Niridazole metabolism by rat embryos in vitro

We report the results of studies on the reductive activation of the schistosomicidal agent, niridazole (NDZ). Intact rat embryos in vitro reduced this compound, generating a stable metabolite in the presence of 5% O2. By contrast, embryo and yolk sac homogenates or liver microsomes appeared to require anaerobiasis. Malformation incidence--specifically, axial asymmetry--showed a strong correlation with nitroreductase activity rates when the latter were modulated by oxygen tension. Data presented here suggest that when embryos are exposed to NDZ under conditions of low oxygen in vitro, redox cycling ensues with molecular oxygen serving to oxidize early reduction products. This process continues, regenerating the parent compound until oxygen is depleted locally. The basis of this localized depletion is unknown, but inability of the immature supply system to replete oxygen or demand by precociously aerobic tissues may be involved. Once local anaerobiasis is attained, further reduction could generate toxic metabolites capable of covalently binding cellular macromolecules. Localized hypoxia represents another potential mechanism of dysmorphogenesis.     

Comparison of cortisol-cortisone interconversion in vitro by the human and baboon placenta

The kinetics of 11 beta-hydroxysteroid dehydrogenase (11HSD) catalyzing the interconversion of cortisol (F) and cortisone (E) were compared in vitro following incubation of homogenates of human (N = 7) and baboon (N = 2) placenta. In both species, enzyme activity catalyzing the conversion of F to E was associated with the membrane fraction of the cell, was greater in the presence of NAD+ than NADP+, was of similar concentration within the placenta, and exhibited a similar Km for F. Moreover, there was no conversion of E to F in either the baboon or human placenta indicating that in both species, term placenta lacks the 11HSD enzyme catalyzing the reduction of the 11-oxo group of corticosteroids. Significantly, the conversion of F to E by both the baboon and human placenta was inhibited when progesterone was added to the reaction mixture at concentrations equimolar to the substrate. We conclude that 11HSD enzyme kinetics in term baboon placental homogenates are similar to those measured in human term placenta. Moreover, progesterone may be a physiologic regulator of 11HSD in both the human and baboon placenta. Collectively, our findings support the use of the baboon as a model for studies of the regulation of placental corticosteroid metabolism during human pregnancy.     

In vitro reductive metabolism of N-nitrosodibenzylamine: Evidence for new reactive intermediates

N-Nitrosodibenzylamine was incubated with rabbit-whole-liver homogenates. Gas-chromatographic and mass spectrometric analysis of the incubation extracts showed the formation of bibenzyl. This biotransformation is the result of a 2-electron reduction of the substrate to 1-hydroxy-2,2-dibenzylhydrazine, an unstable compound which breaks down to bibenzyl and nitrogen. It is suggested that such reductive metabolism may be involved in the generation of toxic metabolites of nitrosamines.     

The Biological Reductive Capacity of Tissues is Decreased Following Exposure to Oxidative Stress: A Cyclic Voltammetry Study of Irradiated Rats

The reductive capacity of rat tissue homogenates and body fluids was determined by cyclic voltammetric measurements. The reductive capacity of rat lung, liver and kidney homogenates was significantly reduced four days after total body γ-ray irradiation with 5.5 Gy as compared to controls. In parallel, reduced ability of the irradiated organ homogenates to scavenge hydroxyl radicals and to destroy hydrogen peroxide was recorded. However, no difference in their superoxide dismutase activity was found. The possible use of cyclic voltammetry as a method for qualitative evaluation of the ability of biological tissues to cope with oxidative stress is discussed.     

In vitro metabolism of the cardiotonic steroids gomphogenin and calactin

The metabolism of gomphogenin and calactin was studied in vitro using respectively microsomes and the S9 fraction of homogenates from rat liver. These two substrates were previously shown to be in vitro and in vivo metabolites of gomphoside, a cardiotonic steroid belonging to a class of 5 alpha-cardenolide glycosides with doubly-linked hexosulose sugars. Structures of new metabolites were elucidated using 400 MHz 1H-NMR and chemical ionization mass spectrometry, while known compounds were identified by direct comparison. The major metabolite isolated from gomphogenin (2 alpha-hydroxyuzarigenin) metabolism was the oxidation product 2-oxo-uzarigenin which was further oxidized metabolically to 4 alpha-hydroxy-2-oxo-uzarigenin. Other metabolites were 2 alpha-hydroxyuzarigenone and its reduction product 3-epigomphogenin. Calactin was oxidized in vitro to 10-carboxyl-19-norgomphoside, the predominant metabolite, and underwent cleavage of the doubly-linked sugar to yield calotropagenin.     

