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 spleen pigment cells in some amphibia

It was demonstrated that the spleen pigment cells of Amphibia are macrophages: they show an ultrastructurally distinctive morphology, are able to phagocytose and react positively for non-specific esterases. These pigmented macrophages express mRNA for tyrosinase and also they show dopa oxidase activity; therefore they are able to synthesize melanins, as Kupffer cells do.     

Tyrosinase in the presumptive pigment cells of ascidian embryos: Tyrosine accessibility may initiate melanin synthesis

Tyrosinase activity appears in the presumptive pigment cells of ascidian embryos (Ciona intestinalis) several hours before the cells begin to synthesize melanin. These presumptive pigment cells develop into the otolith and ocellus pigment cells of the larval brain. Tyrosinase was identified by histochemical tests for tyrosine oxidase and dopa oxidase; both reactions were sensitive to tyrosinase inhibitors. Studies with puromycin suggested that tyrosinase was synthesized at the time it was first detected histochemically and that it was stable during the time interval before melanin synthesis. Supernumerary tyrosinase-containing cells were found adjacent to the presumptive pigment cells in three ascidian species examined (C. intestinalis, Styela partita, and Molgula manhattensis). Tyrosinase disappeared from the supernumerary pigment cells during larval development and these cells did not synthesize melanin.Tyrosinase in the presumptive and supernumerary pigment cells is apparently a functional enzyme which does not interact with substrate. External substrates ( -tyrosine and -dopa) did not react with enzyme in the living cells before the normal time of pigment synthesis, but gentle disruption of the cells (by freezing-and-thawing or osmotic shock) released active tyrosinase. Progessive enlargement of nonpigmented vesicles in the otolith cells of embryos exposed to phenylthiourea, an inhibitor of tyrosinase activity, suggested that tyrosinase vesicles actively accumulate tyrosine at the beginning of melanin synthesis. This tyrosine accumulation probably initiates melanin synthesis.     

Human Melanoma Cell Lines Show Little Relationship Between Expression of Pigmentation Genes and Pigmentary Behaviour In Vitro

Several laboratories are pursuing the question of whether the expression of pigment genes can be used as a useful marker for tumour progression. However, many melanoma tumours are amelanotic in vivo. The purpose of this study was to examine the relationship between the expression of tyrosinase-related genes [tyrosinase, tyrosinase-related protein-1 (TRP-1) and tyrosinase-related protein-2 (TRP-2)] and pigmentation of melanoma cells. Fourteen cutaneous melanoma cell lines were examined for visible pigment, melanin content, and dopa oxidase activity and findings were related to the previously determined expression of the three tyrosinase-related genes in these cells in culture. Four of the cell lines were also stimulated with α-MSH, isobutylmethylxanthine, and forskolin to examine the relationship between induced pigmentation and upregulation of pigmentation genes. There was no simple correlation between pigmentation gene expression and dopa oxidase activity or total melanin content of the 14 melanoma cell lines in culture. In the majority of cells, there was no appreciable pigment, whereas, in contrast, half of the cells showed significant dopa oxidase activity. Upregulation of dopa oxidase activity was achieved by α-MSH in two out of four cell lines examined in detail and with IBMX in three out of four of these cell lines. IBMX increased tyrosinase gene expression in all four cell lines; α-MSH was without effect; and TRP-1 and TRP-2 expression were largely unaffected by IBMX or α-MSH. Modest changes in morphology were noted in response to IBMX. Overall, however, human melanoma cell lines were, with two exceptions, amelanotic in culture despite the fact that 10 out of the 14 lines expressed tyrosinaserelated genes. We conclude that measurable pigmentation is not a necessary consequence of the expression of pigmentation genes. An implication of this work is that amelanotic tumours in vivo may nevertheless be positive for tyrosinase-related genes.     

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.     

Expression of a mouse tyrosinase cDNA in 3T3 Swiss mouse fibroblasts

3T3 Swiss mouse fibroblast cell lines expressing tyrosinase, the critical enzyme in melanin synthesis, have been established by co-transfection of a mouse tyrosinase cDNA and a G418-resistance gene. Of sixty-three clones isolated, four are brown in colour, presumably due to synthesis of melanin. Expression of both the tyrosine hydroxylase and dopa oxidase activities of tyrosinase by these pigmented clones has been demonstrated directly by enzyme assays. Electron microscopic studies suggest that the brown pigment is located in membrane-bound cytoplasmic vesicles.     

Spleen and Liver Pigmented Macrophages of Rana Esculenta L. A New Melanogenic System?

