Luminol chemiluminescence studies of the oxidation of cysteine and other thiols to disulfides

Reaction of N-Acetylcysteine with Cu(2+): Appearance of Intermediates with High Free Radical Scavenging Activity: Implications for Anti-/Pro-Oxidant Properties of Thiols

We studied the kinetics of the reaction of N-acetyl-l-cysteine (NAC or RSH) with cupric ions at an equimolar ratio of the reactants in aqueous acid solution (pH 1.4−2) using UV/Vis absorption and circular dichroism (CD) spectroscopies. Cu2+ showed a strong catalytic effect on the 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonate) radical (ABTSr) consumption and autoxidation of NAC. Difference spectra revealed the formation of intermediates with absorption maxima at 233 and 302 nm (ε302/Cu > 8 × 103 M−1 cm−1) and two positive Cotton effects centered at 284 and 302 nm. These intermediates accumulate during the first, O2-independent, phase of the NAC autoxidation. The autocatalytic production of another chiral intermediate, characterized by two positive Cotton effects at 280 and 333 nm and an intense negative one at 305 nm, was observed in the second reaction phase. The intermediates are rapidly oxidized by added ABTSr; otherwise, they are stable for hours in the reaction solution, undergoing a slow pH- and O2-dependent photosensitive decay. The kinetic and spectral data are consistent with proposed structures of the intermediates as disulfide-bridged dicopper(I) complexes of types cis-/trans-CuI2(RS)2(RSSR) and CuI2(RSSR)2. The electronic transitions observed in the UV/Vis and CD spectra are tentatively attributed to Cu(I) → disulfide charge transfer with an interaction of the transition dipole moments (exciton coupling). The catalytic activity of the intermediates as potential O2 activators via Cu(II) peroxo-complexes is discussed. A mechanism for autocatalytic oxidation of Cu(I)−thiolates promoted by a growing electronically coupled −[CuI2(RSSR)]n− polymer is suggested. The obtained results are in line with other reported observations regarding copper-catalyzed autoxidation of thiols and provide new insight into these complicated, not yet fully understood systems. The proposed hypotheses point to the importance of the Cu(I)−disulfide interaction, which may have a profound impact on biological systems.

Amyloid formation of fish β-parvalbumin involves primary nucleation triggered by disulfide-bridged protein dimers

Amyloid fibrils are generally related to neurodegenerative diseases, but they can also be part of normal protein function. Amyloid formation involves numerous steps and intermediate species. In this study, we investigated a fish protein, beta-parvalbumin, which readily forms amyloid on ligand removal. Using biophysical experiments, we provide evidence that the underlying mechanism of amyloid formation includes primary nucleation and elongation processes; we also reveal a key role for a disulfide-bridged dimer in the nucleation step. Little is known about intermolecular disulfides in amyloid formation, but covalent dimers and dimer-induced aggregation may be of clinical relevance, because oxidative stress, which can trigger covalent bond formation, is often a hallmark of human neurodegenerative diseases.

Amyloid formation involves the conversion of soluble protein species to an aggregated state. Amyloid fibrils of β-parvalbumin, a protein abundant in fish, act as an allergen but also inhibit the in vitro assembly of the Parkinson protein α-synuclein. However, the intrinsic aggregation mechanism of β-parvalbumin has not yet been elucidated. We performed biophysical experiments in combination with mathematical modeling of aggregation kinetics and discovered that the aggregation of β-parvalbumin is initiated by the formation of dimers stabilized by disulfide bonds and then proceeds via primary nucleation and fibril elongation processes. Dimer formation is accelerated by H₂O₂ and hindered by reducing agents, resulting in faster and slower aggregation rates, respectively. Purified β-parvalbumin dimers readily assemble into amyloid fibrils with similar morphology as those formed when starting from monomer solutions. Furthermore, addition of preformed dimers accelerates the aggregation reaction of monomers. Aggregation of purified β-parvalbumin dimers follows the same kinetic mechanism as that of monomers, implying that the rate-limiting primary nucleus is larger than a dimer and/or involves structural conversion. Our findings demonstrate a folded protein system in which spontaneously formed intermolecular disulfide bonds initiate amyloid fibril formation by recruitment of monomers. This dimer-induced aggregation mechanism may be of relevance for human amyloid diseases in which oxidative stress is often an associated hallmark.

