Opiomelanins synthesis and properties.

Opiomelanins represent a new class of synthetic pigments produced by the tyrosinase-catalyzed oxidation of opioid peptides and other tyrosine aminoterminal peptides. In contrast with dopamelanin, these polymers are fully soluble in hydrophilic media, due to the presence of the peptide moiety. Opiomelanins show paramagnetism as demonstrated by the EPR spectrum identical to that of dopamelanin. The presence of the aminoacidic chain linked to the melaninic moiety, influences the electron transfer properties of opiomelanins i.e. the ability to oxidize NADH. Like dopamelanin Tyr-Gly-melanin exhibits this behaviour whereas leuenkmelanin does not show any oxidizing potential. Opiomelanins UV-Vis spectrum is characterized by an absorption band at 330 nm which disappears upon acid hydrolysis, H2O2 treatment and under simulated solar illumination. Opiomelanins exhibit a fluorescence emission peaked at 440 and 520 nm if excited at 330 nm. These fluorescence bands are due to the oligomeric units and high molecular weight units, respectively. When opioid peptides are allowed to react with tyrosinase in the presence of an excess of cysteine, cysteinyldopaenkephalins are synthesized. These peptides are furtherly oxidized giving rise to pheoopiomelanins. Reactive oxygen species also are able to oxidize non enzymatically both enkephalins and cysteinyldopaenkephalins, producing the corresponding melanin pigments.

Interaction of enkephalin derivatives with reactive oxygen species.

The oxidation of opioid peptides by tyrosinase in the presence of an excess of a thiol gives rise to cysteinyldopa derivatives. The major products arising from the reaction between Leu-enkephalin and cysteine are represented by 5-S-cysteinyldopaenkephalin (5-CDenk) and 2-S-cysteinyldopaenkephalin (2-CDenk). The interaction of 5-CDenk and 2-CDenk with reactive oxygen species (ROS) has been studied. These compounds are able to scavenge superoxide anion, hydroxyl and peroxyl radicals as well as to reduce the lipid peroxidation rate induced by ABAP. The scavenging activities in all instances are dose-dependent. In some cases CDenks are more active than compounds recognized as strong radical scavengers, such as Trolox and mannitol. As a result of the action of the Fenton system, the CDenks (as well as the Enks) are oxidized into pigmented derivatives. The possible implications of the interaction of CDenks and Enks with ROS on melanization process in Parkinson's disease are discussed.

Interaction of enkephalins with oxyradicals.

The interaction of enkephalins (leu-enkephalin and met-enkephalin) and other tyrosine amino-terminal peptides with reactive oxygen species has been investigated. All the peptides tested exhibited hydroxyl radical and superoxide anion scavenging ability and the capacity to reduce the rate of lipid peroxidation induced by 2,2'-azobis(2-amidinopropane). The scavenging activity was observed in the 0.1-1 mM concentration range. It has been observed that enkephalins underwent an oxidative modification by Fenton systems. The tyrosine amino-terminal residue was attacked by hydroxyl radical, being converted to dopa. The overall transformation produced opiomelanin pigments. This oxidative process provides evidence of a possible route for opiomelanin synthesis without any enzyme intervention.

Formation of homovanillic acid dimer by enzymatic or Fenton system - catalyzed oxidation.

Homovanillic acid is the most extensively employed reagent for the fluorometric detection of peroxidase. However, the assays based on the determination of the oxidation product of homovanillic acid do not allow a selective detection of the enzyme, because chemical or physical factors can interfere with the fluorometric determination. The aim of this work was to verify if other enzymatic or non-enzymatic systems might catalyze the homovanillic acid oxidation. The reaction was investigated by spectrophotometric and fluorometric assays; HPLC analysis was used to separate homovanillic acid from its oxidation product and to obtain information on the oxidation process. The results obtained showed that soybean lipoxygenase in the presence of hydrogen peroxide can oxidize homovanillic acid with the formation, by an o,o'-biphenyl linkage, of the corresponding dimer as the sole reaction product. The reaction followed Michaelis-Menten kinetics, for both homovanillic acid and hydrogen peroxide. Other systems, such as cytochrome c/H(2)O(2) and Fenton reagents, were also able to oxidize homovanillic acid to its dimer. It can be affirmed that possible interference by other oxidative systems - that could be present in the biological materials tested - should be considered in assays of peroxidase activity based on the detection of the dimer of homovanillic acid.

