Histochemical differentiation of peroxidase-mediated from tyrosinase-mediated melanin formation in mammalian tissues

Summary Preincubation with the copper-chelator, sodium diethyldithiocarbamate (DDC) and the presence of catalase in the incubation media allowed an accurate and reproducible differentiation of the role of tyrosinase from that of peroxidase in the oxidation of tyrosine and dopa in melanocytes, mast cells and eosinophils. These studies indicated that mammalian peroxidase in melanocytes, mast cells and eosinophils can mediate the conversion of tyrosine to melanin in the presence of dopa co-factor, as well as the conversion of dopa to melanin. With the methods employed, there was no evidence that tyrosinase in the preparations studied had significant ability to mediate the oxidation of tyrosine to melanin (even in the presence of dopa co-factor), although there was abundant evidence that it can mediate the conversion of dopa to melanin. Mammalian peroxidase may have roles in initiating melanin synthesis and catechol amine synthesis in vivo.Supported by USPHS Grant T1 AM 5,220, The General Research Support Fund, Boston City Hospital, and The Pathology Research Fund, St. Vincent Hospital.     

Mammalian tyrosinase. A comparison of tyrosine hydroxylation and melanin formation.

1. Melanosomal tyrosinase was isolated from normal C57B1 mice, and a comparison of the tyrosine-hydroxylation and dopa (3,4-dihydroxyphenylalanine)-oxidation activities of this enzyme was made. 2. The results indicate that in the absence of dopa cofactor, this enzyme is capable of tyrosine hydroxylation, but with very little subsequent dopa oxidation and melanin formation. 3. This mechanism of enzyme action may play an important role in the intracellular regulation of melanin formation. 4. Further, dopa appears to act as a positive allosteric effector for tyrosine hydroxylation by tyrosinase, in addition to its known activity as a hydrogen donor for the reaction.     

Assays for mammalian tyrosinase: a comparative study

This work describes a comparative study of the tyrosinase activity determined using three methods which are the most extensively employed; two radiometric assays using L-tyrosine as substrate (tyrosine hydroxylase and melanin formation activities) and one spectrophotometric assay using L-dopa (dopa oxidase activity). The three methods were simultaneously employed to measure the activities of the soluble, melanosomal, and microsomal tyrosinase isozymes from Harding-Passey mouse melanoma through their purification processes. The aim of this study was to find any correlation among the tyrosinase activities measured by the three different assays and to determine whether that correlation varied with the isozyme and its degree of purification. The results show that mammalian tyrosinase has a greater turnover number for L-dopa than for L-tyrosine. Thus, enzyme activity, expressed as mumol of substrate transformed per min, is higher in assays using L-dopa as substrate than those using L-tyrosine. Moreover, the percentage of hydroxylated L-tyrosine that is converted into melanin is low and is affected by several factors, apparently decreasing the tyrosinase activity measured by the melanin formation assay. Bearing these considerations in mind, average interassay factors are proposed. Their values are 10 to transform melanin formation into tyrosine hydroxylase activity, 100 to transform tyrosine hydroxylase into dopa oxidase activity, and 1,000 to transform melanin formation into dopa oxidase activity. Variations in these values due to the presence in the tyrosinase preparations of either inhibitors or regulatory factors in melanogenesis independent of tyrosinase are also discussed.     

Role of estradiol and 2-hydroxyestradiol in melanin formation in vitro

Melanin formation from 3,4-dihydroxyphenylalanine (dopa) was studied in the presence of estradiol and 2-hydroxyestradiol by use of a tyrosinase isolated from B16-F10 melanoma cells grown in C57 black female mice. Both steroids were found incorporated into melanin, but the 2-hydroxy compound was incorporated to a higher extent. The melanin was also able to bind substantial amounts of the two steroids, and the more highly oxidized compound showed higher binding. Melanin isolated from incubates of dopa with mushroom tyrosinase has the ability to bind the steroids and to incorporate small amounts into its structure. It is suggested that melanin in mammalian tissues may function as a depository for estrogens, particularly for those which are more highly oxidized.     

