Johann M. van Zyl

Maternal separation of rat pups increases the risk of developing depressive-like behavior after subsequent chronic stress by altering corticosterone and neurotrophin levels in the hippocampus

Children that are abused have an increased risk for developing psychiatric disorders later in life, because of the negative effects of stress on the developing brain. We used a maternal separation model in rats to see how neurotrophins, stress hormones, behavior and the anti-oxidant potential of serum are affected. Rat pups were separated from their mothers for 3h/day on days 2-14. Maternal separation caused changes in levels of NGF and NT-3 in the dorsal and ventral hippocampus, increased basal corticosterone levels and decreased ACTH levels after acute restraint stress. The anti-oxidant potential of the rat serum was significantly lower in the maternal separation group. Depressive-like behavior, measured during a forced swim test, was seen in maternally separated rats after additional chronic stress during adulthood. Maternal separation caused downregulation of neurotrophins in the ventral hippocampus, possibly as an effect of high corticosterone levels, but compensatory mechanisms against cell death may be involved as neurotrophin levels increased in the dorsal hippocampus. Decreased anti-oxidant potential of serum could have been an effect of downregulated neurotrophin levels.

Mechanisms by which clofazimine and dapsone inhibit the myeloperoxidase system. A possible correlation with their anti-inflammatory properties

The mechanisms by which two anti-leprotic drugs (clofazimine and dapsone), both with anti-inflammatory properties, inhibit myeloperoxidase (MPO)-catalysed reactions, were investigated. The disappearance of NADH fluorescence was used as an assay for its oxidation. Chloride stimulated the oxidation of NADH in the MPO-H2O2 system in a concentration-dependent manner (50-fold at 150 mM NaCl). Under these conditions Cl- is oxidized and the oxidant formed, presumably hypochlorous acid (HOCl), oxidizes NADH. Observations demonstrating the effect of the drugs on the MPO system, are: (1) Inhibition of Cl(-)-stimulated oxidation of NADH. (2) Inhibition of polypeptide modification in a model protein, thyroglobulin (TG). (3) Protection of MPO against loss of catalytic activity caused by chlorinating oxidants generated by the system. (4) Inhibition of haemoglobin oxidation. Only dapsone was active here. HPLC analyses suggested that the drugs were not significantly metabolized in the MPO-H2O2 system in the absence of Cl-. Bleaching of clofazimine was stimulated by Cl- in the MPO system, suggesting the involvement of HOCl. Clofazimine was found to be a more potent scavenger of HOCl than dapsone when the inhibition of NADH oxidation by reagent HOCl was used as an assay. This finding is also supported by HPLC analyses which indicated a greater sensitivity of HOCl for clofazimine than for dapsone. Relatively low concentrations of dapsone inhibited the oxidation of oxygenated haemoglobin (HbO2), suggesting that the drug was not metabolized to its N-hydroxylated derivative which is thought to be responsible for methaemoglobin (metHb) formation in vivo. It is proposed that the inhibitory mechanism of action of clofazimine is to scavenge chlorinating oxidants generated by the MPO-Cl(-)-H2O2 system, while dapsone converts MPO into its inactive compound II (ferryl) form. The different inhibitory mechanisms of clofazimine and dapsone towards the MPO system may contribute to the anti-inflammatory actions of the drugs.

Isoniazid-mediated irreversible inhibition of the myeloperoxidase antimicrobial system of the human neutrophil and the effect of thyronines

