J.A. Lozano

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

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

Kinetic study of the pathway of melanizationn between l-dopa and dopachrome

Abstract The first part of the melanization pathway from l -dopa to dopachrome has been studied as a system of various chemical reactions coupled by an enzymatic reaction. A theoretical and experimental kinetic approach is proposed for such a system. Rate constants for the implicated chemical steps at different pH and temperature values can be evaluated from measurement of the lag period arising from the accumulation of dopachrome that takes place when l -Dopa was oxidized at acid pH. The thermodynamic parameters of the chemical steps, the deprotonation of dopaquinone-H + into dopaquinone and the internal cyclization of dopaquinone into leukodopachrome, have been obtained. From the results presented, an alternative series of chemical reactions to the Raper-Mason scheme are proposed and discussed.

Kinetic study on the suicide inactivation of tyrosinase induced by catechol

Tyrosinase has a suicide inactivation reaction when it acts on omicron-diphenols. In the present paper, this reaction has been studied using a transient phase approach. Explicit equations of product vs. time have been developed for the multisubstrate mechanism of tyrosinase, and the kinetic parameters which characterize the enzyme acting on the suicide substrate catechol have been determined. The effect of pH has also been considered.

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.

A new spectrophotometric assay for dopachrome tautomerase

The existence of a new enzyme involved in mammalian melanogenesis has been recently reported. The names dopachrome oxidoreductase and dopachrome tautomerase have been proposed for the enzyme. So far, this enzyme has been assayed at 475 nm on the basis of its ability to catalyze dopachrome decoloration. This method presents two major problems, derived from the instability of the substrate (dopachrome): (1) dopachrome must be prepared immediately before use, and (2) the rate of dopachrome decoloration in the absence of the enzyme is not negligible, and, furthermore, is enhanced by non-enzymatic agents. In order to overcome these problems, we present a new procedure that combines: (1) a quantitative, fast and easy way to prepare dopachrome from L-dopa by sodium periodate oxidation; (2) a spectrophotometric method in the UV region, at 308 nm, based on following the absorbance increase due to the enzyme-specific tautomerization of dopachrome to 5,6-dihydroxyindole-2-carboxylic acid as opposed to the absorbance decrease due to the spontaneous decarboxylative transformation of dopachrome into 5,6-dihydroxyindole. The advantages of these methods as compared to the previously used procedures are discussed.

Transient-phase kinetics of enzyme inactivation induced by suicide substrates

This paper deals with the kinetic study of reaction mechanisms with enzyme inactivation induced by a suicide substrate in the presence or absence of an auxiliary substrate and in conditions of excess of substrates in relation to the enzyme concentration and vice versa. A transient-phase approach has been developed that enables explicit equations with one or two significant exponentials to be obtained, thereby showing the dependence of product concentration on time. The validity of these equations has been checked, and a comparison made with those previously obtained by other authors. We propose an experimental design to determine the corresponding parameters and kinetic constants. The simplicity of our method allows a systematic application to more complex mechanisms.

Equilibrium between active and inactive forms of rat liver ornithine decarboxylase mediated by L-ornithine and salts

Ornithine decarboxylase Polyamine Association equilibrium Rat liver Ionic strength

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

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

Kinetic study and intermediates identification of noradrenaline oxidation by tyrosinase.

Characterization of intermediates formed in the noradrenaline oxidation by mushroom tyrosinase and sodium periodate has been performed by rapid scanning spectrophotometry and graphical analysis of obtained spectra. In a pH range from 5.0 to 6.0, it has been possible to detect o-noradrenalinequinone-H+ as the first intermediate in these oxidations. The following steps for noradrenaline transformation into noradrenochrome would be: noradrenaline----o-noradrenalinequinone-H+----o- noradrenalinequinone----leukonoradrenochrome----noradreno chrome. It has been also verified that o-noradrenalinequinone-H+ is transformed into noradrenochrome at a constant ratio. The stoichiometry for this converstion followed the equation: 2-noradrenalinequinone-H+----noradrenaline + noradrenochrome. The pathway between noradrenaline and noradrenochrome has been studied as a system of various chemical reactions coupled to an enzymatic reaction. We have denominated this type of mechanism as an enzymatic-chemical-chemical mechanism, (E2CC). Whole rate constants for the implicated chemical steps at different pH and temperature values have been evaluated from measurement of the lag period arising from the accumulation of noradrenochrome that takes place when noradrenaline was oxidized at pH 5-6. The lag period was independent on enzyme concentration, but was increased when pH and/or temperature were increased. Rate constants pH independent for the deprotonation of noradrenalinequinone-H+ into noradrenalinequinone and for the internal cyclization of noradrenalinequinone into leukonoradrenochrome have been obtained. We conclude that this minor pathway of noradrenaline oxidation by tyrosinase follows a scheme similar to that established for L-dopa.

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

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