Thermally induced denaturation and aggregation of BLG-A: effect of the Cu(2+) and Zn (2+) metal ions.

There is growing evidence that metal ions can accelerate the aggregation process of several proteins. This process, associated with several neuro-degenerative diseases, has been reported also for non-pathological proteins. In the present work, the effects of copper and zinc ions on the denaturation and aggregation processes of beta-lactoglobulin A (BLG-A) are investigated by differential scanning calorimetry (DSC), fluorescence, electron paramagnetic resonance (EPR) and optical density. The DSC profiles reveal that the thermal behaviour of BLG-A is a complex process, strongly dependent on the protein concentration. For concentrations 0.13 mM an exothermic peak also appears, above 90 degrees C, related to the aggregation of the denaturated BLG-A molecules. The thioflavin T fluorescence indicates that the thermally induced aggregates show fibrillar features. The presence of either equimolar Cu(2+) or Zn(2+) ions in the protein solution has different effects. In particular, copper binds to the protein in the native state, as evidenced by EPR experiments, and destabilizes BLG-A by decreasing the denaturation temperature by about 10 degrees C, whereas zinc ions probably perturb the partially denaturated state of the protein. The kinetics of BLG-A aggregation shows that both metal ions abolish the lag phase before the aggregation starts. Moreover, the rate of the process is 4.6-fold higher in the presence of copper, whereas the effect of zinc is negligible. The increase of the aggregation rate, induced by copper, may be due to a site-specific binding of the metal ion on the protein.

Evidence of reduced flexibility in disulfide bridge-depleted azurin: a molecular dynamics simulation study.

Two molecular dynamics simulations have been performed for 2 ns, at room temperature, on fully hydrated wild type and Cys3Ala/Cys26Ala double-mutant azurin, to investigate the role of the unique disulfide bridge on the structure and dynamics of the protein. The results show that the removal of the [bond]SS[bond] bond does not affect the structural features of the protein, whereas alterations of the dynamical properties are observed. The root mean square fluctuations of the atomic positions are, on average, considerably reduced in the azurin mutant with respect to the wild type form. The number of intramolecular hydrogen bonds between protein backbone atoms that are lost during the simulation, with respect to the starting configuration, are reduced in the absence of the disulfide bond. The analysis of the dynamical cross-correlation map, characterising the protein co-ordinated internal motions, demonstrates in the mutated azurin a significant decrease in anti-correlated displacements between protein residues, with the only exception occurring in the region of the mutation sites. The overall findings show a relevant reduction in flexibility as a consequence of the disulfide bridge depletion in azurin, suggesting that the [bond]SS[bond] bond is a structural element which significantly contributes to the dynamic properties of the native protein.