Selective uptake of 2-thiouracil into melanin-producing systems depends on chemical binding to enzymically generated dopaquinone

2-Thiouracil (TU), an antithyroid drug, is receiving growing interest as a specific tumor marker for malignant melanoma, owing to its capability of being selectively accumulated into active melanin-producing tissues. However, up until now, the molecular mechanism of TU uptake by growing melanin has remained largely unknown. In an attempt to fill this gap, we have investigated the effect of TU on the tyrosinase catalyzed oxidation of tyrosine. At a concentration of 0.5 mM, TU was found to totally inhibit melanin formation by tyrosinase catalyzed oxidation of 0.25 mM tyrosine in phosphate buffer at pH 6.8. Polarographical monitoring of oxygen consumption under conditions of complete suppression of melanogenesis revealed a significant tyrosinase activity, with TU acting as a modest non-competitive inhibitor of the enzyme (Ki = 0.6 mM). HPLC and TLC analysis of the tyrosine-tyrosinase reaction in the presence of excess TU showed that the substrate is progressively consumed and a major hitherto unknown product (lambda max = 284 nm), positive to ninhydrin and ferric chloride, is concomitantly formed. This was isolated by repeated gel filtration chromatography of the reaction mixture on Sephadex G-10 and was formulated as the TU-dopa adduct 3,4-dihydroxy-6-(4'-hydroxypyrimidinyl-2'-thio)phenylalanine by spectral analysis. These results suggest that selective TU incorporation in pigmented melanomas and other melanin-producing systems is due to the covalent binding to dopaquinone, produced by tyrosinase catalyzed oxidation of tyrosine.     

Mutational mapping of the catalytic activities of human tyrosinase.

Tyrosinase (EC 1.14.18.1) is a copper-containing metalloglycoprotein that catalyzes several steps in the melanin pigment biosynthetic pathway; the hydroxylation of tyrosine to L-3,4-dihydroxyphenylalanine (dopa) and the subsequent oxidation of dopa to dopaquinone. It has been proposed that tyrosinase is also able to oxidize 5,6-dihydroxyindole (DHI), a later product in the melanogenic pathway, to indole-5,6-quinone. Tyrosinase enzymatic activity is deficient in patients with classic type I oculocutaneous albinism (OCA), and more than 50 distinct mutations have now been identified in the tyrosinase genes of such patients. To determine the effects of the various tyrosinase gene mutations on the catalytic activities of the enzyme, we carried out site-directed mutagenesis of human tyrosinase cDNA, transiently expressed the mutant cDNAs in transfected HeLa cells, and assayed the resultant encoded proteins for tyrosine hydroxylase, dopa, and DHI oxidase activities, and resulting melanin production. The tyrosine hydroxylase activity of normal tyrosinase is thermostable, whereas its dopa oxidase and DHI oxidase activities are temperature-sensitive. Although all amino acid substitutions tested generally affected the dopa oxidase and DHI oxidase activities in parallel, several exerted distinctly different effects on the tyrosine hydroxylase activities. Together, these results confirm the DHI oxidase activity of mammalian tyrosinase and suggest that the dopa oxidase and DHI oxidase activities of tyrosinase share a common catalytic site, whereas the tyrosine hydroxylase catalytic site is at least partially distinct in the tyrosinase polypeptide.     

The role of sulfhydryl compounds in mammalian melanogenesis: the effect of cysteine and glutathione upon tyrosinase and the intermediates of the pathway

The effect of cysteine and glutathione on mammalian melanogenesis has been studied. It has been shown that their action is mediated by two different mechanisms. (a) The reaction of the thiol groups with dopaquinone after the tyrosinase-catalyzed oxidation of tyrosine and dopa. This mechanism leads to the formation of sulfhydryl-dopa conjugates and finally sulfur-containing pigments, phaeomelanins instead of eumelanins. This fact might produce an inhibition of melanogenesis due to the slower rate of chemical reactions involved in the polymerization of such thiol-conjugates when compared to that of indoles. (b) The direct interaction between the sulfhydryl compounds and the tyrosinase active site. This interaction may regulate the activity of the enzyme. It is shown that Harding-Passey mouse melanoma tyrosinase is more sensitive to sulfhydryl compounds than mushroom tyrosinase. Cysteine always produces an inhibition of the tyrosinase hydroxylase and dopa oxidase activities of melanoma tyrosinase, this inhibition becoming greater as the cysteine concentration increases. On the other hand, glutathione produces an activation of the tyrosine hydroxylase activity below 3 mM and an inhibition at higher concentrations. The limit between the enzymatic activation and inhibition appears at glutathione concentrations similar to the physiological levels of this compound found in melanocytes. Although the switch from eumelanogenesis to phaeomelanogenesis occurs at much lower concentrations of glutathione, taking into account these data it is discussed that this sulfhydryl compound may regulate not only the type but also the amount of melanin formed inside melanocytes.     

