Mechanistic modeling of cell viability assays with in silico lineage tracing

Arnab Mutsuddy, Jonah R Huggins, Aurore Amrit, Cemal Erdem, Jon C Calhoun, Marc R Birtwistle
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Abstract

Data from cell viability assays, which measure cumulative division and death events in a population and reflect substantial cellular heterogeneity, are widely available. However, interpreting such data with mechanistic computational models is hindered because direct model/data comparison is often muddled. We developed an algorithm that tracks simulated division and death events in mechanistically detailed single-cell lineages to enable such a model/data comparison and suggest causes of cell-cell drug response variability. Using our previously developed model of mammalian single-cell proliferation and death signaling, we simulated drug dose response experiments for four targeted anti-cancer drugs (alpelisib, neratinib, trametinib and palbociclib) and compared them to experimental data. Simulations are consistent with data for strong growth inhibition by trametinib (MEK inhibitor) and overall lack of efficacy for alpelisib (PI-3K inhibitor), but are inconsistent with data for palbociclib (CDK4/6 inhibitor) and neratinib (EGFR inhibitor). Model/data inconsistencies suggest (i) the importance of CDK4/6 for driving the cell cycle may be overestimated, and (ii) that the cellular balance between basal (tonic) and ligand-induced signaling is a critical determinant of receptor inhibitor response. Simulations show subpopulations of rapidly and slowly dividing cells in both control and drug-treated conditions. Variations in mother cells prior to drug treatment all impinging on ERK pathway activity are associated with the rapidly dividing phenotype and trametinib resistance. This work lays a foundation for the application of mechanistic modeling to large-scale cell viability assay datasets and better understanding determinants of cellular heterogeneity in drug response.
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细胞活力测定的机理建模与硅系追踪
细胞存活率测定可测量群体中的累积分裂和死亡事件,并反映细胞的实质性异质性,其数据可广泛获得。然而,用机理计算模型来解释这些数据却受到阻碍,因为直接的模型/数据比较往往是模糊不清的。我们开发了一种算法,可追踪机理上详细的单细胞系中的模拟分裂和死亡事件,以实现这种模型/数据比较,并提出细胞-细胞药物反应变异的原因。利用我们之前开发的哺乳动物单细胞增殖和死亡信号传导模型,我们模拟了四种靶向抗癌药物(阿哌利西布、奈拉替尼、曲美替尼和帕博西利布)的药物剂量反应实验,并与实验数据进行了比较。模拟结果与数据一致,表明曲美替尼(MEK 抑制剂)对生长有很强的抑制作用,而阿来替尼(PI-3K 抑制剂)总体上缺乏疗效,但与帕博西尼(CDK4/6 抑制剂)和奈拉替尼(表皮生长因子受体抑制剂)的数据不一致。模型/数据不一致表明:(i) CDK4/6 对于驱动细胞周期的重要性可能被高估了;(ii) 基础(强直)信号传导和配体诱导信号传导之间的细胞平衡是决定受体抑制剂反应的关键因素。模拟结果显示,在对照组和药物处理组的条件下,都存在快速分裂和缓慢分裂的细胞亚群。药物治疗前母细胞的变化都会影响ERK通路的活性,这与快速分裂表型和曲美替尼耐药有关。这项研究为将机理建模应用于大规模细胞活力测定数据集以及更好地理解药物反应中细胞异质性的决定因素奠定了基础。
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