Effect of 3,4-dihydroxyphenylalanine on Cu2+-induced Inactivation of HDL-associated Paraoxonase1 and Oxidation of HDL; Inactivation of Paraoxonase1 Activity Independent of HDL Lipid Oxidation

Paraoxonase1 (PON1), one of HDL-asssociated antioxidant proteins, is known to be sensitive to oxidative stress. Here, the effect of endogenous reducing compounds on Cu²⁺-mediated inactivation of PON1 was examined. Cu²⁺-mediated inactivation of PON1 was enhanced remarkably by catecholamines, but not by uric acid or homocysteine. Furthermore, catecholamines such as 3,4-dihydroxyphenylalanine (DOPA), dopamine or norepinephrine were more effective than caffeic acid or pyrocatechol in promoting Cu²⁺-mediated inactivation of PON1, suggesting the importance of dihydroxybenzene group as well as amino group. DOPA at relatively low concentrations showed a concentration-dependent inactivation of PON1 in a concert with Cu²⁺, but not Fe²⁺. The DOPA/Cu²⁺-induced inactivation of PON1 was prevented by catalase, but not hydroxyl radical scavengers, consistent with Cu²⁺-catalyzed oxidation. A similar result was also observed when HDL-associated PON1 (HDL-PON1) was exposed to DOPA/Cu²⁺. Separately, it was found that DOPA at low concentrations (1-6 μM) acted as a pro-oxidant by enhancing Cu²⁺-induced oxidation of HDL, while it exhibited an antioxidant action at ≥10 μM. In addition, Cu²⁺-oxidized HDL lost the antioxidant action against LDL oxidation. Meanwhile, the role of DOPA/Cu²⁺-oxidized HDL differed according to DOPA concentration; HDL oxidized with Cu²⁺ in the presence of DOPA (60 or 120 μM) maintained antioxidant activity of native HDL, in contrast to an adverse effect of DOPA at 3 or 6 μM. These data indicate that DOPA at micromolar level may act as a pro-oxidant in Cu²⁺-induced inactivation of PON1 as well as oxidation of HDL. Also, it is proposed that the oxidative inactivation of HDL-PON1 is independent of HDL oxidation.     

Cu2+-catalyzed oxidative degradation of thyroglobulin

Thyroglobulin (Tg) was subjected to metal-catalyzed oxidation, and the oxidative degradation was analyzed by SDS-polyacrylamide gel electrophoresis under reducing conditions. In contrast to no effect of hydrogen peroxide (H₂O₂) alone on the Tg degradation, the inclusion of Cu²⁺ (30 μM), in combination with 2 mM H₂O₂, caused a remarkable degradation of Tg, time- and concentration-dependent. The action of Cu²⁺ was not mimicked by Fe²⁺, suggesting that Tg may interact selectively with Cu²⁺. A similar degradation of Tg was also observed with Cu²⁺corbate system, and the concentration of Cu²⁺ (5-10 μM), in combination with ascorbate, required for the effective degradation was smaller than that of Cu²⁺ (10-30 μM) in combination with H₂O₂. In support of involvement of H₂O₂ in the Cu²⁺ corbate action, catalase expressed a complete protection. However, hydroxyl radical scavengers such as dimethylsulfoxide or mannitol failed to prevent the oxidation of Tg whereas phenolic compounds, which can interact with Cu²⁺, diminished the oxidative degradation, presumably consistent with the mechanism for Cu²⁺-catalyzed oxidation of protein. Moreover, the amount of carbonyl groups in Tg was increased as the concentration (3-100 μM) of Cu²⁺ was enhanced, while the formation of acid-soluble peptides was not remarkable in the presence of Cu²⁺ up to 200 μM. In further studies, Tg pretreated with heat or trichloroacetic acid seemed to be somewhat resistant to Cu²⁺-catalyzed oxidation, implying a possible involvement of protein conformation in the susceptibility to the oxidation. Based on these observations, it is proposed that Tg could be degraded non-enzymatically by Cu²⁺-catalyzed oxidation.     