Mössbauer and EPR study of recombinant acetyl-CoA synthase from Moorella thermoacetica

M?ssbauer and EPR spectroscopies were used to study the electronic structure of the A-cluster from recombinant acetyl-CoA synthase (the alpha subunit of the alpha2beta2 acetyl-CoA synthase/CO dehydrogenase). Once activated with Ni, these subunits have properties mimicking those associated with the alpha2beta2 tetramer, including structural heterogeneities. The Fe4S4 portion of the A-cluster in oxidized, methylated, and acetylated states was in the 2+ core oxidation state. Upon reduction with dithionite or Ti3+ citrate, samples of Ni-activated alpha developed the ability to accept a methyl group. Corresponding M?ssbauer spectra exhibited two populations of A-clusters; roughly, 70% contained [Fe4S4]1+ cubanes, while approximately 30% contained [Fe4S4]2+ cubanes, suggesting an extremely low [Fe4S4](1+/2+) reduction potential for the 30% portion (perhaps <-800 mV vs NHE). The same population ratio was observed when Ni-free unactivated alpha was used. The 70% fraction exhibited paramagnetic hyperfine structure in the absence of an applied magnetic field, excluding the possibility that it represents an [Fe4S4]1+ cluster coupled to a (proximal) Ni(p)1+. EPR spectra of dithionite-reduced, Ni-activated alpha exhibited features at g = 5.8 and g(ave) approximately 1.93, consistent with a physical mixture of {S = 3/2; S = 1/2} spin-states for A-clusters containing [Fe4S4]1+ clusters. Incubation of Ni-activated alpha with dithionite and CO converted 25% of alpha subunits into the S = 1/2 A(red)-CO state. Previous correlation of this state to functional A-clusters suggests that only the 30% fraction not reduced by dithionite or Ti3+ citrate represents functional A-clusters. Comparison of spin states in oxidized and methylated states suggests that two electrons are required for reductive activation, starting from the oxidized state containing Ni(p)2+. Refitting published activity-vs-potential data supports an n = 2 reductive activation. Enzyme starting in the methylated state exhibited catalytic activity in the absence of an external reductant, suggesting that the two electrons used in reductive activation are retained by the enzyme after each catalytic cycle and that the enzyme does not have to pass through the A(red)-CO state during catalysis. Taken together, our results suggest that a Ni(p)0 state may form upon reductive activation and reform after each catalytic cycle.     

Melanin biosynthesis and the metabolism of flaviolin and 2-hydroxyjuglone inWangiella dermatitidis

Melanin biosynthesis in the human pathogenWangiella dermatitidis was inhibited by tricyclazole, causing pentaketide melanin metabolites to accumulate in the cultures. One of these metabolites, scytalone, was racemic and thus different than the (+)-enantiomer fromVerticillium dahliae. An albino mutant ofW. dermatitidis metabolized scytalone to a pigment ultrastructurally identical to wild-type melanin. Cell-free homogenates of the wild type carried out typical reductive and dehydrative reactions with known melanin intermediates and the reductive reactions were inhibited by tricyclazole. Other reductive and dehydrative reactions that utilize flaviolin and 2-hydroxyjuglone were studied anaerobically with homogenates from both the wild type and the albino mutant. The homogenates converted flaviolin to 5-hydroxyscytalone and products identical to those obtained from 2-hydroxyjuglone. The albino, in culture, carried out the same reactions with 2-hydroxyjuglone but metabolized flaviolin to a number of unknown colored products apparently through oxidative reactions. Similarities between the melanin pathway and the flaviolin and 2-hydroxyjuglone branch pathways are discussed and tricyclazole is shown to inhibit reductive reactions with naphthols in the three pathways.Abbreviations DHN dihydroxynaphtalene - HJ hydroxyjuglone - THT trihydroxytetralone - THN trihydroxynaphthalene or tetrahydroxynaphthalene - DTT dithiothreitol - HS hydroxyscytalone - PHN pentahydroxynaphthalene     

