A new algorithm and parameters for force field calculations of copper(II) complexes

## Abstract The heme protein, cytochrome P450, is an oxidoreductase that plays an important role in drug metabolism. To model P450s using molecular mechanics methods and classical molecular dynamics simulations, force field parameters and atomic charges are required. Because these parameters are ge

## Abstract A molecular mechanics force field for blue copper proteins has been developed, based on a rigid potential energy surface scan of the Cu^II^/His/His/Cys/Met chromophore, using DFT (B3LYP) calculations and the AMBER force field for the protein backbone. The strain–energy‐minimized structu

## Abstract Phosphorylation of histidine‐containing proteins is a key step in the mechanism of many phosphate transfer enzymes (kinases, phosphatases) and is the first stage in a wide variety of signal transduction cascades in bacteria, yeast, higher plants, and mammals. Studies of structural and d

## Abstract Accurate force fields are essential for reproducing the conformational and dynamic behavior of condensed‐phase systems. The popular AMBER force field has parameters for monophosphates, but they do not extend well to polyphorylated molecules such as ADP and ATP. This work presents parame

## Abstract A stochastic technique based on genetic algorithms was implemented to develop new force fields by optimizing molecular mechanics (MM) parameters. These force fields have been optimized for inorganic compounds such as polyoxometalates (POMs) and especially for type‐I polymolybdate and po