Hypochlorite scavenging activity of flavonoids.

Scavengers of hypochlorite, a highly reactive oxidant produced by activated phagocytes, could have potential therapeutic effects in diseases in which this oxidant plays a pathogenic role. Flavonoids are polyphenolic substances present in food plants and have been extensively studied for their antioxidant properties against various free radicals. Less is known about their reactivity with hypochlorite. In this study, the hypochlorite scavenging activity of flavonoids was investigated using a microplate assay recently developed in our laboratory. This method evaluates the ability of a substance to inhibit the formation of chloramines in human serum albumin upon oxidation by hypochlorite. Thirteen flavonoids were tested. Most of them inhibited human serum albumin oxidation at micro-molar concentrations and appeared more active than Trolox, a water-soluble equivalent of vitamin E. It was observed that the greater the number of hydroxyl substitutions, the greater the scavenging activity. The 3-hydroxy substitution seemed to be particularly important for scavenging activity, whereas the presence of a 2,3-double bond in the C ring did not. Flavonoids were found to be good hypochlorite scavengers in-vitro and further information is provided about the chemical aspects important for scavenging activity. Thus, flavonoids could have beneficial effects in diseases such as atherosclerosis in which hypochlorite plays a pathogenic role.

Advanced glycation end products and advanced oxidation protein products in hemodialyzed patients.

Chronic renal failure is associated with increased oxidative and carbonyl stresses that contribute to long-term uremic complications. In our study, we determined two markers of these stresses--AGEs (advanced glycation end products) and AOPP (advanced oxidation protein products)--in chronic hemodialysis patients in order to find out their relationship to the dialysis treatment. Plasmas of 20 hemodialyzed patients treated with modified cellulose membranes were examined at 0 and 15 min and at the end (i.e. after 4 h) of the dialysis session. AGEs were estimated using a spectrofluorometric method (excitation 350 nm, emission 440 nm) and are expressed in AU (arbitrary units)/g protein. AOPP were determined spectrophotometrically (absorbance at 340 nm) and are expressed in chloramine units per gram of protein (micromol/g). AOPP decrease slightly from 0 to 15 min of the dialysis procedure (4.0 +/- 1.5 vs. 3.0 +/- 0.9 micromol/g, p < 0.01). However, they are increased at the end of the session (5.0 +/- 2.1 micromol/l vs. 15 min, p < 0.01, not significant vs. beginning). On the other hand, AGEs decrease continuously from the beginning to the end of the session (mainly in the first minutes of the dialysis) (1.52 +/- 0.34 x 10(4) AU/g at 0 min, 1.39 +/- 0.33 x 10(4) AU/g at 15 min, p < 0.001 vs. beginning, 1.30 +/- 0.33 x 10(4) AU/g at the end, p < 0.001 vs. beginning, not significant vs. 15 min). Neither AGEs nor AOPP correlate with the age of hemodialyzed patients and with the number of years of the dialysis treatment. AOPP correlate with AGEs before the dialysis session (r = 0.62, p < 0.05) but not after the session (r = 0.29, not significant). According to our results, AGEs may serve more as a marker of chronic damage while AOPP may better describe acute oxidative stress during the dialysis treatment.

Relative reactivities of N-chloramines and hypochlorous acid with human plasma constituents.

Hypochlorous acid (HOCl), the major strong oxidant produced by the phagocyte enzyme myeloperoxidase, reacts readily with free amino groups to form N-chloramines. Since different N-chloramines have different stabilities and reactivities depending on their structures, we investigated the relative reactivities of three model N-chloramines and HOCl with human plasma constituents. TheN-chloramines studied were N(alpha)-acetyl-lysine chloramine (LysCA, a model of protein-associated N-chloramines), taurine chloramine (TaurCA, the primary N-chloramine produced by activated neutrophils), and monochloramine (MonoCA, a lipophilic N-chloramine). Addition of these chlorine species (100--1000 microM each) to plasma resulted in rapid loss of thiols, with the extent of thiol oxidation decreasing in the order TaurCA = LysCA > MonoCA = HOCl. The single reduced thiol of albumin was the major target. Loss of plasma ascorbate also occurred, with the extent decreasing in the order HOCl > LysCA > TaurCA > MonoCA. Experiments comparing equimolar albumin thiols and ascorbate showed that while HOCl caused equivalent loss of thiols and ascorbate, theN-chloramines reacted preferentially with thiols. The chlorine species also inactivated alpha(1)-antiproteinase, implicating oxidation of methionine residues, and ascorbate provided variable protection depending on the chlorine species involved. Together, our data indicate that in biological fluids N-chloramines react more readily with protein thiols than with methionine residues or ascorbate, and thus may cause biologically relevant, selective loss of thiol groups.