Enzymatic and Non-Enzymatic Oxygenation of Tyrosine

Tyrosinase isolated from cultured human melanoma cells was studied for tyrosine oxygenation activity. l -Tyrosine and d -tyrosine were used as substrates and dopa was measured with HPLC and electrochemical detection as the product of oxygenation. Incubations were performed in the presence or absence of dopamine as co-substrate. Oxygenation of l -tyrosine occurred only in the presence of dopamine as co-substrate. No oxygenation of d -tyrosine was found, and we conclude that human tyrosinase is characterised by exclusive specificity for the l -isomer of tyrosine in its oxygenase function. It has recently been suggested that superoxide anion is a preferential oxygen substrate for human tyrosinase. Incubations were therefore performed with l - and d -tyrosine, human tyrosinase, and xanthine/xanthine oxidase in the system, generating superoxide anion and hydrogen peroxide. Considerable formation of dopa was observed, but the quantity was the same irrespective of whether d -tyrosine or l -tyrosine was used as the substrate. Furthermore, formation of dopa occurred in a xanthine/xanthine oxidase system when bovine serum albumin (BSA) was substituted for tyrosinase. Our results provide no evidence that superoxide anion is an oxygen substrate for human tyrosinase. In the incubate containing xanthine/xanthine oxidase, catalase completely inhibited dopa formation, and superoxide dismutase and mannitol each strongly inhibited dopa formation. The results are compatible with hydroxyl radicals being responsible for the formation of dopa, since such radicals may be secondarily formed in the presence of superoxide anion and hydrogen peroxide.     

Mammalian tyrosinase: isolation by a simple new procedure and characterization of its steric requirements for cofactor activity.

A method for the isolation of tyrosinase is described, which involves preparative polyacrylamide gel electrophoresis, requires only 24 to 36 h to carry out, and yields ostensibly homogeneous enzyme. The ability of purified tyrosinase to utilize 3,4-dihydroxyphenylalanine (dopa) analogs as cofactors was determined for both of the reactions catalyzed by tyrosinase: (i) tyrosine hydroxylation and (ii) dopa oxidation and melanin formation. The cofactor analogs studied included those in which steric modifying groups were added and those in which substitutions were made at the location of the amine, carboxylic acid, or hydroxyl groups of dopa. The results indicate that each of these groups is essential for maximal enzyme activity and that each is optimally located for tyrosinase activation when in the precise steric conformation found in l-dopa.     

In vitro modulation of proliferation and melanization of melanoma cells by citrate

B16/F10 murine melanoma cells were grown for 24 and 36 h in Dulbecco's modified Eagle medium in presence of 10-20 mM trisodium citrate. The intracellular melanin concentration and the melanin secreted in the extracellular medium was estimated. It is observed that 20 mM citrate stimulates extracellular melanin secretion in B16/F10 melanoma cells by 200% at 36 h treatment. The intracellular melanin content increased by 90%. This stimulatory effect of citrate was totally abolished when these cells were grown in presence of 1 mM phenyl thiourea, a specific inhibitor of tyrosinase activity. Citrate (0.1-5 mM) had no effect on dopa oxidase activity either at pH 5.0 or at pH 6.8. There was no increase in the tyrosinase specific activity in presence of citrate. The increased melanin synthesis was shown to be due to stimulation of cellular tyrosine hydroxylase activity by citrate. It has been suggested that enhanced melanin synthesis results in an increased production of metabolites that are toxic to the growth of melanoma cells. We have studied the effect of citrate on cellular proliferation. Following 24 and 36 h treatment with citrate, the cells exhibited a dose-dependent decrease in proliferation. In presence of 20 mM citrate the cell number was only up to 50% of the control cultures after 36 h of incubation. The growth retardation was not due to cytotoxicity. Citrate, a natural metabolite, is a unique molecule which may be involved in the regulation of melanin biosynthetic pathway, since it enhances melanogenesis by increasing the hydroxylase activity of tyrosinase which is the regulatory enzyme of this pathway. These observations add further support to the critical role of intramelanosomal pH in regulation of melanogenesis.     

