Cell Decision Making through the Lens of Bayesian Learning

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    Abstract

    Cell decision making refers to the process by which cells gather information from their local microenvironment and regulate their internal states to create appropriate responses. Microenvironmental cell sensing plays a key role in this process. Our hypothesis is that cell decision-making regulation is dictated by Bayesian learning. In this article, we explore the implications of this hypothesis for internal state temporal evolution. By using a timescale separation between internal and external variables on the mesoscopic scale, we derive a hierarchical Fokker–Planck equation for cell-microenvironment dynamics. By combining this with the Bayesian learning hypothesis, we find that changes in microenvironmental entropy dominate the cell state probability distribution. Finally, we use these ideas to understand how cell sensing impacts cell decision making. Notably, our formalism allows us to understand cell state dynamics even without exact biochemical information about cell sensing processes by considering a few key parameters.

    Original languageBritish English
    Article number609
    JournalEntropy
    Volume25
    Issue number4
    DOIs
    StatePublished - Apr 2023

    Keywords

    • Bayesian learning
    • cell decision making
    • cell sensing dynamics
    • hierarchical Fokker–Planck equation
    • least microenvironmental uncertainty principle (LEUP)
    • multiscale

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