Oxidation of intracellular glutathione after exposure of human red blood cells to hypochlorous acid.

Exposure of human red blood cells to low doses of hypochlorous acid (HOCl) resulted in the loss of intracellular GSH. Oxidation occurred less than 2 min after the addition of HOCl, and required approx. 2.5 mol of HOCl per mol of GSH lost. Loss of GSH preceded oxidation of membrane thiols, the formation of chloramines and haemoglobin oxidation. The susceptibility of intracellular GSH to oxidation by HOCl was two-thirds that of GSH in cell lysates. These results indicate that HOCl can penetrate the red cell membrane, which provides little barrier protection for cytoplasmic components, and that GSH oxidation by HOCl may be a highly selective process. Virtually all of the GSH lost was converted into GSSG. If glucose was added to the medium, most of the GSH oxidized by low doses of HOCl was rapidly regenerated. At higher doses, recovery was less efficient. However, when HOCl was added as a slow infusion rather than in a single bolus, there was increased recovery at higher doses. This indicates that in metabolically active cells regeneration is rapid and GSH may protect cell components from damage by HOCl. HOCl-induced lysis was only slightly delayed by adding glucose to the medium, indicating that lytic injury is not ameliorated by GSH.

An outbreak of Heinz body positive hemolytic anemia in chronic hemodialysis patients.

During the four month period, from December 1988 to March 1989, there was an outbreak of Heinz body positive hemolytic anemia in 34 patients undergoing hemodialysis in a 500-bed hospital, Seoul, Korea. The episodes of hemolysis were not reduced by changing the charcoal column and reverse osmosis system, or by adding ascorbic acid to the dialysate. The concentrations of nitrate, copper, aluminum and zinc in the treated water were all within the standards for hemodialysis. The chloramine concentration of the treated water was over 0.6 mg/L, markedly exceeding the allowable level of 0.1 mg/L. This high level of chloramine was proved to be due to the contamination of the water source by raw sewage. After we changed the source of water supply to another, no more episodes of hemolytic anemia occurred. It is concluded that chloramine is one of the major contaminants causing dialysis-induced hemolytic anemia and regular determinations are necessary, especially during winter and dry seasons.

A direct approach in fibrinolysis diagnostic: mimicry of the leukocyte by attack by oxidants.

Activated leukocytes release large amounts of chloramine like oxidizing agents (see Weiss et al. Science 222, 625-628, 1983) which inactivate protease inhibitors, creating microenvironments of uncontrolled protease activity. The biological result is an increased proteo- and fibrino- lysis. Functional determination of tissue type (t-PA) or urinary type (u-PA) plasminogen activator, the key enzymes of fibrinolysis, is of clinical importance. Assay techniques have been developed but are troublesome due to predilution, acidification or separation steps in order to eliminate the PA and plasmin inhibiting effect of plasmatic inhibitors of anti-PA and of anti-plasmin type, respectively. In this study, evidence is presented that performance of fibrinolytic assays using N-chloroamines offers great advantage: plasmatic plasminogen activator activity both of urinary and of tissue type can be measured precisely within minutes in untreated (direct) plasma samples. Therefore, mimicking the oxidative inflammatory response, for the first time it gets feasible to analyze blood factors involved in the physiological course of fibrinolysis by means of a functional, sensitive, and rapid assay procedure.

Oxidized fibrin(ogen) derivatives enhance the activity of tissue type plasminogen activator.