The present study reports the results of a morpho‐functional analysis of spleen pigmented cells from Rana esculenta L. and comparison with liver melanin‐synthesizing cells, belonging to the macrophage cell lineage. Cytological and cytochemical analyses show that parenchymal pigmented cells of the spleen, like those of the liver, are positive to peroxidase and lipase reactions and have phagocytic properties. The observation of premelanosomes in various stages of differentiation, together with the demonstration of dopa oxidase activity in the melanosome proteins, indicate that spleen pigmented macrophages have endogenous melanogenic ability as do liver pigmented macrophages. Attempts to demonstrate tyrosine‐hydroxylase activity in melanosome protein extracts from frog spleen and liver, using the same protocol as for mammalian tyrosinases, gave negative results. As regards the dopa oxidase activity revealed, some of its properties differ from the typical behaviour observed for tyrosinases from different sources. Peroxidase activity is shown in spleen and liver melanosome proteins with p‐phenylenediamine‐pyrocatechol (PPD‐PC), and not with typical peroxidase substrates. Suitable inhibition tests revealed that dopa oxidase and peroxidase activities might be supported by two different proteins. Liver melanosome extracts display a very strong laccase (dimethoxyphenol‐oxidase) activity but spleen extracts do not. Differences observed in the enzymatic properties of the spleen and liver melanosomes suggest that pigmented macrophages may undergo tissue‐specific differentiation. These preliminary data show that the melanin pathway of pigmented macrophages is different from that of melanocytes and may pave the way to identification of a new melanogenic pathway in vertebrates.     

Distribution of extracutaneous melanin pigment in Sparus auratus, Mugil cephalus, and Dicertranchus labrax (Pisces, Teleostei)

The morphological and biochemical characteristics of pigment accumulations found in the kidney, liver, spleen, and mesentery of three different species of teleost fishes have been studied. There are significant differences in number, distribution, and morphology of pigment accumulations in different organs of the three species. Biochemical studies have shown the existence of tyrosinase activity in the mesentery of Mugil cephalus and in the kidney and mesentery of Sparus auratus. No tyrosinase activity was found in any internal organs of Dicertranchus labrax. That activity was assayed using three methods: tyrosine hidroxylation, dopa oxidation, and melanin formation. The morphological and biochemical observations are in agreement. In those organs in which we have demonstrated melanin synthetic activity, the pigment cells are morphologically and like melanophores, while in the organs that show no melanin synthetic activity, the pigment cells resemble macrophages.     

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.     

Truffle Melanogenesis: Correlation With Reproductive Differentiation and Ascocarp Ripening

The present work uses histochemical techniques to investigate the correlation between reproductive differentiation and age of truffles (Tuber aestivum and Tuber melanosporum) with melanin synthesis. The dopa oxidase and tyrosine hydroxylase activities of tyrosinase have been localized within the ascocarp and melanin localization was performed by the Schmorl's reaction. A true tyrosinase is present in truffles, able to oxidize both 1-tyrosine and 1-dopa. The tyrosinase activity is on in the young ascocarps (in the peridium, hypothecium, and fertile veins) and off in the ripe ones, thus it appears correlated with the age and differentiation of the sporogenic hyphae that arise from the hypothecium; a similar correlation has been previously described in Neurospora crassa which is an ascomycete as well as the truffles.     

Limitations of the quantitative cytochemical assay of catechol oxidase in melanoma cells

Summary The cytochemical quantification of catechol oxidase activity in fixed B16 melanoma cells was investigated using dopa as the substrate. Inhibitors showed that peroxidases do not significantly interfere. The kinetics of melanin formation were studied initially in solution with purified catechol oxidase. Two key parameters were identified: lag-time and the rate of melanin formation. The lag-time was taken as the time required by intermediates to reach a critical concentration at which the polymerization process starts and melanin production becomes measurable (at 640 nm). In solution, the lag-time decreases as the enzyme activity increases, particularly when the activity is very low. The rate at which melanin is formed by pure enzyme in solution is independent of dopa concentration when its activity is low but increases linearly with dopa concentration when the activity is comparatively high.In fixed melanoma cells, the lag-time decreases linearly with increases of dopa concentrations up to 20mm; at concentrations higher than this, the lag decreases more slowly. In contrast, the rate of melanin production is unaffected by changes in dopa concentration. The lag-times of different cells lines incubated at the same substrate concentration decrease as the enzyme activity of the cells increases. The rate of melanin production seems to be affected by factors other than catechol oxidase activity, such as the intracellular organization and distribution of the enzyme.     

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.     

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.     

Biogenesis of melanosomes in Kupffer cells of Proteus anguinus (Urodela,Amphibia)

The ultrastructural characteristics of melanosomes and premelanosomes observed during the biogenesis of melanosomes in liver pigment cells of the neotenic cave salamander Proteus anguinus (Proteidae) are described. It is well known that amphibian liver pigment cells, also known as Kupffer cells (KC), contain melanosomes and are able to synthesize melanin. Liver pigment cells of P. anguinus contain numerous siderosomes and melanosomes. The melanosomes are grouped together within single-membrane-bounded bodies, named as 'clusters of melanosomes' or 'melanosomogenesis centers'. Inside such clusters, different structures are present: (1) filament-like structures, characteristic of the initial stage of melanosome biogenesis, (2) medium electron-dense melanosomes in different stages of melanization, (3) melanosomes with an electron-dense cortical area and a less electron-dense medullar area, and (4) uniformly highly electron-dense mature melanosomes or melanin granules. Histochemical and cytochemical dihydroxyphenylalanine (DOPA) oxidase reactions in pigment cells were positive. Our results confirm the ability of amphibian KC to synthesize melanin and contribute to this little known subject.     

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.