AbstractSimple coarse-grained models, such as the Gaussian network model, have been shown to capture some of the features of equilibrium protein dynamics. We extend this model by using atomic contacts to define residue interactions and introducing more than one interaction parameter between residues. We use B-factors from 98 ultra-high resolution (≤1.0Å) x-ray crystal structures to optimize the interaction parameters. The average correlation between Gaussian network-model fluctuation predictions and the B-factors is 0.64 for the data set, consistent with a previous large-scale study. By separating residue interactions into covalent and noncovalent, we achieve an average correlation of 0.74, and addition of ligands and cofactors further impr...
Abstract. Simulations of protein dynamics may work on different levels of mole-cular detail. The lev...
Currently, the best existing molecular dynamics (MD) force fields cannot accurately reproduce the gl...
We are optimizing a force-field to be used with our coarsegrained protein model for the recognition...
AbstractSimple coarse-grained models, such as the Gaussian network model, have been shown to capture...
AbstractAn all-atom local contact model is described that can be used to predict protein motions und...
AbstractCoarse graining of protein interactions provides a means of simulating large biological syst...
We introduce a method to bring nearly atomistic resolution to coarse-grained models, and we apply th...
textIn general, this dissertation is concerned with modeling of mechanical behavior of protein molec...
AbstractThe REACH (realistic extension algorithm via covariance Hessian) coarse-grained biomolecular...
AbstractIn this study, the variance-covariance matrix of protein motions is used to compare several ...
AbstractNormal mode analysis using elastic network models has grown popular for probing the low-freq...
SummaryFor a representative set of 64 nonhomologous proteins, each containing a structure solved by ...
AbstractCoarse-graining of protein interactions provides a means of simulating large biological syst...
The overwhelming majority of biological processes relies on the capability of proteins to sustain co...
Theoretical prediction of protein structures and dynamics is essential for understanding the molecul...
Abstract. Simulations of protein dynamics may work on different levels of mole-cular detail. The lev...
Currently, the best existing molecular dynamics (MD) force fields cannot accurately reproduce the gl...
We are optimizing a force-field to be used with our coarsegrained protein model for the recognition...
AbstractSimple coarse-grained models, such as the Gaussian network model, have been shown to capture...
AbstractAn all-atom local contact model is described that can be used to predict protein motions und...
AbstractCoarse graining of protein interactions provides a means of simulating large biological syst...
We introduce a method to bring nearly atomistic resolution to coarse-grained models, and we apply th...
textIn general, this dissertation is concerned with modeling of mechanical behavior of protein molec...
AbstractThe REACH (realistic extension algorithm via covariance Hessian) coarse-grained biomolecular...
AbstractIn this study, the variance-covariance matrix of protein motions is used to compare several ...
AbstractNormal mode analysis using elastic network models has grown popular for probing the low-freq...
SummaryFor a representative set of 64 nonhomologous proteins, each containing a structure solved by ...
AbstractCoarse-graining of protein interactions provides a means of simulating large biological syst...
The overwhelming majority of biological processes relies on the capability of proteins to sustain co...
Theoretical prediction of protein structures and dynamics is essential for understanding the molecul...
Abstract. Simulations of protein dynamics may work on different levels of mole-cular detail. The lev...
Currently, the best existing molecular dynamics (MD) force fields cannot accurately reproduce the gl...
We are optimizing a force-field to be used with our coarsegrained protein model for the recognition...