Incorporation and binding of estrogens into melanin: comparison of mushroom and mammalian tyrosinases.

The activities of mushroom and melanoma tyrosinases towards the estrogens were compared. While the fungal enzyme is capable of hydroxylating estradiol to the 2-hydroxy compound and to oxidize the latter to the quinone, the mammalian enzyme does not have this ability. With dopa as substrate and an estrogen present in the reaction mixture, both enzyme reactions yield melanin with the steroid firmly incorporated into the pigment, although with the mammalian enzyme the incorporation is small. The steroid appears to be incorporated by covalent linkage. It is suggested that the incorporation of estrogens into melanin produced by mammalian tyrosinase is via their oxidation by oxidized intermediates of the dopa to melanin transformation. Melanin itself may function as oxidant for the estrogens. Whole melanoma cells are capable of binding estrogens and incorporating small amounts into melanosomes. Similarly, fresh melanosomes in isolation can incorporate estrogens into their structure, presumably by covalent bonding to their melanin.     

Optimization of hydroxylation of tyrosine and tyrosine-containing peptides by mushroom tyrosinase

Free tyrosine and tyrosine residues in various peptides and proteins are converted into dopa and dopa residues by tyrosinase (monophenol,L-dopa:oxygen oxidoreductase, EC 1.14.18.1) in the presence of reductants. The efficiency of the tyrosine-to-dopa conversion was examined under varied conditions, such as the substrate-to-tyrosine ratio, concentrations of reductant and oxygen in the reaction solution, pH, temperature and reaction time. The highest dopa yields were achieved with the following optimal conditions for hydroxylation: 0.1 M phosphate buffer at pH 7, 25 mM ascorbic acid, 1 mM tyrosine, 50 micrograms/ml tyrosinase and 20 degrees C. Using these conditions, up to 70% of free tyrosine was converted into dopa, and tyrosine residues in several synthetic peptides were also hydroxylated to dopa residues at ratios as high as free tyrosine. The preparation of hydroxylated analogues of the decapeptide (Ala-Lys-Pro-Ser-Tyr-Pro-Pro-Thr-Tyr-Lys), in particular, may contribute to a better understanding of adhesion in the dopa-containing mussel glue protein.     

Effect of metal ions on the kinetics of tyrosine oxidation catalysed by tyrosinase.

The conversion of tyrosine into dopa [3-(3,4-dihydroxyphenyl)alanine] is the rate limiting step in the biosynthesis of melanins catalysed by tyrosinase. This hydroxylation reaction is characterized by a lag period, the extent of which depends on various parameters, notably the presence of a suitable hydrogen donor such as dopa or tetrahydropterin. We have now found that catalytic amounts of Fe2+ ions have the same effect as dopa in stimulating the tyrosine hydroxylase activity of the enzyme. Kinetic experiments showed that the shortening of the induction time depends on the concentration of the added metal and the nature of the buffer system used and is not suppressed by superoxide dismutase, catalase, formate or mannitol. Notably, Fe3+ ions showed only a small delaying effect on tyrosinase activity. Among the other metals which were tested, Zn2+, Co2+, Cd2+ and Ni2+ had no detectable influence, whereas Cu2+ and Mn2+ exhibited a marked inhibitory effect on the kinetics of tyrosine oxidation. These findings are discussed in the light of the commonly accepted mechanism of action of tyrosinase.     

