Recombinant production of ACAP1 protease of Aspergillus carbonarius to study its involvment in OTA degradation.

Ochratoxin A (OTA) undergoes to enzymatic biodegradation by proteolytic enzymes able to hydrolyze its amide bond with consequent formation of ochratoxin ? (OT?) and L-?-phenylalanine. This mechanism can be regarded as a detoxification method since OT? and L-?-phenylalanine are considered as less and non-toxic, respectively. Different microorganisms belonging to bacterial, yeast and fungal species have been reported to degrade OTA. Several enzymes may be involved in microbiological degradation of OTA, such as carboxypeptidase A, lipase, and acid proteases. Also Aspergillus carbonarius, one of the most important fungal producer of OTA and the major responsible of OTA contamination of grapes, wine and by-products, turned out to be able to degrade OTA. In the attempt to identify the enzyme able to degrade OTA in this microorganism, a protease encoding gene, located in the genomic region recognized as OTA cluster, has driven our attention. In particular, this gene, namely Acap1 of A. carbonarius strain ITEM 5010, encodes for an aspartic protease and is located downstream of the core genes involved in OTA biosynthesis. Acap1gene was isolated and cloned for its characterization. The gene is 1367 bp long and the in silico analyses of the deduced protein sequence of 421 aa revealed that the AcAP1 protein shows the functional typical structure of aspartic protease enzymes. Aspartyl proteases are a highly specific family of proteases that tend to cleave dipeptide bond and they are optimally active at acidic pH. Heterologous recombinant production of the AcAP1 protein has been carried out in order to verify the involvement of AcAP1 in the ability of A. carbonarius in OTA degradation and to analyze its structural and functional properties for a potential biotechnological use of the enzyme. Acap1 gene was cloned in two expression vectors (p426 and pYES), carrying a constitutive and an inducible promoter, respectively, in fusion with a sequence encoding for a His-tag at the 3'-terminus. Three different strains of Saccharomyces cerevisiae, carrying diverse genotypes, have been transformed. Data concerning the protein expression by yeast, evaluation of the protease activity, and purification of the recombinant protein will be produced.