Copper (II) complex-catalyzed oxidation of NADH by hydrogen peroxide

Among various metal ions of physiological interest, Cu²⁺ is uniquely capable of catalyzing the oxidation of NADH by H₂O₂. This oxidation is stimulated about fivefold in the presence of imidazole. A similar activating effect is found for some imidazole derivatives (1-methyl imidazole, 2-methyl imidazole, andN-acetyl-L-histidine). Some other imidazole-containing compounds (L-histidine,L-histidine methyl ester, andL-carnosine), however, inhibit the Cu²⁺-catalyzed peroxidation of NADH. Other chelating agents such as EDTA andL-alanine are also inhibitory. Stoichiometry for NADH oxidation per mole of H₂O₂ utilized is 1, which excludes the possibility of a two-step oxidation mechanism with a nucleotide free-radical intermediate. About 92% of the NADH oxidation product can be identified as enzymatically active NAD⁺. D₂O, 2,5-dimethylfuran, and 1,4-diazabicyclo [2.2.2]-octane have no significant effect on the oxidation, thus excluding¹O₂ as a mediator. Similarly, OH· is also not a likely intermediate, since the system is not affected by various scavengers of this radical. The results suggest that a copper-hydrogen peroxide intermediate, when complexed with suitable ligands, can generate still another oxygen species much more reactive than its parent compound, H₂O₂.     

Action of Heavy Metals on Hill Activity and O(2) Evolution in Anacystis nidulans

Addition of 5 micromolar Cu²⁺, Cd²⁺, and Zn²⁺ was inhibitory to 10 micromolar H₂O₂-supported Hill activity (dichlorophenolindophenol reduction) and O₂ evolution in membrane preparation from Anacystis nidulans. The reversal of Cd²⁺ and Zn²⁺ inhibition, in contrast to Cu²⁺, by exogenously added catalase (EC 1.11.1.6) suggested that the former cations were inhibitory to H₂O₂ degradation. Ascorbic acid (20 micromolar) supported 27% of the Hill activity which was insensitive to DCMU (10 micromolar) and the remaining activity, attributable to the DCMU sensitive process, was sensitive to inhibition by Cu²⁺ only. It is suggestive that the action site of Cd²⁺ and Zn²⁺ is located between the electron donation sites of H₂O₂ and ascorbic acid, while that of Cu²⁺ is located beyond it. Electron donation by reduced glutathione was insensitive to DCMU and Cu²⁺, indicating that the action site of Cu²⁺ is prior to its electron donation site. Further, the phenanthroline (10 micromolar) reversal of Cu²⁺ inhibition of Hill activity suggested a tentative action site of Cu²⁺ at the level of cytochrome.     

Hemolysis of human red blood cells induced by the combination of diethyldithiocarbamate (DDC) and divalent metals: Modulation by anaerobiosis,certain antioxidants and oxidants

The objective of the present communication is to describe the role played by combinations between diethydithiocarbamate (DDC) and divalent metals in hemolysis of human RBC. RBC which had been treated with DDC (10–50 μM) were moderately hemolyzed (about 50%) upon the addition of subtoxic amounts of Cu²⁺ (50 μM). However, a much stronger and a faster hemolysis occurred either if mixtures of RBC-DDC were immediately treated either by Co²⁺ (50 μM) or by a premixture of Cu²⁺ and Co²⁺ (Cu:Co) (50 μM).

While Fe²⁺ and Ni²⁺, at 50 μM, initiated 30–50% hemolysis when combined with DDC (50 μM), on a molar basis, Cd²⁺ was at least 50 fold more efficient than any of the other metals in the initiation of hemolysis by DDC. On the other hand, neither Mn²⁺ nor Zn²⁺, had any hemolysis-initiating effects. Co²⁺ was the only metal which totally blocked hemolysis if added to DDC prior to the addition of the other metals.