Cysteinyldopaenkephalins: synthesis, characterization and binding to bovine brain opioid receptors.

The reaction of opioid peptides with mushroom tyrosinase in the presence of an excess of a thiol compound gives rise to cysteinyldopaenkephalins (CDEnks). The major product is represented by the 5-S-CDEnk (80%) and the minor one by the isomer 2-S-CDEnk (20%). The adducts between leucine-enkephalin (Leu-enk) and cysteine have been isolated by high performance liquid chromatography (HPLC) and identified by amino acid analysis and electrospray ion mass spectrometry. 5-S-CDEnk is able to bind to opioid receptors in bovine brain membranes. Its binding affinity is higher for delta than for mu receptors and about 8-fold lesser than that exploited by Leu-enk. In the presence of the peroxidase/H(2)O(2) system, CDEnks can be converted into the corresponding pheo-opiomelanins.

Fluorescence properties of melanins from opioid peptides.

Recently our group synthesized a new class of melanins obtained by the tyrosinase-catalyzed oxidation of opioid peptides (opiomelanins). Owing to the presence of the peptide moiety such pigments exhibit high solubility in hydrophilic solvents, which allows spectroscopic investigations. In particular, the absence of solid-state quenching effects enables the study of melanin fluorescence properties, till now poorly investigated due to the complete insolubility of melanins produced from tyrosine or Dopa. Opiomelanins dissolved in aqueous medium show a characteristic emission peaked at 440 and 520 nm when excited around 330 nm, where a maximum is observed in the absorption spectrum. Kinetic measurements performed on the tyrosinase-catalyzed oxidation of opioid peptides show that the 440-nm fluorescence band arises in the early stages of peptide oxidation, whereas the 520-nm band appears in later stages of oxidation, i.e., during the polymerization of indole-quinone units. Moreover, molecular sieve fractionation shows that in the opiomelanin fraction with a molecular weight lower than 10 kDa the 440-nm band is dominant in the fluorescence spectrum. The breakdown of the polymer induced by hydrogen peroxide and light (i.e., the photobleaching of melanin pigments) produces a marked enhancement of the 440-nm fluorescence band while the 520-nm band disappears. Hence, our findings suggest that the observed fluorescence contains contributions from both oligomeric units (440-nm band) and high-molecular-weight polymers (520-nm band).

Lipoxygenase/H2O2-catalyzed oxidation of dihdroxyindoles: synthesis of melanin pigments and study of their antioxidant properties.

5,6-Dihydroxyindole (DHI) and 5,6-dihydroxyindole-2-carboxylic acid (DHICA), which are important intermediates in melanogenesis, can be converted into the corresponding melanin pigments by the action of the lipoxygenase/H2O2 system. Kinetic and HPLC analyses indicate that both DHI and DHICA are good substrates for this enzymatic system. Enzyme activity on both substrates was measured in comparison with peroxidase and tyrosinase; the oxidizing behaviour of lipoxygenase is more similar to that of peroxidase rather than that of tyrosinase. The antioxidant properties of DHI- and DHICA-melanins have been investigated in comparison with other kinds of melanins. DHICA-melanin shows a more pronounced antioxidant effect than that of DHI-melanin and this behaviour can be ascribed to the different structure and solubility of the two pigments. The mixed polymer synthesized from DHI and DHICA is the most effective one. Some implications about the possible explanation of the above mentioned behaviour are discussed.

Production of melanin pigments by cytochrome c/H2O2 system.

