Structural and functional analysis of broad pH and thermal stable protease from Penicillium aurantiogriseum URM 4622.

This study aimed to better characterize a recently purified stable extracellular alkaline peptidase produced by Penicillium aurantiogriseum (URM 4622) through fluorescence spectroscopy, far-UV circular dichroism, kinetic and thermodynamic models to understand its' structure-activity and denaturation. Fluorescence data showed that changing pH leads to tryptophan residues exposure to more hydrophilic environments at optimum activity pH 9.0 and 10.0. When thermally treated, it displayed less unfolding at these pH values, along with 4-fold less photoproducts formation than at neutral pH. Different pH CD spectra showed more ß-sheet (21.5-43.0%) than α-helix (1-6.2%). At pH9.0, more than 2-fold higher α-helix content than any other pH. The melting temperature (Tm) was observed between 50 and 60 °C at all pH studied, with lower Tm at pH 9.0-11.0 (54.9-50.3 °C). The protease displayed two phase transition, with two energies of denaturation, and a 4-fold higher thermal stability (ΔH°m) than reports for other microorganism's proteases. An irreversible folding transition occurs between 50 and 60 °C. It displayed energies of denaturation suggesting higher thermal stability than reported for other microorganism's proteases. These results help elucidating the applicability of this new stable protease.

Pectin hydrolysis in cashew apple juice by Aspergillus aculeatus URM4953 polygalacturonase covalently-immobilized on calcium alginate beads: A kinetic and thermodynamic study.

The kinetics and thermodynamics of pectin hydrolysis in cashew apple juice by polygalacturonase (PG) from Aspergillus aculeatus URM4953 covalently-immobilized on calcium alginate beads were investigated. Immobilized-PG activity in cashew apple juice was the highest at 20 °C, showing a maximum hydrolysis rate of 58.2 mg/mL·min, a catalytic constant of 166.2 s-1 and an affinity constant of 113.0 mg/mL. Since the enzyme exhibited an allosteric behavior, the hydrolysis rate was modeled, with excellent accuracy, by the Hill Equation as function of pectin concentration. The Hill coefficient increased from 3 to 5 with increasing temperature from 20 to 50 °C, evidencing a positive cooperativity mechanism. The reaction activation energy and the standard enthalpy variation of enzyme unfolding were 80.3 and 16.6 kJ/mol, respectively. Consistently with the kinetic results, PG-catalyzed pectin hydrolysis proceeded with maximum spontaneity at 20 °C, showing activation Gibbs free energy, enthalpy and entropy of 59.3 kJ/mol, 77.9 kJ/mol and 63.4 J/mol·K, respectively. Immobilized PG was successful in the hydrolysis of cashew apple juice pectin, requiring a low temperature to act optimally.

Biophysical, photochemical and biochemical characterization of a protease from Aspergillus tamarii URM4634.

Circular dichroism (CD) and fluorescence spectroscopy (FS) were used to monitor the pH-dependent conformational and structural stability changes induced by temperature and UV light on the protease from Aspergillus tamarii URM4634 at different pH values. The formation of photoproducts, such as N-formylkynurenine, dityrosine and kynurenine, were monitored with FS. The pH-dependent melting temperatures (Tm) were determined using CD and FS from 20 to 90 °C. Conformational changes were correlated with the pH-dependent biochemical activities. CD revealed that the protease is rich in α-helices. Thermal denaturation was irreversible at all pH range and displayed Tm values from 42.8 to 67.8 °C (CD) and from 38 to 60.3 °C (FS), which the highest Tm was observed at pH 6. The light and temperature induced to the formation of photoproducts was more intense at high pH value. Despite the biochemical data shows optimum pH 9, the highest stability was at pH 6, maintaining 100% of activity after 24 h. The acquired data permits to select the best physicochemical parameters to secure the optimal activity and stability when used in biotechnological applications. Furthermore, the conformal changes induced by temperature in the protein are directly correlated with its level of biochemical activity.