Hemolysis by mixtures of DDC + (Cu:Co) was strongly inhibited by anaerobiosis (flushing with nitrogen gas), by the reducing agents glutathione, N-acetyl cysteine, mercaptosuccinate, ascorbate, TEMPO, and α-tocopherol, by the PLA₂ inhibitor bromophenacylbromide (BrPACBr), by tetracycline as well as by phosphatidyl choline, cholesterol and by trypan blue. However, TEMPO, BrPACBr and PC were the only agents which inhibited hemolysis induced by DDC:Cd²⁺ complexes.

On the other hand, none of the classical scavengers of reactive oxygen species (ROS) employed e.g dimethylthiourea, catalase, histidine, mannitol, sodium benzoate, nor the metal chelators desferal and phenanthroline, had any appreciable inhibitory effects on hemolysis induced by DDC + (Cu:Co).

DDC oxidized by H₂O₂ lost its capacity to act in concert either with Cu²⁺ or with Cd²⁺ to hemolyze RBC.

While either heating RBC to temperatures greater than 37°C or exposure of the cells to glucose-oxidase-generated peroxide diminished their susceptibility to hemolysis, exposure to the peroxyl radical from AAPH, enhanced hemolysis by DDC + (Cu:Co).

The cyclovoltammetry patterns of DDC were drastically changed either by Cu²⁺, Co²⁺ or by Cd²⁺ suggesting a strong interaction of the metals with DDC. Also, while the absorbance spectrum of DDC at 280 nm was decreased by 50% either by Co²⁺, Cd²⁺ or by H₂O₂, a 90% reduction in absorbance occurred if DDC + H₂O₂ mixtures were treated either by Cu²⁺ or by Co²⁺, but not by Cd²⁺.

Taken together, it is suggested that DDC-metal chelates can induce hemolysis by affecting the stability and the integrity of the RBC membrane, and possibly also of the cytoskeleton and the role played by reducing agents as inhibitors might be related to their ability to deplete oxygen which is also supported by the inhibitory effects of anaeobiosis.     

Oxidative Inactivation of Brain Alkaline Phosphatase Responsible for Hydrolysis of Phosphocholine

Abstract : Alkaline phosphatase, one of the enzymes responsible for the conversion of phosphocholine into choline, was purified from bovine brain membrane, where the phosphatase is bound as glycosylphosphatidylinositollinked protein, and subjected to oxidative inactivation. The phosphatase activity, based on the hydrolysis of p-nitrophenyl phosphate and phosphocholine, decreased slightly after the exposure to H₂O₂. Inclusion of Cu²⁺ in the incubation with 1 mM H₂O₂ led to a rapid decrease of activity in a time- and concentration-dependent manner. In comparison, the H₂O₂/Cu²⁺ system was much more effective than the H₂O₂/Fe²⁺ system in inactivating brain phosphatase. In a further study, it was observed that the hydroxy radical scavengers mannitol, ethanol, or benzoate failed to prevent against H₂O₂/Cu²⁺-induced inactivation of the phosphatase, excluding the involvement of extraneous hydroxy radicals in metalcatalyzed oxidation. In addition, it was found that both substrates, p-nitrophenyl phosphate and phosphocholine, and an inhibitor, phosphate ion, at their saturating concentrations exhibited a remarkable, although incomplete, protection against the inactivating action of H₂O₂/Cu²⁺. A similar protection was also expressed by divalent metal ions such as Mg²⁺ or Mn²⁺. Separately, it was found that H₂O₂/Fe²⁺-induced inactivation was prevented by p-nitrophenyl phosphate or Mg²⁺ but not phosphate ions. Thus, it is implied that phosphocholine-hydrolyzing alkaline phosphatase in brain membrane might be one of enzymes susceptible to metal-catalyzed oxidation.     

