The process for the activation of frog epidermis pro-tyrosinase

Molecular and biochemical characterization of Paragonimus westermani tyrosinase

Trematode tyrosinases (TYRs) play a major role in the tanning process during eggshell formation. We investigated the molecular and biochemical features of Paragonimus westermani TYR (PwTYR). The PwTYR cDNA was composed of 1568-bp encompassing a 1422-bp-long open reading frame (474-amino acid polypeptide). A strong phylogenetic relationship with Platyhelminthes and Deuterostomian orthologues was evident. The recombinant PwTYR expressed in prokaryotic cells promptly oxidized diphenol substrates, with a preferential affinity toward ortho-positioned hydroxyl groups. It demonstrated fairly weak activity for monophenol compounds. Diphenol oxidase activity was augmented with an increase of pH from 5.0 to 8.0, while monophenol oxidase activity was highest at an acidic pH and gradually decreased as pH increased. Transcription profile of PwTYR was temporally upregulated along with worm development. PwTYR was specifically localized in vitellocytes and eggs. The results suggested that conversion of tyrosine to L-dihydroxyphenylalanine by PwTYR monophenol oxidase activity might be rate-limiting step during the sclerotization process of P. westermani eggs. The pH-dependent pattern of monophenol and diphenol oxidase activity further proposes that the initial hydroxylation might slowly but steadily progress in acidic secreted vesicles of vitellocytes and the second oxidation process might be rapidly accelerated by neural or weak alkaline pH environments within the ootype.

Purification and primary structural characterization of prophenoloxidases from Aedes aegypti larvae

There are more prophenoloxidase (proPO) genes in mosquitoes than other model insect species studied to date. The high sequence similarity among mosquito proPOs makes it extremely difficult to use histochemical methods to determine the presence of individual proPOs in different stages of mosquito development or their tissue locations. As a consequence, there always are questions when attempting to assign any observed functions to a particular proPO. By following the PO fractions of Aedes aegypti larval proteins during chromatographic separations, we were able to isolate two proPO fractions. Each displayed a single protein band on SDS-PAGE gel. The two fractions showed relative molecular weights of 75 and 60k Da. In-gel trypsin-digestion of the two protein bands and subsequent mass spectrometry of their tryptic peptides confirmed their proPO identities. The 75 kDa protein was a new Aedes aegypti proPO that has not been described in databases, whereas the 60 kDa band contained three previously described Aedes aegypti proPO sequences, with the absence of approximately 125-128 residues at their carboxyl end as compared with their deduced sequences, which suggests that some proPOs might undergo specific proteolytic processing after synthesis. Comparison between the transcriptional profiles of different proPOs and the number of isolated proPO proteins in late-stage larvae indicates that individual proPOs might be transcribed during the earlier stages of larval development, and that resulting proPO proteins persist through all larval stages. Results of this study provide a basis for developing a comprehensive understanding of structure/function relationships of individual proPOs in mosquitoes.

Kinetic study of the activation process of a latent mushroom (Agaricus bisporus) tyrosinase by serine proteases

Latent mushroom tyrosinase can be considered as a zymogen when activated by proteases because the activation process fulfilled all of the kinetic dependencies predicted by a theoretical zymogen activation model previously reported. The activation was studied under two assay conditions: high and low ratio of latent tyrosinase/serine protease (trypsin and subtilisin Carlsberg) concentrations, in the presence and in the absence of a serine protease inhibitor (aprotinin). The size of the latent enzyme was 67 kDa, determined by denaturing SDS-PAGE electrophoresis and Western blot assays. After proteolytic activation, the size was 43 kDa, with an intermediate band of 58 kDa. The values of the catalytic () and Michaelis () constants for the active forms of tyrosinase resulting from the activation by subtilisin, trypsin, or sodium dodecyl sulfate on the substrate tert-butylcatechol were slightly different, which could support the idea of "one activator-one different active tyrosinase". Vacuum infiltration experiments tried to reproduce in vivo the role of mushroom serine proteases in the activation of latent tyrosinase. The use of serine protease inhibitors is proposed as a new alternative tool to prevent melanin formation.

