ABSTRACT
The effect on protein conformation and thermal stability was studied for ß-Galactosidase (ß-Gal) encapsulated in the nanopores of a silicate matrix (Eß-Gal). Circular dichroism spectra showed that, compared with the enzyme in buffer (Sß-Gal), Eß-Gal exhibited a higher content of α-helix structure. Heating Eß-Gal up to 75⯰C caused a decrease in the content of ß-sheet structure and additional augments on Eß-Gal components attributed to helical content, instead of the generalized loss of the ellipticity signal observed with Sß-Gal. Steady state fluorescence spectroscopy analysis evidenced an Eß-Gal structure less compact and more accessible to solvent and also less stable against temperature increase. While for Sß-Gal the denaturation midpoint (Tm) was 59⯰C, for Eß-Galit was 48⯰C. The enzymatic activity assays at increasing temperatures showed that in both conditions, the enzyme lost most of its hydrolytic activity against ONPG at temperatures above 65⯰C and Eß-Gal did it even at lower T values. Concluding, confinement in silica nanopores induced conformational changes on the tertiary/cuaternary structure of Eß-Gal leading to the loss of thermal stability and enzymatic activity.