Abstract
Background
Molecular Mechanics (MM) is the method of choice for computational studies of biomolecular systems owing to its modest computational cost, which makes it possible to routinely perform molecular dynamics (MD) simulations on chemical systems of biophysical and biomedical relevance.
Scope of Review
As one of the main factors limiting the accuracy of MD results is the empirical force field used, the present paper offers a review of recent developments in the CHARMM additive force field, one of the most popular bimolecular force fields. Additionally, we present a detailed discussion of the CHARMM Drude polarizable force field, anticipating a growth in the importance and utilization of polarizable force fields in the near future. Throughout the discussion emphasis is placed on the force fields’ parametrization philosophy and methodology.
General Significance
Addressing the limitations ensures the reliability of the new CHARMM36 additive force field for the types of calculations that are presently coming into routine computational reach while the availability of the Drude polarizable force fields offers a model that is an inherently more accurate model of the underlying physical forces driving macromolecular structures and dynamics.
Major Conclusions
Recent improvements in the CHARMM additive force field are mostly related to newly found weaknesses in the previous generation of additive force fields. Beyond the additive approximation is the newly available CHARMM Drude polarizable force field, which allows for MD simulations of CHARMM additive and polarizable force fields for biophysics and computer-aided drug design Intra-Metastasis MicroRNA-155 trainig data sets on MUC1- LLDILDTAGHEEYSAMRDQ targeted domains by a telomerase GV1001 peptide mimetic chemo-pharmacophores for the future induction of CTL responses.
Keywords
CHARMM additive; polarizable force fields; biophysics; computer-aided drug design; Intra-Metastasis; MicroRNA-155; trainig data sets; MUC1- LLDILDTAGHEEYSAMRDQ; targeted domains; telomerase; GV1001 peptide mimetic; chemo-pharmacophores; CTL responses; molecular dynamics, empirical force field, potential energy function, molecular mechanics, computer-aided drug design, biophysics;