Effect of specific inhibitors on the anaerobic reductive dechlorination of 2,4,6-trichlorophenol by a stable methanogenic consortium

The transformation of 2,4,6-trichlorophenol (TCP) into 4-chlorophenol (4CP) was studied using a stable methanogenic enrichment culture derived from an anaerobic fixed bed reactor. Using acetate as a growth substrate, different inhibitors of methanogenesis exhibited distinct effects on TCP dechlorination. Whereas reductive dechlorination activity was not affected by 2% ethylene in the gas phase, 25 mM bromoethanesulfonic acid (BESA) had a direct inhibitory effect on this process. The choice of BESA as a specific inhibitor for identifying the subpopulations involved in reductive dechlorination of chloroaromatics is thus questionable. Inhibitors of sulfate reduction such as molybdate (20 mM) and selenate (20 mM) had a direct inhibitory effect on reductive dechlorination independently of the presence of sulfate in the medium supplemented with acetate as growth substrate. Consequently much more care must also be taken with these inhibitors to prove that reductive chlorination is coupled to sulfate reduction.     

Two distinct enzyme systems are responsible for tetrachloroethene and chlorophenol reductive dehalogenation in Desulfitobacterium strain PCE1

Desulfitobacterium strain PCE1 is able to use tetrachloroethene and chloroaromatics as terminal electron acceptors for growth. Cell extracts of Desulfitobacterium strain PCE1 grown with tetrachloroethene as electron acceptor showed no dehalogenase activity with 3-chloro-4-hydroxyphenylacetate (Cl-OH-phenylacetate) and other ortho-chlorophenolic compounds in an in vitro assay. Extracts of cells that were grown with Cl-OH-phenylacetate as electron acceptor dechlorinated tetrachloroethene at 10% of the dechlorination rate of Cl-OH-phenylacetate. In both cell extracts dechlorination was inhibited by the addition of 1-iodopropane and dinitrogen oxide, inhibitors of cobalamin-containing enzymes. The enzymes responsible for tetrachloroethene and Cl-OH-phenylacetate dechlorination were partially purified. A 100-fold enriched fraction of chlorophenol reductive dehalogenase was obtained that mainly contained a protein with a subunit size of 48 kDa. The characteristics of this enzyme are similar to that of the chlorophenol reductive dehalogenase of D. dehalogenans. After partial purification of the tetrachloroethene reductive dehalogenase, a fraction was obtained that also contained a 48-kDa protein, but the N-terminal sequence showed no similarity with that of the chlorophenol reductive dehalogenase sequence or with the N-terminal amino acid sequence of tetra- and trichloroethene reductive dehalogenase of Desulfitobacterium strain TCE1. These results provide strong evidence that two different enzymes are responsible for tetrachloroethene and chlorophenol dechlorination in Desulfitobacterium strain PCE1. Furthermore, the characterization of partially purified tetrachloroethene reductive dehalogenase indicated that this enzyme is a novel type of reductive dehalogenase.     

Renal epithelial cell lines (BSC-1, MDCK, LLC-PK1) express 11 beta-hydroxysteroid dehydrogenase activity

Renal tissue of several species has been shown to express considerable 11 beta-hydroxysteroid dehydrogenase (11-HSD, EC 1.1.1.146) activity. However, it is uncertain as to which renal cell types exhibit 11-HSD activity. In the present study, we investigated corticosterone metabolism in BSC-1 cells, a continuous renal epithelial cell line derived from the African green monkey (Cercopithecus aethiops). In incubation experiments using 3H-labelled corticosterone and HPLC, we have demonstrated oxidative 11-HSD activity in intact monolayers of BSC-1 cells as well as in BSC-1 cell homogenates. 11-HSD activity in cell homogenates could be stimulated 7-9-fold by the addition of exogenous NADP+ (1 mM). In contrast, no reductive 11-HSD could be detected either in intact cells or in cell homogenates under various experimental conditions which were designed to favor reductive 11-HSD activity. Pilot experiments were performed in cell homogenates from two other renal epithelial cell lines derived from canine (MDCK) and porcine (LLC-PK1) kidney. They also revealed oxidative but no reductive 11-HSD activity. The data provide evidence for an epithelial localization of renal oxidative 11-HSD activity.     