Inhibitory effect of dalbergioidin isolated from the trunk of Lespedeza cyrtobotrya on melanin biosynthesis

Tyrosinase is a key enzyme for melanin biosynthesis, and hyperpigmentation disorders are associated with abnormal accumulation of melanin pigments, which can be reduced by treatment with depigmenting agents. The methanol extract of Lespedeza cyrtobotrya MIQ showed inhibitory activity against mushroom tyrosinase. The active compound was purified from the methanol extract of L cyrtobotrya, followed by several chromatographic methods, and identified as dalbergioidin (DBG) by spectroscopic methods. The results showed that DBG exhibited tyrosinase inhibitory activity with an IC50 of 20 mM. The kinetic analysis tyrosinase inhibition revealed that DBG acted as noncompetitive inhibitor. In addition, DBG showed a melanin biosynthesis inhibition zone in the culture plate of Streptomyces bikiniensis that has commonly been used as an indicator organism. Furthermore, 27 mM DBG decreased more than 50% of melanin contents on the pigmentation using immortalized mouse melanocyte, melan-a cell.     

Methyl p-coumarate, a melanin formation inhibitor in B16 mouse melanoma cells

p-Coumaric acid (4-hydroxycinnamic acid) and methyl p-coumarate (methyl 4-hydroxycinnamate) inhibit the oxidation of L-tyrosine catalyzed by mushroom tyrosinase. However, both were oxidized as monophenol substrate analogues at an extremely slow rate. This oxidation was significantly accelerated as soon as catalytic amounts (0.01 mM) of L-3,4-dihydroxyphenylalanine (L-DOPA) became available as a co-factor. Methyl p-coumarate significantly suppressed the melanin formation in B16 mouse melanoma cells, whereas p-coumaric acid did not show this activity.     

Pheomelanogenesis is promoted at a weakly acidic pH

The diversity of pigmentation in the skin, hair, and eyes of humans has been largely attributed to the diversity of pH in melanosomes with an acidic pH being proposed to suppress melanin production, especially eumelanogenesis. We previously showed that an acidic pH greatly suppresses the late stage of eumelanogenesis after the dopachrome stage. The oxidation of tyrosine by tyrosinase in the presence of cysteine forms cysteinyldopa isomers, which are further oxidized to give rise to pheomelanin via benzothiazine intermediates. However, how those steps are controlled by pH has not been characterized. We therefore examined whether pheomelanin synthesis is chemically promoted at an acidic pH. We found that pheomelanin production either from dopa or tyrosine in the presence of cysteine by tyrosinase was greatest at pH values of 5.8–6.3, while eumelanin production was suppressed at pH 5.8. This suggests that mixed melanogenesis is chemically shifted to more pheomelanic states at a weakly acidic pH.     

Purification of human skin tyrosinase and its protein inhibitor: properties of the enzyme and the mechanism of inhibition by protein

Tyrosinase from normal human skin was purified to high specific activity; 228 nmol of dopa formed/min/mg protein. The properties of the purified enzyme differ from those of the same enzyme in crude homogenates. The activity of the purified enzyme is not affected by dopa. It is not inhibited by excess tyrosine and exhibits no lag in its rate at 4 mm concentration of ascorbic acid. This preparation is free of peroxidase and yet will catalyze both hydroxylation of tyrosine to dopa and its further oxidation to dopa quinone with fourfold more activity with dopa as substrate suggesting that mammalian tyrosinase catalyzes both reactions rather than dopa oxidation alone as suggested by M. Okun, L. Edelstein, R. Patel, and B. Donnellan (1973, Yale J. Biol. Med.46, 535–540). A protein present in the cytosol and melanosomes that constitutes 30% of soluble epidermal proteins was purified and found to inhibit tyrosinase competitively with tyrosine. Its molecular weight was estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be 66,000.     

