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Carbohydrate force fields for structure, dynamics and molecular recognition

用于结构、动力学和分子识别的碳水化合物力场

基本信息

批准号：
7927925
负责人：
ALEXANDER D MACKERELL
金额：
$ 29.18万
依托单位：
UNIVERSITY OF MARYLAND BALTIMORE
依托单位国家：
美国
项目类别：
财政年份：
2005
资助国家：
美国
起止时间：
2005-09-01 至 2014-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7927925
关键词：
Biological Biological Phenomena Biological Process Biopolymers Carbohydrates Cell Communication Cells Cerebrosides Communities Complex Computer Simulation Data Development Disaccharides Electronics Environment Equilibrium Eukaryota Event Extracellular Matrix Foundations Funding Ganglioside GM1 Glycolipids Glycoproteins Goals Hyaluronan Hydroxyl Radical Immune response Interstitial Cystitis Knowledge Laboratories Lipids Metabolic Methods Modeling Molecular Neurons Nucleic Acids Outcome Phase Play Polysaccharides Procedures Prokaryotic Cells Property Proteins Reproduction Role Series Sphingolipids Structure Structure-Activity Relationship System Technology Theoretical Studies Therapeutic Agents Vaccines Validation Water Work aqueous base carbohydrate structure computational chemistry design field study functional group improved insight intermolecular interaction molecular recognition novel novel therapeutics octylglucopyranoside programs public health relevance small molecule tool web site

项目摘要

DESCRIPTION (provided by applicant): Carbohydrates are the most abundant biopolymers on earth. Their biological functions include fuels, energy storage, metabolic intermediates, structural roles and, importantly, molecular recognition. Accordingly, detailed knowledge of carbohydrate structure-function relationships will allow for better understanding of a variety of biological phenomena as well as facilitate the development of therapeutic agents and energy technologies. To explore such structure-function relationships theoretical approaches offer great potential. The proposed study will expand and improve theoretical methods for the study of carbohydrates, including those involved in molecular recognition, and improve our understanding of the structural and dynamical properties of these important molecules, including the role of solvation on those properties. These goals will be achieved by extending the additive empirical force field developed in our laboratory during the initial funding period to furanose containing disaccharides, glycoproteins and glycolipids, and carbohydrates that include non-hydroxyl functional groups. Force fields developments efforts will also initiate the optimization of a polarizable force field based on the classical Drude oscillator and include development of a 5-point polarizable water model. The proposed force fields will then be validated on a series of di-, tri and polysaccharides, glycoproteins and glycolipids. A variety of experimental data is available for the targeted molecules and the proposed calculations will also yield insights into the properties of these biologically important systems. Upon completion of the proposed study validated additive and polarizable force fields for carbohydrates will be available to the scientific community that are compatible with available force fields for proteins, lipids and nucleic acids. The availability of these tools will greatly enhance the applicability of computational approaches to these biologically essential molecules, facilitating the development of novel therapeutic agents, vaccines, approaches to clean energy and counterterrorism agents. PUBLIC HEALTH RELEVANCE: Carbohydrate's biological functions include fuels, energy storage, metabolic intermediates, structural roles and molecular recognition. The proposed study will develop new computational models for carbohydrates that will allow for studies on the structural and dynamical properties at a molecular level of detail. These tools will facilitate the development of novel therapeutic agents, vaccines, approaches to clean energy and counterterrorism agents.

描述（由申请人提供）：碳水化合物是地球上最丰富的生物聚合物。它们的生物学功能包括燃料、能量储存、代谢中间体、结构作用以及重要的分子识别。因此，碳水化合物结构-功能关系的详细知识将允许更好地理解各种生物现象，以及促进治疗剂和能源技术的发展。探索这种结构-功能关系的理论方法提供了巨大的潜力。拟议的研究将扩大和改进研究碳水化合物的理论方法，包括参与分子识别的方法，并提高我们对这些重要分子的结构和动力学性质的理解，包括溶剂化对这些性质的作用。这些目标将通过将我们实验室在初始资助期间开发的添加剂经验力场扩展到含有二糖、糖蛋白和糖脂以及包括非羟基官能团的碳水化合物的呋喃糖来实现。力场开发工作还将启动基于经典Drude振荡器的可极化力场的优化，包括开发5点可极化水模型。然后将在一系列的二，三和多糖，糖蛋白和糖脂上验证所提出的力场。各种实验数据可用于目标分子和拟议的计算也将产生洞察这些生物重要系统的属性。在完成拟议的研究后，科学界将获得碳水化合物的经验证的加性和可极化力场，这些力场与蛋白质、脂质和核酸的可用力场兼容。这些工具的可用性将大大提高计算方法对这些生物学必需分子的适用性，促进新型治疗剂，疫苗，清洁能源和反恐剂的开发。公共卫生相关性：碳水化合物的生物学功能包括燃料、能量储存、代谢中间体、结构作用和分子识别。这项研究将开发新的碳水化合物计算模型，以便在分子水平上详细研究其结构和动力学特性。这些工具将有助于开发新的治疗剂、疫苗、清洁能源方法和反恐剂。