In the presence of hydrogen peroxide cytochrome c can perform the oxidation of catecholamines and their S-cysteinyl-derivatives yielding melanins as final products. The initial reaction rate is linearly dependent on cytochrome c and H2O2 concentration; the reaction follows the Michaelis and Menten kinetics both for H2O2 and hydrogen donors. Sulfhydryl compounds inhibit the formation of the pigment. The reported data indicate that a heme-containing protein belonging to the mitochondrial chain can accelerate the oxidation of catecholamines to eumelanins.

Production of melanins by ceruloplasmin.

It was shown that ceruloplasmin, apart from the known oxidative conversion of dopamine into melanin, can also produce (DHI)-melanin from 5,6-dihydroxyindole and THP-melanin from tetrahydropapaveroline. Ceruloplasmin acts as an oxidase and the kinetic parameters for these oxidative reactions are reported. Since these ceruloplasmin-catalyzed reactions occur also at pH 7.4, they could have a significant physiological impact. This ceruloplasmin-oxidasic activity is enhanced by copper ions and inhibited by chelators, such as ethylenediaminetetraacetic acid (EDTA) and desferoxamine (DEF). Some possible implication of melanin production in blood are discussed.

Melanins from tetrahydroisoquinolines: spectroscopic characteristics, scavenging activity and redox transfer properties.

Tetrahydroisoquinolines (TIQs) are endogenous compounds deriving from the nonenzymatic Pictet-Spengler condensation of catecholamines (CA) with aldehydes. TIQs have been extensively studied in the last years not only because they have been found in the brain of postmortem specimens of Parkinson's patients, but also because they are able to induce parkinsonian symptoms if injected in animals. In the present article we demonstrate that TIQs bearing a catecholic moiety (tetrahydropapaveroline, salsolinol, laudanosoline, and apomorphine) are easily oxidized in the presence of hydrogen peroxide by various enzymes--i.e., peroxidase (POD), lipoxygenase (LOX), and xanthine oxidase (XO)--into the corresponding TIQ-melanins. The kinetic parameters of the above-mentioned reactions and some spectroscopic characteristics of the synthetized pigments are reported. In particular, UV-VIS and EPR spectra emerge as very similar to those exhibited by dopa-melanin. Furthermore, TIQ-melanins appear to be similar to dopa-melanin regarding some specific physico-chemical properties: NADH-oxidizing properties, oxy-radicals scavenging activity, and ability to form soluble mixed polymers with melanins from opioid peptides.

A specific assay for discriminating between peroxidase and lipoxygenase activities.

Peroxidases are widespread heme-containing enzymes able to catalyze the oxidation of a large array of organic substrates. There is growing interest in the measurements of peroxidase activity. We noticed that many substrates used in the routine assays for the biological and cytological determinations of peroxidase could be oxidized by lipoxygenase. We found interesting to set up a procedure to detect selectively peroxidase. In the present note, we report a fluorometric test for peroxidase detection using phenolic compounds or hydroxycoumarins.

[New possible pathways for melanogenesis: opiomelanins]. / Nuove possibili vie per la melanogenesi: le opio-melanine.

Opioid peptides and other Tyr-NH2-terminal peptides are substrates in vitro for mushroom and sepia tyrosinase giving rise to synthetic melanins retaining the peptide moiety (opiomelanins). The melanopeptides are characterized by a total solubility in hydrophilic solvents at neutral and basic pH. Opioid peptides (enkephalins, endorphins, esorphins), if oxidized by tyrosinase in the presence of Dopa are easily incorporated into Dopa-melanin, producing mixed-type pigments which can also be solubilized in hydrophilic solvents. Melanins deriving from opioid peptides exhibit paramagnetism as evidenced by an EPR spectrum identical to that of Dopa-melanin. However the presence of the linked peptide chain is able to influence dramatically the electron transfer properties and the oxidizing behaviour of the melanopeptides, so that whereas Tyr-Gly-melanin appears to behave as Dopa-melanin, Enk-melanin does not exhibit any oxidizing activity. Opiomelanins are characterized by a peculiar UV-VIS spectrum i.e. by the presence of a well distinct peak (330 nm) disappearing upon chemical treatment by acid hydrolysis. Opiomelanins are stable pigments at neutral and basic pH in the dark, whereas H2O2 addition leads to a 15% degradation. Under simulated solar illumination opiomelanins are more easily destroyed with respect to Dopa-melanin with increasing degradation of exposed to increased hydrogen peroxide concentrations and more alkaline pH. Some speculations on the possible existence and role of opiomelanins have been outlined.

