Fluoro-substitution effects in deoxyfluoro-D-glucose derivatives: random conformational search and quantum chemical calculation.

The effect of substitution by the fluorine atom at different positions of D-glucose was investigated by quantum chemical calculation of the low-energy conformers. These were obtained through the Random conformational search method. The geometries of conformers were optimized at the RHF/6-31(d) level, then reoptimization and vibrational analysis were performed at the B3LYP/6-31+G(d) level. Single-point energies were calculated at the B3LYP/6-311++G(2d,2p) level. The free energies of solvation in water were calculated utilizing the AM1-SM5.4 solvation model. For all substitution positions, the ring conformation does not change much, and the pyranoid 4C1 conformers are dominant, while variations in the substitution site result in different effects in the network of hydrogen bonds, anomeric effect, the solvation free energy, and the ratio of alpha- and beta-anomers.

Recognition of LXXLL by ligand binding domain of the Farnesoid X receptor in molecular dynamics simulation.

The Farnesoid X receptor (FXR) has recently become a potential therapeutical target. The recruitment of coactivator protein (specified by LXXLL sequence) is the initial step in transcriptional activation of nuclear receptors (NRs). In this paper, the process of recognition of the LXXLL motif by the ligand binding domain (LBD) of FXR is observed in a 25 ns molecular dynamics simulation. The hydrophobic and hydrogen bonding interactions between the LBD and the coactivator are fully analyzed. This observation provides justification for the 'on deck' model proposed by Nettles and Greene. At last, insight to the protein-polypeptide interactions and protein conformational changes are discussed.