Programmable self-assembly of a cystamine-block copolymer in response to pH and progressive reduction–ionization–oxidation

A water-soluble cystamine-block copolymer undergoes air/pH-mediated programmable self-assembly/reconstructions simply stemming from the unique environment-mediated reaction complexity of the cystamine-functionalized unit.

Factors Affecting Activity and Stability of the Kluyveromyces lactis Killer Toxin

A number of physical parameters determining the activity and stability of the killer toxin produced by the yeast Kluyveromyces lactis have been investigated. The toxin was active over a relatively narrow pH range of 4.4 to 5.8, with a maximum at the lower end of the range. However, it was stable up to at least pH 8.0 but appeared to be irreversibly inactivated below pH 4.4. The toxin was stable at 40 degrees C but rapidly inactivated at 50 degrees C. Strong agitation caused the inactivation of the toxin in one medium but not another; this seemed to be due to oxygen-mediated disulfide bond formation, which could be prevented by sulfhydryl protecting agents.

Superoxide-superoxide oxidoreductase activity of the captopril-copper complex

BACKGROUND

The purpose of this study was to determine whether the interaction of captopril, an angiotensin-converting enzyme inhibitor, with copper could modify the superoxide dismutase activity of this metal. Results may help to explain the interaction of captopril with reactive oxygen species in the stunned myocardium where substantial mobilization of copper and iron in the coronary flow following ischemia has been reported.

METHODS

An assay that generates superoxide anion radicals without the intervention of metal ions was utilized. In addition, direct EPR analysis was applied to assess the redox state of copper during reactions.

RESULTS

Captopril-copper complex inhibited the superoxide-mediated reduction of nitroblue tetrazolium. In addition, captopril-copper complex was able to suppress formazan production by potassium superoxide. Direct EPR analysis showed that copper was reduced to the cuprous state by captopril and remained in this state in the course of the reaction. Captopril was also stable during the dismutation reaction.

CONCLUSIONS

We conclude that cuprous-captopril complex is a catalytic species with properties different from those of Cu(2+) alone. A model in which sulfur acts as electron acceptor/donor in place of the metal is proposed and a mechanism of action for this complex is discussed.

Thiols enhance the sensitivity of luminescent assays for non-cross-linked and covalently cross-linked aminophthalhydrazides

Transglutaminases catalyse an acyl-transfer reaction between the gamma-carboxamide of a protein or peptide-bound glutamine (P-CH2-gammaCH2-CO-1NH2) and the primary amino group of mono- or polyamines (R-2NH2), covalently cross-linking the reactants by an isopeptide bond: P-CH2-gammaCH2-CO-1NH2 + R-2NH2 --> P-CH2-gammaCH2-CO-2NH-R + 1NH3. We reported that N-(4-aminobutyl)-N-ethylisoluminol (ABEI) was a chemiluminescent (CL) amine substrate for transglutaminases. We now identified N-(6-aminohexyl)-N-ethylisoluminol (AHEI) as a second, less reactive, transglutaminase substrate. A structure-based explanation is offered for the lower reactivity of AHEI. Optimum CL from non-cross-linked or cross-linked ABEI or AHEI was elicited in the presence of 10 mmol/L dithiothreitol, by oxidizing with a mixture of 20 mmol/L potassium ferricyanide and 10 mmol/L hydrogen peroxide in 100 mmol/L NaOH. The limits of detection and quantitation for non-cross-linked aminophthalhydrazides obtained in this system were: 20 fmol and 60 fmol for ABEI and 10 fmol and 30 fmol for AHEI. These values represented a 500-800-fold improved sensitivity. Delayed peak CL and CL decay in the presence of dithiothreitol contributed to improving the sensitivity. The data could be useful for improving the immunoassays for aminophthalhydrazides and facilitate the development of high throughput assays for transglutaminases.