Protein oxidation: examination of potential lipid-independent mechanisms for protein carbonyl formation

Previous data indicated that diquat-mediated protein oxidation (protein carbonyl formation) occurs through multiple pathways, one of which is lipid dependent, and the other, lipid independent. Studies reported here investigated potential mechanisms of the lipid-independent pathway in greater detail, using bovine serum albumin as the target protein. One hypothesized mechanism of protein carbonyl formation involved diquat-dependent production of H₂O₂, which would then react with site-specifically bound ferrous iron as proposed by Stadtman and colleagues. This hypothesis was supported by the inhibitory effect of catalase on diquat-mediated protein carbonyl formation. However, exogenous H₂O₂ alone did not induce protein carbonyl formation. Hydroxyl radical-generating reactions may result from the H₂O₂-catalyzed oxidation of ferrous iron, which normally is bound to protein in the ferric state. Therefore, the possible reduction of site-specifically bound Fe³⁺ to Fe²⁺ by the diquat cation radical (which could then react with H₂O₂) was also investigated. The combination of H₂O₂ and an iron reductant, ascorbate, however, also failed to induce significant protein carbonyl formation. In a phospholipid-containing system, an ADP:Fe²⁺ complex induced both lipid peroxidation and protein carbonyl formation; both indices were largely inhibitable by antioxidants. There was no substantial ADP:Fe²⁺-dependent protein carbonyl formation in the absence of phospholipid under otherwise identical conditions. Based on the lipid requirement and antioxidant sensitivity, these data suggest that ADP:Fe²⁺-dependent protein carbonyl formation occurs through reaction of BSA with aldehydic lipid peroxidation products. The precise mechanism of diquat-mediated protein carbonyl formation remains unclear, but it appears not to be a function of H₂O₂ generation or diquat cation radical-dependent reduction of bound Fe³⁺. © 1998 John Wiley & Sons, Inc. J Biochem Toxicol 12: 185–190, 1998     

Methionine does not reduce Cu(II)–β-amyloid!—Rectification of the roles of methionine-35 and reducing agents in metal-centered oxidation chemistry of Cu(II)–β-amyloid

The potential risk of metal-centered oxidative catalysis has been overlooked in the research of the copper complexes of the Alzheimer's disease-related β-amyloid (Aβ) peptides. Cu²⁺ complexes of Aβ_1–40 and its 1–16 and 1–20 fragments have recently been shown to exhibit significant metal-centered oxidative activities toward several catecholamine neurotransmitters with and without H₂O₂ around neutral pH [G.F.Z. da Silva, L.-J. Ming, “Metallo-ROS” in Alzheimer's disease: metal-centered oxidation of neurotransmitters by Cu^II–β-amyloid and neuropathology of Alzheimer's disease, Angew. Chem. Int. Ed. 46 (2007) 3337–3341]. The results further support the metallo-Aβ-associated oxidative stress theory often considered to be connected to the neuropathology of the disease. The metal-centered oxidative catalysis of CuAβ_1–16/20 challenges the long-standing proposed redox role of Met35 in Aβ because Aβ_1–16/20 do not contain a Met. External Met has been determined by kinetic, optical, and electron paramagnetic resonance methods to bind directly to the Cu²⁺ center of CuAβ_1–40 and CuAβ_1–20 with K_d = 2.8 mM and 11.3 μM, respectively, which reflects less accessibility of the metal center in the full-length CuAβ_1–40. However, Met does not serve as a reducing agent for the Cu(II) which thus must amplify the observed oxidative catalysis of CuAβ_1–20 through a non-redox mechanism. Conversely, the CuAβ-catalyzed oxidation reaction of dopamine is inhibited by bio-available reducing agents such as ascorbate (competitive K_ic = 66 μM) and glutathione (non-competitive, K_inc = 53 μM). These data indicate that the oxidation chemistry of metallo-Aβ is not initiated by Met35. The results yield further molecular and mechanistic insights into the roles of metallo-Aβ in this disease.     

