A three-dimensional model of mammalian tyrosinase active site accounting for loss of function mutations

Tyrosinases are the first and rate-limiting enzymes in the synthesis of melanin pigments responsible for colouring hair, skin and eyes. Mutation of tyrosinases often decreases melanin production resulting in albinism, but the effects are not always understood at the molecular level. Homology modelling of mouse tyrosinase based on recently published crystal structures of non-mammalian tyrosinases provides an active site model accounting for loss-of-function mutations. According to the model, the copper-binding histidines are located in a helix bundle comprising four densely packed helices. A loop containing residues M374, S375 and V377 connects the CuA and CuB centres, with the peptide oxygens of M374 and V377 serving as hydrogen acceptors for the NH-groups of the imidazole rings of the copper-binding His367 and His180. Therefore, this loop is essential for the stability of the active site architecture. A double substitution (374)MS(375) --> (374)GG(375) or a single M374G mutation lead to a local perturbation of the protein matrix at the active site affecting the orientation of the H367 side chain, that may be unable to bind CuB reliably, resulting in loss of activity. The model also accounts for loss of function in two naturally occurring albino mutations, S380P and V393F. The hydroxyl group in S380 contributes to the correct orientation of M374, and the substitution of V393 for a bulkier phenylalanine sterically impedes correct side chain packing at the active site. Therefore, our model explains the mechanistic necessity for conservation of not only active site histidines but also adjacent amino acids in tyrosinase.     

Cloning and Molecular Characterization of a SDS‐Activated Tyrosinase from Marinomonas mediterranea

The sequence of the tyrosinase gene cloned from Marinomonas mediterranea is reported. It is the second tyrosinase cloned from a Gram negative bacterium. Its size is higher than that of Gram positive tyrosinases from Streptomyces, and more similar to the eukaryotic enzymes. Its sequence shares the features of copper‐binding sites found in all tyrosinases. Based in the comparison of tyrosinases from all types of organisms, an extension of the characteristic signatures existing at Prosite is proposed. This tyrosinase shares with some plant and amphibian tyrosinases a strong specific activation by submicellar concentrations of SDS. Intrinsic fluorescence and kinetic properties indicate that the activation is caused by an SDS‐dependent conformational change that facilitates the substrate accessibility to the dicopper active site.     

Bacterial tyrosinases

Tyrosinases are nearly ubiquitously distributed in all domains of life. They are essential for pigmentation and are important factors in wound healing and primary immune response. Their active site is characterized by a pair of antiferromagnetically coupled copper ions, CuA and CuB, which are coordinated by six histidine residues. Such a "type 3 copper centre" is the common feature of tyrosinases, catecholoxidases and haemocycanins. It is also one of several other copper types found in the multi-copper oxidases (ascorbate oxidase, laccase). The copper pair of tyrosinases binds one molecule of atmospheric oxygen to catalyse two different kinds of enzymatic reactions: (1) the ortho-hydroxylation of monophenols (cresolase activity) and (2) the oxidation of o-diphenols to o-diquinones (catecholase activity). The best-known function is the formation of melanins from L-tyrosine via L-dihydroxyphenylalanine (L-dopa). The complicated hydroxylation mechanism at the active centre is still not completely understood, because nothing is known about their tertiary structure. One main reason for this deficit is that hitherto tyrosinases from eukaryotic sources could not be isolated in sufficient quantities and purities for detailed structural studies. This is not the case for prokaryotic tyrosinases from different Streptomyces species, having been intensively characterized genetically and spectroscopically for decades. The Streptomyces tyrosinases are non-modified monomeric proteins with a low molecular mass of ca. 30kDa. They are secreted to the surrounding medium, where they are involved in extracellular melanin production. In the species Streptomyces, the tyrosinase gene is part of the melC operon. Next to the tyrosinase gene (melC2), this operon contains an additional ORF called melC1, which is essential for the correct expression of the enzyme. This review summarizes the present knowledge of bacterial tyrosinases, which are promising models in order to get more insights in structure, enzymatic reactions and functions of "type 3 copper" proteins in general.     

