A deterministic method for estimating free energy genetic network landscapes with applications to cell commitment and reprogramming paths

Victor Olariu, Erica Manesso, Carsten Peterson

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Depicting developmental processes as movements in free energy genetic landscapes is an illustrative tool. However, exploring such landscapes to obtain quantitative or even qualitative predictions is hampered by the lack of free energy functions corresponding to the biochemical Michaelis– Menten or Hill rate equations for the dynamics. Being armed with energy landscapes defined by a network and its interactions would open up the possibility of swiftly identifying cell states and computing optimal paths, including those of cell reprogramming, thereby avoiding exhaustive trial-and-error simulations with rate equations for different parameter sets. It turns out that sigmoidal rate equations do have approximate free energy associations. With this replacement of rate equations, we develop a deterministic method for estimating the free energy surfaces of systems of interacting genes at different noise levels or temperatures. Once such free energy landscape estimates have been established, we adapt a shortest path algorithm to determine optimal routes in the landscapes. We explore the method on three circuits for haematopoiesis and embryonic stem cell development for commitment and reprogramming scenarios and illustrate how the method can be used to determine sequential steps for onsets of external factors, essential for efficient reprogramming.

    Original languageEnglish
    Article number160765
    JournalRoyal Society Open Science
    Volume4
    Issue number6
    DOIs
    Publication statusPublished - 2017 Jun 1

    Subject classification (UKÄ)

    • Bioinformatics (Computational Biology)
    • Other Physics Topics
    • Genetics

    Free keywords

    • Deterministic models
    • Energy landscape
    • Reprogramming
    • Stem cell commitment

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