A new B-chain mutant of insulin: comparison with the insulin crystal structure and role of sulfonate groups in the B-chain structure.

The solution structure of a new B-chain mutant of bovine insulin, in which the cysteines B7 and B19 are replaced by two serines, has been determined by circular dichroism, 2D-NMR and molecular modeling. This structure is compared with that of the oxidized B-chain of bovine insulin [Hawkins et al. (1995) Int. J. Peptide Protein Res.46, 424-433]. Circular dichroism spectroscopy showed in particular that a higher percentage of helical secondary structure for the B-chain mutant is estimated in trifluoroethanol solution in comparison with the oxidized B-chain. 2D-NMR experiments confirmed, among multiple conformations, that the B-chain mutant presents defined secondary structures such as a alpha-helix between residues B9 and B19, and a beta-turn between amino acids B20 and B23 in aqueous trifluoroethanol. The 3D structures, which are consistent with NMR data and were obtained using a simulated annealing protocol, showed that the tertiary structure of the B-chain mutant is better resolved and is more in agreement with the insulin crystal structure than the oxidized B-chain structure described by Hawkins et al. An explanation could be the presence of two sulfonate groups in the oxidized insulin B-chain. Either by their charges and/or their size, such chemical groups could play a destructuring effect and thus could favor peptide flexibility and conformational averaging. Thus, this study provides new insights on the folding of isolated B-chains.

Structural studies by 1H NMR and molecular modeling of peptide substrates of thermolysin in relation with its proteasic activity in water and glycerol.

In an attempt to explain the relationship between conformations of peptide substrates of thermolysin in natural form and the experimental enzymatic cleavages, five peptides of various length were studied in two solvents H2O and glycerol, which may mimic the catalytic environmental conditions. As NMR failed to define sufficiently rough constraints to ensure a convergence of a refinement process for such short and flexible peptides, the conformational space was first searched using the MCMM method. The generated structures were then clustered in families using a 0.3A rmsd criterion and the derived structural characteristics were compared to the experimental NMR parameters. In a first approach, the NMR consistent conformations were compared with the structure of a thermolysin bound peptidic inhibitor ZG(P)LL to characterize the free-ligand predisposition to be cleaved. Further molecular dynamic calculations were performed at 300 K on the conformations corresponding to families in agreement with the ZG(P)LL structure in order to obtain information on their stability and on the trajectories of the torsion angles involved in the active site recognition. In conclusion, for four studied peptides, some conformations were found to be in agreement with 5 of the 8 cleavages experimentally observed.

Glycerol's influence on the oxidized insulin B-chain conformation in relation to the selectivity variation of subtilisin: an nuclear magnetic resonance and simulated annealing study.

Glycerol, employed to mimic biological media with restricted water activity, has been shown to modify the activity of subtilisin BPN', an endopeptidase, towards the oxidized insulin B-chain, a well-studied substrate (FEBS Lett., 279 (1991) 123-131). Without minimizing the role of the microenvironment on the enzyme, we have studied the effect of glycerol addition on the structure of the enzyme substrate by homonuclear NMR spectroscopy and simulated annealing. Our results show that, in water, the oxidized insulin B-chain tertiary structure loses its central helix (residues B9-B19) and presents a folded structure with a flexible turn (residues B18-B24) in the beta-turn region of the insulin B-chain; whereas, in glycerol, the peptide is more rigid and is not folded. Moreover, in our experimental conditions, glycerol favors beta-strand secondary structure formation. Following these results, hypotheses about the differences observed in enzymatic activity on this substrate in glycerol have been postulated.