Structure–activity relationships of the thujaplicins for inhibition of human tyrosinase

Tyrosinase inhibitors have become increasingly critical agents in cosmetic, agricultural, and medicinal products. Although a large number of tyrosinase inhibitors have been reported, almost all the inhibitors were unfortunately evaluated by using commercial available mushroom tyrosinase. Here, we examined the inhibitory effects of three isomers of thujaplicin (α, β, and γ) on human tyrosinase and analyzed their binding modes using homology model and docking studies. As the results, γ-thujaplicin was found to strongly inhibit human tyrosinase with the IC₅₀ of 1.15 μM, extremely superior to a well-known tyrosinase inhibitor kojic acid (IC₅₀ = 571.17 μM). MM-GB/SA binding free energy decomposition analyses suggested that the potent inhibitory activity of γ-thujaplicin may be due to the interactions with His367, Ile368, and Val377 (hot spot amino acid residues) in human tyrosinase. Furthermore, the binding mode of α-thujaplicin indicated that Val377 and Ser380 may cause van der Waals clashes with the isopropyl group of α-thujaplicin. These results provide a novel structural insight into the hot spot of human tyrosinase for the specific binding of γ-thujaplicin and a way to optimize not only thujaplicins but also other lead compounds as specific inhibitors for human tyrosinase in a rational manner.     

New insights into the active site structure and catalytic mechanism of tyrosinase and its related proteins

Tyrosinases are widely distributed in nature. They are copper‐containing oxidases belonging to the type 3 copper protein family, together with catechol oxidases and haemocyanins. Tyrosinases are essential enzymes in melanin biosynthesis and therefore responsible for pigmentation of skin and hair in mammals, where two more enzymes, the tyrosinase‐related proteins (Tyrps), participate in the pathway. The structure and catalytic mechanism of mammalian tyrosinases have been extensively studied but they are not completely understood because of the lack of information on the tertiary structure. The availability of crystallographic data of one plant catechol oxidase and one bacterial tyrosinase has improved the model of the three‐dimensional structure of the active site of the enzyme. Furthermore, sequence comparison of tyrosinase and the Tyrps reveals that the three orthologue proteins share many key structural features, because of their common origin from an ancestral gene, although the specific residues responsible for their different catalytic capabilities have not been identified yet. This review summarizes our current knowledge of tyrosinase and Tyrps structure and function and describes the catalytic mechanism of tyrosinase and Dct/Tyrp2, which are better characterized.     

Homology models of four Agaricus bisporus tyrosinases

Partially purified tyrosinase from the white button mushroom Agaricus bisporus is available commercially and is a widely used experimental model for the study of tyrosinase. The structure of an H₂L₂ tetrameric form of the mushroom enzyme was recently determined by X-ray crystallography. In this structure the two H subunits originate from the PPO3 gene, and the two L subunits are formed by a protein of unknown function with a lectin-like fold. However, the X-ray structures and oligomeric states of the mushroom PPO1, PPO2, PPO4, and PPO5 gene products remain unknown. Commercial mushroom tyrosinase powder is a mixture containing several or all of these tyrosinases, so knowledge of their structures should provide insight regarding interpretation of experimental data generated using commercial preparations of the enzyme. The PPO3 structure (H-subunit) was used as a template to generate homology models for the structures of the other four tyrosinases, and the resulting structural models were evaluated. Due to the moderate to high percentage of sequence identity (∼37-76%) between PPO3 and the other four tyrosinases, the backbone conformations of the predicted structures are very similar to that of PPO3. The alpha carbons of the six copper-coordinating histidines in the active site are positioned properly in the predicted structures, but their side chains are not oriented optimally for copper binding in some cases. Thus, the models are likely to provide an accurate representation of the actual tertiary structures, but they may have limited use in studies involving docking of substrates or inhibitors in the active site. Comparison of the homology models to the structure of molluscan hemocyanin enabled a prediction of the orientation of the enzyme's C-terminal domain over the active site in the latent enzyme.     

