Calculation of conformational free energy of histamine

A number of strain energy calculations for the conformations of cyclooctane have been published. l-4 However, the interconversion paths linking these conformations have not been extensively investigated, although Hendrickson' has reported the energy profiles for certain paths where at least one ele

## Abstract The ability to predict and characterize free energy differences associated with conformational equilibria or the binding of biomolecules is vital to understanding the molecular basis of many important biological functions. As biological studies focus on larger molecular complexes and pr

Two different structures of ligand-free HIV protease have been determined by X-ray crystallography. These structures differ in the position of two 12 residue, ␤-hairpin regions (or ''flaps'') which cap the active site. The movements of the flaps must be involved in the binding of substrates since, i

## Abstract The free energy landscapes of peptide conformations were calibrated by __ab initio__ quantum chemical calculations, after the enhanced conformational diversity search using the multicanonical molecular dynamics simulations. Three different potentials of mean force for an isolated dipept

## Abstract Empirical energy calculations on cyclo‐Gly‐X with X‐ Phe, Tyr, Val, and Leu as a function of the side‐chain torsion angles χ indicate that the conformation of minimum energy are characterized by χ~1~ = 60°, χ^2^ = 90° for Phe and Try, χ^1^ = −60° for Val and χ^1^ = −60°, χ^2^ = 180° and

There is much concern about the accuracy of freeenergy perturbation calculations. Here we have investigated the problem of ignoring the conformational variation of atomic charges by calculating the difference in the free energy of hydration between ethanol and propanol and comparing the results obta