Stochastic Models of Cell Cycle Regulation in Eukaryotes

真核生物细胞周期调控的随机模型

• 批准号: 7436098
• 负责人: John J. Tyson
• 金额: $ 31.33万
• 依托单位: VIRGINIA POLYTECHNIC INST AND ST UNIV
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-06-06 至 2010-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7436098
• 关键词: Accounting; Area; Behavior; Biochemical Reaction; Biological Process; Cell Cycle; Cell Cycle Regulation; Cell division; Cells; Complex; Computer software; Computing Methodologies; DNA biosynthesis; DNA chemical synthesis; Development; Environment; Equation; Eukaryota; Eukaryotic Cell; Event; Genes; Goals; Growth; Health; Human; Individual; Life; Messenger RNA; Methods; Mitosis; Modeling; Molecular; Multiprotein Complexes; Noise; Numbers; Organism; Probability; Process; Proteins; Research Personnel; Role; Saccharomycetales; Science; Stochastic Processes; System; Translating; Virginia; Wound Healing; Yeasts; carcinogenesis; cell growth; daughter cell; genetic regulatory protein; research study; simulation; stem; success; theories; tissue regeneration; tool; yeast genetics

DESCRIPTION (provided by applicant): The cycle of cell growth, DNA synthesis, mitosis and cell division is 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 dozens of 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 noisy events in the growth-division cycle. Noise stems 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). The goal of the proposed project is to create a realistic and accurate stochastic model of cell cycle control in budding yeast. To accomplish this goal the investigators will: 1) Formulate the molecular regulatory system in terms of elementary biochemical reactions, suitable for exact stochastic simulation. 2) Employ appropriate methods for approximate simulation of these stochastic process, in order to efficiently compute probabilities suitable for comparison to experiments. 3) Develop methods for parameter estimation, sensitivity analysis and bifurcation theory of stochastic dynamical systems. 4) Create a software/hardware environment that supports the demanding computations required of stochastic models of any realistic gene/mRNA/protein regulatory network. 5) Apply the methods and tools to known variability in growth and division of single yeast cells. The multi-disciplinary team at Virginia Tech has proven expertise in all aspects of the project and will be supported by external advisors who are top researchers in the areas of stochastic simulation, sensitivity analysis, bifurcation theory 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 roles of cell division in basic biological processes of significant relevance to human health: e.g., embyronic development, tissue regeneration, wound healing, and carcinogenesis.

描述（由申请人提供）：细胞生长、DNA合成、有丝分裂和细胞分裂的周期是细胞（和所有生物体）生长、发育和繁殖的基本过程。因此，了解真核细胞中控制这些过程的分子机制对科学和人类健康至关重要。控制系统是如此复杂，以至于需要数学和计算方法来可靠地跟踪数十个基因，mRNA，蛋白质和多蛋白质复合物的相互作用。确定性模型（常微分方程）足以理解细胞群的平均行为，但要理解单个细胞的远离平均的行为，需要精确解释生长-分裂周期中噪声事件的随机模型。噪音来源于单个细胞内参与分子的数量很少，以及分裂过程的变幻莫测（即，子细胞之间分子组分的不均等分配）。该项目的目标是建立一个现实的和准确的随机模型的细胞周期控制芽殖酵母。为了实现这一目标，研究人员将：1）根据基本的生物化学反应制定分子调控系统，适用于精确的随机模拟。2)采用适当的方法对这些随机过程进行近似模拟，以便有效地计算适合与实验进行比较的概率。3)发展随机动态系统的参数估计、灵敏度分析和分叉理论的方法。4)创建一个软件/硬件环境，支持任何现实的基因/mRNA/蛋白质调控网络的随机模型所需的苛刻计算。5)将这些方法和工具应用于已知的单个酵母细胞生长和分裂的变异性。弗吉尼亚理工大学的多学科团队在该项目的各个方面都有专业知识，并将得到外部顾问的支持，他们是随机模拟，敏感性分析，分叉理论和酵母遗传学领域的顶级研究人员。由于所有真核细胞似乎都采用相同的调节酵母细胞周期的基本分子机制，因此成功模拟单个酵母细胞的生长和分裂将转化为更好地理解细胞分裂在与人类健康显著相关的基本生物过程中的作用：例如，胚胎发育、组织再生、伤口愈合和致癌作用。