The effect of 7,8,4´‐trihydroxyflavone on tyrosinase activity and conformation: Spectroscopy and docking studies

Tyrosinase is a ubiquitous enzyme that plays an essential role in the production of melanin. Effective inhibitors of tyrosinase have extensive applications in the medical, cosmetic and food industries. In this study, a combination of enzyme kinetics, ultraviolet (UV)‐visible absorption, fluorescence spectroscopic techniques and a computational simulation method was used to characterize the inhibitory mechanism of 7,8,4´‐trihydroxyflavone on tyrosinase. 7,8,4´‐Trihydroxyflavone was found to strongly inhibit the oxidation of l ‐DOPA by tyrosinase with an IC₅₀ value of 10.31 ± 0.41 μM. The inhibitory mechanism was determined to be reversible and non‐competitive with a K_i of 9.50 ± 0.40 μM. The UV absorption spectra showed that 7,8,4´‐trihydroxyflavone could chelate with copper ions and form a complex with tyrosinase. The intrinsic fluorescence of tyrosinase was quenched by 7,8,4´‐trihydroxyflavone through a static quenching mechanism. 7,8,4´‐Trihydroxyflavone was found to occupy a single binding site with a binding constant of 7.50 ± 1.20 × 10⁴ M^?1 at 298 K. The conformation of tyrosinase changed, and the microenvironment became more hydrophilic after 7,8,4´‐trihydroxyflavone binding. Thermodynamics parameters indicated that the binding was a spontaneous process and involved hydrogen bonds and van der Waals forces. The binding distance was evaluated to be 4.54 ± 0.05 nm. Docking simulation analysis further authenticated that 7,8,4´‐trihydroxyflavone could form hydrogen bonds with the residues His244 and Met280 within the tyrosinase active site. Our results will contribute to further understanding of the inhibitory mechanisms of 7,8,4´‐trihydroxyflavone against tyrosinase and will facilitate future screening for tyrosinase inhibitors.     

The crystal structure of an extracellular catechol oxidase from the ascomycete fungus Aspergillus oryzae

Catechol oxidases (EC 1.10.3.1) catalyse the oxidation of o-diphenols to their corresponding o-quinones. These oxidases contain two copper ions (CuA and CuB) within the so-called coupled type 3 copper site as found in tyrosinases (EC 1.14.18.1) and haemocyanins. The crystal structures of a limited number of bacterial and fungal tyrosinases and plant catechol oxidases have been solved. In this study, we present the first crystal structure of a fungal catechol oxidase from Aspergillus oryzae (AoCO4) at 2.5-Å resolution. AoCO4 belongs to the newly discovered family of short-tyrosinases, which are distinct from other tyrosinases and catechol oxidases because of their lack of the conserved C-terminal domain and differences in the histidine pattern for CuA. The sequence identity of AoCO4 with other structurally known enzymes is low (less than 30 %), and the crystal structure of AoCO4 diverges from that of enzymes belonging to the conventional tyrosinase family in several ways, particularly around the central α-helical core region. A diatomic oxygen moiety was identified as a bridging molecule between the two copper ions CuA and CuB separated by a distance of 4.2–4.3 Å. The UV/vis absorption spectrum of AoCO4 exhibits a distinct maximum of absorbance at 350 nm, which has been reported to be typical of the oxy form of type 3 copper enzymes.     

Crystal structure of Agaricus bisporus mushroom tyrosinase: identity of the tetramer subunits and interaction with tropolone

Tyrosinase catalyzes the conversion of phenolic compounds into their quinone derivatives, which are precursors for the formation of melanin, a ubiquitous pigment in living organisms. Because of its importance for browning reactions in the food industry, the tyrosinase from the mushroom Agaricus bisporus has been investigated in depth. In previous studies the tyrosinase enzyme complex was shown to be a H(2)L(2) tetramer, but no clues were obtained of the identities of the subunits, their mode of association, and the 3D structure of the complex. Here we unravel this tetramer at the molecular level. Its 2.3 ? resolution crystal structure is the first structure of the full fungal tyrosinase complex. The complex comprises two H subunits of ～392 residues and two L subunits of ～150 residues. The H subunit originates from the ppo3 gene and has a fold similar to other tyrosinases, but it is ～100 residues larger. The L subunit appeared to be the product of orf239342 and has a lectin-like fold. The H subunit contains a binuclear copper-binding site in the deoxy-state, in which three histidine residues coordinate each copper ion. The side chains of these histidines have their orientation fixed by hydrogen bonds or, in the case of His85, by a thioether bridge with the side chain of Cys83. The specific tyrosinase inhibitor tropolone forms a pre-Michaelis complex with the enzyme. It binds near the binuclear copper site without directly coordinating the copper ions. The function of the ORF239342 subunits is not known. Carbohydrate binding sites identified in other lectins are not conserved in ORF239342, and the subunits are over 25 ? away from the active site, making a role in activity unlikely. The structures explain how calcium ions stabilize the tetrameric state of the enzyme.     