Oxymetric and spectrophotometric study of the ascorbate oxidase activity shown by frog epidermis tyrosinase

Many studies concerning the effect of ascorbic acid on the action of tyrosinase on several substrates have been carried out with contradictory results. The results shown in this work comprise a hypothetical reaction mechanism, which explains the ascorbate oxidase activity of frog epidermis tyrosinase. The reaction between frog epidermis tyrosinase and L-ascorbic acid was studied by oxymetric and spectrophotometric assays. The activity was linearly related to enzyme concentration, with a Michaelis constant for L-ascorbic acid of 0.160 +/- 0.009 mM and Vmax of 90 +/- 4 nM/s. Maximum activity was obtained at pH 7.5. The stoichiometry of the reaction was calculated by measuring the substrate (O2 and L-ascorbic acid) consumption as well as the initial rates of the consumption of oxygen and the disappearance of L-ascorbic acid. The stoichiometry was found to be 1:2 (O2:L-ascorbic acid). The action of the tyrosinase inhibitor tropolone was also studied. All the results present evidence concerning the ascorbate oxidase activity of frog epidermis tyrosinase and a possible reaction mechanism based on the different enzymatic forms of tyrosinase to explain such activity.

Tyrosinase: kinetic analysis of the transient phase and the steady state

The transient phase of tyrosinase activity acting on monophenols has been investigated. Although an analytical solution for the lag period (tau) cannot be obtained, its dependence on reagent concentration and pH is studied. It is established that decreases as the quantity of enzyme increases, although it increases when monophenol or pH are increased. The computer simulation shows those rate constants whose variations affect the transient phase most significantly. In addition, the steady state of the pathway is studied using tyrosinases from several sources such as mushroom, frog epidermis and grape. The kinetic analysis, which is based on not imposing restrictions on the values of the rate constants involved in the mechanism, allows us to obtain analytical expressions for both monophenolase and diphenolase activities and explains the experimental results obtained with the different enzymes. The values determined for the kinetic parameter, R, point to the monophenol hydroxylation step as being the limiting step of the turnover, while the values obtained for n suggest the absence of fast equilibrium in the oxidation of diphenol by Emet.

Proteolysis with trypsin of mammalian tyrosinase isoforms from B16 mouse melanoma

In spite of the central role of tyrosinase in mammalian pigmentation, few data are available on its structure and structure-function relationships based on direct analysis of the protein. A number of reasons have been invoked to account for this situation, including the problems for its purification and its resistance to proteases. However, no study on the effects of proteases on purified tyrosinase has been reported. We have purified the melanosomal and cytosolic tyrosinases from B16 mouse melanoma and analyzed their susceptibility to trypsin digestion. Both isoforms are sensitive to trypsin, and display similar peptide maps and kinetics of proteolysis, suggesting that they are products of the same gene. The peptide maps and the kinetics of appearance of the fragments were consistent with the sequential removal of N-terminal peptides, leading to a core of 55.3 kDa for the melanosomal form and 48.6 kDa for the cytosolic enzyme. This core was apparently resistant to further proteolysis and catalytically inactive. The difference in molecular weight for the core of the cytosolic and melanosomal forms is the same as that calculated for the native isoforms. The kinetics of enzyme inactivation indicate that the tyrosine hydroxylase and Dopa oxidase activities of tyrosinase are lost at the same rate, and should therefore display similar if not identical structural requirements. The results are discussed in terms of the relationship of both isoforms and of the putative protein sequences deduced from the cDNA clones proposed for tyrosinase.

Synthesis and activity of Xenopus laevis oocyte tyrosinase

This study investigates the mechanisms that control pigment synthesis in Xenopus laevis oocytes. Although we find the molecular weight of oocyte tyrosinase to be similar to that of amphibian skin, we were unable to increase its activity by proteases or detergents, as has been reported for skin tyrosinase. On the other hand, by measuring the activity of polysomal-bound enzyme, we were able to correlate increased tyrosinase activity with increased levels of enzyme synthesis. We therefore suggest that in oocytes, the activity of tyrosinase is primarily dependent on its synthesis, whereas in skin, the rate-limiting step is the post-translational activation of the enzyme. We speculate on these differences in relation to the functional role of melanin in skin and oocytes.

