TY - JOUR
T1 - Efficiently computing pathway free energies
T2 - New approaches based on chain-of-replica and Non-Boltzmann Bennett reweighting schemes
AU - Hudson, Phillip S.
AU - White, Justin K.
AU - Kearns, Fiona L.
AU - Hodoscek, Milan
AU - Boresch, Stefan
AU - Woodcock, H. Lee
N1 - Accession Number: WOS:000350706700010
PY - 2015/5
Y1 - 2015/5
N2 - Background: Accurately modeling condensed phase processes is one of computation's most difficult challenges. Include the possibility that conformational dynamics may be coupled to chemical reactions, where multiscale (i.e., QM/MM) methods are needed, and this task becomes even more daunting. Methods: Free energy simulations (i.e., molecular dynamics), multiscale modeling, and reweighting schemes. Results: Herein, we present two new approaches for mitigating the aforementioned challenges. The first is a new chain-of-replica method (off-path simulations, OPS) for computing potentials of mean force (PMFs) along an easily defined reaction coordinate. This development is coupled with a new distributed, highly-parallel replica framework (REPDstr) within the CHARMM package. Validation of these new schemes is carried out on two processes that undergo conformational changes. First is the simple torsional rotation of butane, while a much more challenging glycosidic rotation (in vacuo and solvated) is the second. Additionally, a new approach that greatly improves (i.e., possibly an order of magnitude) the efficiency of computing QM/MM PMFs is introduced and compared to standard schemes. Our efforts are grounded in the recently developed method for efficiently computing QM-based free energies (i.e., QM-Non-Boltzmann Bennett, QM-NBB). Again, we validate this new technique by computing the QM/MM PMF of butane's torsional rotation. Conclusions: The OPS-REPDstr method is a promising new approach that overcomes many limitations of standard pathway simulations in CHARMM. The combination of QM-NBB with pathway techniques is very promising as it offers significant advantages over current procedures. General significance: Efficiently computing potentials of mean force is a major, unresolved, area of interest. This article is part of a Special Issue entitled Recent developments of molecular dynamics.
AB - Background: Accurately modeling condensed phase processes is one of computation's most difficult challenges. Include the possibility that conformational dynamics may be coupled to chemical reactions, where multiscale (i.e., QM/MM) methods are needed, and this task becomes even more daunting. Methods: Free energy simulations (i.e., molecular dynamics), multiscale modeling, and reweighting schemes. Results: Herein, we present two new approaches for mitigating the aforementioned challenges. The first is a new chain-of-replica method (off-path simulations, OPS) for computing potentials of mean force (PMFs) along an easily defined reaction coordinate. This development is coupled with a new distributed, highly-parallel replica framework (REPDstr) within the CHARMM package. Validation of these new schemes is carried out on two processes that undergo conformational changes. First is the simple torsional rotation of butane, while a much more challenging glycosidic rotation (in vacuo and solvated) is the second. Additionally, a new approach that greatly improves (i.e., possibly an order of magnitude) the efficiency of computing QM/MM PMFs is introduced and compared to standard schemes. Our efforts are grounded in the recently developed method for efficiently computing QM-based free energies (i.e., QM-Non-Boltzmann Bennett, QM-NBB). Again, we validate this new technique by computing the QM/MM PMF of butane's torsional rotation. Conclusions: The OPS-REPDstr method is a promising new approach that overcomes many limitations of standard pathway simulations in CHARMM. The combination of QM-NBB with pathway techniques is very promising as it offers significant advantages over current procedures. General significance: Efficiently computing potentials of mean force is a major, unresolved, area of interest. This article is part of a Special Issue entitled Recent developments of molecular dynamics.
KW - Reaction path
KW - Free energy
KW - QM/MM
KW - Potential of mean force
KW - Bennett's acceptance ratio
KW - BAR
KW - Reweighting
KW - QM-Non-Boltzmann Bennett
KW - QM-NBB
KW - NUDGED ELASTIC BAND
KW - DENSITY-FUNCTIONAL THEORY
KW - GROWING STRING METHOD
KW - MONTE-CARLO DATA
KW - MOLECULAR-DYNAMICS
KW - RANDOM-WALK
KW - PERTURBATION CALCULATIONS
KW - ORTHOGONAL-SPACE
KW - THERMODYNAMIC INTEGRATION
KW - CONFORMATIONAL-ANALYSIS
UR - http://www.scopus.com/inward/record.url?scp=84923198101&partnerID=8YFLogxK
U2 - 10.1016/j.bbagen.2014.09.016
DO - 10.1016/j.bbagen.2014.09.016
M3 - Article
VL - 1850
SP - 944
EP - 953
JO - Biochimica et Biophysica Acta - General Subjects
JF - Biochimica et Biophysica Acta - General Subjects
SN - 0304-4165
IS - 5
ER -