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AF: SMALL: Developing Novel Computational Methods for Investigating Protein Dynamics Using a Multi-Scale Approach

$249,774FY2011CSENSF

University Of Massachusetts Boston, Dorchester MA

Investigators

Abstract

Proteins are the workhorses of the cell, involved in virtually every process in life. Many proteins are flexible molecules that undergo structural changes as part of their function. In other words ? they can assume various possible structures (conformations) via changes that range from small-scale movements to large domain motions. The question of how the structure and dynamics of proteins relate to their function has challenged scientists for several decades but still remains largely open. Existing computational methods for simulating protein dynamics can sample atomic level dynamic processes, yet their usefulness is limited as they require large computational resources, and they only allow for modeling of interactions that take place on very small time scales (e.g., several hundreds of nanoseconds). There is promise that understanding the connection between protein structure, dynamics and function can contribute a lot to the understanding of how molecular machines function and may aid in drug design and functional analysis. A computational framework for an efficient large-scale exploration of protein conformational changes is proposed in this work. Given a protein structure, the aim is to efficiently generate a diverse set of conformations representing the low energy landscape of this protein under physiological conditions. The suggested methodology can be used to explore the conformational space of proteins and protein complexes and gain better understanding of protein dynamics and function. To overcome the computational demands of a full scale conformational search, the search will be done in two stages: first, conduct a fast and approximate geometry-based exploration of the low energy landscape of proteins and protein complexes in an efficient way, temporarily sacrificing small-scale details for efficiency. The approximate search is enhanced with a novel biasing scheme that drives the search towards more flexible regions of the protein, reducing the huge search space into a manageable size. The reduced representation of the conformational landscape will be enhanced and complemented with detailed, physics based simulations applied to interesting and important regions in the proteins or to intermediate structures. This last stage will take advantage of massive parallel computing. The combination of fast, approximate search techniques and detailed physics-based simulation methods will create an enhanced, more complete picture of the low-energy landscape of those proteins and will improve understanding about how proteins perform their function. The methodology can be applied to problems related to protein interactions and rational drug design. The broader impact of this project is partly due to the central role of proteins in virtually every basic biological function. This project addresses a significant question of the biological research community. Educational and outreach activities will be implemented through the following: a) Interdisciplinary collaborations with members of the CS department and other departments in the College of Science and Mathematics at UMass Boston. b) Training and mentoring the research of undergraduate and graduate students, including women and students from under-represented groups in science. c) Help setting up a Bioinformatics research and teaching program at UMass Boston.

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AF: SMALL: Developing Novel Computational Methods for Investigating Protein Dynamics Using a Multi-Scale Approach · GrantIndex