Nitro-Tyrosine as Promoter of Free Radical Damage in a DNA Model System

Nitro-tyrosine considerably promotes the degradation of DNA, when incubated with Cu²⁺ and ascorbate in oxygenated aqueous solution. This deleterious process requires oxygen and can be inhibited with catalase, indicating that H₂O₂ is involved, via the reduction of oxygen. Menadione and 2,4,6-trinitro-benzenesulfonate, known to catalyze particularly fast such reduction of oxygen, were only slightly more active than nitro-tyrosine. Degradation of DNA can be explained by a site-specific Fenton type reaction of H₂O₂ with the DNA-Cu⁺ complex.

DNA-Cu⁺ + H₂O₂ → DNA' ' 'OH + Cu²⁺ + OH^?

Copper-chelating agents (EDTA and penicillamine) prevent DNA degradation, whereas OH-scavengers (t-butanol) are ineffective. The deleterious activity of nitro-tyrosine (and of other nitroaromatics) in the DNA model system may indicate important toxicological implications, since aromatic nitration is a significant mode of action of nitrogen dioxide.     

Oxygen consumption during the fenton-type reaction between hydrogen peroxide and a ferrous-chelate (Fe2+-DTPA)

The Fenton-type reaction between ferrous diethylenetriamine pentaacetic acid (Fe²⁺-DTPA, 50–200 μM) and H₂O₂ (20–1000 μM) in phosphate buffer at pH 7.0 results in consumption of dissolved oxygen. This observation differs from many prior reports that oxygen is liberated when more concentrated solutions of H₂O₂ are decomposed by iron salts. The rate and total quantity of oxygen consumed were dependent upon the concentrations of ferrous chelate, H₂O₂, and excess DTPA. Evidence is provided that both the ferrous-DTPA chelate and free DTPA can participate in the oxygen-consuming reactions. Oxygen was also consumed during the Fenton reaction between ferrous ions and H₂O₂ when DTPA and phosphate buffer were omitted. Under these conditions, oxygen evolution was observed at higher H₂O₂ concentrations (e.g., 400 μM). The consumption of oxygen during the Fenton-type reaction of an iron chelate at neutral pH may be relavant to events that take place in biologic systems.     

Pyrophosphate as substrate for alkaline phosphatase activity: A convenient flow‐injection chemiluminescence assay

A sensitive and convenient flow‐injection chemiluminescence (FI‐CL) turn‐on assay for alkaline phosphatase (ALP) activity without any label and synthesis is developed. Cu²⁺ can catalyze the luminol–H₂O₂ CL reaction. Pyrophosphate (PPi) can chelate Cu²⁺ and therefore the Cu²⁺‐mediated luminol‐H₂O₂ CL reaction is inhibited. The addition of ALP can catalyze the hydrolysis of PPi into phosphate ions, Cu²⁺ is released and the chemiluminescence recovers. A detection limit of 1 mU/mL ALP is obtained.     

Influence of copper-(II) on colloidal carbon-induced kupffer cell-dependent oxygen uptake in rat liver: Relation to hepatotoxicity

Formation of reactive O₂ species in biological systems can be accomplished by copper-(II) (Cu²⁺) catalysis, with the consequent cytotoxic response. We have evaluated the influence of Cu²⁺ on the respiratory activity of Kupffer cells in the perfused liver after colloidal carbon infusion. Studies were carried out in untreated rats and in animals pretreated with the Kupffer cell inactivator gadolinium chloride (GdCl₃) or with the metallothionein (MT) inducing agent zinc sulphate, and results were correlated with changes in liver sinusoidal efflux of lactate dehydrogenase (LDH) as an index of hepatotoxicity. In the concentration range of 0.1–1 μM, Cu²⁺ did not modify carbon phagocytosis by Kupffer cells, whereas the carbon-induced liver O₂ uptake showed a sigmoidal-type kinetics with a half-maximal concentration of 0.23 μM. Carbon-induced O₂ uptake occurred concomitantly with an increased LDH efflux, effects that were significantly correlated and abolished by GdCl₃ pretreatment or by MT induction. It is hypothesized that Cu²⁺ increases Kupffer cell-dependent O₂ utilization by promotion of the free radical processes related to the respiratory burst of activated liver macrophages, which may contribute to the concomitant development of hepatocellular injury.     