Tyrosinase-catalyzed hydroxylation of hydroquinone,a depigmenting agent,to hydroxyhydroquinone: A kinetic study

Hydroquinone (HQ) is used as a depigmenting agent. In this work we demonstrate that tyrosinase hydroxylates HQ to 2-hydroxyhydroquinone (HHQ). Oxy-tyrosinase hydroxylates HQ to HHQ forming the complex met-tyrosinase-HHQ, which can evolve in two different ways, forming deoxy-tyrosinase and p-hydroxy-o-quinone, which rapidly isomerizes to 2-hydroxy-p-benzoquinone or on the other way generating met-tyrosinase and HHQ. In the latter case, HHQ is rapidly oxidized by oxygen to generate 2-hydroxy-p-benzoquinone, and therefore, it cannot close the enzyme catalytic cycle for the lack of reductant (HHQ). However, in the presence of hydrogen peroxide, met-tyrosinase (inactive on hydroquinone) is transformed into oxy-tyrosinase, which is active on HQ. Similarly, in the presence of ascorbic acid, HQ is transformed into 2-hydroxy-p-benzoquinone by the action of tyrosinase; however, in this case, ascorbic acid reduces met-tyrosinase to deoxy-tyrosinase, which after binding to oxygen, originates oxy-tyrosinase. This enzymatic form is now capable of reacting with HQ to generate p-hydroxy-o-quinone, which rapidly isomerizes to 2-hydroxy-p-benzoquinone. The formation of HHQ during the action of tyrosinase on HQ is demonstrated by means of high performance liquid chromatography mass spectrometry (HPLC–MS) by using hydrogen peroxide and high ascorbic acid concentrations. We propose a kinetic mechanism for the tyrosinase oxidation of HQ which allows us the kinetic characterization of the process. A possible explanation of the cytotoxic effect of HQ is discussed.     

A study of the supposed hydroxylation of tyrosine catalysed by peroxidase.

The claim that peroxidase (rather than tyrosinase) is the enzyme responsible for the conversion of tyrosine into dopa (3,4-dihydroxyphenylalanine) in melanogenesis was investigated. The spectral changes that occurred during the action of horseradish peroxidase in the presence of H2O2 on dopa, tyrosine and mixtures of dopa with tyrosine or other phenolic compounds were studied. The effect of ascorbic acid or dihydroxyfumaric acid on some of these changes was also investigated. No evidence was found that tyrosine was hydroxylated by peroxidase in the presence of H2O2 and dopa as cofactor, although tyrosine or other phenolic compounds increased the rate of oxidation of dopa to dopachrome (indoline-5,6-quinone-2-carboxylic acid). Peroxidase was, however, effective in oxidizing tyrosine to dopa in the presence of dihydroxyfumaric acid and oxygen.     

The effects of nitric oxide on the oxidations of l-dopa and dopamine mediated by tyrosinase and peroxidase

The effects of nitric oxide (NO) on both tyrosinase/O(2)- and horseradish peroxidase/H(2)O(2)-mediated oxidations of dopamine and its o-dihydric phenol precursor l-dopa were compared with autoxidative processes and quantitatively assessed by oxidative and reductive electrochemical detection systems. In peroxidase/H(2)O(2)/NO-catalyzed reactions, significantly more substrate was oxidized than in the corresponding control incubations lacking NO. In tyrosinase/O(2)/NO-promoted reactions the total amounts of l-dopa and dopamine oxidized were significantly less than the amounts of the substrates oxidized by enzyme alone. These data indicate that the activity of the heme protein peroxidase was enhanced by NO, whereas tyrosinase, a copper-containing monoxygenase, was inhibited. The NO-mediated reduction of tyrosinase/O(2) activity may be attributed to the formation of an inhibitory copper.nitrosyl complex. An oxidized nitrodopamine derivative, considered to be either the quinone or semiquinone of 6-nitrosodopamine, was generated in peroxidase/H(2)O(2)/NO-mediated reactions with dopamine along with two oxidized melanin precursors, dopamine quinone and dopaminechrome. No corresponding nitroso compound was formed in reactions involving l-dopa or in any of the tyrosinase-mediated reactions. The formation of such a noncyclized nitrosodopamine represents an important alternative pathway in catecholamine metabolism, one that by-passes the formation of cytoprotective indole precursors of melanin. The results of this investigation suggest that cellular integrity and function can be adversely affected by NO-promoted oxidations of dopamine and other catechols, reactions that not only accelerate their conversion to reactive quinones but also form potentially cytotoxic noncyclized nitroso derivatives. Reduced levels of dopamine in the brain through NO-enhanced oxidation of the catecholamine will almost certainly be manifested by diminished levels of the dopamine-derived brain pigment neuromelanin.