During aerobic myeloperoxidase-catalysed oxidation of isoniazid at pH 7.8, compound III was generated. Oxidation of isoniazid or hydrazine sulphate at pH values of 6.5 or 7.8 in a myeloperoxidase-H2O2 system caused considerable haem loss, which was associated with compound III formation. Haem loss and also compound III formation could be inhibited when 8 microM thyroxine was included in the reaction mixtures. During the reaction with isoniazid, an intense pink-coloured pigment with maximum absorbance at 500 nm was formed which could be bleached with ascorbate or hypochlorous acid. The pigment was more stable at pH 7.8 than at pH 6.5. A similar pink colour was generated when a mixture of isoniazid and thyroxine in alkaline solution was irradiated with light of wavelength greater than 300 nm. A possible product of thyroxine oxidation, 3,5-diiodotyrosine, could not protect the enzyme against isoniazid-mediated haem loss and no colour formation was observed. Haem loss was most extensive when isoniazid was oxidised in a myeloperoxidase system at pH 7.8 in the presence of 0.1 M NaCl. Thyroxine (8 microM), however, could still inhibit haem loss under these conditions. A good correlation was found between haem loss and irreversible loss of peroxidase activity.

Anti-oxidant properties of H2-receptor antagonists: Effects on myeloperoxidase-catalysed reactions and hydroxyl radical generation in a ferrous-hydrogen peroxide system

Ulcerogenesis of the gastroduodenal mucosa is caused by the digestive action of gastric juice and initially involves an inflammatory reaction with infiltration of phagocytes. The anti-inflammatory activity of many drugs have been attributed to the inhibition of the leukocyte enzyme, myeloperoxidase (MPO). In this study, the H2-antagonists in clinical use were found to be potent inhibitors of MPO-catalysed reactions (IC50 < 3 microM) under conditions resembling those in experiments with intact neutrophils. Since peak plasma concentrations of cimetidine, ranitidine and nizatidine are well within the micromolar range, after oral therapeutic dosing, our results may be of clinical relevance. The inhibitory actions of cimetidine and nizatidine were largely due to scavenging of hypochlorous acid (HOCl), a powerful chlorinating oxidant produced in the MPO-H2O2-Cl- system. In contrast to famotidine, ranitidine was also a potent scavenger of HOCl, while both drugs inhibited MPO reversibly by converting it to compound II, which is inactive in the oxidation of Cl-. The HOCl scavenging potencies of ranitidine and nizatidine were about three times higher than that of the anti-rheumatic drug, penicillamine, which had a potency similar to that of cimetidine. The rapid HOCl scavenging ability of penicillamine is thought to contribute to its anti-inflammatory effects. Using riboflavin as a probe, the H2-antagonists were found to be inhibitors of hydroxyl radical (.OH) generated in a Fe(2+)-H2O2 reaction mixture. Spectral analyses of the interaction of iron ions with the drugs and studies with chelators, suggest that the drugs were efficient chelators of Fe2+, in addition to their .OH scavenging abilities. Since the gastrointestinal tract can contain potentially reactive iron, the simultaneous presence of H2-antagonists may help to suppress iron-driven steps in tissue damage.

The inhibitory effect of acetaminophen on the myeloperoxidase-induced antimicrobial system of the polymorphonuclear leukocyte.

Acetaminophen binds via its acetamido side chain to purified myeloperoxidase in a pH-dependent manner and maximum binding occurred around pH 6. The H2O2-dependent myeloperoxidase-catalysed polymerization products of acetaminophen had excitation maxima at 304 nm and 334 nm in acid and alkaline solutions, respectively, and an intense blue fluorescence maximum at 426 nm. Acetaminophen can compete effectively with Cl- as myeloperoxidase substrate and thus HOCl formation is suppressed while HOCl, nevertheless present, can be scavenged by the drug. In this way the microbicidal action of the myeloperoxidase-H2O2-Cl- system can be seriously limited in the presence of high concentrations of acetaminophen. To study the effect of acetaminophen on peptide bond splitting in the myeloperoxidase antimicrobial system, thyroglobulin was used as a model peptide. Peptide bond splitting was inhibited at acetaminophen concentrations below the accepted toxic range for plasma values.

