TY - GEN
T1 - A multi-directional Rapidly Exploring Random Graph (mRRG) for protein folding
AU - Nath, Shuvra Kanti
AU - Thomas, Shawna
AU - Ekenna, Chinwe
AU - Amato, Nancy M.
N1 - Copyright:
Copyright 2012 Elsevier B.V., All rights reserved.
PY - 2012
Y1 - 2012
N2 - Modeling large-scale protein motions, such as those involved in folding and binding interactions, is crucial to better understanding not only how proteins move and interact with other molecules but also how proteins misfold, thus causing many devastating diseases. Robotic motion planning algorithms, such as Rapidly Exploring Random Trees (RRTs), have been successful in simulating protein folding pathways. Here, we propose a new multi-directional Rapidly Exploring Random Graph (mRRG) specifically tailored for proteins. Unlike traditional RRGs which only expand a parent conformation in a single direction, our strategy expands the parent conformation in multiple directions to generate new samples. Resulting samples are connected to the parent conformation and its nearest neighbors. By leveraging multiple directions, mRRG can model the protein motion landscape with reduced computational time compared to several other robotics-based methods for small to moderate-sized proteins. Our results on several proteins agree with experimental hydrogen out-exchange, pulse-labeling, and F-value analysis. We also show that mRRG covers the conformation space better as compared to the other computation methods.
AB - Modeling large-scale protein motions, such as those involved in folding and binding interactions, is crucial to better understanding not only how proteins move and interact with other molecules but also how proteins misfold, thus causing many devastating diseases. Robotic motion planning algorithms, such as Rapidly Exploring Random Trees (RRTs), have been successful in simulating protein folding pathways. Here, we propose a new multi-directional Rapidly Exploring Random Graph (mRRG) specifically tailored for proteins. Unlike traditional RRGs which only expand a parent conformation in a single direction, our strategy expands the parent conformation in multiple directions to generate new samples. Resulting samples are connected to the parent conformation and its nearest neighbors. By leveraging multiple directions, mRRG can model the protein motion landscape with reduced computational time compared to several other robotics-based methods for small to moderate-sized proteins. Our results on several proteins agree with experimental hydrogen out-exchange, pulse-labeling, and F-value analysis. We also show that mRRG covers the conformation space better as compared to the other computation methods.
KW - Algorithms
UR - http://www.scopus.com/inward/record.url?scp=84869413057&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=84869413057&partnerID=8YFLogxK
U2 - 10.1145/2382936.2382942
DO - 10.1145/2382936.2382942
M3 - Conference contribution
AN - SCOPUS:84869413057
SN - 9781450316705
T3 - 2012 ACM Conference on Bioinformatics, Computational Biology and Biomedicine, BCB 2012
SP - 44
EP - 51
BT - 2012 ACM Conference on Bioinformatics, Computational Biology and Biomedicine, BCB 2012
T2 - 2012 ACM Conference on Bioinformatics, Computational Biology and Biomedicine, BCB 2012
Y2 - 7 October 2012 through 10 October 2012
ER -