The cycle of cell growth, DNA synthesis, mitosis and cell division is the fundamental process by which cells (and all living organisms) grow, develop and reproduce. Hence, it is of crucial importance to science and human health to understand the molecular mechanisms that control these processes in eukaryotic cells. The control system is so complex that mathematical and computational methods are needed to reliably track the interactions of all the relevant genes, mRNAs, proteins, and multiprotein complexes. Deterministic models (ordinary differential equations) are adequate for understanding the average behavior of groups of cells, but to understand the far-from-average behavior of individual cells requires stochastic models that accurately account for noise stemming from small numbers of participating molecules within a single cell and from vagaries of the division process (i.e., unequal partitioning of molecular components between daughter cells). Accurately modeling the variable responses among cells in a population may be critical to understanding abnormal and diseased cell proliferation. The goals of the proposed renewal are to 1) develop a realistic and accurate stochastic model of cell cycle control in budding yeast and to extend this model to the control of mammalian cell proliferation, 2) measure stochastic effects in single yeast cells in order to provide experimental constraints on and tests of the model, and 3) develop effective algorithms and software to support stochastic modeling and simulation, and to make these tools readily available to the scientific community. Our multi-disciplinary team at Virginia Tech has proven expertise in all aspects of the project and close collaborations with top researchers in the areas of stochastic simulation, sensitivity analysis, bifurcation theory, modeling software, and yeast genetics. Because all eukaryotic cells seem to employ the same fundamental molecular machinery that regulates the cell cycle of yeast, success in modeling growth and division of single yeast cells will translate into better understanding of the role of mammalian cell division in basic biological processes of significance to human health: e.g., embyronic development, tissue regeneration, wound healing, and carcinogenesis.
The cell division cycle is the fundamental process of biological growth and reproduction, and mistakes in this process underlie many serious health problems, especially cancer. An integrative understanding of the cellular basis of health and disease will require, among other things, a description of the cell cycle by computational models that account accurately for the reliability of DNA replication and inheritance despite the molecular fluctuations that inevitably occur in the small confines of a living cell. Hence, a validated stochastic model of the eukaryotic cell cycle is essential to progress in the field of molecular systems biology.
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