Formation of nitrotyrosine by methylene blue photosensitized oxidation of tyrosine in the presence of nitrite.

Methylene blue photosensitized oxidation of tyrosine in the presence of nitrite produces 3-nitrotyrosine, with maximum yield at pH 6. The formation of 3-nitrotyrosine requires oxygen and increases using deuterium oxide as solvent, suggesting the involvement of singlet oxygen in the reaction. The detection of dityrosine as an additional reaction product suggests that the first step in the interaction of tyrosine with singlet oxygen generates tyrosyl radicals which can dimerize to form dityrosine or react with a nitrite-derived species to produce 3-nitrotyrosine. Although the chemical identity of the nitrating species has not been established, the possible generation of nitrogen dioxide (*NO(2)) by indirect oxidation of nitrite by intermediately produced tyrosyl radical, via electron transfer, is proposed. One important implication of the results of this study is that the oxidation of tyrosine by singlet oxygen in the presence of nitrite may represent an alternative or additional pathway of 3-nitrotyrosine formation of potential importance in oxidative injures such as during inflammatory processes.

Methylene blue photosensitized oxidation of cysteine sulfinic acid and other sulfinates: the involvement of singlet oxygen and the azide paradox.

The methylene blue photosensitized oxidation of cysteine sulfinic acid is investigated. Enhancement of the oxygen consumption rate in deuterium oxide suggests the involvement of singlet oxygen ((1)O(2)) in oxidation. Addition of the (1)O(2) quencher azide produced an unusual enhancement of the oxidation rate of all the sulfinates assayed. It is assumed that azide works as a one-electron carrier between (1)O(2) and the sulfur compounds. Analyses of the products indicate that the photochemical oxidation of cysteine sulfinic acid proceeds through two simultaneous mechanisms. The Type II (singlet oxygen) mechanism is responsible for oxidation of the sulfinic group to the sulfonic group with production of cysteic acid, stable to the photooxidation system, whereas the Type I (electron transfer) mechanism is involved in the degradation of cysteine sulfinic acid to acetaldehyde. Other products detected were ammonia, sulfate, and hydrogen peroxide which account for the degradation of cysteine sulfinic acid and for the excess of oxygen consumption detected during the oxidative reaction.

Hypotaurine and superoxide dismutase: protection of the enzyme against inactivation by hydrogen peroxide and peroxidation to taurine.

Hypotaurine is able to prevent the inactivation of SOD by H2O2. The protection is concentration-dependent: at 20 mM hypotaurine the inactivation of SOD is completely prevented. It is likely that hypotaurine exerts this effect by reacting with hydroxyl radicals, generated during the inactivation process, in competition with the sensitive group on the active site of the enzyme. According to this, spectral studies indicate that in presence of hypotaurine the integrity of the active site of SOD is preserved by the disruptive action of H2O2. An interesting outcome of the SOD/H2O2/hypotaurine interaction is that SOD catalyzes the peroxidation of hypotaurine to taurine. Indeed, the formation of taurine increases with the reaction time and with the enzyme concentration. Although the peroxidase activity of SOD is not specific and relatively slow compared to the dismutation of superoxide, it might represent another valuable mechanism of production of taurine.

Oxidation of hypotaurine to taurine with photochemically generated singlet oxygen: the effect of azide.

Hypotaurine is oxidized to taurine by singlet oxygen (1O2) generated with methylene blue used as a photosensitizer. The oxidation rate increases in the presence of deuterium oxide as expected for the involvement of 1O2. Addition of the 1O2 quencher azide also produced an activating effect in contrast with the expected inhibition. Azidyl radicals produced by the oxidation of azide by the horseradish peroxidase/hydrogen peroxide system stimulate the oxidation of the added hypotaurine. It is concluded that azide competes with hypotaurine for 1O2 generating the azidyl radical which is a strong one-electron oxidant transfer of the radical to hypotaurine. The hypotaurine radical is then converted into taurine, possibly through the disulfone intermediate. Formation of the sulfonic hydroperoxide is the possible intermediate in the absence of azide. The finding that the azidyl radical efficiently oxidizes hypotaurine to its metabolic product taurine raises the expectation of hypotaurine being a valuable scavenger of endogenous and exogenous radicals.

Some new details of the copper-hydrogen peroxide interaction.

