Mechanistic aspects of the tyrosinase oxidation of hydroquinone

Contradictory reports on the behaviour of hydroquinone as a tyrosinase substrate are reconciled in terms of the ability of the initially formed ortho-quinone to tautomerise to the thermodynamically more stable para-quinone isomer. Oxidation of phenols by native tyrosinase requires activation by in situ formation of a catechol formed via an enzyme generated ortho-quinone. In the special case of hydroquinone, catechol formation is precluded by rapid tautomerisation of the ortho-quinone precursor to catechol formation.     

The effect of thiobarbituric acid on tyrosinase: inhibition kinetics and computational simulation

Tyrosinase plays various roles in organisms and much research has focused on the regulation of tyrosinase activity. We studied the inhibitory effect of thiobarbituric acid (TBA) on tyrosinase. Our kinetic study showed that TBA inhibited tyrosinase in a reversible noncompetitive manner (K(i) 5 14.0 ± 8.5 mM and IC?? 5 8.0 ± 1.0 mM). Intrinsic and ANS-binding fluorescences studies were also performed to gain more information regarding the binding mechanism. The results showed that no tertiary structural changes were obviously observed. For further insight, we predicted the 3D structure of tyrosinase and simulated the docking between tyrosinase and TBA. The docking simulation was successful with significant scores (binding energy for AutoDock4: -5.52 kcal/mol) and suggested that TBA was located in the active site. The 11 ns molecular dynamics simulation convinced that the four HIS residues (residue numbers: 57, 90, 250, and 282) were commonly responsible for the interaction with TBA. Our results provide a new inhibition strategy that works using an antioxidant rather than targeting the copper ions within the tyrosinase active site.     

The effect of fucoidan on tyrosinase: computational molecular dynamics integrating inhibition kinetics

Fucoidan is a complex sulfated polysaccharide extracted from brown seaweed and has a wide variety of biological activities. In this study, we investigated the inhibitory effect of fucoidan on tyrosinase via a combination of inhibition kinetics and computational simulations. Fucoidan reversibly inhibited tyrosinase in a mixed-type manner. Time-interval kinetics showed that the inhibition was processed as first order with biphasic processes. For further insight, we simulated dockings with various sizes of molecular models (monomer to decamer) of fucoidan and showed that the best binding energy change results were obtained from the pentamer (-1.89?kcal/mol) and the hexamer (-1.97?kcal/mol) models of AutoDock Vina. The molecular dynamics simulation confirmed the binding mechanisms between tyrosinase and fucoidan and suggested that fucoidan mostly interacts with several residues including copper ions located in the active site. Our study suggests that fucoidan might be a potential natural antipigment agent.     

The effect of fucoidan on tyrosinase: computational molecular dynamics integrating inhibition kinetics

Fucoidan is a complex sulfated polysaccharide extracted from brown seaweed and has a wide variety of biological activities. In this study, we investigated the inhibitory effect of fucoidan on tyrosinase via a combination of inhibition kinetics and computational simulations. Fucoidan reversibly inhibited tyrosinase in a mixed-type manner. Time-interval kinetics showed that the inhibition was processed as first order with biphasic processes. For further insight, we simulated dockings with various sizes of molecular models (monomer to decamer) of fucoidan and showed that the best binding energy change results were obtained from the pentamer (?1.89?kcal/mol) and the hexamer (?1.97?kcal/mol) models of AutoDock Vina. The molecular dynamics simulation confirmed the binding mechanisms between tyrosinase and fucoidan and suggested that fucoidan mostly interacts with several residues including copper ions located in the active site. Our study suggests that fucoidan might be a potential natural antipigment agent.     

Inactivation kinetics of mushroom tyrosinase by cetylpyridinium chloride

Cetylpyridinium chloride (CPC) was found to inactivate tyrosinase from mushroom (Agaricus bisporus). CPC can bind to the enzyme molecule and induce the enzyme conformation changes. The fluorescence intensity (at 338.4 nm) of the enzyme decreased distinctly with increasing CPC concentrations, and a new little fluorescence emission peak appeared near 372 nm. The inactivation of the enzyme by CPC had first been studied by using the kinetic method of the substrate reaction described by Tsou. The results showed that the enzyme was inactivated by a complex mechanism that had not been previously identified. The enzyme first quickly binds with CPC reversibly and then undergoes a slow irreversible inactivation. The inactivation reaction is a single molecule reaction and the apparent inactivation rate constant is a saturated trend being independent of CPC concentration if the concentration is sufficiently high. The micro rate constants of inactivation and the association constant were determined.     

