New Theoretical Tools for Biocatalysis

生物催化新理论工具

• 批准号: 8248951
• 负责人: Darrin M York
• 金额: $ 23.41万
• 依托单位: RUTGERS, THE STATE UNIV OF N.J.
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-04-01 至 2012-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8248951
• 关键词: New; Theoretical; Tools; Biocatalysis

DESCRIPTION (provided by applicant): The broad objective of this research is to establish the foundation for a novel fully quantum mechanical forcefield for simulations of biocatalysis that can be seamlessly integrated with other multi-scale modeling tools and applied to complex biological problems not accessible by other methods. The design of these new computational tools will greatly extend the scope of biocatalysis applications that can be reliably addressed. The impact of this work with be to create a paradigm shift away from conventional mixed quantum mechanical/molecular mechanical (QM/MM) models toward a united fully quantum mechanical approach for molecular simulations of reactive processes in complex environments. The core methods will be based on a new quantum mechanical model for biocatalysis (Biocat-QM) that combines the advantages of existing semiempirical models and extends their capabilities to accurately model reaction barriers, and charge-dependent many-body exchange, polarization and dispersion effects. The Biocat-QM will form the base of a QM/MM model that contains a new form of the QM/MM interaction where non-bonded terms automatically adjust in response to changes in charge state and hybridization. Ultimately, the Biocat-QM will be made into a novel fully quantum mechanical forcefield for simulations of biocatalysis, based on a new linear-scaling quantum method that utilizes a density-overlap repulsion model to circumvent the need for large local basis projections, and that takes advantage of a recently developed adaptive fast-multipole algorithm for efficient calculation of electrostatic interactions for generalized charge distributions. The new tools for simulations of biocatalysis developed in this proposal are designed to surmount the difficulties presented by specific driving applications: the study of the molecular mechanisms of ribozyme catalysis. The methods will be applied to two ribozyme systems that exhibit large-scale conformational changes and divalent metal ion binding coupled with catalysis, and for which very recent structural data has become available through collaborator Prof. William Scott: the full length hammerhead ribozyme and the L1 ligase ribozyme/riboswitch. These systems present unique challenges for which there currently exists no sufficiently reliable biocatalysis simulation model. The computational tools developed in this proposal will be implemented as publicly available modular software, optimized and ported to several high-performance computing platforms, and integrated with the molecular simulation packages AMBER and CHARMM.

描述(申请人提供)：这项研究的广泛目标是为模拟生物催化的新型全量子力学力场奠定基础，该力场可以与其他多尺度建模工具无缝集成，并应用于其他方法无法处理的复杂生物学问题。这些新计算工具的设计将极大地扩大生物催化应用的范围，这些应用是可以可靠地解决的。这项与BE合作的工作的影响是创造一种范式转变，从传统的混合量子力学/分子力学(QM/MM)模型转向用于复杂环境中反应过程的分子模拟的统一的全量子力学方法。核心方法将基于一种新的生物催化量子力学模型(Biocat-QM)，该模型结合了现有半经验模型的优点，并扩展了它们的能力，以准确地模拟反应势垒，以及依赖电荷的多体交换、极化和色散效应。Biocat-QM将形成QM/MM模型的基础，该模型包含一种新形式的QM/MM相互作用，其中非键项根据电荷状态和杂交的变化自动调整。最终，Biocat-QM将被制成一个新的全量子力学力场来模拟生物催化，基于一种新的线性定标量子方法，该方法利用密度重叠排斥模型来避免大的局部基投影，并利用最近开发的自适应快速多极算法来有效地计算广义电荷分布的静电相互作用。在这项建议中开发的用于模拟生物催化的新工具旨在克服特定驱动应用带来的困难：研究核酶催化的分子机制。这些方法将应用于两个核酶系统，它们表现出大规模的构象变化和二价金属离子结合与催化作用，其最新结构数据已通过合作者William Scott教授获得：全长锤头状核酶和L1连接酶核酶/核糖开关。这些系统提出了独特的挑战，目前还没有足够可靠的生物催化模拟模型。该方案中开发的计算工具将作为公开可用的模块化软件实现，经过优化并移植到几个高性能计算平台上，并与分子模拟程序包Amber和CHARMM集成。