物理学科Seminar 分子切块药物设计和虚拟筛选的量子力学方法计算研究

创建时间:  2017/02/21  龚惠英   浏览次数:   返回

报告题目Title: Fragment Based Drug Design and Virtual Screening(分子切块药物设计和虚拟筛选的量子力学方法计算研究)
报 告 人Speaker:Dr.Jun Zeng (RMIT Melbourne Australia)
报告时间Time:2017年2月21日 (周二) 16:00
报告地点Venue:校本部E106 (8455新葡萄场网站量子与分子结构国际中心SHU ICQMS)
摘要:The success of Fragment based drug design (FBDD) and structure-based drug design in general depends crucially on the accuracy of the algorithms used in the underlying docking and evaluation methods. Available software packages almost exclusively use molecular mechanics approximations based on Newtonian mechanics to describe target and ligand molecules. While reliable force fields are available for proteins and DNA molecules, a force field representation, and often even the 3D coordinates, of a given small organic molecules that is accurate and consistent with the protein force field used is in most cases still a hit-and-miss.   In particular hydrogen bond interactions between ligands and protein and interactions involving metal ions are often misrepresented.
 
We have implemented a computational FBDD approach ("MFMD") based on molecular dynamics simulations combined with quantum mechanical optimization, in order to avoid artifacts from empirical force fields and to take more accurately into account electron-electron interactions between fragments and protein side chains. Examples for FBDD using MFMD for the inhibitor design for kinases and malaria aminopeptidases will be presented.  More importantly, the feasibility of advanced quantum mechanical virtual screening of chemical library will be demonstrated for the first time .

上一条:数学系Seminar第1399期 利用卫星和飞机观察数据做火山灰云预报

下一条:物理学科Seminar 复杂卤化物闪烁晶体探测辐射的第一原理研究


物理学科Seminar 分子切块药物设计和虚拟筛选的量子力学方法计算研究

创建时间:  2017/02/21  龚惠英   浏览次数:   返回

报告题目Title: Fragment Based Drug Design and Virtual Screening(分子切块药物设计和虚拟筛选的量子力学方法计算研究)
报 告 人Speaker:Dr.Jun Zeng (RMIT Melbourne Australia)
报告时间Time:2017年2月21日 (周二) 16:00
报告地点Venue:校本部E106 (8455新葡萄场网站量子与分子结构国际中心SHU ICQMS)
摘要:The success of Fragment based drug design (FBDD) and structure-based drug design in general depends crucially on the accuracy of the algorithms used in the underlying docking and evaluation methods. Available software packages almost exclusively use molecular mechanics approximations based on Newtonian mechanics to describe target and ligand molecules. While reliable force fields are available for proteins and DNA molecules, a force field representation, and often even the 3D coordinates, of a given small organic molecules that is accurate and consistent with the protein force field used is in most cases still a hit-and-miss.   In particular hydrogen bond interactions between ligands and protein and interactions involving metal ions are often misrepresented.
 
We have implemented a computational FBDD approach ("MFMD") based on molecular dynamics simulations combined with quantum mechanical optimization, in order to avoid artifacts from empirical force fields and to take more accurately into account electron-electron interactions between fragments and protein side chains. Examples for FBDD using MFMD for the inhibitor design for kinases and malaria aminopeptidases will be presented.  More importantly, the feasibility of advanced quantum mechanical virtual screening of chemical library will be demonstrated for the first time .

上一条:数学系Seminar第1399期 利用卫星和飞机观察数据做火山灰云预报

下一条:物理学科Seminar 复杂卤化物闪烁晶体探测辐射的第一原理研究