The effects of antioxidants and enzymes involved in glutathione metabolism on mutagenesis by glutathione and L-cysteine

The effects of small molecular weight antioxidants and antioxidant enzymes on the mutagenicities of glutathione (GSH) and L-cysteine were studied in Salmonella typhimurium strain TA102. GSH and cysteine mutagenesis were inhibited by antioxidants and radical scavengers such as alpha-tocopherol, Trolox C, butylated hydroxyanisole (BHA), and retinyl acetate. Superoxide dismutase (SOD) had no effect, but catalase and horseradish peroxidase (HRP) inhibited mutagenesis. The heat-denatured enzymes had no effect on mutagenesis. Cysteine mutagenesis was enhanced by native and by heat-denatured rat-kidney post-mitochondrial supernatant, and by ferric ions. H2O2 and the H2O2-generating system of glucose-glucose oxidase (GOX) were mutagenic in TA102. Synergistic increases in mutagenesis were obtained in systems containing combinations of GSH or cysteine, with either H2O2 or the H2O2-generating system of glucose-GOX. GSH peroxidase (GPX) had no effect on mutagenesis of GSH or of H2O2, whereas the synergistic increase in mutagenesis by a combination of GSH and H2O2 was effectively inhibited by GPX. The results suggest strongly that, at least in biochemically-defined systems, GSH and cysteine mutagenesis are oxidative in nature, and involve reactive forms of oxygen and/or other radicals.

Iron-thiolate induced oxidation of methionine to methionine sulfoxide in small model peptides. Intramolecular catalysis by histidine

Peptides containing either glycine and methionine, or glycine, methionine and histidine at various locations were oxidized by the dithiothreitol/ferric chloride system in phosphate buffer. The yields of peptide degradation and sulfoxide formation were measured as a function of peptide sequence and pH. In general little change of the final yields of peptide degradation is observed whereas the final yields of sulfoxide formation progressively decrease on going from pH 6.0 to 8.0. The pH profiles vary with the structure of the respective peptide. Efficient sulfoxide formation occurred when histidine and methionine were present within the same peptides sequence, and particularly when methionine was located at the C-terminus of the peptide. Added superoxide dismutase, catalase, and methanol did neither promote nor inhibit both the degradation of peptide and the formation of sulfoxide excluding free superoxide, hydrogen peroxide, and hydroxyl radicals as responsible reactive oxygen species. The observations are rationalized by invoking a pH-dependent conversion of an efficiently sulfoxide yielding oxidant into another oxidant which still degrades peptides but does not form methionine sulfoxide. The first might be a metal-bound peroxide or peroxyl species which converts into a metal-bound or 'complexed' hydroxyl radical.

What we can learn from the effects of thiol reagents on transport proteins

Many secondary membrane transport systems contain reactive sulfhydryl groups. In this review the applications of SH reagents for analyzing the role of sulfhydryl groups in membrane transport systems will be discussed. First an overview will be given of the more important reagents, that have been used to study SH-groups in membrane transport systems, and examples will be given of transport proteins in which the role of cysteines have been analyzed. An important application of SH-reagents to label transport proteins using various SH-reagents modified with fluorescent- or spin-label moieties will be discussed. Two general models are shown which have been proposed to explain the role of sulfhydryl groups in some membrane transport systems.

Inhibition by thiols of copper(II)-induced oxidation of oxyhemoglobin

The ability of thiols, 2-imidazolethiones and uric acid to protect bovine oxyhemoglobin from copper(II)-induced oxidation to methemoglobin was investigated. The oxidation of oxyhemoglobin by Cu(II) proceeded in two phases: (1) an initial rapid reaction (less than 30 s) followed by (2) a slower reaction that carried it to completion. Thiols, including N-acetyl-L-cysteine, DL-dithiothreitol, reduced glutathione, DL-homocysteine, 2-mercaptoethanol and 2- and 3-mercaptopropionic acid, whose sulfhydryl groups were slowly oxidized by Cu(II) (with the exception of 2-mercaptopropionic acid), protected oxyhemoglobin in both phases of the reaction. Other thiols, including L-cysteine, cysteamine, and D-penicillamine, whose sulfhydryl groups were readily oxidized by Cu(II), protected hemoglobin initially, but within 2-4 min, the rate of methemoglobin formation was the same as Cu(II)-treated oxyhemoglobin. 2-Mercaptoimidazole and 1-methyl-2-mercaptoimidazole, which complex Cu(II) and inhibit Cu(II)-catalyzed oxidation of ascorbic acid, also protected hemoglobin in the initial phase, but not in the second phase. Uric acid, L-ergothioneine, and thiourea did not protect oxyhemoglobin in either the fast or slow phase. Cu(II) may have a coordination site involved in the oxidation of hemoglobin that is not blocked by the 2-imidazolethiones, uric acid, or the oxidized thiols. It is concluded that certain thiols that complex Cu(II) and are not rapidly oxidized will protect oxyhemoglobin from Cu(II)-induced oxidation, but the thiols are no longer effective once they are oxidized.

