Systems modeling of oncogenic G-protein and GPCR signaling reveals unexpected differences in downstream pathway activation.

IF 3.5 2区 生物学 Q1 MATHEMATICAL & COMPUTATIONAL BIOLOGY
Michael Trogdon, Kodye Abbott, Nadia Arang, Kathryn Lande, Navneet Kaur, Melinda Tong, Mathieu Bakhoum, J Silvio Gutkind, Edward C Stites
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Abstract

Mathematical models of biochemical reaction networks are an important and emerging tool for the study of cell signaling networks involved in disease processes. One promising potential application of such mathematical models is the study of how disease-causing mutations promote the signaling phenotype that contributes to the disease. It is commonly assumed that one must have a thorough characterization of the network readily available for mathematical modeling to be useful, but we hypothesized that mathematical modeling could be useful when there is incomplete knowledge and that it could be a tool for discovery that opens new areas for further exploration. In the present study, we first develop a mechanistic mathematical model of a G-protein coupled receptor signaling network that is mutated in almost all cases of uveal melanoma and use model-driven explorations to uncover and explore multiple new areas for investigating this disease. Modeling the two major, mutually-exclusive, oncogenic mutations (Gαq/11 and CysLT2R) revealed the potential for previously unknown qualitative differences between seemingly interchangeable disease-promoting mutations, and our experiments confirmed oncogenic CysLT2R was impaired at activating the FAK/YAP/TAZ pathway relative to Gαq/11. This led us to hypothesize that CYSLTR2 mutations in UM must co-occur with other mutations to activate FAK/YAP/TAZ signaling, and our bioinformatic analysis uncovers a role for co-occurring mutations involving the plexin/semaphorin pathway, which has been shown capable of activating this pathway. Overall, this work highlights the power of mechanism-based computational systems biology as a discovery tool that can leverage available information to open new research areas.

Abstract Image

致癌 G 蛋白和 GPCR 信号的系统建模揭示了下游通路激活中意想不到的差异。
生化反应网络的数学模型是研究涉及疾病过程的细胞信号网络的一种重要的新兴工具。此类数学模型的一个前景广阔的潜在应用领域是研究致病突变如何促进导致疾病的信号表型。人们通常认为,数学建模必须具备对网络的全面描述才能发挥作用,但我们假设,在知识不完整的情况下,数学建模也能发挥作用,它可以成为一种发现工具,为进一步探索开辟新的领域。在本研究中,我们首先建立了一个在几乎所有葡萄膜黑色素瘤病例中都发生突变的 G 蛋白偶联受体信号转导网络的机理数学模型,并利用模型驱动的探索来发现和探索研究这种疾病的多个新领域。我们的实验证实,相对于Gαq/11,致癌的CysLT2R在激活FAK/YAP/TAZ通路方面有缺陷。我们的生物信息学分析揭示了涉及 plexin/semaphorin 通路的共生突变的作用,该通路已被证明能够激活该通路。总之,这项工作凸显了基于机制的计算系统生物学作为一种发现工具的威力,它可以利用现有信息开辟新的研究领域。
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来源期刊
NPJ Systems Biology and Applications
NPJ Systems Biology and Applications Mathematics-Applied Mathematics
CiteScore
5.80
自引率
0.00%
发文量
46
审稿时长
8 weeks
期刊介绍: npj Systems Biology and Applications is an online Open Access journal dedicated to publishing the premier research that takes a systems-oriented approach. The journal aims to provide a forum for the presentation of articles that help define this nascent field, as well as those that apply the advances to wider fields. We encourage studies that integrate, or aid the integration of, data, analyses and insight from molecules to organisms and broader systems. Important areas of interest include not only fundamental biological systems and drug discovery, but also applications to health, medical practice and implementation, big data, biotechnology, food science, human behaviour, broader biological systems and industrial applications of systems biology. We encourage all approaches, including network biology, application of control theory to biological systems, computational modelling and analysis, comprehensive and/or high-content measurements, theoretical, analytical and computational studies of system-level properties of biological systems and computational/software/data platforms enabling such studies.
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