Terephthalic acid: A dosimeter for the detection of hydroxyl radicals in vitro

Hydroxylation reactions of aromatic compounds have been used to detect hydroxyl radicals produced by gamma irradiation and ultrasound. The present study investigated the suitability of terephthalic acid (THA) as a hydroxyl radical dosimeter for general use in biologically relevant reactions. Hydroxyl radicals were generated by: (1) irradiating, THA with a 254 nm ultraviolet; (2) irradiating with gamma rays from a cesium source; and (3) generating hydroxyl radicals with 1 mM H₂O₂ and 10 μM Cu⁺². In each of the three experiments, a fluorescent product was generated which exhibited identical fluorescent excitation and emission spectra. THA is non-fluorescent, eliminating the problem of a high initial background. Because THA has four ring hydrogens, only one mon-hydroxylated isomer was formed. The hydrogen peroxide reaction was dependent on the presence of a metal and cupric ions were effective in enhancing the reaction. With a Cu⁺² concentration of 10 μM, the reation was linear between 0–30 mM H₂O₂. Catalase abolished the reaction at a concentration of 100 μg/ml and the effects could still be observed at 10 ng/ml, consistent with the very high rate at which catalase destroys hydrogen peroxide. Tertbutyl- hydroperoxide did not generate any fluorescence in this system which makes THA a very specific detector of hydroxyl radicals.     

A colorimetric probe for detection of Cu2+ by the naked eye and application in test paper

A novel colorimetric probe RP1 was synthesized using rhodamine derivatives and heterocyclic compounds for the purpose of detecting Cu²⁺. RP1 showed good selectivity, high sensitivity and affinity toward Cu²⁺ over other competing ions in CH₃OH–H₂O (1/1, v/v) solution. Absorbance intensity showed a good linear fit between probe R1 and Cu²⁺ over the concentration range 1–8 μM and the association constant was also calculated to be 1.145 × 10⁵ M^?1. The sensing mechanism was deduced using Job's plot, Fourier transform infrared spectroscopy, and density functional theory studies. In addition, the colorimetric experiment indicated that probe RP1 could be made into test paper to detect Cu²⁺ with a colour change from colourless to pink.     

Terbium (III) coordination polymer–copper (II) compound as fluorescent probe for time‐resolved fluorescence ‘turn‐on’ detection of hydrogen sulfide

With recognition of the biological importance of hydrogen sulfide (H₂S), we present a simple and effective fluorescent probe for H₂S using a Tb³⁺ coordination polymer–Cu²⁺ compound (DPA/Tb/G–Cu²⁺). Dipicolinic acid (DPA) and guanosine (G) can coordinate with Tb³⁺ to form a macromolecular coordination polymer (DPA/Tb/G). DPA/Tb/G specifically binds to Cu²⁺ in the presence of coexisting cations, and obvious fluorescence quenching is observed. The quenched fluorescence can be exclusively recovered upon the addition of sulfide, which is measured in the mode of time‐resolved fluorescence. The fluorescence intensities of the DPA/Tb/G–Cu²⁺ compound enhance linearly with increasing sulfide concentrations from 1 to 30 μM. The detection limit for sulfide in aqueous solution is estimated to be 0.3 μM (at 3σ). The DPA/Tb/G–Cu²⁺ compound was successfully applied to sense H₂S in human serum samples and exhibited a satisfactory result. It displays some desirable properties, such as fast detection procedure, high selectivity and excellent sensitivity. This method is very promising to be utilized for practical detection of H₂S in biological and environmental samples.     