Chemical cleavage of plasmid DNA by glutathione in the presence of Cu(II) ions. The Cu(II)-thiol system for DNA strand scission

In the presence of Cu(II) ions, supercoiled DNA is cleaved in neutral solution by low concentrations of thiols. Supercoiled plasmid DNA is cleaved first to open circular DNA, which in turn produces linear DNA and eventually fragments. Cleavage is strongly temperature-dependent and is maximal at 0.10-0.25 M-NaCl concentration. In the presence of excess of either component of the Cu(II)-thiol pair, the extent of cleavage depended on the concentration of the limiting partner, and was easily detectable down to micromolar concentrations of limiting GSH. Scavengers of oxygen-derived species (such as hydrogen peroxide, superoxide radical ion and hydroxyl radical) indicated that the hydroxyl radical may be involved in the cleavage mechanism. DNA cleavage leads to some production of 2-thiobarbituric acid-reactive species and some of the cleavage sites, at least, had 5'-hydroxy and/or 3'-hydroxy groups. There was extensive base damage before cleavage. Studies with S1 nuclease indicated no gross sequence preference for Cu(II)-GSH cleavage of pSP64 plasmid DNA. The Cu(II)-thiol system did not appear to target special structural features in the DNA such as Z-DNA inserts, cruciform structures or left-handed (but non-Z) DNA. Cleavage might arise from a reagent generated either by the Cu(II)-thiol combination in free solution or by attack involving Cu(II) ions pre-bound to DNA. The attack of GSH plus Cu(II) ions on DNA may be a potential toxic lesion under physiological conditions unless special protective measures operate efficiently in the cell.

Stability of protein pharmaceuticals

Recombinant DNA technology has now made it possible to produce proteins for pharmaceutical applications. Consequently, proteins produced via biotechnology now comprise a significant portion of the drugs currently under development. Isolation, purification, formulation, and delivery of proteins represent significant challenges to pharmaceutical scientists, as proteins possess unique chemical and physical properties. These properties pose difficult stability problems. A summary of both chemical and physical decomposition pathways for proteins is given. Chemical instability can include proteolysis, deamidation, oxidation, racemization, and beta-elimination. Physical instability refers to processes such as aggregation, precipitation, denaturation, and adsorption to surfaces. Current methodology to stabilize proteins is presented, including additives, excipients, chemical modification, and the use of site-directed mutagenesis to produce a more stable protein species.

A mitochondrial chemiluminescence evoked by a novel mixed copper(II)-cyanide complex/acetaldehyde cyanohydrin chelate: a kinetic analysis suggesting a role for membrane-bound vicinal sulfhydryls

