Prelude to a Compositional Systems Biology

Eran Agmon
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Abstract

Composition is a powerful principle for systems biology, focused on the interfaces, interconnections, and orchestration of distributed processes. Whereas most systems biology models focus on the structure or dynamics of specific subsystems in controlled conditions, compositional systems biology aims to connect such models into integrative multiscale simulations. This emphasizes the space between models--a compositional perspective asks what variables should be exposed through a submodel's interface? How do coupled models connect and translate across scales? How can we connect domain-specific models across biological and physical research areas to drive the synthesis of new knowledge? What is required of software that integrates diverse datasets and submodels into unified multiscale simulations? How can the resulting integrative models be accessed, flexibly recombined into new forms, and iteratively refined by a community of researchers? This essay offers a high-level overview of the key components for compositional systems biology, including: 1) a conceptual framework and corresponding graphical framework to represent interfaces, composition patterns, and orchestration patterns; 2) standardized composition schemas that offer consistent formats for composable data types and models, fostering robust infrastructure for a registry of simulation modules that can be flexibly assembled; 3) a foundational set of biological templates--schemas for cellular and molecular interfaces, which can be filled with detailed submodels and datasets, and are designed to integrate knowledge that sheds light on the molecular emergence of cells; and 4) scientific collaboration facilitated by user-friendly interfaces for connecting researchers with datasets and models, and which allows a community of researchers to effectively build integrative multiscale models of cellular systems.
合成系统生物学的前奏
大多数系统生物学模型侧重于特定子系统在受控条件下的结构或动力学,而组合系统生物学则旨在将这些模型连接成综合的多尺度模拟。这就强调了模型之间的空间--组合视角会问哪些变量应通过子模型的界面暴露出来?耦合模型如何跨尺度连接和转换?我们如何连接生物和物理研究领域的特定领域模型,以推动新知识的合成?将不同的数据集和子模型集成到统一的多尺度模拟中的软件需要具备哪些条件?由此产生的集成模型如何才能被研究人员群体访问、灵活地重新组合成新的形式并得到文学上的完善?本文从高层次概述了组合系统生物学的关键要素,包括1)概念框架和相应的图形框架,用于表示接口、组合模式和协调模式;2)标准化的组合模式,为组合数据类型和模型提供一致的格式,为可灵活组合的模拟模块注册中心提供强大的基础设施;3)一套基本的生物学模板--细胞和分子界面的模式,可填充详细的子模型和数据集,旨在整合揭示细胞分子出现的知识;以及4)通过用户友好界面促进科学合作,将研究人员与数据集和模型连接起来,使研究人员社区能够有效地构建细胞系统的多尺度综合模型。
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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