The inhibition kinetics and thermodynamic changes of tyrosinase via the zinc ion

We found that Zn(2+) conspicuously inactivated tyrosinase in a mixed-type inhibition manner: the final level of residual activity was abolished at the equilibrium state with concentration of 0.25 mM Zn(2+). Changes of both K(m) and V(max) by various concentrations of Zn(2+) in Lineweaver-Burk plot were observed. To see whether Zn(2+) also induced conformational change of tyrosinase and how thermodynamical changes by ligand binding were occurred, the intrinsic fluorescence studies as well as calorimetric measurements were conducted. The results showed that the Zn(2+) binding to tyrosinase directly induced conformational change of tyrosinase, and the changes of thermodynamic parameters such as enthalpy (DeltaH), Gibbs free-energy (DeltaG), and entropy (DeltaS) were obtained as 60+/-7.0 kJ/mol, -14.54 kJ/mol and 248.53 J/(K mol), respectively. The inactivating effect of Zn(2+) on tyrosinase was completely prevented by incubation with bovine serum albumin, which has a Zn(2+) binding motif in its structure. We suggested that Zn(2+) ligand-binding affected the substrate's accessibility due to the conformational changes and thus, the complex type of inhibition has occurred with the calorimetric changes.     

Effects of isorhamnetin on tyrosinase: inhibition kinetics and computational simulation

We studied the inhibitory effects of isorhamnetin on mushroom tyrosinase by inhibition kinetics and computational simulation. Isorhamnetin reversibly inhibited tyrosinase in a mixed-type manner at Ki=0.235±0.013 mM. Measurements of intrinsic and 1-anilinonaphthalene-8-sulfonate(ANS)-binding fluorescence showed that isorhamnetin did not induce significant changes in the tertiary structure of tyrosinase. To gain insight into the inactivation process, the kinetics were computed via time-interval measurements and continuous substrate reactions. The results indicated that inactivation induced by isorhamnetin was a first-order reaction with biphasic processes. To gain further insight, we simulated docking between tyrosinase and isorhamnetin. Simulation was successful (binding energies for Dock6.3: -32.58 kcal/mol, for AutoDock4.2: -5.66 kcal/mol, and for Fred2.2: -48.86 kcal/mol), suggesting that isorhamnetin interacts with several residues, such as HIS244 and MET280. This strategy of predicting tyrosinase interaction in combination with kinetics based on a flavanone compound might prove useful in screening for potential natural tyrosinase inhibitors.     

Effects of boldine on tyrosinase: Inhibition kinetics and computational simulation

Boldine is one of the most potent natural antioxidants and displays some important pharmacological activities, such as cytoprotective and anti-inflammatory activities. Based on its antioxidant properties, we studied the effects of boldine on l-DOPA oxidation by evaluating the inhibitory kinetics and a computational simulation between boldine and tyrosinase. Boldine reversibly inhibited tyrosinase from mushroom (Agaricus bisporus) in a mixed-type manner, with a K_i = 7.203 ± 0.933 mM. To gain insight into the inactivation process, we computed the kinetics via time-interval measurements and continuous substrate reactions. The results indicated that the inactivation induced by boldine was a first-order reaction with biphasic processes and that the substrate can promote the inactivation process. To gain further insight, we performed computational docking and molecular dynamics simulations, and the results showed that boldine can interact with several residues near the tyrosinase active site. Our study provides insight into the inhibition of tyrosinase in response to alkaloids. Based on its tyrosinase-inhibiting effect and low toxicity, boldine is a potential natural anti-pigmentation agent.     