The addition of neocuproine (NC) or bathocuproinedisulphonate at the end of the autooxidation of Cu(I) in phosphate buffer, pH 7.4, regenerates almost entirely the O2 consumed. Other chelating agents assayed, including o-phenanthroline, cannot replace NC in promoting the O2 formation. O2 is also produced by adding NC to a mixture of Cu(II) and H2O2. Concomitant with the O2 evolution, the typical absorbance of the (NC)2Cu(I) complex appears to account for the complete reduction of Cu(II) to Cu(I). It is concluded that the addition of H2O2 with Cu(II) produces the equilibrium Cu(II)(O2H)(-)<--> Cu(I.)O2H. Addition of NC shifts the equilibrium to the right side by binding Cu(I). The released O2.- then reacts with the remaining Cu(II) yielding, in the presence of NC, the net reaction of 4 NC + 2 Cu(II) + H2O2 --> 2 (NC)2Cu(I) + O2 + 2 H+. O2 is also released in the absence of added NC provided the H2O2 concentration is increased. In these conditions the Cu(II)(O2H) complex undergoes other reactions leading to the copper-catalysed decomposition of H2O2.

An insight in the mechanism of the aminoethylcysteine ketimine autoxidation.

Oxidation of aminoethylcysteine ketimine (AECK) is followed by the change of 296nm absorbance, by the O2 consumption and by the HPLC analysis of the oxidation products. The oxidation is strongly inhibited by the addition of superoxide dismutase (SOD) but not by hydroxyl radical scavengers or catalase. Addition of EDTA or o-phenanthroline (OPT) favours the oxidation, probably by keeping contaminating metals in solution at the pH studied. Addition of Fe(3+) ions strongly accelerates the oxidation in the presence of EDTA or OPT. AECK reacts stoichiometrically with OPT-Fe(3+) complex producing the Fe(2+) complex which is not reoxidised by bubbling O2. HPLC analyses of the final oxidation products reacting with 2,4-dinitrophenylhydrazine (DNPH) confirm the AECK sulfoxide as the main product of the slow spontaneous oxidation. The detection of other oxidation products when the reaction is speeded up by the addition of the OPT-Fe(3+) complex, suggests that the oxidation takes place essentially on the carbon portion of the AECK molecule in the side of the double bond. On the basis of the results presented here, a scheme of reactions is illustrated which starts with the transfer of one electron from AECK to a contaminating metal ion (possibly Fe(3+)) producing the radical AECK(•) as the initiator of a self propagating reaction. The radical AECK(•) reacting with O2 starts a series of reactions accounting for most of the products detected.

Antioxidant properties of the decarboxylated dimer of aminoethylcysteine ketimine.

The decarboxylated dimer of aminoethylcysteine ketimine has been investigated for a possible general protective effect against oxyradical damage. It has been found that the dimer protects brain microsomes against lipid peroxidation induced by NADPH in the presence of Fe(III)-ADP chelate or by cumene hydroperoxide. The compound also inhibits lipid peroxidation stimulated by L-dopa and related compounds in the presence of Fe(III)-ADP complex. Furthermore the dimer is able to protect deoxyribose against hydroxyl radical induced degradation. These observations suggest that the dimer is a lipid peroxidation protective agent and a free radical scavenger.

Aminoethylcysteine ketimine decarboxylated dimer protects submitochondrial particles from lipid peroxidation at a concentration not inhibitory of electron transport.

In contrast with other inhibitors of the NADH dehydrogenase of the respiratory chain, the decarboxylated dimer of aminoethylcysteine ketimine protects bovine heart submitochondrial particles (SMP) from the NADH-Fe(+3)-ADP-induced lipid peroxidation. This effect, measured as inhibition of malondialdehyde formation, is concentration-dependent in the range 0.02-0.2 mM. This range of concentration is not inhibitory on NADH-oxidase activity of SMP. Furthermore the dimer is able to counteract the malondialdehyde formation stimulated by the Complex I inhibitors rotenone and N-methyl-4-phenylpyridinium (MPP+).

Aminoethylcysteine ketimine decarboxylated dimer inhibits mitochondrial respiration by impairing electron transport at complex I level.

The product of the spontaneous dimerization and decarboxylation of aminoethylcysteine ketimine (simply named the dimer in this note) has been investigated for a possible biochemical activity. It has been found that the dimer inhibits the ADP-dependent oxidation of NAD(+)-linked substrates in rat liver mitochondria and electron transport from NADH to O2 in bovine heart submitochondrial particles (SMP). Oxidation of succinate by SMP is not impaired by concentrations of the dimer inhibiting almost totally NADH oxidation. Furthermore, the dimer did not affect the rotenone-insensitive electron transfer from NADH to menadione. These results give a preliminary indication suggesting that the dimer inhibits electron flow from NADH dehydrogenase to ubiquinone at or near the rotenone binding site(s). The dimer inhibition falls in the same range exhibited by some neurotoxins which are known to interact with the rotenone binding site.

The oxidative deamination of L-aminoethylcysteine sulfoxide and sulfone by snake venom L-amino acid oxidase.