Free‐Radical‐Scavenging,Antityrosinase, and Cellular Melanogenesis Inhibitory Activities of Synthetic Isoflavones

In this study, we examined the potential of synthetic isoflavones for application in cosmeceuticals. Twenty‐five isoflavones were synthesized and their capacities of free‐radical‐scavenging and mushroom tyrosinase inhibition, as well as their impact on cell viability of B16F10 murine melanoma cells and HaCaT human keratinocytes were evaluated. Isoflavones that showed significant mushroom tyrosinase inhibitory activities were further studied on reduction of cellular melanin formation and antityrosinase activities in B16F10 melanocytes in vitro. Among the isoflavones tested, 6‐hydroxydaidzein ( 2 ) was the strongest scavenger of both ABTS ^{. +} and DPPH ^. radicals with SC₅₀ values of 11.3±0.3 and 9.4±0.1 μM , respectively. Texasin ( 20 ) exhibited the most potent inhibition of mushroom tyrosinase (IC₅₀ 14.9±4.5 μM ), whereas retusin ( 17 ) showed the most efficient inhibition both of cellular melanin formation and antityrosinase activity in B16F10 melanocytes, respectively. In summary, both retusin ( 17 ) and texasin ( 20 ) exhibited potent free‐radical‐scavenging capacities as well as efficient inhibition of cellular melanogenesis, suggesting that they are valuable hit compounds with potential for advanced cosmeceutical development.     

(−)-N-Formylanonaine from Michelia alba as a human tyrosinase inhibitor and antioxidant

Tyrosinase is the first and rate limiting enzyme in the synthesis of melanin pigments for coloring hair, skin, and eyes. As reported in this study, a natural product, (?)-N-formylanonaine isolated from the leaves of Michelia alba D.C. (Magnolianceae), was found to inhibit mushroom tyrosinase with an IC₅₀ of 74.3 μM and to have tyrosinase and melanin reducing activities in human epidermal melanocytes without apparent cytotoxicity to human cells, superior to the known tyrosinase inhibitors, such as kojic acid and 1-phenyl-2-thiourea (PTU). Based on homology modeling, the compound binds the active site by coordinating with two Cu²⁺ ions. In addition, the compound had antioxidation activities in tests for scavenging 1,1-diphenyl-2-picrylhydrazyl (DPPH), reducing power, and chelating metal ions. To our knowledge, this is the first study to reveal the bioactivities of (?)-N-formylanonaine from this plant species.     

Repeated-batch fermentation using flocculent hybrid, <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> CHFY0321 for efficient production of bioethanol

A new tyrosinase was isolated from Aeromonas media strain WS and purified to homogeneity. The purified tyrosinase, termed TyrA, had a molecular mass of 58 kDa and an isoelectric point of 4.90. It exhibited optimal monophenol and diphenol oxidase activities under basic conditions (pH > 8.0). TyrA had a relatively higher affinity to diphenol substrate l-dihydroxyphenylalanine (l-dopa) than many other tyrosinases. EDTA or glutathione notably inhibited the enzymatic activities of TyrA, whereas Triton X-100 and SDS activated them. The full-length TyrA gene was cloned, and it encodes a 518 amino acid protein with little similarities to other reported tyrosinases. However, the purified recombinant TyrA expressed in Escherichia coli demonstrated tyrosinase activity. These results suggest that TyrA is the first reported distinct tyrosinase involved in melanin production in the genus Aeromonas.     

Identification of active site residues involved in metal cofactor binding and stereospecific substrate recognition in Mammalian tyrosinase. Implications to the catalytic cycle.