Cyanide added to mitochondria in the presence of copper and acetaldehyde evokes a chemiluminescence which follows series pseudo-first-order kinetics: (formula; see text) An evaluation of the effects of protein (mitochondria), copper, cyanide, acetaldehyde, and oxygen on the kinetic parameters shows that k1 is influenced by protein, cyanide (at low concentrations), and oxygen while k2 is influenced by cyanide, acetaldehyde (at low, less than 11.9 mM, and high, greater than 35.6 mM, concentrations), and oxygen. The integral light increases linearly with the square root of total copper(II) and with the square of the total acetaldehyde. The sustained emissions appear to reflect an initial oxidative event mediated by a novel mixed copper(II)-cyanide complex/acetaldehyde cyanohydrin chelate. Cu(I) formed by the reduction of Cu(II), probably by mitochondrial vicinal sulfhydryls, reacts with dioxygen to form an O2-copper complex which reacts with acetaldehyde to form the acetyl-1-hydroxyhydroperoxyl radical. This radical disproportionates by the Russell mechanism to generate electronically excited singlet and triplet carbonyl functions and singlet oxygen species whose emissive relaxations to the ground state display as the observed chemiluminescence. The kinetic evidence indicates that there are two Cu(I)-oxygen cyanide complexes transferring O2- to acetaldehyde. This evidence addresses the mechanisms of autoxidation of low-molecular-weight Cu(I) complexes with dioxygen. A suggested role for the involvement of vicinal sulfhydryl groups in the reactions is shown, kinetically, by the influence of copper and acetaldehyde on the integral light.

Secretion of pyruvate. An antioxidant defense of mammalian cells

Cells in culture are exposed to marked oxidative stress, H2O2 being one of the predominant agents. Pyruvate and other alpha-ketoacids reacted rapidly, stoichiometrically, and nonenzymatically with H2O2, and they protected cells from its cytolytic effects. All five human and murine cell types studied, both malignant and nonmalignant, released pyruvate at an initial rate of 35-60 microM/h/2.5 X 10(6) cells when placed in 1 ml pyruvate-free medium. After 6-12 h a plateau of 60-150 microM pyruvate was attained, corresponding to concentrations reported for normal human serum and plasma. The rate of pyruvate accumulation was almost doubled in the presence of exogenous catalase, suggesting that released pyruvate functions as an antioxidant. The rate of pyruvate accumulation was dependent on cell number. Succinate, fumarate, citrate, oxaloacetate, alpha-ketoglutarate, and malate were not secreted in significant amounts from P815 cells; export was specific for pyruvate and lactate among the metabolites tested. Extracellular pyruvate was in equilibrium with intracellular stores. Thus, cells conditioned the extracellular medium with pyruvate at the expense of intracellular pyruvate, until homeostatic levels were attained in both compartments. We propose that cells plated at low density in the absence of exogenous pyruvate fail to thrive for two reasons: prolonged depletion of intracellular pyruvate and prolonged vulnerability to oxidant stress.

A versatile transition metal salt reaction for a wide range of common biochemical reagents: an instantaneous and quantifiable color test

A rapid and sensitive spot test amenable to visual or spectrophotometric quantitation has been developed for a wide variety of biochemical reagents by utilizing the transition metal salt cupric chloride and its large number of related colored compounds. This assay is potentially a widely applicable multipurpose test for rapidly detecting the presence of unknown substances. Combination of the test sample with the working reagent results in the immediate formation of a distinctive colored product that may be precipitable. Some compounds require the further addition of sodium hydroxide in order to generate the distinctively colored product. Distinctive reactions occur with the following reagents, and their limit of visual detection is indicated in parentheses: ammonium bicarbonate (12.5 mM), ammonium acetate (25 mM), ammonium hydroxide (0.1%), ammonium sulfate (2%), ammonium persulfate (0.02 mM), L-(+)-cysteine (0.07 mM), dithiothreitol (DTT) (1.25 mM), EDTA (0.6 mM), ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid (5 mM), D-glucose (6 mM), glycerol (0.3%), imidazol (12.5 mM), DL-methionine (100 mM), mercaptoethanol (0.05%), sodium azide (19 mM, 0.1%), sodium dithionite (0.25%), sodium metabisulfite (25 mM), sodium nitrite (6.2 mM), sodium periodate (3.1 mM), sodium sulfite (12.5 mM), sodium thiosulfite (12.5 mM), sucrose (6 mM), and N,N,N',N'-tetramethylethylenediamine (0.05%). A distinctive exothermic reaction occurs with hydrogen peroxide, but without color change. Compounds reacting insignificantly include 50 mM Tris buffer, urea, N,N'-methylene bisacrylamide, sodium dodecyl sulfate, isopropyl alcohol, sodium fluoride, trichloroacetic acid, phenol, mannose, K2HPO4, guanidine HCl, chloramine-T, magnesium chloride, and boric acid, where the solids were tested at approximately 10 mg/ml. Spectrophotometric standard curves were developed for DTT and sodium azide utilizing the clear supernatants resulting from these reactions. Combinations of at least four reagents could be discriminated, as demonstrated with mixtures of glucose, sodium azide, EDTA, and DTT. In addition ammonium sulfate could be detected to a limit of 4% in the presence of protein, DTT, and EDTA in a 50 mM Tris buffer. Spot tests were developed which utilized reagent-impregnated filter paper and gave distinctive colored products on addition of 5 microliter of test sample.

