Mapping and modeling transcription factor networks

转录因子网络的映射和建模

• 批准号: 10596647
• 负责人: MICHAEL R BRENT
• 金额: $ 39.38万
• 依托单位: WASHINGTON UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2021
• 资助国家: 美国
• 起止时间: 2021-06-01 至 2026-03-31
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10596647
• 关键词: Address; Benchmarking; Cell physiology; Cells; Chronic; Collection; Computer software; DNA Binding; Data; Data Set; Disease; Engineering; Environment; Experimental Designs; Funding; Gene Expression Profile; Genes; Genetic; Genetic Transcription; Genome; Goals; Growth; Health; Human; Lead; Maps; Metabolic; Methods; Modeling; Molecular; Nutrient; Organism; Personal Satisfaction; Pharmaceutical Preparations; Production; Proteins; Reaction; Research; Resources; Saccharomyces cerevisiae; Sampling; Scientist; Signal Transduction; Stimulus; Systems Biology; Testing; Work; Yeasts; fungus; infectious disease treatment; model organism; overexpression; pathogenic fungus; programs; response; sensor; success; transcription factor; transcriptome

PROJECT ABSTRACT Cells choose transcriptional programs, in part, by passing information from molecular sensors to signaling cascades that modulate the activity of DNA-binding transcription factors (TFs). Changes in TF activity lead to changes in the transcription rates of specific genes, which are often the first steps in responding to new information. The molecular machinery responsible for this can be thought of as the cell's control circuits. My research program focuses on developing computational and molecular methods that make it possible to map out a cell's control circuits, to watch them as they respond to new information, and ultimately to rewire them in ways that contribute to human health and well-being. Saccharomyces cere- visiae (yeast) is the ideal organism for developing these methods because of its relatively simple ge- nome, extensive collections of strains engineered for experimental systems biology, and comprehensive datasets for testing and optimizing new methods. The research proposed here focuses exclusively on yeast, but our methods will be immediately applicable to fungal pathogens and ultimately adaptable for model organisms and humans. The first objective of our plan is to optimize methods for determining which genes are regulated by each TF. We will use these methods to produce a map of the TF-target network that goes significantly beyond what is known today, both in accuracy and completeness. Like the map of metabolic reactions, this will be a valuable resource for addressing many scientific questions. Our second objective is to develope methods for inferring the activity levels of all TFs in any sample of cells by analyzing their transcriptomes. One product of this work will be easy-to-use software that will enable other scientists to identify changes in TF activity in any set of yeast transcriptional profiles. Our third objective is to develop methods for identifying proteins that regulate the activities of each TF. This will make it possible to explain the changes in TF activity we observe when stimuli, such as drugs or nutrients, are provided to cells, and to design experiments that test those explanations. Achieving these objectives will make it possible to approach our ultimate goal – to develop a quan- titative model that can predict the transcriptional response to genetic and environmental perturbations. As a concrete benchmark for success, this model should accurately predict the effect on the entire yeast transcriptome when combinations of TFs are simultaneously perturbed (deleted or overex- pressed) under growth conditions for which we have no perturbation data. We can achieve this ambi- tious, long term goal only with stable MIRA funding.

项目摘要 细胞选择转录程序，部分是通过将来自分子传感器的信息传递给 调节DNA结合转录因子（TF）活性的信号级联。变化 TF活性导致特定基因转录速率的变化，这通常是转录调控的第一步。 回应新的信息。对此负责的分子机制可以被认为是 细胞的控制电路。 我的研究项目侧重于开发计算和分子方法， 可以绘制出细胞的控制电路，观察它们对新信息的反应， 最终以有助于人类健康和福祉的方式重新连接它们。酿酒酵母 酵母菌是开发这些方法的理想生物体，因为其相对简单的基因， nome，广泛收集了用于实验系统生物学的菌株， 用于测试和优化新方法的全面数据集。本文提出的研究重点 我们的方法只适用于酵母，但我们的方法将立即适用于真菌病原体， 适用于模式生物和人类。 我们计划的第一个目标是优化确定哪些基因受 每个TF我们将使用这些方法来生成TF-目标网络的地图， 在准确性和完整性上都超出了我们今天所知的。就像代谢反应图一样， 这将是解决许多科学问题的宝贵资源。 我们的第二个目标是开发推断任何样品中所有TF活性水平的方法 通过分析它们的转录组。这项工作的一个产品将是易于使用的软件， 将使其他科学家能够确定任何一组酵母转录谱中TF活性的变化。 我们的第三个目标是开发鉴定调节每个蛋白活性的蛋白质的方法。 TF这将使我们有可能解释在TF活动的变化，我们观察到当刺激，如 药物或营养物质，提供给细胞，并设计实验来测试这些解释。 实现这些目标将使我们有可能接近我们的最终目标-发展一个全面的、 定量模型，可以预测基因和环境扰动的转录反应。 作为衡量成功的具体基准，该模型应能准确预测对整体的影响。 当TF组合同时受到干扰（缺失或过度表达）时，酵母转录组 按下）的生长条件下，我们没有扰动数据。我们可以实现这一目标- 稳定的，长期的目标，只有稳定的MIRA资金.