Catecholamines oxidation by xanthine oxidase.

Dopamine and structurally related catecholamines in the presence of hydrogen peroxide are oxidized in vitro by xanthine oxidase producing the corresponding melanin pigments. The kinetic parameters of the reaction, measured as aminochrome formation, have been calculated. The rate of peroxidation depends on enzyme and hydrogen peroxide concentration. The optimum pH for the peroxidative activity of the enzyme is around 8.5. Activation of the peroxidative reaction is also elicited by catechol compounds through a redox cycle mechanism. Implications about the possible biochemical relevance of xanthine oxidase activity on catecholamines oxidation are discussed.

Melanins from opioid peptides.

Opioid peptides and other Tyr-NH2-terminal peptides are substrates in vitro for mushroom and sepia tyrosine, giving rise to synthetic melanins retaining the peptide moiety (opiomelanins). The melanopeptides are characterized by a total solubility in hydrophylic solvents at neutral and basic pH. Opioid peptides (enkephalins, endorphins, and esorphins), if oxidized by tyrosinase in the presence of Dopa, are easily incorporated into Dopa-melanin, producing mixed-type pigments that can also be solubilized in hydrophylic solvents. Melanins derived from opioid peptides exhibit paramagnetism, as evidenced by an EPR spectrum identical to that of Dopa-melanin. However, the presence of the linked peptide chain is able to influence dramatically the electron transfer properties and the oxidizing behaviour of the melanopeptides, so that whereas Tyr-Gly-melanin appears to behave as Dopa-melanin, Enk-melanin does not exhibit any oxidizing activity. Opiomelanins are characterized by a peculiar UV-VIS spectrum; that is, by the presence of a distinct peak (330 nm) that disappears upon chemical treatment by acid hydrolysis. Opiomelanins are stable pigments at neutral and basic pH in the dark, whereas the addition of H2O2 leads to a 15% degradation. Under stimulated solar illumination, opiomelanins are more easily destroyed with respect to Dopa-melanin, with increasing degradation when exposed to increased hydrogen peroxide concentrations and more alkaline pH. Some speculations on the possible existence and role of opiomelanins have been outlined.

Pheomelanin production by the lipoxygenase-catalyzed oxidation of 5-S-cysteinyldopa and 5-S-cysteinyldopamine.

5-S-cysteinyl-dopa (cysdopa) and 5-S-cysteinyl-dopamine (cysdopamine) are oxidized in vitro by soybean lipoxygenase (LOX) in the presence of hydrogen peroxide giving rise to the corresponding pheomelanins. The reaction is activated by caffeic acid and other catechols, suggesting a cofactor role for these compounds. The activating effect is proportional to the concentration of the cofactor, with a saturation profile. The activation extent of the various cofactors is directly related to LOX affinity for the same compounds. The possible implications of the peroxidative action of LOX in Parkinson's disease and in aging are discussed.

Production of melanin pigments by chemical and enzymatic oxidation of tetrahydroisoquinolines.

