TY - JOUR T1 - A Simple and Efficient Pipeline for Construction, Merging, Expansion, and Simulation of Large-Scale, Single-Cell Mechanistic Models JF - bioRxiv DO - 10.1101/2020.11.09.373407 SP - 2020.11.09.373407 AU - Cemal Erdem AU - Ethan M. Bensman AU - Arnab Mutsuddy AU - Michael M. Saint-Antoine AU - Mehdi Bouhaddou AU - Robert C. Blake AU - Will Dodd AU - Sean M. Gross AU - Laura M. Heiser AU - F. Alex Feltus AU - Marc R. Birtwistle Y1 - 2020/01/01 UR - http://biorxiv.org/content/early/2020/11/10/2020.11.09.373407.abstract N2 - The current era of big biomedical data accumulation and availability brings data integration opportunities for leveraging its totality to make new discoveries and/or clinically predictive models. Black-box statistical and machine learning methods are powerful for such integration, but often cannot provide mechanistic reasoning, particularly on the single-cell level. While single-cell mechanistic models clearly enable such reasoning, they are predominantly “small-scale”, and struggle with the scalability and reusability required for meaningful data integration. Here, we present an open-source pipeline for scalable, single-cell mechanistic modeling from simple, annotated input files that can serve as a foundation for mechanistic data integration. As a test case, we convert one of the largest existing single-cell mechanistic models to this format, demonstrating robustness and reproducibility of the approach. We show that the model cell line context can be changed with simple replacement of input file parameter values. We next use this new model to test alternative mechanistic hypotheses for the experimental observations that interferon-gamma (IFNG) inhibits epidermal growth factor (EGF)-induced cell proliferation. Model- based analysis suggested, and experiments support that these observations are better explained by IFNG-induced SOCS1 expression sequestering activated EGF receptors, thereby downregulating AKT activity, as opposed to direct IFNG-induced upregulation of p21 expression. Overall, this new pipeline enables large-scale, single-cell, and mechanistically-transparent modeling as a data integration modality complementary to machine learning.Competing Interest StatementThe authors have declared no competing interest. ER -