Many proteins display complex dynamical properties that are often intimately linked to their biological functions. As the native state of a protein is best described as an ensemble of conformations, it is important to be able to generate models of native state ensembles with high accuracy. Due to limitations in sampling efficiency and force field accuracy it is, however, challenging to obtain accurate ensembles of protein conformations by the use of molecular simulations alone. Here we show that dynamic ensemble refinement, which combines an accurate atomistic force field with commonly available nuclear magnetic resonance (NMR) chemical shifts and NOEs, can provide a detailed and accurate description of the conformational ensemble of the na...
Proteins are dynamic systems whose internal motions and resulting conformational changes are essenti...
Understanding protein function requires detailed knowledge about protein dynamics, i.e. the differen...
Molecular dynamics ensembles of proteins generated by different force fields (AMBER ff99, ff99SB, ff...
AbstractDescribing and understanding the biological function of a protein requires a detailed struct...
ABSTRACT Describing and understanding the biological function of a protein requires a detailed struc...
AbstractPerhaps one of the most prominent realizations of recent years is the critical role that pro...
Perhaps one of the most prominent realizations of recent years is the critical role that protein dyn...
An atomic resolution description of protein flexibility is essential for understanding the role that...
Currently, the best existing molecular dynamics (MD) force fields cannot accurately reproduce the gl...
About a third of the proteome consists of intrinsically disordered proteins (IDPs) that fold, whethe...
Nuclear magnetic resonance (NMR) has the unique advantage of elucidating the structure and dynamics ...
The motions of biological macromolecules are tightly coupled to their functions. However, while the ...
Basic principles of statistical mechanics require that proteins sample an ensemble of conformations ...
Protein motions play a critical role in many biological processes, such as enzyme catalysis, alloste...
SummaryWe introduce a procedure to determine the structures of proteins by incorporating NMR chemica...
Proteins are dynamic systems whose internal motions and resulting conformational changes are essenti...
Understanding protein function requires detailed knowledge about protein dynamics, i.e. the differen...
Molecular dynamics ensembles of proteins generated by different force fields (AMBER ff99, ff99SB, ff...
AbstractDescribing and understanding the biological function of a protein requires a detailed struct...
ABSTRACT Describing and understanding the biological function of a protein requires a detailed struc...
AbstractPerhaps one of the most prominent realizations of recent years is the critical role that pro...
Perhaps one of the most prominent realizations of recent years is the critical role that protein dyn...
An atomic resolution description of protein flexibility is essential for understanding the role that...
Currently, the best existing molecular dynamics (MD) force fields cannot accurately reproduce the gl...
About a third of the proteome consists of intrinsically disordered proteins (IDPs) that fold, whethe...
Nuclear magnetic resonance (NMR) has the unique advantage of elucidating the structure and dynamics ...
The motions of biological macromolecules are tightly coupled to their functions. However, while the ...
Basic principles of statistical mechanics require that proteins sample an ensemble of conformations ...
Protein motions play a critical role in many biological processes, such as enzyme catalysis, alloste...
SummaryWe introduce a procedure to determine the structures of proteins by incorporating NMR chemica...
Proteins are dynamic systems whose internal motions and resulting conformational changes are essenti...
Understanding protein function requires detailed knowledge about protein dynamics, i.e. the differen...
Molecular dynamics ensembles of proteins generated by different force fields (AMBER ff99, ff99SB, ff...