PGD2 formation in the vasculature: characteristics of rat tail vein prostaglandin endoperoxide-D isomerase

Rat tail vein homogenates, microsome and high speed supernatant fractions were incubated with [1-(14) C]prostaglandin endoperoxide (PGH2) and products separated and identified by radio-thinlayer chromatography. PGI2 synthase was localized to the microsomal fraction, but exhibited low activity compared to rat tail arteries prepared in the same manner. PGH-D isomerase was identified in the cytosolic fraction of tail veins. The isomerase was maximally active in the presence of reduced glutathione at pH 7.5-8.0, exhibited a Km for PGH2 of 33 microM, and was inhibited sulfhydryl-directed reagents. The similarities of this enzyme to PGD synthase of the rat cerebral microvasculature are discussed.     

Red wine-dependent reduction of nitrite to nitric oxide in the stomach

Nitrite may be a source for nitric oxide (*NO), particularly in highly acidic environments, such as the stomach. Diet products contribute also with reductants that dramatically increase the production of *NO from nitrite. Red wine has been attributed health promoting properties largely on basis of the reductive antioxidant properties of its polyphenolic fraction. We show in vitro that wine, wine anthocyanin fraction and wine catechol (caffeic acid) dose- and pH-dependently promote the formation of *NO when mixed with nitrite, as measured electrochemically. The production of *NO promoted by wine from nitrite was substantiated in vivo in healthy volunteers by measuring *NO in the air expelled from the stomach, following consumption of wine, as measured by chemiluminescence. Mechanistically, the reaction involves the univalent reduction of nitrite, as suggested by the formation of *NO and by the appearance of EPR spectra assigned to wine phenolic radicals. Ascorbic and caffeic acids cooperate in the reduction of nitrite to *NO. Moreover, reduction of nitrite is critically dependent on the phenolic structure and nitro-derivatives of phenols are also formed, as suggested by caffeic acid UV spectral modifications. The reduction of nitrite may reveal previously unrecognized physiologic effects of red wine in connection with *NO bioactivity.     

Development of Amphioplus abditus (Verrill) (Echinodermata: Ophiuroidea): I. Larval biology

A fraction rich in secretory granules was prepared from the pyloric caeca of Asterias amurensis by sucrose density gradient centrifugation. The freshly prepared fraction exhibited no casein-hydrolyzing activity- but showed nine times as much specific activity as that of tissue homogenates after incubation at 37 degrees C for thirty minutes. Electron microscopy showed that the secretory granules were membrane-bound granules measuring 0.5-290 mu in diameter and contained dense and/or light amorphous substances.     

Modulation of aortic protein phosphorylation by benzo(a)pyrene: Implications in PAH-induced atherogenesis