Tyrosinase (Tyr) and tyrosinase-related proteins (Tyrps) 1 and 2 are the enzymes responsible for mammalian melanogenesis. They display high similarity but different substrate and reaction specificities. Loss-of-function mutations lead to several forms of albinism or other pigmentation disorders. They share two conserved metal binding sites (CuA and CuB) which, in Tyr, bind copper. To define some structural determinants for these differences, we mutated Tyr at selected residues on the basis of (i) conservation of the original residues in most tyrosinases, (ii) their nonconservative substitution in the Tyrps, and (iii) their possible involvement as an endogenous bridge between the copper pair. Two mutations at the CuA site, S192A and E193Q, did not affect Tyr activities, thus excluding S192 and E193 as endogenous ligands of the copper pair. Concerning CuB, the H390Q mutation completely abolished Tyr activity, whereas Q378H and H389L mutants showed 10-20% residual specific activities. Their kinetic behavior suggests that (i) H390 is the actual third ligand for CuB, (ii) H389 is critical for stereospecific recognition of o-diphenols but not monophenols, and (iii) the involvement in metal binding of the central extra H residue at the Tyrps CuB site is unlikely. However, replacement of Q (in Tyr) by H (in Tyrps) greatly diminished the affinity for L-dopa, consistent with the low/null tyrosinase activity of the Tyrps. These are the first data showing a physical difference in docking of mono- and o-diphenols to the Tyr active site, and they are used to propose a revised scheme of the catalytic cycle.     

A novel synthetic compound, (Z)-5-(3-hydroxy-4-methoxybenzylidene)-2-iminothiazolidin-4-one (MHY773) inhibits mushroom tyrosinase

As part of continued efforts for the development of new tyrosinase inhibitors, (Z)-5-(substituted benzylidene)-2-iminothiazolidin-4-one derivatives (1a – 1l) were rationally synthesized and evaluated for their inhibitory potential in vitro. These compounds were designed and synthesized based on the structural attributes of a β-phenyl-α,β-unsaturated carbonyl scaffold template. Among these compounds, (Z)-5-(3-hydroxy-4-methoxybenzylidene)-2-iminothiazolidin-4-one (1e, MHY773) exhibited the greatest tyrosinase inhibition (IC₅₀ = 2.87 μM and 8.06 μM for monophenolase and diphenolase), and outperformed the positive control, kojic acid (IC₅₀ = 15.59 and 31.61 μM). The kinetic and docking studies demonstrated that MHY773 interacted with active site of tyrosinase. Moreover, a melanin quantification assay demonstrated that MHY773 attenuates α-melanocyte-stimulating hormone (α-MSH) and 3-isobutyl-1-methylxanthine (IBMX)-induced melanin contents in B16F10 melanoma cells. Taken together, these data suggest that MHY773 suppressed the melanin production via the inhibition of tyrosinase activity. MHY773 is a promising for the development of effective pharmacological and cosmetic agents for skin-whitening.     

Tyrosinase inhibition and anti-melanin generation effect of cinnamamide analogues

Abnormal melanogenesis results in excessive production of melanin, leading to pigmentation disorders. As a key and rate-limiting enzyme for melanogenesis, tyrosinase has been considered an important target for developing therapeutic agents of pigment disorders. Despite having an (E)-β-phenyl-α,β-unsaturated carbonyl scaffold, which plays an important role in the potent inhibition of tyrosinase activity, cinnamic acids have not attracted attention as potential tyrosinase inhibitors, due to their low tyrosinase inhibitory activity and relatively high hydrophilicity. Given that cinnamic acids’ structure intrinsically features this (E)-scaffold and following our experience that minute changes in the chemical structure can powerfully affect tyrosinase activity, twenty less hydrophilic cinnamamide derivatives were designed as potential tyrosinase inhibitors and synthesised using a Horner-Wadsworth-Emmons reaction. Four of these cinnmamides (4, 9, 14, and 19) exhibited much stronger mushroom tyrosinase inhibition (over 90% inhibition) at 25 µM compared to kojic acid (20.57% inhibition); crucially, all four have a 2,4-dihydroxy group on the β-phenyl ring of the scaffold. A docking simulation using tyrosinase indicated that the four cinnamamides exceeded the binding affinity of kojic acid, and bound more strongly to the active site of tyrosinase. Based on the strength of their tyrosinase inhibition, these four cinnamamides were further evaluated in B16F10 melanoma cells. All four cinnamamides, without cytotoxicity, exhibited higher tyrosinase inhibitory activity (67.33 – 79.67% inhibition) at 25 μM than kojic acid (38.11% inhibition), with the following increasing inhibitory order: morpholino (9) = cyclopentylamino (14) < cyclohexylamino (19) < N-methylpiperazino (4) cinnamamides. Analysis of tyrosinase activity and melanin content in B16F10 cells showed that the four cinnamamides dose-dependently inhibited both cellular tyrosinase activity and melanin content and that their inhibitory activity at 25 μM was much better than that of kojic acid. The results of melanin content analysis well matched those of the cellular tyrosinase activity analysis, indicating that tyrosinase inhibition by the four cinnamamides is a major factor in the reduction of melanin production. These results imply that these four cinnamamides with a 2,4-dihydroxyphenyl group can act as excellent anti-melanogenic agents in the treatment of pigmentation disorders.     