The oxidation of L-aminoethylcysteine (AEC) by L-amino acid oxidase has been compared with that of the respective sulfoxide (AEC-SO) and sulfone (AEC-SO2). Spectral and HPLC analyses of the incubates reveal the formation of the respective cyclic ketimines. While the ketimine coming from AEC is subjected to autooxidation yielding the sulfoxide and other products, the ketimines produced from AEC-SO and AEC-SO2 are more stable and account for almost the total conversion of the substrate in the product. Spectrophotometric and HPLC properties of the ketimine produced from AEC-SO are identical to those reported earlier for the main product of the autooxidation of AEC ketimine, thus confirming its identification. These results could explain the presence of chondrine in biological materials as a product of reduction of AEC-SO ketimine.

Reversible cyclization ofS-(2-oxo-2-carboxyethyl)-L-homocysteine to cystathionine ketimine.

S-(2-oxo-2-carboxyethyl)homocysteine (OCEHC), produced by the enzymatic monodeamination of cystathionine, is known to cyclize producing the seven membered ring of cystathionine ketimine (CK) which has been recognized as a cystathionine metabolite in mammals. Studies have been undertaken in order to find the best conditions of cyclization of synthetic OCEHC to CK and for the preparation of solid CK salt product. It has been found that ring closure takes place at alkaline pH and is highly accelerated in 0.5 M phosphate buffer. The sodium salt of CK has been prepared by controlled additions of NaOH to water-ethanol solution of OCEHC under N2 atmosphere. A solid product is obtained which, dissolved in water, shows the spectral features of CK. Solutions of the sodium salt of CK show the presence of a pH depending reversible equilibrium with the open OCEHC form. Plot of the absorbance at 296 nm in function of pH indicates that at pH 9 the compound is completely cyclized while at pH 6 is totally in the open OCEHC form. At intermediate pHs variable ratios between the two forms occur. According to the results obtained by the spectral analysis, HPLC assays of the sodium salt of CK show different patterns depending on the pH of the elution buffer.

The oxidation of sulfur containing cyclic ketimines The sulfoxide is the main product of S-aminoethyl-cysteine ketimine autoxidation.

The products of autoxidation of S-aminoethyl-L-cysteine ketimine (AECK) have been analysed with the amino acid analyzer, with thin layer chromatography and with high performance liquid chromatography. Under the conditions of the assay (pH 8.5, 38°C, O2 bubbling) AECK is almost totally oxidized in 1.5 hours. Among the final products a component running fast in HPLC, named Cx1, has been isolated, reduced with NaBH4 and analysed. Reduced Cx1 resulted to show the same properties of synthetic thiomorpholine-3-carboxylic acid-S-oxide, known in the past literature with the name of "chondrine". On the basis of these results and by specific chromatographic tests, Cx1 has been identified as the sulfoxide of AECK. Among the other autoxidation products, thiomorpholine-3-one has been identified. The detection, after HCl hydrolysis, of glyoxylic acid and mesoxalic semialdehyde together with cysteamine indicates that compounds provided with easily cleavable S-C bonds, possibly thiohemiacetals or (and) thioesters, are the likely intermediates for other products. AECK sulfoxide and thiomorpholine-3-one are relatively stable and cannot be taken as the main intermediates for the remaining oxidation products.

The reducing activity of S-aminoethylcysteine ketimine and similar sulfur-containing ketimines.

S-aminoethylcysteine ketimine and other sulfur-containing similar ketimines reduce molecular oxygen and phospho-18-tungstate (Folin Marenzi reagent), although the sulfur atom is formally present in the non reducing thioether form. We have now found that 2,6-diclorophenolindophenol, some ferrihemoproteins and other reagents are also reduced by this group of ketimines. Ferricytochrome c is reduced faster than methemoglobin, metmyoglobin and free hematin, whereas horse radish peroxidase compound I is reduced at once. These results indicate a wider reducing activity of this type of ketimine. The oxidation of ketimines by ferric cytochrome c appears a relevant finding pointing to a new possible way of enzymatic modification of sulfur-ketimines in tissues.

Identification of 1,4-thiomorpholine-3-carboxylic acid (TMA) in normal human urine.

The sulfur-containing cyclic imino acid 1,4-thiomorpholine-3-carboxylic acid (TMA) has been identified in normal human urine. After the enrichment procedure with ion-exchange chromatography, the urine extracts were reacted with diazomethane. Gas-liquid chromatography revealed the presence of two peaks with the same retention times exhibited by authentic TMA after the same derivatization. The two compounds have been identified by mass-spectrometry as the monomethylated and dimethylated derivatives of TMA. This result represents the first indication of the occurrence of TMA in a mammalian sample.