Biochemical Model for Inflammation of the Brain: The Effect of Iron and Transferrin on Monocytes and Lipid Peroxidation

Cerebral inflammation plays a role in diseases such as multiple sclerosis (MS), Alzheimers disease (AD), and depression. Iron is involved in infection and inflammation through free radical production. Theoretically transferrin should prohibit iron from participating in oxidative reactions, but transferrin has also been found to promote free radical damage. We reported previously that isolation of transferrin from plasma by ion exchange column chromatography produced a broad pink protein band that subsequently separated on a gel filtration column into three proteins containing many metals. In this study some properties of the three proteins were studied in 20 volunteers. Protein 3 (identified as transferrin by nephelometry) contained the most iron while Protein 1 (called “toxiferrin”) contained significantly less iron (p < 0.00001). Plasma from volunteers obtained under conditions of infection/inflammation with fever (n = 5) had a significantly increased toxiferrin to transferrin ratio compared to healthy volunteers (n = 15; p < 0.001). In vitro, Protein 2 and transferrin inhibited lipid peroxidation, while toxiferrin (possibly a protease degradation product of transferrin), enhanced lipid peroxidation. Also, toxiferrin (1 mg/mL) caused a significant increase in viability of monocytes as measured by the 3-(4,5-dimethyl-thiazol-2-yl) 2,5-diphenyl tetrazolium bromide (MTT) reduction test, as well as the morphological transformation of monocytes to macrophages.

Activation of chlorpromazine by the myeloperoxidase system of the human neutrophil

The univalent oxidation of chlorpromazine (CPZ) by the myeloperoxidase (MPO-H2O2) system led to the formation of a cation free radical (CPZ+) which was observed optically at 527 nm. CPZ protected MPO against loss of catalytic activity when co-oxidized in a MPO-Cl(-)-H2O2 system. Due to the stability of CPZ+ either further oxidation, or reduction back to the mother compound, become important mechanisms for disappearance of the free radical. Thus, the rate of formation and decay of CPZ+ were higher in the presence of Cl- than in its absence, since the radical can also be oxidized further by hypochlorous acid (HOCl), which is formed in the MPO-Cl(-)-H2O2 system. Decay of CPZ+ can also be due to electron acceptance from ascorbic acid or oxygenated haemoglobin (HbO2), resulting in regeneration of CPZ. When CPZ+ was generated in the MPO-H2O2 system, addition of HbO2 resulted in a sudden decrease in CPZ+ absorbance at 527 nm and a concomitant formation of metHb. When HbO2 was not added, the decay of CPZ+ was much slower. CPZ (in the absence of the MPO system) also stimulated the oxidation of HbO2 in the presence of 20 microM H2O2, but this reaction was considerably slower than when CPZ+ (generated by the MPO system) was allowed to react directly with HbO2. These results suggest that HbO2 was oxidized by CPZ+. To study the effect of CPZ intermediates, thyroglobulin (TG) was used as a model polypeptide. Chlorinated oxidants formed in the MPO system (in the absence of CPZ) induced TG peptide bond splitting. In contrast, CPZ metabolites generated by the MPO system (in the absence of Cl-) induced polymerization of TG, as revealed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE).

Apparent hydroxyl radical generation without transition metal catalysis and tyrosine nitration during oxidation of the anti-tubercular drug, isonicotinic acid hydrazide

Aromatic hydroxylation and formation of thiobarbituric acid-reactive substances occurred in a mixture of isonicotinic acid hydrazide (isoniazid) and catalase. Since these reactions were stimulated by phytic acid (a potent metal chelator), rather than inhibited, transition metal-catalysed hydroxyl radical generation was not implicated. Hydroxylation also occurred with isoniazid and phytic acid in the absence of catalase, albeit to a lesser extent. The independent effects of catalase and phytic acid are related to their abilities to catalyse isoniazid oxidation. In the presence of tyrosine, both the isoniazid/phytic acid system and authentic peroxynitrite generated dityrosine. Authentic peroxynitrite, as well as a phytic acid-mediated isoniazid oxidation product, have absorbance maxima at 302 nm. The yield of this isoniazid-derived product increased with pH and in the presence of a superoxide-generating system. A good correlation existed between absorbance at 302 nm and aromatic hydroxylation. Acid-induced decomposition of the 302 nm absorbance in the presence of superoxide dismutase led to the formation of a product absorbing in the same region as peroxynitrite-modified superoxide dismutase (350 nm at acid pH). Catalase catalysed peroxynitrite-mediated, as well as isoniazid/phytic acid-mediated tyrosine nitration, which was accompanied by Compound II formation (ferryl-catalase) in both cases. We postulate that peroxynitrite or a similar species is formed during isoniazid oxidation.