Inhibition kinetics of mushroom tyrosinase by copper-chelating ammonium tetrathiomolybdate

With a strategy of chelating coppers at tyrosinase active site to detect an effective inhibitor, several copper-specific chelators were applied in this study. Ammonium tetrathiomolybdate (ATTM) among them, known as a drug for treating Wilson's disease, turned out to be a significant tyrosinase inhibitor. Treatment with ATTM on mushroom tyrosinase completely inactivated enzyme activity in a dose-dependent manner. Progress-of-substrate reaction kinetics using the two-step kinetic pathway and dilution of the ATTM revealed that ATTM is a tight-binding inhibitor and high dose of ATTM irreversibly inactivated tyrosinase. Progress-of-substrate reaction kinetics and activity restoration with a dilution of the ATTM indicated that the copper-chelating ATTM may bind slowly but reversibly to the active site without competition with substrate, and the enzyme-ATTM complex subsequently undergoes reversible conformational change, leading to complete inactivation of the tyrosinase activity. Thus, inhibition by ATTM on tyrosinase could be categorized as complexing type of inhibition with a slow and reversible binding. Detailed analysis of inhibition kinetics provided IC50 at the steady-state and inhibitor binding constant (K(I)) for ATTM as 1.0+/-0.2 microM and 10.65 microM, respectively. Our results may provide useful information regarding effective inhibitor of tyrosinase as whitening agents in the cosmetic industry.     

The influence of micelle formation on lipoxygenase kinetics.

The effects of a series of n-alcohols and n-carboxylic acids on lipoxygenase activity was studied. It was shown that to a large extent the effects of these compounds could be ascribed to physiochemical interaction with the substrate solution rather than a direct action on the enzyme itself. The effect of better substrate analogues such as stearate and oleate could also be ascribed to this effect. A type-2 lipoxygenase was found to have a very unusual velocity-substrate relationship which could be normalized by addition of calcium chloride in amounts stoichiometric with the substrate. An excess of calcium inhibited the enzyme. By comparison of results with linoleoyl sulphate/linoleoyl alcohol mixed micelles, an explanation for this unusual velocity-substrate activity is presented.     

The influence of high substrate concentrations on microbial kinetics

High substrate concentrations inhibit growth and may distort the metabolism of microorganisms. Mechanisms causing substrate inhibition are discussed and used to derive several mathematical models representative of the entire concentration range, including stimulation of growth by low substrate concentrations. These kinetic models are tested with a variety of batch culture measurements of specific growth rate and respiration rate at widely-ranging substrate concentrations. Using one of the kinetic models, equations are developed for batch, continuous, and exponential-feed reactors. Comparison of results obtained in continuous culture with results from exponential-feed culture systems is shown to offer a novel experimental method for evaluating the effect of the cell age distribution on the properties and metabolic activity of a culture.     

Effect of hesperetin on tyrosinase: inhibition kinetics integrated computational simulation study

Tyrosinase inhibitors have potential applications in medicine, cosmetics and agriculture to prevent hyperpigmentation or browning effects. Some of the flavonoids mostly found in herbal plants and fruits are revealed as tyrosinase inhibitors. We studied the inhibitory effects of one such flavonoid, hesperetin, on mushroom tyrosinase using inhibition kinetics and computational simulation. Hesperetin reversibly inhibited tyrosinase in a competitive manner with K_i = 4.03 ± 0.26 mM. Measurements of ANS-binding fluorescence showed that hesperetin induced the hydrophobic disruption of tyrosinase. For further insight, we used the docking algorithms to simulate binding between tyrosinase and hesperetin. Simulation was successful (binding energies for Dock6.3: −34.41 kcal/mol and for AutoDock4.2: −5.67 kcal/mol) and showed that a copper ion coordinating with 3 histidine residues (HIS61, HIS85, and HIS259) within the active site pocket was chelated via hesperetin binding. Our study provides insight into the inhibition of tyrosinase in response to flavonoids. A combination of inhibition kinetics and computational prediction may facilitate the identification of potential natural tyrosinase inhibitors such as flavonoids and the prediction of their inhibitory mechanisms.     

Effect of Cl- on tyrosinase: complex inhibition kinetics and biochemical implication

Tyrosinase plays a core role in melanogenesis of the various organisms. Therefore, the regulation of the tyrosinase activity is directly related with melanin synthesis. In this study, we investigated the Cl(-)-induced inhibition of human tyrosinase and the potent role of Cl(-) as a negative regulator in melanogenesis. For the inhibition kinetic studies, human tyrosinase was differently prepared from the TXM13 melanotic cells as well as from cells that had undergone gene transfection. We found that Cl(-) inhibited tyrosinase in a slope-parabolic competitive manner and tyrosinase gene transfection into HEK293 cell significantly down-regulated the expression levels of solute carrier family 12, member 4 (potassium/chloride transporters, SLC12A7) and solute carrier family 12, member 7 (potassium/chloride transporters, SLC12A7), which are known to be Cl(-) transporters. From the results of the inhibition kinetic studies and the Cl(-) transporter expression level, we suggested that Cl(-) might act as a potent regulatory factor in melanogenesis. It is worth notice that a high content of Cl(-) exists physiologically and tyrosinase reacts sensitively to Cl- in a complex interaction manner.     

