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Mathematical models of the early embryonic cell cycle: the role of MPF activation and cyclin degradation

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Abstract

Recent advances in cell biology indicate that the interactions between two proteins, cdc2 and cyclin, together with the activity of the cdc2/cyclin complex called MPF in the cytoplasm form the basis of a universal biochemical control mechanism for the cell division cycle in eukaryotes. Based on experimental facts that total cdc2 level is constant throughout the cell cycle and that onset of mitosis is subsequent to activation of MPF, we propose and analyze two different but related models — an ordinary differential equations model and a delay differential equations model — for the control of the early embryonic cell division cycle. Assuming very general reaction terms in the model equations, it is shown that MPF activation and rapid cyclin degradation triggered by active MPF drive cells to alternate between interphase and mitosis, the two phases of the cell cycle.

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Authors and Affiliations

  1. Department of Mathematics, Harvey Mudd College, 91711, Claremont, CA, USA

    Stavros Busenberg

  2. Department of Mathematics, Arizona State University, 85287, Tempe, AZ, USA

    Betty Tang

Authors
  1. Stavros Busenberg
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  2. Betty Tang
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Additional information

S. Busenberg passed away on April 3, 1993 from complications of ALS (Lou Gehrig's disease). His research was supported by NSF Grant DMS-9112821

Research was carried out at Harvey Mudd College and was supported by NSF Grant HRD-9252994

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Busenberg, S., Tang, B. Mathematical models of the early embryonic cell cycle: the role of MPF activation and cyclin degradation. J. Math. Biology 32, 573–596 (1994). https://doi.org/10.1007/BF00573462

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  • DOI: https://doi.org/10.1007/BF00573462

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