Oxidation of fibrinogen degradation products (FDP) with chloramines, results in a five- fold increase of their property to stimulate plasminogen activation by tissue type plasminogen activator (t-PA). Binding studies with immobilized stimulators demonstrated greater affinity of t-PA to oxidized than to unmodified FDP. The fibrin (ogen) domain responsible for this oxidant mediated increase in t-PA stimulation is localized in the D- subunit of fibrin(ogen). Thus, experimental data with (oxidized) I-labelled fibrin(ogen) should be interpreted with caution: the oxidized product might behave in a distinct manner than the unoxidized, native, one. As activated leukocytes release large amounts of oxidants of the chloramine type (Weiss et al., Science 222, 625-628, 1983), oxidation of fibrin might contribute significantly to fibrinolysis and proteolysis in areas of inflammation. The data give further evidence for an involvement of physiological components of haemostasis in non haemostasis but inflammation related processes.

Proteins released from stimulated neutrophils contain very high levels of oxidized methionine.

In proteins released from quiescent human neutrophils during incubation, 21% of the methionine (Met) residues were found to be oxidized. However, the portion of oxidized Met in extracellular proteins increased to 66% after stimulating the cells with zymosan and to 75% after stimulation with phorbol myristate acetate (PMA). Generation of such high levels of oxidized Met in native proteins by activated neutrophils has, so far, not been observed. The presence of superoxide dismutase during incubation of PMA-stimulated cells produced a negligible effect on methionine oxidation, while the presence of catalase resulted in a methionine sulfoxide (Met(O)) content of only 28% in the released proteins. It is proposed that the conversion of Met to Met(O) in these proteins predominantly occurs by action of the myeloperoxidase/H2O2/Cl- system in the extracellular space.

Chlorination of endogenous amines by isolated neutrophils. Ammonia-dependent bactericidal, cytotoxic, and cytolytic activities of the chloramines.

Isolated human neutrophilic leukocytes were stimulated to produce hydrogen peroxide (H2O2) and to secrete cytoplasmic granule components including myeloperoxidase into the medium. Myeloperoxidase catalyzed the oxidation of chloride (Cl-) by H2O2 to yield hypochlorous acid (HOCl), which reacted with endogenous nitrogen compounds to yield derivatives containing nitrogen-chlorine (N-Cl) bonds. Compounds available for reaction with HOCl were ammonia (NH+4), taurine, alpha-amino acids, and granule proteins and peptides that were released into the medium. A portion of the N-Cl derivatives formed under these conditions accumulated in the extracellular medium. These long lived oxidizing agents were characterized as hydrophilic, low molecular weight, mono-N-chloramine (RNHCl) derivatives based on their absorption spectrum, ability to oxidize 5-thio-2-nitrobenzoic acid and to chlorinate ammonia (NH+4), and behavior upon ultrafiltration, gel chromatography, and extraction with organic solvents. The RNHCl derivatives were of low toxicity, but reacted with NH+4 to yield the lipophilic oxidizing agent monochloramine (NH2Cl). Therefore, the addition of NH+4 conferred bactericidal, cytotoxic, and cytolytic activities on the RNHCl derivatives. The results indicate that taurine and other neutrophil amines protect neutrophils and other cells against oxidative attack by acting as a trap for HOCl and by competing with endogenous NH+4 for reaction with HOCl. However, the RNHCl derivatives act as a reserve of oxidizing equivalents that is converted to a toxic form when an increase in NH+4 concentration favors formation of NH2Cl.

Determination of cyanide and thiocyanate in blood plasma and red cells by high-performance liquid chromatography with fluorometric detection.

A method for the determination of cyanide and thiocyanate in blood plasma and red cells of humans was established. It involved high-performance liquid chromatography and fluorometric detection by the König reaction. Calibration curves for cyanide and thiocyanate were linear in the range 1-200 pmol and 2-300 pmol, respectively. Clean-up methods for the determination of cyanide and thiocyanate in red cells were also developed. These methods were applied for the determination of cyanide and thiocyanate in the blood of smokers and non-smokers.