zenodo.org/records/14008247，R 代码可从 https://github.com/kreutz-lab/RTF 获取。

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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Bioinformatics (Oxford, England)

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