TY - JOUR
T1 - Escape of a Small Molecule from Inside T4 Lysozyme by Multiple Pathways
AU - Nunes-Alves, Ariane
AU - Zuckerman, Daniel M.
AU - Arantes, Guilherme Menegon
N1 - Funding Information:
Grants from São Paulo Research Foundation (FAPESP projects 2014/17008-7 , 2014/21900-2 , 2015/19912-5 , and 2016/24096-5 ) and from the National Institutes of Health ( GM115805 ) are gratefully acknowledged. Computing resources were in part provided by the University of Pittsburgh Center for Research Computing .
Publisher Copyright:
© 2018 Biophysical Society
PY - 2018/3/13
Y1 - 2018/3/13
N2 - The T4 lysozyme L99A mutant is often used as a model system to study small-molecule binding to proteins, but pathways for ligand entry and exit from the buried binding site and the associated protein conformational changes have not been fully resolved. Here, molecular dynamics simulations were employed to model benzene exit from its binding cavity using the weighted ensemble (WE) approach to enhance sampling of low-probability unbinding trajectories. Independent WE simulations revealed four pathways for benzene exit, which correspond to transient tunnels spontaneously formed in previous simulations of apo T4 lysozyme. Thus, benzene unbinding occurs through multiple pathways partially created by intrinsic protein structural fluctuations. Motions of several α-helices and side chains were involved in ligand escape from metastable microstates. WE simulations also provided preliminary estimates of rate constants for each exit pathway. These results complement previous works and provide a semiquantitative characterization of pathway heterogeneity for binding of small molecules to proteins.
AB - The T4 lysozyme L99A mutant is often used as a model system to study small-molecule binding to proteins, but pathways for ligand entry and exit from the buried binding site and the associated protein conformational changes have not been fully resolved. Here, molecular dynamics simulations were employed to model benzene exit from its binding cavity using the weighted ensemble (WE) approach to enhance sampling of low-probability unbinding trajectories. Independent WE simulations revealed four pathways for benzene exit, which correspond to transient tunnels spontaneously formed in previous simulations of apo T4 lysozyme. Thus, benzene unbinding occurs through multiple pathways partially created by intrinsic protein structural fluctuations. Motions of several α-helices and side chains were involved in ligand escape from metastable microstates. WE simulations also provided preliminary estimates of rate constants for each exit pathway. These results complement previous works and provide a semiquantitative characterization of pathway heterogeneity for binding of small molecules to proteins.
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U2 - 10.1016/j.bpj.2018.01.014
DO - 10.1016/j.bpj.2018.01.014
M3 - Article
C2 - 29539393
AN - SCOPUS:85043512205
SN - 0006-3495
VL - 114
SP - 1058
EP - 1066
JO - Biophysical Journal
JF - Biophysical Journal
IS - 5
ER -