Modifying a bacterial tyrosinase zymogen for use in protease activity assays.

Current clinical laboratory assays are not sufficient for determining the activity of many specific human proteases yet. In this study, we developed a general approach that enables the determination of activities of caspase-3 based on the proteolytic activation of the engineered zymogen of the recombinant tyrosinase from Verrucomicrobium spinosum (Vs-tyrosinase) by detecting the diphenolase activity in an increase in absorbance at 475 nm. Here, we designed three different zymogen constructs of Vs-tyrosinase, including RSL-pre-pro-TYR, Pre-pro-TYR, and Pro-TYR. The active domain was fused to the reactive site loop (RSL) of α1-proteinase inhibitor and/or its own signal peptide (pre) and/or its own C-terminal domain (pro) via a linker containing a specific caspase-3 cleavage site. Further studies revealed that both RSL peptide and TAT signal peptide were able to inhibit tyrosinase diphenolase activity, in which RSL-pre-pro-TYR had the lowest background signals. Therefore, a specific protease activity such as caspase-3 could be detected when a suitable zymogen was established. Our results could provide a new way to directly detect the activities of key human proteases, for instance, to monitor the efficacy and safety of tumor therapy by determining the activity of apoptosis-related caspase-3 in patients. KEY POINTS: • RSL inhibited the activity of Verrucomicrobium spinosum tyrosinase. • N-pre and C-terminal domain exerted stronger dual inhibition on the Vs-tyrosinase. • The activity of caspase-3 could be measured by the zymogen activation system.

Unusual Stability of a Recombinant Verrucomicrobium spinosum Tyrosinase to Denaturing Agents and Its Use for a Production of a Protein with Adhesive Properties.

Tyrosinases catalyze oxidation of phenols with a formation of biphenols, quinones, and highly polymerized melanins. Tyrosinases have prospects for industrial use to remove phenols, also in biosensors, in bioorganic synthesis, and for a production of biocompatible adhesives (medical glues). Despite growing fields of potential applications, a selection of commercially available tyrosinases are currently limited to a single enzyme which is isolated from fruiting bodies of mushrooms. This article describes a preparation of recombinant tyrosinase from a bacterium Verrucomicrobium spinosum using a heterologous expression in Escherichia coli. Recombinant V. spinosum tyrosinase has high specific activity (13,200 U/mg). A resistance of the enzyme was investigated to chemical agents used to denature proteins and keep poorly solvable proteins in a solution. The enzyme preserves activity in the presence of urea and retains at least a fraction of its enzymatic activity at concentrations of urea up to 4.5 M. An addition of sodium lauroyl sarcosinate to 1 or 2% activates the tyrosinase. Novel means of quantitatively expressing tyrosinase activity is described in this article. The method uses a set of parameters obtained from non-linear estimation of the progress curves and is suitable for enzymatic reactions which do not comply with Michaelis-Menten kinetics. Tyrosinase may be used to introduce into proteins a post-translational modification which is a conversion of tyrosine residues (Tyr) into residues of 3,4-dioxyphenylalanine (DOPA). The presence of DOPA provides the polypeptides with a capability of strong molecular adhesion. Co-expression of tyrosinase and a recombinant protein mimicking marine mussel-encoded adhesive proteins resulted in obtaining of the protein in which at least a part of Tyr residues had been converted to DOPA. The DOPA-containing protein had high adhesion strength (2.5 MPa).