Role of keto acids and reduced-oxygen-scavenging enzymes in the growth of Legionella species

Keto acids and reduced-oxygen-scavenging enzymes were examined for their roles in supporting the growth of Legionella species and for their potential reactions between the chemical components of the media. When grown in an experimental ACES (2-[(2-amino-2-oxoethyl)-amino] ethanesulfonic acid)-buffered chemically defined (ABCD) broth, the presence of keto acids shortened the lag periods, increased the rates of growth, and gave maximum cell yields. In addition, keto acids affected the specific activities of reduced-oxygen-scavenging enzymes determined during growth. The specific activities of superoxide dismutase of Legionella pneumophila (Knoxville) and L. dumoffii (TEX-KL) were increased three- to eightfold, while that of L. bozemanii (WIGA) was not affected. All strains appeared to be equally sensitive to the effects of superoxide anion (O2-) generated by light-activated riboflavin, and all were equally protected by the presence of keto acids in the ABCD broth. Production of trace amounts of acetate and succinate in pyruvate- and alpha-ketoglutarate-containing media exposed to light suggested that hydrogen peroxide was formed. Pyruvate and alpha-ketoglutarate were products of growth on amino acids, and there was no quantitative evidence that these keto acids were metabolized when they were added to the medium. The rate of cysteine oxidation in ABCD broth was increased by the presence of ferric ion or by exposure to light or by both, and keto acids reduced the rate of this oxidation. ACES buffer was a substrate for the production of O2- in the presence of light, and the combined addition of Fe2+ ions, cysteine, and either keto acid to the medium strongly inhibited the production of O2-. Thus, keto acids inhibited the rate of cysteine oxidation, they stimulated rapid growth by an unknown process, and, in combination with added Fe2+ ions and cysteine, they reversed the toxic effects of light by inhibiting O2- production.

Hydrogen peroxide from cellular metabolism of cystine. A requirement for lysis of murine tumor cells by vernolepin, a glutathione-depleting antineoplastic

The sesquiterpene lactone antineoplastic vernolepin acutely depletes murine tumor cell glutathione (GSH), and lyses the cells by an unknown mechanism that is enhanced synergistically by inhibition of GSH synthesis with buthionine sulfoximine (BSO) (Arrick et al. 1983. J. Clin. Invest. 71:258). We found here that lysis of P815 mastocytoma cells by vernolepin, with or without BSO, required cystine in the culture medium. Addition of catalase markedly suppressed vernolepin-mediated cytolysis in cystine-containing media, suggesting the involvement of hydrogen peroxide in the cytolytic action of vernolepin. Consistent with this, inhibition of tumor cell glutathione disulfide reductase with 1,3-bis(2-chloroethyl)-1-nitrosourea or inhibition of endogenous catalase with aminotriazole synergistically augmented cytolysis by vernolepin. Moreover, H2O2 was released by suspensions of P815 cells in cystine-containing buffer (63 pmol/10(6) cells X h). Omission of cystine reduced the rate of H2O2 accumulation 10-fold. No H2O2 was detected without cells. Cytolysis by vernolepin could be restored in cystine-deficient medium by several other disulfides, themselves noncytolytic, such as disulfiram and oxidized Captopril, as well as by cysteine. In contrast, withholding two other essential amino acids (leucine or tryptophan) or adding cycloheximide did not interfere with cytolysis by vernolepin. These results suggest that cellular uptake of disulfides of physiologic and pharmacologic interest may be followed by their intracellular reduction and autooxidation with generation of H2O2. This previously unrecognized source of intracellular oxidant stress may be an important component of injury to GSH-depleted cells.

