Expression of a protease of biotechnological interest cloned from C. d. collilineatus venom gland

Snake venom serine proteases (SVSPs) act on specific points of the circulatory system and are promising for the treatment of a variety of hemostatic disorders. In the present study, we describe the expression of a serine protease from Crotalus durissus collilineatus (Collineina- 1) in Pichia pastoris, the purification of the native toxin from C. d. collilineatus venom and the structural and enzymatic characterization of Collineina-1 in native and recombinant forms. The cDNA encoding the serine protease was amplified from cDNA library of C. d. collilineatus venom gland and cloned into pPICZ A vector. KM71H P. pastoris strain was transformed with the recombinant plasmid and colonies were selected by zeocin resistance. Heterologous expression was carried out in minimal medium supplemented with methanol, resulting in a yield of 56 mg of protein per liter of culture. The recombinant protein was purified by ion exchange and reverse phase chromatography. Purification of the native serine protease was accomplished by combining techniques of molecular exclusion, ion exchange and reversed phase, and resulted in the isolation of two isoforms, named Collineina-1 and 2. When analyzed by mass spectrometry, the recombinant Collineina-1 showed a molar mass of 28,868 Da, while Collineina-1 and 2 presented masses of 29,475 and 29,388 Da, respectively. The alignment of partial sequences of the enzymes resulted in 100% of amino acid identity between native and recombinant Collineina-1. The multiple alignment of deduced amino acid sequence of Collineina-1 indicates structural similarity with other snake venom serine proteases. The native and recombinant forms of the enzyme showed similar effects on bovine fibrinogen by cleaving preferentially A chain, releasing fibrinopeptide A. Both enzymes induced coagulation of bovine plasma in a dose-dependent way, though recombinant Collineina-1 presented a higher coagulant potential, with a minimum coagulant dose (MCD) of 0.08 mg/uL against 0.225 mg/uL for the native form. The serine proteases hydrolyzed S- 2222, S-2238 and S2302 chromogenic substrates, although both enzymes demonstrated increased activity upon S-2302. The esterase activity on TAME was evaluated at different temperatures and in the presence of divalent ions. Both enzymes showed high thermostability and their activity were inhibited in the presence of Zn2+ and Cu2+. The enzyme kinetics of both serine proteases followed Michaelis-Menten model. The native Collineina-1 showed a Km value of 1.43 mM, against 1.682 mM for the recombinant form, indicating that the native protein has a higher affinity for TAME substrate. However, enzymes had similar values for Kcat/Km (250.69 mM.min-1 for Collineina-1 and 248.03 mM.min-1 for rCollineina-1), suggesting that the serine proteases did not differ significantly in the efficiency to hydrolyze the substrate. These results demonstrated the adequacy of the system of choice in producing the snake venom serine protease, since the recombinant protein was expressed with functional integrity on the evaluated parameters. (AU)