Inactivation kinetics of mushroom tyrosinase in the dimethyl sulfoxide solution

Mushroom tyrosinase (EC 1.14.18.1) is a kind of copper-containing oxidase that catalyzes both the hydroxylation of tyrosine into o-diphenols and the oxidation of o-diphenols into o-quinones and then forms brown or black pigments. In the present paper, the effects of dimethyl sulfoxide on the enzyme activity for the oxidation of L-3,4-dihydroxyphenylalanine (L-DOPA) have been studied. The results show that low concentrations of dimethyl sulfoxide (DMSO) can lead to reversible inactivation of the enzyme, and the IC ₅₀ is estimated to be 2.45 M. Inactivation of the enzyme by DMSO is classified as mixed type. The kinetics of inactivation of mushroom tyrosinase at low concentrations of DMSO solution has been studied using the kinetic method of the substrate reaction. The rate constants of inactivation have been determined. The results show the free enzyme molecule is more fragile than the enzyme–substrate complex in the DMSO solution. It is suggested that the presence of the substrate offers marked protection of this enzyme against inactivation by DMSO.     

Effects of piperonylic acid on tyrosinase: Mixed-type inhibition kinetics and computational simulations

Piperonylic acid is a natural molecule with a benzoic acid group and high antioxidant capacity. Based on its aromatic acid structure and antioxidant properties, we studied the effects of piperonylic acid on tyrosinase by the analysis of its inhibitory kinetics and computational simulations. Piperonylic acid reversibly inhibited tyrosinase through a mixed-type inhibitory mechanism. The time courses of the tyrosinase inhibition showed that piperonylic acid binds to tyrosinase very quickly and the inactivation processes follow first-order kinetics. The continuous substrate reactions indicated that piperonylic acid induced a tight-binding inhibition and the substrate can promote the inactivation process. The ANS-binding fluorescence of tyrosinase suggested that piperonylic acid did not detectably disrupt the tertiary structure of the enzyme. The results of the computational docking and molecular dynamics simulations showed that piperonylic acid closely interacts with three residues and it might block the active site of tyrosinase.     

The effect of histidine residue modification on tyrosinase activity and conformation: inhibition kinetics and computational prediction

We found that the histidine chemical modification of tyrosinase conspicuously inactivated enzyme activity. The substrate reactions with diethylpyridinecarbamate showed slow-binding inhibition kinetics (K(I) = 0.24 +/- 0.03 mM). Bromoacetate, as another histidine modifier, was also applied in order to study inhibition kinetics. The bromoacetate directly induced the exposures of hydrophobic surfaces following by complete inactivation via ligand binding. For further insights, we predicted the 3D structure of tyrosinase and simulated the docking between tyrosinase and diethylpyridinecarbamate. The docking simulation was shown to the significant binding energy scores (-3.77 kcal/mol by AutoDock4 and -25.26 kcal/mol by Dock6). The computational prediction was informative to elucidate the role of free histidine residues at the active site, which are related to substrate accessibility during tyrosinase catalysis.     

Selective cytotoxicity of hydroquinone for melanocyte-derived cells is mediated by tyrosinase activity but independent of melanin content

In previous studies we have shown melanotic melanomas to be exquisitely more sensitive to hydroquinone (HQ) inhibition than non-melanotic cell lines in vitro. Indeed, incorporation of [H3] Urd and [H3] Thd have been shown to be respectively 80 and 35 times more sensitive to HQ inhibition. The difference between the cell lines studied was their derivation, marked by their different melanin contents. The presence of melanin was proposed as a possible explanation of the differences. However, comparative experiments reported here demonstrate that amelanotic melanoma cell lines are equally susceptible to HQ inhibition. Thus, the action of HQ is apparently independent of the melanin content of the cell. Significantly, the tyrosinase levels in the melanomas and the amelanomas were found to be comparable and markedly different from that in the non-melanoma control cell lines. Thus, the results reported here support the hypothesis put forward by other workers that hydroquinone melanotoxicity is independent of cellular melanin content but requires the presence of active tyrosinase.     

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.