The toxicity of polycyclic aromatic hydrocarbons such as benzo(a)pyrene, 7,12-dimethylbenz(a)anthracene, and 3-methylcholanthrene has been associated with alterations in the proliferation of vascular smooth muscle cells and the development of lesions of mesenchymal origin. Because phosphorylation of endogenous substrates plays a central role in the regulation of smooth muscle cell growth, the present studies were conducted to evaluate the phosphorylation pattern of medial aortic protein upon repeated in vivo exposure of Japanese quail to benzo(a)pyrene (BaP). Medial aortic homogenates from quail treated for 10 weeks with 10 mg/kg benzo(a)pyrene or vehicle were processed for in vitro measurements of protein phosphorylation. In vitro phosphorylation of endogenous or exogenous proteins stimulated in vitro by phorbol myristate acetate/phosphatidyl-serine or cyclic AMP, known activators of protein kinase C and cyclic AMP-dependent protein kinase, respectively, was examined in the cytosolic and particulate fractions of homogenates from control and treated animals. Benzo(a)pyrene treatment significantly enhanced the basal phosphorylation of Mr 113, 35, and 23 kDa proteins in the cytosolic fraction. Modest increases in the phosphorylation of Mr 71, 52, and 38 kDa were also observed under basal conditions. No changes in the basal phosphorylation of particulate proteins were observed. Phosphorylation of endogenous protein substrates by protein kinase C in the cytosolic fraction was not altered by benzo(a)pyrene treatment. In contrast, inhibition of C-kinase-mediated phosphorylation of endogenous Mr 272, 72, and 45 kDa proteins was observed in the particulate fraction of aortic homogenates from benzo(a)pyrene-treated quail relative to controls. Exogenous histone phosphorylation by PKC in the particulate, but not cytosolic fraction, was decreased by benzo(a)pyrene treatment. The effects of benzo(a)pyrene on the C-kinase system were specific, since cAMP-mediated phosphorylation of endogenous proteins, as well as exogenous histone, was not altered by benzo(a)pyrene. Interestingly, benzo(a)pyrene treatment was associated with a selective increase of Mr 200, 80, and 67 kDa proteins in the cytosolic fraction. Collectively, these data are consistent with the hypothesis that medial protein phosphorylation is a significant molecular target of benzo(a)pyrene within the vascular wall.     

Cystine antagonism of the antibacterial action of lactoperoxidase-thiocyanate-hydrogen peroxide on Streptococcus agalactiae.

Cystine reduction in Streptococcus agalactiae, resulting in sulfhydryl formation, may account for antagonism of the antibacterial effect of lactoperoxidase-thiocyanate-hydrogen peroxide when cystine is present in excess of the amount needed for maximum growth. Accumulation of cystine by S. agalactiae and its reduction to form sulfhydryl compounds were demonstrated. The reduction of cystine appeared to occur by a couple reaction between glutathione reductase and glutathione-disulfide transhydrogenase activity, both of which were found in the supernatant fraction from cell homogenates. NADPH-specific glutathione reductase activity was found in the pellet and supernatant fractions from cell homogenates. Two sulfhydryls were formed for each mole of NADPH used during cystine reduction. The information presented offers a plausible explanation of how cystine, when present in excess of growth needs, may be reduced to generate sulfhydryl compounds which neutralize the antibacterial effect of lactoperoxidase-thiocyanate-hydrogen peroxide on S. agalactiae.     

Cystine antagonism of the antibacterial action of lactoperoxidase-thiocyanate-hydrogen peroxide on Streptococcus agalactiae

Cystine reduction in Streptococcus agalactiae, resulting in sulfhydryl formation, may account for antagonism of the antibacterial effect of lactoperoxidase-thiocyanate-hydrogen peroxide when cystine is present in excess of the amount needed for maximum growth. Accumulation of cystine by S. agalactiae and its reduction to form sulfhydryl compounds were demonstrated. The reduction of cystine appeared to occur by a couple reaction between glutathione reductase and glutathione-disulfide transhydrogenase activity, both of which were found in the supernatant fraction from cell homogenates. NADPH-specific glutathione reductase activity was found in the pellet and supernatant fractions from cell homogenates. Two sulfhydryls were formed for each mole of NADPH used during cystine reduction. The information presented offers a plausible explanation of how cystine, when present in excess of growth needs, may be reduced to generate sulfhydryl compounds which neutralize the antibacterial effect of lactoperoxidase-thiocyanate-hydrogen peroxide on S. agalactiae.     

Hydrolysis of retinyl palmitate by enzymes of rat pancreas and liver. Differentiation of bile salt-dependent and bile salt-independent, neutral retinyl ester hydrolases in rat liver