Chemical and enzymatic oxidation of 4-methylcatechol in the presence and absence of L-serine. Spectrophotometric determination of intermediates

A pathway for 4-methylcatechol oxidation by tyrosinase (monophenol, dihydroxy-L-phenylalanine:oxygen oxidoreductase, EC 1.14.18.1) in the presence of L-serine is proposed. Characterization of intermediates in this oxidative reaction and stoichiometry determination have both been performed. It has been possible to detect spectrophotometrically 4-methyl-o-benzoquinone as the first intermediate in this pathway after oxidizing 4-methylcatechol with epidermis tyrosinase or sodium periodate at pH 6.5. The steps for 4-methylcatechol transformation in the presence of L-serine could be: 4-methylcatechol----4-methyl-o-benzoquinone----5-methyl-4N-serine-catechol----5 - methyl-4N-serine-o-benzoquinone. Matrix analysis of the spectra obtained with a rapid-scan spectrophotometer verified that 4-methyl-o-benzoquinone was transformed into 5-methyl-4N-serine-o-benzoquinone at a constant ratio, the stoichiometry for this conversion being the equation: 2-(4-methyl-o-benzoquinone) + L-serine----4-methylcatechol + 5-methyl-4N-serine-o-benzoquinone.

A kinetic study of the melanization pathway between L-tyrosine and dopachrome

In the pathway of melanin biosynthesis originating from L-tyrosine, the dopachrome accumulation at physiological pH is produced with a pronounced lag period, during which the level of L-dopa increases, following a sigmoidal kinetics to reach a steady-state. A kinetic model has been proposed for the overall pathway of melanization from L-tyrosine to dopachrome; it explains the lag period present during the dopachrome accumulation as well as the influence of L-tyrosine and tyrosinase over this lag period. Use of this model is also valid to explain the kinetics of L-dopa accumulation in the reaction medium, as has been tested by simulation.

Comparative study of tyrosinases from different sources: relationship between halide inhibition and the enzyme active site

The inhibition of tyrosinases from frog epidermis (Rana esculenta ridibunda), mushroom (Agaricus bisporus) and Harding-Passey mouse melanoma by halides is compared. In all cases, the inhibition is pH dependent, increasing when the pH decreases. The order of inhibition is I- greater than Br- greater than Cl- much greater than F- for frog epidermis tyrosinase, F- greater than I- greater than Cl- greater than Br- for mushroom tyrosinase and F- greater than Cl- much greater than Br- greater than I- for the mouse melanoma enzyme. These results are discussed in terms of the active site accessibility to exogenous ligands. The activation energies of the enzyme-catalysed L-dopa oxidation were also calculated, being the values 6.86, 17.01 and 20.25 kcal/mol for frog epidermis, mushroom and Harding-Passey mouse melanoma, respectively. A relationship between these values and the evolutionary adaptation of these enzymes is proposed.

Aggregation equilibria of tyrosinase of Harding-Passey mouse melanoma

The purification of two isoenzymes of tyrosinase has been carried out in Harding-Passey mouse melanoma. One is found in the cytosol and the other one bound to melanosomes. Both migrate as single bands on sodium dodecyl sulphate/polyacrylamide gels, having an apparent Mr of 58 000. Solubilized particulate tyrosinase showed an aggregation equilibrium involving a monomer, tetramer, octamer and a high-Mr micellar form with Brij 35, the solubilizing agent. H.p.l.c. studies indicated a interconversion between those species, the monomer contribution increasing with the sample dilution. The tetramer and the octamer probably represent the predominant forms in vivo. Soluble tyrosinase showed a simpler aggregation equilibrium, involving two forms, monomer and tetramer, with the same interconversion pattern. Fluorescence studies suggested that tryptophan residues were exposed to the aqueous environment when tyrosinase was dissociated by dilution. Tyrosinase shows a tendency to aggregate, at low protein concentration, and a resistance to dissociation by urea or SDS so remarkable that gel-permeation chromatography in 4M-urea does not affect the equilibrium, and the band obtained on SDS/polyacrylamide-gel electrophoresis is a dimer.

