@ARTICLE{10.3389/fmolb.2022.800152, AUTHOR={Stoll, Gautier and Naldi, Aurélien and Noël, Vincent and Viara, Eric and Barillot, Emmanuel and Kroemer, Guido and Thieffry, Denis and Calzone, Laurence}, TITLE={UPMaBoSS: A Novel Framework for Dynamic Cell Population Modeling}, JOURNAL={Frontiers in Molecular Biosciences}, VOLUME={9}, YEAR={2022}, URL={https://www.frontiersin.org/articles/10.3389/fmolb.2022.800152}, DOI={10.3389/fmolb.2022.800152}, ISSN={2296-889X}, ABSTRACT={Mathematical modeling aims at understanding the effects of biological perturbations, suggesting ways to intervene and to reestablish proper cell functioning in diseases such as cancer or in autoimmune disorders. This is a difficult task for obvious reasons: the level of details needed to describe the intra-cellular processes involved, the numerous interactions between cells and cell types, and the complex dynamical properties of such populations where cells die, divide and interact constantly, to cite a few. Another important difficulty comes from the spatial distribution of these cells, their diffusion and motility. All of these aspects cannot be easily resolved in a unique mathematical model or with a unique formalism. To cope with some of these issues, we introduce here a novel framework, UPMaBoSS (for Update Population MaBoSS), dedicated to modeling dynamic populations of interacting cells. We rely on the preexisting tool MaBoSS, which enables probabilistic simulations of cellular networks. A novel software layer is added to account for cell interactions and population dynamics, but without considering the spatial dimension. This modeling approach can be seen as an intermediate step towards more complex spatial descriptions. We illustrate our methodology by means of a case study dealing with TNF-induced cell death. Interestingly, the simulation of cell population dynamics with UPMaBoSS reveals a mechanism of resistance triggered by TNF treatment. Relatively easy to encode, UPMaBoSS simulations require only moderate computational power and execution time. To ease the reproduction of simulations, we provide several Jupyter notebooks that can be accessed within the CoLoMoTo Docker image, which contains all software and models used for this study.} }