Molecular modeling of amphotericin B-ergosterol primary complex in water II.

The work presented is a part of our continual study on the behavior of the polyene macrolide antibiotic amphotericin B (AmB) complexes with sterols on the molecular level. In contrast to the previously researched AmB-ergosterol binary complex, the AmB-ergosterol-AmB aggregates simulated of 2:1 stoichiometry retain significantly higher stability and relatively rigid, "sandwich" geometry. Van der Waals forces with a considerable share of the electrostatic interactions are responsible for such behavior. System of the intermolecular hydrogen bonds also seems to be of notable importance for the complex's structure preservation. The most energetically favored geometries match fairly close the geometric criteria and the network of interactions postulated in the contemporary hypothetical and computational models of antibiotic-sterol complexes. On the basis of works previously published and the present study novel hypotheses on the AmB selectivity towards sterols varying in chemical structure and on the possible mechanisms of channel structure formation were presented.

Molecular modelling of membrane sterols with the use of the GROMOS 96 force field.

Membrane located sterols determine the structure and function of eucariotic cell membranes. Moreover, they are targets for important antifungal antibiotic amphotericin B. Knowledge about the geometry and dynamics of sterols in the environment of lipidic membranes is necessary to understand their functions. However, due to the dynamic character of the membrane, no experimental data about sterol behaviour on the molecular level is available. Hence molecular modelling simulations could be a source of useful information. The main goal of this paper is to prove the adequacy of the GROMOS 96 force field for molecular simulations of membrane sterols. We focused our attention on the reproduction of characteristic geometrical features observed in the crystal of cholesterol hemiethanolate by molecular dynamics simulations. The results presented clearly indicate that the GROMOS 96 force field can be a useful tool to simulate the highly lipophilic systems. Moreover, interactions responsible for the stability of such systems can also be recognised.

Molecular modelling of amphotericin B-ergosterol primary complex in water.

The properties of amphotericin B-ergosterol primary complex have been studied with the use of the molecular dynamics simulation. Possible geometries of the complex were tested first in order to find the structures with the most favourable values of the intermolecular interactions energy. The molecules studied possessed a tendency to fit each other's shapes, which favours intermolecular van der Waals interactions. The main simulations were performed for the best structures found. Presence of hydrogen bonds between the sterol hydroxyl group and polar fragments of mycosamine (most frequently 2'OH) was coupled with a relatively high level of the intermolecular energy values. The structures obtained are hardly comparable to the hypothetical and 'computational' models of the antibiotic-sterol complex. The geometries found are not suitable to assemble the presupposed structure of the water channel, however, the existence of the complex in the shape anticipated is not in contradiction to the results of biophysical experiments on the complexation in water and in hydroalcoholic media.