Tetrahydropapaveroline (THP) oxidation was studied in various experimental conditions by absorbance spectroscopy. THP was found to be easily oxidized by mushroom tyrosinase, giving rise to the formation of a chromophore (THP-chrome) with absorption maxima at 308 and 470 nm. The oxidation further proceeds leading to the formation of a melanin-like pigment. The use of periodate as oxidant at pH 7.4 allows the visualization of the THP-chrome, as well. Other tetrahydroisoquinolines bearing a catechol moiety, such as salsolinol, laudanosoline and apomorphine, have been found to be easily oxidized in the same conditions, giving rise to pigmented derivatives. The products of THP oxidation are able to copolymerize with dopa or opioid peptides in the presence of tyrosinase, generating mixed-type melanins.

Spectroscopic features of native and bleached opio-melanins.

Opioid peptides can be converted by tyrosinase into melanin-like compounds, in which the peptide moiety is retained. Such pigments, named opio-melanins, exhibit a characteristic absorption spectrum with a maximum at about 330 nm and a different solubility behaviour with respect to dopa-melanin, being completely soluble in hydrophylic solvents at neutral and basic pH. Opio-melanins precipitate in aqueous solutions below pH 5.0, and show apparent pKa values of 3.1, 3.6 and 4.4 for Tyr-Gly-melanin, Tyr-Gly-Gly-melanin and leuenk-melanin, respectively. The concomitant oxidation of dopa and opioid peptides by tyrosinase produces mixed polymers, showing the distinctive absorption peak at 330 nm. In the dark, in the pH range 5.5-7.0 the pigments are completely stable, whereas H2O2 addition provokes a slight degradation. At higher pH values or under simulated solar illumination with or without hydrogen peroxide, bleaching occurs more rapidly than in dopa-melanin. Upon photoirradiation the absorption spectrum of opio-melanins undergoes a marked variation, the peak at 330 nm being replaced by a broad shoulder in the range 280-350 nm. The absorption spectra of native and bleached pigments and the extent of opio-melanins degradation by bleaching agents, confirm the hypothesis that the different initial structure of the precursors accounts for a final diverse polymeric architecture of these pigments with respect to dopa-melanin.

The oxidation of oxytocin and vasopressin by peroxidase/H2O 2 system.

Oxytocin and vasopressin are oxidized by horseradish peroxidase and by lactoperoxidase, in the presence of hydrogen peroxide. Spectrophotometric measurements are indicative of the formation of dityrosine. Kinetic parameters indicate that the affinity of horseradish peroxidase is slightly higher for oxytocin with respect to vasopressin and that the two hormones are better substrates for both peroxidases than free tyrosine.

Lipoxygenase-catalyzed oxidation of catecholamines.

Dopa and structurally related catecholamines in presence of hydrogen peroxide are oxidized in vitro by soybean lipoxygenase producing the corresponding melanin pigments. The kinetic parameters of the catecholasic reaction, measured as aminochrome formation, have been calculated. The rate of peroxidation depends on catecholamine and hydrogen peroxide concentration. The optimum pH for the peroxidative activity of the enzyme is around 8.5. The enzyme, at higher pH values (pH 9-9.5), is also able to perform an oxidative reaction of the substrates. Implications of the possible biochemical relevance of the reactions are discussed.

Some biochemical properties of melanins from opioid peptides.

Opioid peptides are converted by mushroom tyrosinase into melanin-like compounds retaining the peptide moiety (opio-melanins). Opio-melanins, owing to the presence of the linked aminoacids and in contrast with DOPA-melanin, are soluble compounds. The enkephalin-generated melanins are cleaved by carboxypeptidase A and pronase whereas aminopeptidase M cannot remove aminoacids from the pigment. Enkephalins, as well as other opioid peptides, (alpha-endorphin, kyotorphin, esorphins) if oxidized in presence of DOPA and tyrosinase are readily incorporated into DOPA-melanin. The resulting mixed-melanins (opio-melanin + DOPA-melanin) can be solubilized in hydrophilic solvents. Melanin from leu-enkephalin exhibits paramagnetism as evidenced by an EPR spectrum identical to that of DOPA-melanin, but unlike the latter pigment, it does not appear to oxidize NADH, probably for the presence of the peptide moiety that exerts a hampering effect on the oxidizing capacity.