Coarse-Grained Models of Proteins

蛋白质的粗粒度模型

• 批准号: 6914431
• 负责人: ROBERT L JERNIGAN
• 金额: $ 26.32万
• 依托单位: IOWA STATE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-07-01 至 2008-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6914431
• 关键词: chemical models; computer data analysis; computer program /software; computer simulation; computer system design /evaluation; diphtheria toxin; mathematical model; molecular biology information system; protein structure function; statistics /biometry

DESCRIPTION (provided by applicant): The goal of the proposed project is to develop several new coarse-grained computational models to describe protein structures and protein dynamics. These innovations will let us approach much larger structures, as well as to comprehend important functional behaviors more readily. The realization of the proposed project might be extremely important for the development of computational cell biology and for practical applications in drug design. The project focuses on three specific aims: Specific Aim I: Study protein dynamics using the Gaussian Network Model and Anisotropic Network Model. We will develop a mixed coarse-grained method where the 'interesting' or functional parts of proteins are modeled at a higher resolution than the remainder of the structure. By using this approach, normal mode analysis can be performed to discern the important functional motions with high computational efficiency for large biologically important molecules. Specific Aim II: Develop an extremely efficient transfer matrix method for attrition-free generation of lattice proteins on the square lattice in 2-dimensions and for the cubic lattice in 3-dimensions. The proposed method is an extension of the transfer matrix method for generating and the enumerating compact self-avoiding walks on lattices previously developed by the project's investigators. Specific Aim Ill: Conduct an off-lattice study of the dependencies between protein shapes and their conformations. The goal is to generate libraries of possible three-dimensional protein structures using a minimal set of assumptions. We constrict the shape of the protein within a three-dimensional ellipsoid of revolution and generate all possible compact protein conformations within the shape. We will also study in a systematic way the interdependence between the structures and the shapes of the proteins, as well as their dynamics with the Gaussian Network Models developed in the Specific Aim 1. These findings open the way for more abstract and mathematical representations of biological structure that can lead directly to a better and more complete comprehension of structure and function.

描述（由申请人提供）：拟议项目的目标是开发几种新的粗粒计算模型来描述蛋白质结构和蛋白质动力学。这些创新将使我们更加容易地了解更大的结构，并更容易理解重要的功能行为。拟议项目的实现对于开发计算细胞生物学和药物设计中的实际应用可能非常重要。该项目侧重于三个特定目标：特定目的I：使用高斯网络模型和各向异性网络模型研究蛋白质动力学。我们将开发一种混合的粗粒方法，在该方法中，蛋白质的“有趣”或功能部分以高于结构的其余部分建模。通过使用这种方法，可以进行正常的模式分析，以辨别重要具有较高的生物学重要分子的重要功能运动。特定目标II：开发一种极有效的传递矩阵方法，用于在2维中在方格上的无损耗生成晶格蛋白，并在三维中为立方晶格生成。所提出的方法是传输矩阵方法的扩展，用于生成和列举紧凑的自我避免自我避免步行，以先前由项目研究者开发的晶格。特定目标：对蛋白质形状及其构象之间的依赖性进行非法研究。目标是使用最小的假设集生成可能的三维蛋白质结构的库。我们在革命的三维椭圆形中限制了蛋白质的形状，并在形状内产生所有可能的紧凑型蛋白质构象。我们还将以系统的方式研究结构和蛋白质的形状之间的相互依赖性，以及它们与特定目标中开发的高斯网络模型的动力学研究。这些发现为生物结构的更抽象和数学表示开辟了道路，可以直接导致对结构和功能的更好和更完整的结构和功能的完整理解。