Presence of hydrogen peroxide in media used for cultivation of Neisseria gonorrhoeae

Defined complex media used for cultivation of Neisseria gonorrhoeae were tested for the presence of H2O2 by both a spectrophotometric and a polarographic assay. H2O2 (35 to 165 microM) was present in all media tested. In the defined media, H2O2 was generated by the interaction of cysteine with other amino acids. The addition of the chelator 8-hydroxyquinoline prevented formation of detectable H2O2, suggesting that metal ions were necessary. The persistence of H2O2 varied greatly among different media. Medium components which affected the presence of H2O2 were pyruvate, oxalacetate, and sodium sulfite. Sodium sulfite also generated superoxide radical. In liquid medium containing H2O2, the endogenous gonococcal catalase present in an inoculum of about 2 X 10(7) colony-forming units/ml destroyed detectable H2O2. The long lag phase which resulted from a 10-fold lower inoculum could not be shortened by the addition of exogenous catalase. Small amounts of residual H2O2 in agar plates of complex medium affected the viability of gonococci which had been suspended in buffer and incubated for 60 min at 37 degrees C. Addition of pyruvate or catalase increased viable counts in medium containing H2O2.

Induction of sister-chromatid exchanges in Chinese hamster ovary cells by thiol and hydrazine compoudns

Cysteine, cysteamine and glutathione all induce sister-chromatid exchanges (SCEs) in Chinese hamster ovary (CHO) cells when applied to cell cultures at concentrations between 10(-4) and 10(-2) M. Acute exposure of cells th thiol compound for a period of 2--3 h resulted in a unique dose--response relationship in each instance. This consisted of two peak SCE frequencies, one at either extreme of the concentration range. Each peak corresponded to a 2--3-fold increase over the spontaneous level. A chronic exposure of 24 h, in contrast, resulted in a dose--response relationship consisting of a single peak SCE frequency (representing a 4--5-fold increase over the spontaneous level) at a concentration of approx. 4 x 10(-4) M. The effect of Cu2+ ions included in the medium at a concentration of 10(-5) M was to increase the toxicity and, at some concentrations, the SCE levels occurring after either acute or chronic exposure to thiols. Hydrazine and its derivatives, dimethylhydrazine and isonicotinic acid hydrazide (isoniazid), as well as hydrogen peroxide, also induce SCEs in CHO cells. A 2--3-fold increase over the spontaneous level was observed, depending upon the particular treatment protocol applied. SCE yields after 3 h treatment with dimethylhydrazine and isoniazid were increased if Mn2+, but not Cu2+, was included in the tissue culture medium at a concentration of 10(-5) M. SCE yields after a 24-h treatment with dimethylhydrazine in which Mn2+ was present in, and absent from, the medium were similar. Catalase was observed to reduce the SCE levels resulting from treatment with hydrogen peroxide, dimethylhydrazine and isoniazid. The effect of catalase upon SCEs induced by dimethylhydrazine and isoniazid in the presence of Mn2+ was more evident than when Mn2+ was not included in the culture medium. The significance of these results with respect to the possible active chemical species produced and the mutagenic/carcinogenic risk associated with thiol and hydraizine compounds is discussed.

[The change of hyaluronic acid of the vitreous humour by oxidation-reduction-systems (author's transl)]

Purified hyaluronic acid of ox vitreous humour was isolated treating the acetone precipitate of a vitreous humour homogenate with 1 M NaCl solution and thereafter with cetylpyridiniumchloride. Both disc-electrophoresis and hydroxyproline content proved the absence of collagen in the purified hyaluronic acid. FeSO4, ascorbate, and cysteine changed the hyaluronic acid molecule and lowered the viscosity of the hyaluronic acid solution, EDTA alone did not affect the viscosity but enhanced the effectiveness of iron ions or ascorbate on the viscosity of the solution. Catalase prevented the reduction of the viscosity by the above mentioned substances. Therefore, it is suggested that H2O2 and free radicals are generated during the reaction. The free radicals produced are responsible for the change of the hyaluronic acid molecule.