Origin of bistability underlying mammalian cell cycle entry |
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| Authors: | Guang Yao Mike West Joseph R Nevins Lingchong You |
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| Affiliation: | 1. Department of Molecular & Cellular Biology, University of Arizona, , Tucson, AZ, USA;2. Institute for Genome Sciences and Policy, Duke University, , Durham, NC, USA;3. Department of Statistical Science, Duke University, , Durham, NC, USA;4. Department of Molecular Genetics and Microbiology, Duke University Medical Center, , Durham, NC, USA;5. Department of Biomedical Engineering, Duke University, , Durham, NC, USA;6. Duke Center for Systems Biology, , Durham, NC, USA |
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| Abstract: | Precise control of cell proliferation is fundamental to tissue homeostasis and differentiation. Mammalian cells commit to proliferation at the restriction point (R‐point). It has long been recognized that the R‐point is tightly regulated by the Rb–E2F signaling pathway. Our recent work has further demonstrated that this regulation is mediated by a bistable switch mechanism. Nevertheless, the essential regulatory features in the Rb–E2F pathway that create this switching property have not been defined. Here we analyzed a library of gene circuits comprising all possible link combinations in a simplified Rb–E2F network. We identified a minimal circuit that is able to generate robust, resettable bistability. This minimal circuit contains a feed‐forward loop coupled with a mutual‐inhibition feedback loop, which forms an AND‐gate control of the E2F activation. Underscoring its importance, experimental disruption of this circuit abolishes maintenance of the activated E2F state, supporting its importance for the bistability of the Rb–E2F system. Our findings suggested basic design principles for the robust control of the bistable cell cycle entry at the R‐point. |
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