Previous studies have demonstrated that homogenates of the livers of rats contain a neutral retinyl ester hydrolase activity that requires millimolar concentrations of bile salts for maximal in vitro activity. The enzymatic properties of this neutral, bile salt-dependent retinyl ester hydrolase activity in liver homogenates are nearly identical to those observed in the present report for the in vitro hydrolysis of retinyl palmitate by purified rat pancreatic cholesteryl ester hydrolase (EC 3.1.1.13). Moreover, anti-rat pancreatic cholesteryl ester hydrolase IgG completely inhibits the bile salt-dependent retinyl ester hydrolase activity of rat liver homogenates whereas normal rabbit IgG does not. We also show that liver homogenates contain a neutral, bile salt-independent retinyl ester hydrolase activity that differs from the bile salt-dependent activity in that 1) its absolute activity does not vary markedly among individual rats, 2) it is not inhibited by antibodies to pancreatic cholesteryl ester hydrolase, and 3) it is localized in the microsomal fraction of liver homogenates. Subfractionation of microsomes demonstrates that the neutral, bile salt-independent retinyl ester hydrolase activity is associated with liver cell plasma membranes and thus may play a role in the hydrolysis of retinyl esters delivered to the liver by chylomicron remnants.     

Isoprostanes, a novel markers of oxidative stress in schizophrenic disorders

It is a well known fact that 3H-panthenol (PL) has a high bioavailability, so we studied its biotransformation and its protective action against lipoperoxide activation in homogenates and mitochondrial-synaptosomal fraction (11 000 g) of rat brain. The lipoperoxidation was initialized by Fe²⁺-ascorbate complex (Fe²⁺-Asc). In experiments in vivo , after 30 min, we demonstrated accumulation of intermediate products of CoA biosynthesis – pantothenic acid (PA), phospho-PA, and phosphopantetheine – in postmitochondrial fraction of brain, by using a HPLC technique. Addition of the PL (10 m m ) to brain hemispheres homogenates or mitochondrial-synaptosomal fraction caused a remarkable reduction of malondialdehyde production. However, 30 min preincubation with the PL, but not with PA, was ineffective. The data obtained may be a reason for a high neuroprotective activity of PL in curing brain diseases with vessel or alcohol-induced damages.     

Involvement of the intestinal microflora in nitrazepam-induced teratogenicity in rats and its relationship to nitroreduction

A study was undertaken to investigate the relationship between nitroreduction of nitrazepam and its teratogenic effects and the involvement of the intestinal microflora in Sprague-Dawley rats. Incubation of bacterial suspensions from rat cecal contents with nitrazepam resulted in extensive reduction to 7-aminonitrazepam. Rat liver homogenates also reduced nitrazepam but only under anaerobic conditions. Following oral administration of 300 mg/kg nitrazepam to pregnant rats, total excretion of reduced metabolites (7-aminonitrazepam and 7-acetylaminonitrazepam) in urine and feces accounted for approximately 30% of the administered dose. When antibiotics were administered to dams to deplete their intestinal microflora prior to administration to nitrazepam, the total excretion of the reduced metabolites in the urine and feces decreased to 2% of the dose. Nitroreductase activity of cecal contents was almost completely suppressed by antibiotic pretreatment, but the activity of liver homogenates was not significantly altered by the same treatment. The incidence of nitrazepam-induced malformations was markedly decreased by antibiotic pretreatment. These results suggest that the intestinal microflora plays an important role in the reductive metabolism of nitrazepam and that the teratogenicity of nitrazepam may be related to its nitroreduction by the microflora.     

Transglutaminase-catalysed cross-linking of proteins phosphorylated in the intact glucose-stimulated pancreatic beta-cell

Incubation of intact islets in the presence of [32P]Pi and stimulatory levels of glucose followed by separation of phosphorylated islet proteins by SDS-polyacrylamide gel electrophoresis revealed the presence of a high molecular weight phosphopolymer which did not transverse a 3% (w/v) acrylamide gel. The majority of this phosphopolymer (approx. 70%) was present in the 600 x g sedimented fraction of islet homogenates. Islet homogenates obtained from intact islets previously incubated with [32P]Pi and stimulatory levels of glucose when incubated under conditions that activated the islet transglutaminase resulted in an increase in the amount of phosphopolymer present in the 600 x g sedimented fraction. Inhibitors of transglutaminase activity which are known to inhibit glucose-stimulated insulin release led to a significant reduction in the fraction of phosphopolymer present in the glucose-stimulated intact islet. These findings suggest that protein cross-linking and phosphorylation reactions may be closely linked in the pancreatic beta-cell.