Biomolecular force fields: where have we been, where are we now, where do we need to go and how do we get there?

In this perspective, we review the theory and methodology of the derivation of force fields (FFs), and their validity, for molecular simulations, from their inception in the second half of the twentieth century to the improved representations at the end of the century. We examine the representations of the physics embodied in various force fields, their accuracy and deficiencies. The early days in the 1950s and 60s saw FFs first introduced to analyze vibrational spectra.

Molecular dynamics: deciphering the data.

The dynamic behaviour of molecules is important in determining their activity. Molecular dynamics (MD) simulations give a detailed description of motion, from small fluctuations to conformational transitions, and can include solvent effects. However, extracting useful information about conformational motion from a trajectory is not trivial.

FOCUS: a program for analyzing molecular dynamics simulations, featuring digital signal-processing techniques.

FOCUS is a program for analyzing molecular dynamics simulations. It enables the researcher to monitor structural and energetic properties during the trajectory, and to calculate the corresponding statistical averages, correlation functions and Fourier transforms. In addition to these conventional methods, the program also utilizes novel methods based on digital signal-processing techniques to characterize the various motions.

Modeling of substrate and inhibitor binding to phospholipase A2.

Molecular graphics and molecular mechanics techniques have been used to study the mode of ligand binding and mechanism of action of the enzyme phospholipase A2. A substrate-enzyme complex was constructed based on the crystal structure of the apoenzyme. The complex was minimized to relieve initial strain, and the structural and energetic features of the resultant complex analyzed in detail, at the molecular and residue level.

Conformational analysis of peptide surrogates. Reduced and retro-amide links in blocked alanine and in secondary structures.

We have investigated the conformational effects of modifying the amide link of peptides. We studied a reverse amide bond psi [NHCO], a reduced amide bond psi [CH2NH] and a retro-reduced bond psi [NHCH2] as surrogates for the amide link [CONH] in native peptides. A complete search of the conformational space available to residues with these modified links was carried out.