Theory and Modeling of Biomolecules and their Interactions

生物分子及其相互作用的理论和建模

基本信息

批准号：
10554419
负责人：
CHARLES L BROOKS
金额：
$ 83.16万
依托单位：
UNIVERSITY OF MICHIGAN AT ANN ARBOR
依托单位国家：
美国
项目类别：
财政年份：
2019
资助国家：
美国
起止时间：
2019-02-01 至 2024-03-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10554419
关键词：
Acids Actin-Binding Protein Address Area Big Data Biological Biomedical Research CREBBP gene Chemicals Collaborations Communities Complex Computer Simulation Computer software Computing Methodologies Development Docking Environment Enzymes Equilibrium Evolution Fibroblast Growth Factor Flavins Free Energy GTP-Binding Proteins Genetic Transcription Goals HRX protein Interleukins Ligand Binding Ligands MED25 gene Malignant Neoplasms Mediating Mediation Menin Methodology Methods Mixed Function Oxygenases Modeling Molecular Nucleic Acids Oncogenic Pharmaceutical Preparations Pharmacologic Substance Phosphotransferases Play Process Proteins Protocols documentation Research Role Signal Transduction Statistical Mechanics Statistical Methods Structure Technology Testing Thermodynamics Transcriptional Activation Work cancer therapy design improved inhibitor innovation insight models and simulation molecular dynamics myristoylation novel protein protein interaction protonation receptor sensor simulation small molecule software development software infrastructure theories tool

项目摘要

Project Summary/Abstract The establishment of tools and methods from statistical mechanics and computer simulation technology to enable the exploration of biological molecules and their interactions plays a central role in discovery within biomedical research. This proposal represents a request for support of our ongoing efforts in this area and includes objectives to address challenges in the theory and modeling associated with these problems, as well as strategically chosen collaborations that will help elucidate important biomedical questions and provide crucial tests of the approaches we develop. Our proposed development efforts include the exploration of receptor-ligand interactions and the thermodynamics of ligand binding to biological receptors through the continued development and application of novel methods of free energy simulations to ligand binding thermodynamics, docking and receptor-ligand interaction modeling. The continued refinement, hardening and application of theoretical and computational methods of constant pH molecular dynamics to integrate the critical aspects of pH and protonation state changes in protein and nucleic acid receptors and their ligands in molecular simulations and modeling represents another challenge we will continue to address with the proposed work. Finally, software infrastructure, specifically the CHARMM macromolecular simulation package, provides the framework for advancing our methodological approaches and enabling the broader community to explore biomedically motivated questions via its wide usage and distribution. A component of our proposed efforts will be to continue the innovative implementation of methods and simulation approaches into this community standard software package. We will balance and drive our development efforts in the areas of free energy simulations, ligand – receptor docking and pH-mediated structure-function processes, important to a deeper mechanistic understanding of biomedically directed questions, through strategic collaborations with experimental colleagues in the areas of: transcriptional activation based on small amphipathic molecules targeting co-activators from the CREB binding protein (KIX) and the AciD domain of Med25; key cancer targets such as menin-MLL protein- protein interaction inhibition; inhibitors of acyl protein thioesterases, targeted in anti-cancer therapies for oncogenic HRas; enzyme redesign and substrate scope expansion to better understand the evolution of function of a novel Flavin-dependent hydroxylase in exploiting complex chemical transformations important in the development of pharmaceuticals; pH-regulated sensors in kinase signaling associated with the G-protein from the tetrameric Gai protein; the pH-modulated switch for myristoylated histactophilin, the actin binding protein that is structurally homologous with interleukin-1b and fibroblast growth factor. Finally, we will engage experts in the development of big data applications of molecular simulations and the design and execution of robust user APIs to work with us toward advancing objectives in software development for large multi-scale simulations of cellular environments and automated workflows, through CHARMM-GUI, for sophisticated simulation protocols.

项目摘要/摘要从统计力学和计算机模拟技术建立工具和方法到实现生物分子及其相互作用的探索在发现中起着核心作用生物医学研究。该提案代表了我们在这一领域正在进行的努力的要求，还包括解决理论中挑战的目标，以及与这些问题相关的建模作为战略性选择的合作，将有助于阐明重要的生物医学问题并提供关键测试我们开发的方法。我们提出的开发工作包括探索接收器配体通过持续发展，配体与生物受体结合的相互作用和热力学新型自由能模拟方法的应用在配体结合热力学，对接和受体配体相互作用建模。理论和恒定pH分子动力学的计算方法整合了pH和质子化的关键方面蛋白质和核酸受体及其配体的状态变化在分子模拟和建模中的变化代表了我们将继续解决拟议工作的另一个挑战。最后，软件基础架构，特别是CHARMM大分子模拟软件包，为推进我们的方法论方法，并使更广泛的社区能够探索生物医学通过其广泛的使用和分发来激发问题。我们提出的努力的一个组成部分将是继续方法和模拟方法的创新实施到该社区标准软件中包裹。我们将在自由能模拟，配体 - 配体 - 受体对接和pH介导的结构功能过程，对更深的机理很重要通过与实验同事的战略合作，了解生物医学指示的问题在以下区域：基于针对共激活剂的小两亲分子的转录激活 CREB结合蛋白（KIX）和MED25的酸域；关键癌症靶标，例如Menin-Mll蛋白质 - 蛋白质相互作用抑制；针对抗癌疗法的酰基蛋白硫酯酶的抑制剂致癌hras;酶重新设计和底物范围扩展以更好地了解功能的演变一种新型黄素依赖性羟化酶在利用复杂化学转化中重要制药的开发；与G蛋白相关的激酶信号传导中的pH调节传感器四聚体GAI蛋白；肉豆蔻酰化的组织酚蛋白（肌动蛋白结合蛋白）的pH调节开关与白介素1b和成纤维细胞生长因子在结构上是同源的。最后，我们将参与专家开发分子模拟的大数据应用以及强大的用户API的设计和执行与我们合作，以推进软件开发中的对象，以进行大型蜂窝的多尺度模拟环境和自动化工作流，通过CHARMM-GUI，用于复杂的仿真协议。