Changes in tyrosinase specificity by ionic liquids and sodium dodecyl sulfate

Tyrosinase is a member of the type 3 copper enzyme family involved in the production of melanin in a wide range of organisms. The ability of tyrosinases to convert monophenols into diphenols has stimulated studies regarding the production of substituted catechols, important intermediates for the synthesis of pharmaceuticals, agrochemicals, polymerization inhibitors, and antioxidants. Despite its enormous potential, the use of tyrosinases for catechol synthesis has been limited due to the low monophenolase/diphenolase activity ratio. In the presence of two water miscible ionic liquids, [BMIM][BF₄] and ethylammonium nitrate, the selectivity of a tyrosinase from Bacillus megaterium (TyrBm) was altered, and the ratio of monophenolase/diphenolase activity increased by up to 5-fold. Furthermore, the addition of sodium dodecyl sulphate (SDS) at levels of 2–50 mM increased the activity of TyrBm by 2-fold towards the natural substrates l-tyrosine and l-Dopa and 15- to 20-fold towards the non-native phenol and catechol. The R209H tyrosinase variant we previously identified as having a preferential ratio of monophenolase/diphenolase activity was shown to have a 45-fold increase in activity towards phenol in the presence of SDS. We propose that the effect of SDS on the ability of tyrosinase to convert non-natural substrates is due to the interaction of surfactant molecules with residues located at the entrance to the active site, as visualized by the newly determined crystal structure of TyrBm in the presence of SDS. The effect of SDS on R209 may enable less polar substrates such as phenol and catechol, to penetrate more efficiently into the enzyme catalytic pocket.     

Cloning and molecular characterization of a SDS-activated tyrosinase from Marinomonas mediterranea

The sequence of the tyrosinase gene cloned from Marinomonas mediterranea is reported. It is the second tyrosinase cloned from a Gram negative bacterium. Its size is higher than that of Gram positive tyrosinases from Streptomyces, and more similar to the eukaryotic enzymes. Its sequence shares the features of copper-binding sites found in all tyrosinases. Based in the comparison of tyrosinases from all types of organisms, an extension of the characteristic signatures existing at Prosite is proposed. This tyrosinase shares with some plant and amphibian tyrosinases a strong specific activation by submicellar concentrations of SDS. Intrinsic fluorescence and kinetic properties indicate that the activation is caused by an SDS-dependent conformational change that facilitates the substrate accessibility to the dicopper active site.     

The existence of apotyrosinase in the cytosol of Harding-Passey mouse melanoma melanocytes and characteristics of enzyme reconstitution by Cu(II)

This paper reports the effect of Cu(II) supplementation on the tyrosinase isozymes from Harding-Passey mouse melanoma. The dopa-oxidase activity of the microsomal and soluble isozymes is increased by incubation with Cu(II), whereas the activity of the unique 'in vivo' melanin-forming isozyme, bound to melanosomes, is not. Other divalent cations are ineffective in increasing the dopa-oxidase activity of tyrosinases. These results indicate the existence of a mixture of tyrosinase and apotyrosinase in the cytosol of melanocytes before reaching the melanosome. The paucity of Cu(II) in the cytosol could be one of the mechanisms of regulation contributing to avoid the formation of melanin outside the melanosome. Some kinetic characteristics of the enzymatic reconstitution of soluble and microsomal isozymes by Cu(II) are also studied, and the results suggest that the glycosylation of apotyrosinase during its maturation yields a conformational change favouring the binding of Cu(II) at the enzyme active site, by lowering the activation energy of the reconstitution reaction.