Kinetic study of the interaction between frog epidermis tyrosinase and chloride

The effect of halide ions on frog epidermis tyrosinase has been characterized with the trypsin-activated enzyme. At pH 7, the order of inhibition is I- greater than Br- greater than Cl- greater than F-. Chloride, the most extensively studied halide, shows a competitive pattern with respect to the substrate, L-DOPA. Inhibition is strongly pH-dependent, with a pKa of 6.12 for the responsible protonatable group. Other kinetic constants are also calculated using a novel approach. The mechanism of interaction between chloride and the enzyme is discussed, and a model is proposed in which chloride interferes the tyrosinase activity by displacing a catalytically important ligand, probably a histidine residue of the side-chain, from the copper at the enzyme-active site.

Multiple forms of protyrosinase from Aspergillus oryzae and their mode of activation at pH 3.0

This paper describes the isolation of three molecular forms (I-III) of protyrosinase and catalytically active tyrosinase ( monophenol ,dihydroxyphenylalanine: oxygen oxidoreductase, E.C. 1.14.18.1) from fresh mycelia of Aspergillus oryzae BIR 128 by (NH4)2SO4 fractionation, successive chromatographies and disc-gel electrophoresis. Experimental evidence is presented that purified protyrosinase is contaminated with firmly attached proteinases, and that this contamination may account for both the multiple molecular forms of protyrosinase /tyrosinase and the activation of the proenzyme at acidic pH (2.5-3.0). The activation process of protyrosinase seems to be the result of a cleavage of the polypeptide chain by aspartic proteinase from Aspergillus (EC 3.4.23.6) in the purified protyrosinase preparation. Protyrosinase and tyrosinase have different conformation, different stabilities and some different properties.

Conformational studies of soluble and immobilized frog epidermis tyrosinase by fluorescence

Fluorescence spectra and soluble quenching of intrinsic protein fluorescence were used as indexes of conformational changes suffered by frog epidermis tyrosinase. The activation process and the immobilization of the enzyme involving either free amino groups or its carbohydrate moiety were studied. The conformational changes resulting from denaturation of each one of the protein derivatives, as well as the effect of active center copper extraction, were followed by fluorescence studies. The results showed that: both activation and immobilization were accompanied by conformational changes of the protein leading to more unfolded states; neither enzyme nor immobilized enzyme were fully unfolded upon denaturation although enzymic activity was lost; the enzyme immobilized through its carbohydrate moiety was more unfolded upon denaturation than the enzyme immobilized through amino groups, thus pointing to a higher conformational stabilization in the last situation; and that tryptophyl residues moved to a localization near the active site upon activation.

Steady-state study of the mechanism of dopa-oxidase activity of tyrosinase

The mechanism of the dopa-oxidase activity of frog epidermis tyrosinase has been studied. Initial reaction rates have been measured as function of substrate concentrations, L-dopa and oxygen, in the presence and absence of an inhibitor, product of the reaction. Initial reaction rates versus substrate concentrations, without inhibitor, show a linear dependence in the double-reciprocal space, that discarded Ordered and Random mechanisms. Initial reaction rates versus substrate concentrations, in the presence of an inhibitor product of the reaction, show a non-linear dependence in the double-reciprocal space. This point, joined to the former one, indicates a Ping-Pong mechanism, different of the Hexa-Uni type. The reaction is discussed for first time taking into account a trisubstrate mechanism. The experimental results lead to an (Uni Uni Bi Uni) Ping-Pong mechanism. On the other hand, they can explain the differences between known data of tyrosinases from several sources. Michaelis constant have been calculated for both substrates. The values are 0.16 and 7.14 mM for oxygen and L-dopa respectively.