Comparative diffusion of drugs through bronchial tissue

The purpose of the study was to investigate the molecular diffusion of drugs across porcine bronchial tissue. Using an in vitro flow-through diffusion system, a series of model compounds were tested. These included theophylline, caffeine, theobromine, enprofylline, salbutamol, ipratropium bromide, and trimethoprim. All drugs were assayed by HPLC in conjunction with UV/vis or MS/MS detection. The results indicated that the mean flux value of theophylline was higher than that of all the other drugs listed above. Within the log10P range from -2.21 (ipratropium bromide) to 1.364 (trimethoprim), a sigmoidal relationship was found to exist between the apparent permeability coefficients (Papp) and the octanol/water partition coefficients across the bronchial tissue. The diffusion of ipratropium bromide (Papp 1.6 x 10(-8)cm/s) across bronchial tissue was similar to that of salbutamol (Papp 1.5 x 10(-8)cm/s). The data obtained in this study indicate that although lipophilicity is a main determinant in the diffusion of drug compounds across bronchial tissue, the number and position of alkyl groups also reflect the ability of the latter to cross membrane barriers.

Low Concentrations of Chlorpromazine and Related Phenothiazines Stimulate Gene Transfer in HeLa Cells Via Receptor-Mediated Endocytosis

Chlorpromazine and related phenothiazine antipsychotic compounds at the low concentration of 10 -5 M stimulated luciferase pRSVL DNA uptake and expression in HeLa cells. On the other hand, chloroquine at a 10 -5 M was without effect at this low concentration. However, at the higher normally used concentration of 10 -4 M (100 μM), chloroquine strongly stimulated luciferase expression and activity. Unfortunately, at 10 -4 M, the phenothiazines were toxic to the cells and could not be tested at this concentration. Further experimental work was carried out to elucidate the mechanism of action of phenothiazines and chloroquine on DNA uptake and expression. Interaction of [3 H] pBR 322 DNA with chlorpromazine, perphenazine, and chloroquine was studied using these compounds as their free bases dissolved in chloroform, followed by their impregnation onto Whatman No. 1 filter paper discs. Both phenothiazines on filter paper discs bound [3 H] pBR 322 DNA to a far greater extent than chloroquine. The method of assay (free base) suggests that the major contribution to binding is through intercalation. A further possible assay for studying the interaction of phenothiazines and chloroquine made use of the ethidium bromide/calf thymus DNA intercalation method. Intercalated calf thymus (CT) DNA complexes with ethidium bromide (EB) were examined for possible dissociation into free DNA and EB on the addition of either chloroquine. SO 4 or chlorpromazine.HCl (soluble salts). Partial dissociation was observed with both compounds. Further experiments on the stability of pBR 322 DNA-polylysine complexes were also carried out using an alternative method of assay. Chloroquine (10 -2 - 10 -4 M) and chlorpromazine (10 -4 M) did not bring about a dissociation of [3 H] pBR 322 DNA-polylysine 200 complexes when reactions were studied by nitrocellulose filter assays to measure released double-stranded DNA. The results indicate that chlorpromazine and related phenothiazines stimulate luciferase DNA uptake expression at 10 -5 M. Chloroquine at this concentration had practically no effect on expression of luciferase activity. Further studies of chloroquine and chlorpromazine on their interaction with plasmid DNA as well as DNA-polylysine complexes are reported.