Enzymes melanin synthesis

The pathway of melanin synthesis starts from the amino acid tyrosine (Fig. 1). The first two reactions are catalyzed by the copper-containing enzyme tyrosinase (EC 1.14.18.1). Tyrosine is hydroxylated to 3,4-dihy-... 

Polyphenol oxidase occurs within certain mammalian tissues as well as both lower (46,47) and higher (48-55) plants. In mammalian systems, the enzyme as tyrosinase (56) plays a significant role in melanin synthesis. The PPO complex of higher plants consists of a cresolase, a cate-cholase and a laccase. These copper metalloproteins catalyze the one and two electron oxidations of phenols to quinones at the expense of 02. Polyphenol oxidase also occurs in certain fungi where it is involved in the metabolism of certain tree-synthesized phenolic compounds that have been implicated in disease resistance, wound healing, and anti-nutrative modification of plant proteins to discourage herbivory (53,55). This protocol presents the Triton X-114-mediated solubilization of Vida faba chloroplast polyphenol oxidase as performed by Hutcheson and Buchanan (57). 

Melanin Synthesis. Tyrosinase is a copper-containing enzyme that is present in melanocytes and catalyzes the synthesis of melanin. Starting with L-dopa as a substrate, tyrosi-... 

Biochemical basis of hypopigmentation Phenylalanine is competitive inhibitor of tyrosinase (key enzyme in melanin synthesis)... 

Epidermal melanin synthesis is a multistage process involving fast or slow reactions, some of which are enzyme catalyzed, others requiring only oxygen. The process is controlled by pH, temperature, redox... 

Because both tryptophan and tyrosine participate in melanogenic processes, the possible influence of different enzymes like tyrosinase, tryptophan pyrrolase (TP), indoleamine 2,3-dioxygenase (lOD), and tyrosine aminotransferase (TAT) on the regulation of melanin synthesis as it relates to vitiligo has been depicted in Fig. 8, which constitutes a modification of the Raper-Mason scheme for melanin synthesis (53, 54). 

Tyrosine is either used for the biosynthesis of proteins, thyroxine, epinephrine, or melanin, or catabo-lized to yield fumaryl acetoacetate. The biosynthesis of proteins and thyroxine is discussed elsewhere this discussion is restricted to epinephrine and melanin synthesis and tyrosine catabolism. Dopa 3,4-dihydroxy-phenylalanine is an intermediate common to epinephrine and melanin. To yield epinephrine, dopa is first decarboxylated by an enzyme called dopa decarboxylase. This enzyme is present in several mammalian tissues, including the adrenal medulla, where the reaction yields hydroxytryptamine chloride. From this... 

Melanoma can be diagnosed throngh the monitoring of tyrosinase, a cytoplasmic melanocyte differentiation protein, which is a key enzyme in melanin synthesis and has been listed as important melanoma biomarker. Mossberg et al. (2014) developed an electrochemical biosensor platform with an amperometric detection mode to detect the enzymatic activity of tyrosinase in fresh biopsy samples withont pretreatment of the samples. The combination of this method with modem portable devices can provide interesting POC sensors in the fnture. 

This enzyme exhibits no hydroxylase activity and is involved in the final synthesis of many naturally occurring /t-quinoncs. e.g. the naphthaquinone juglone in walnut (1.58) and the benzoquinone arbutin (hydroquinone-(3-D-glucopyranoside 2.46). Arbutin is a plant cryo-protectant that stabilizes membranes (Hincha et al., 1999). This compound has medicinal properties and has, for example, been used to treat urinary tract infections in humans. It is also used to lighten skin color, because it inhibits tyrosinase and hence the formation of melanin. The derivative deoxyarbutin (2.47 note the difference in the sugar molecule) was recently reported to be considerably more effective as a skin-lightening compound (Boissy et al., 2005). 

Oxidative coupling polymerization provides great utility for the synthesis of high-performance polymers. Oxidative polymerization is also observed in vivo as important biosynthetic processes that, when catalyzed by metalloenzymes, proceed smoothly under an air atmosphere at room temperature. For example, lignin, which composes 30% of wood tissue, is produced by the oxidative polymerization of coniferyl alcohol catalyzed by laccase, an enzyme containing a copper complex as a reactive center. Tyrosine is an a-amino acid and is oxidatively polymerized by tyrosinase (Cu enzyme) to melanin, the black pigment in animals. These reactions proceed efficiently at room temperature in the presence of 02 by means of catalysis by metalloenzymes. Oxidative polymerization is observed in vivo as an important biosynthetic process that proceeds efficiently by oxidases. 

Enzymes present in melanosomes synthesize two types of melanin, eumelanin and pheomelanin. Figure 2 illustrates the proposed biosynthetic pathways of eumelanin and pheomelanin. The synthesis of eumelanin requires tyrosinase, an enzyme located in melanosomes. Tyrosinase catalyzes the conversion of tyrosine to dopa, which is further oxidized to dopaquinone. Through a series of enzymatic and nonenzymatic reactions, dopaquinone is converted to 5,6-indole quinone and then to eumelanin, a polymer. This polymer is always found attached to proteins in mammalian tissues, although the specific linkage site between proteins and polymers is unknown. Polymers affixed to protein constitute eumelanin, but the exact molecular structure of this complex has not been elucidated. Pheomelanin is also synthesized in melanosomes. The initial steps in pheomelanin synthesis parallel eumelanin synthesis, since tyrosinase and tyrosine are required to produce dopaquinone. Dopaquinone then combines with cysteine to form cysteinyldopa, which is oxidized and polymerized to pheomelanin. The exact molecular structure of pheomelanin also has not been determined. 

Copper-dependent enzymes include tyrosinase (which is involved in melanin pigment formation) and the various oxidases (i.e., cytochrome oxidase, superoxide dismutase, amine oxidase, and uricase). Copper plays a major role in the incorporation of iron into the heme of hemoglobin. Copper deficiency is characterized by hypochromic, microcytic anemia resulting from defective hemoglobin synthesis. 

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