Copper ions and hydrogen peroxide form hypochlorite from NaCl thereby mimicking myeloperoxidase

Sea urchins have elaborated multiple defenses to assure monospermic fertilization. In this work, we have concentrated on a study of the mechanism(s) by which hydrogen peroxide (H₂O₂) prevents polyspermy in Arbacia punctulata. We found that it is not H₂O₂ but probably hypochlorous acid/hypochlorite (HOCl/OCl^?) derived from H₂O₂ that is toxic to the supernumerary sperm. The spermicidal activity of H₂O₂ is potentiated by at least one order of magnitude by cupric ions (Cu²⁺). This increased toxicity is not due to the formation of hydroxyl radicals (·OH) because ·OH scavengers did not counteract the activity of Cu²⁺. More-over, substitution of Cu²⁺ by ferrous ions (Fe²⁺), which are known to cause formation of ·OH from H₂O₂, had no effect on fertilization even at 10²?10³ times higher concentrations. In contrast, 3-amino-1,2,4-triazole (AT), an HOCl/OCl^? scavenger, totally reversed the toxic effects of Cu²⁺. Furthermore, we found that HOCl/OCl^? is generated in solutions of H₂O₂ and Cu²⁺ in the presence of 0.5 M NaCl and that its accumulation is abolished by AT. Thus it is possible that the antifertility properties of copper are due to its ability to mediate formation of HOCl/OCl^?. HOCl/OCl^? generated by Cu²⁺ from H₂O₂ and Cl^?, a low concentration of exogenously added HOCl/OCl^?, or increased concentrations of H₂O₂ has similar inhibitory effects on the fertilization process in sea urchins. Therefore, we suggest that polyspermy is prevented by the action of a myeloperoxidase that affects the formation of HOCl/OCl^? from the Cl^? present in sea water through reaction with H₂O₂ generated by the newly fertilized egg.     

Purification and Properties of Sarcosine Oxidase from Cylindrocarpon didymum M–1

Sarcosine oxidase was purified to homogeneity from the cell extract of Cylindrocarpon didymum M–1, aerobically grown in medium containing choline as the carbon source. The molecular weight of the enzyme was estimated to be 45,000 by gel filtration method and 48,000 by the sodium dodecylsulfate disc gel electrophoresis method. The enzyme exhibited an absorption spectrum with maxima at 277 and 450 run and shoulders at 370 and 470 nm. The anaerobic addition of sarcosine to the enzyme resulted in the disappearance of the peak at 450 nm. The enzyme contained one mol of covalently bound FAD per mol of enzyme. Enzyme activity was inhibited by Ag⁺, Cu²⁺, Hg²⁺, p-chloromercuribenzoate and iodoacetate. The enzyme oxidized sarcosine but was inert toward choline, betaine, dimethylglycine and N-methyl amino acids. Km and V_max values for sarcosine were 1.8 ihm and 26.2 μmol/min/mg, respectively. The enzyme catalyzed the following reaction: Sarcosine+O₂+H₂O→glycine +formaldehyde+H₂O₂.     

An optical material for the detection of trace S<Subscript>2</Subscript>O<Subscript>3</Subscript><Superscript>2−</Superscript> in milk based on a copper complex

A novel S₂O₃ ^2? luminescent sensor (Cu²⁺-p-CPIP) was developed and the presence of S₂O₃ ^2? caused an obvious fluorescence enhancement at 420 nm upon excitation at 330 nm, which could be distinguished with the naked eye under a UV lamp. Remarkably, the compound exhibited excellent selective and sensitive response to S₂O₃ ^2? over other common anions with a micromolar limit of detection (0.442 μM) in DMSO/H₂O (v/v, 1:1) buffer. The absorbance intensity and the color of Cu²⁺-p -CPIP solution changed gradually with the increase of S₂O₃ ^2? concentration. The proposed method was applied to the determination of S₂O₃ ^2? in milk samples and the recoveries were 97.5–105%. The preparation of Cu²⁺-p -CPIP exhibited the quick, simple and facile advantages. The results showed that Cu²⁺-p -CPIP can be a good candidate for simple, rapid and sensitive colorimetric detection of S₂O₃ ^2? in aqueous solution.