5-Hydroxy-3-Ethylamino-2-Oxindole Is Not Formed in Rat Brain Following a Neurotoxic Dose of Methamphetamine: Evidence that Methamphetamine Does Not Induce the Hydroxyl Radical-Mediated Oxidation of Serotonin

Abstract: Oxygen radicals have been implicated in the neurodegenerative and other neurobiological effects evoked by methamphetamine (MA) in the brain. It has been reported that shortly after a single large subcutaneous dose of MA to the rat, the serotonergic neurotoxin 5,6-dihydroxytryptamine (5,6-DHT) is formed in the cortex and hippocampus. This somewhat controversial finding suggests that MA potentiates formation of the hydroxyl radical (HO^?) that oxidizes 5-hydroxytryptamine (5-HT) to 5,6-DHT, which, in turn, mediates the degeneration of serotonergic terminals. A major and more stable product of the in vitro HO^?-mediated oxidation of 5-HT is 5-hydroxy-3-ethylamino-2-oxindole (5-HEO). In this investigation, a method based on HPLC with electrochemical detection (HPLC-EC) has been developed that permits measurement of very low levels of 5-HEO in rat brain tissue in the presence of biogenic amine neurotransmitters/metabolites. After intracerebroventricular administration into rat brain, 5-HEO is transformed into a single major, but unknown, metabolite that can be detected by HPLC-EC. One hour after administration of MA (100 mg/kg s.c.) to the rat, massive decrements of 5-HT were observed in all regions of the brain examined (cortex, hippocampus, medulla and pons, midbrain, and striatum). However, 5-HEO, its unidentified metabolite, or 5,6-DHT were not detected as in vivo metabolites of 5-HT. MA administration, in particular to rats pretreated with pargyline, resulted in the formation of low levels of N-acetyl-5-hydroxytryptamine (NAc-5-HT) in all brain regions examined. These results suggest that MA does not potentiate the HO^?-mediated oxidation of 5-HT. Furthermore, the rapid MA-induced decrease of 5-HT might not only be related to oxidative deactivation of tryptophan hydroxylase, as demonstrated by other investigators, but also to the inhibition of tetrahydrobiopterin biosynthesis by NAc-5-HT. The massive decrements of 5-HT evoked by MA are accompanied by small or no corresponding increases in 5-hydroxyindole-3-acetic acid (5-HIAA) levels. This is due, in part, to the relatively rapid clearance of 5-HIAA from the brain and monoamine oxidase (MAO) inhibition by MA. However, the loss of 5-HT without corresponding increases in its metabolites point to other mechanisms that might deplete the neurotransmitter, such as oxidation by superoxide radical anion (O₂^??), a reaction that in vitro does not generate 5-HEO or 5,6-DHT but rather another putative neurotoxin, tryptamine-4,5-dione. One hour after administration, MA evokes large depletions of norepinephrine (NE) throughout the brain but somewhat smaller decrements of dopamine (DA) that are restricted to the nigrostriatal pathway. Furthermore, MA evokes a major shift in the metabolism of both NE and DA from the pathway mediated by MAO to that mediated by catechol-O-methyltransferase. The profound and widespread effects of MA on the noradrenergic system, but more anatomically localized influence on the dopaminergic system, suggests that NE in addition to DA, or unusual metabolites of these neurotransmitters, might play roles in the neurodegenerative effects evoked by this drug.     

Localization of dihydroorotate oxidase in myocardium and kidney cortex of the rat

Biochemical studies have demonstrated that dihydroorotate dehydrogenase (DHOdehase; EC 1.3.3.1 or 1.3.99.11) is the sole enzyme of de novo pyrimidine synthesis in mitochondria, whereas the rest of the pathway takes place in the cytosol. The dehydrogenation of dihydroorotate to orotate is linked to the respiratory chain via ubiquinone. In this study, we show for the first time the ultrastructural localization of DHOdehase. Since the purified enzyme was found to act both as dehydrogenase and as oxidase, the cerium capture technique for detecting enzymatically generated hydrogen peroxide could be applied to pin-point the in situ activity of DHOdehase oxidase in mitochondria of rat heart and kidney cortex. Cerium perhydroxide as the final reaction product was detected predominantly in the matrix with some focal condensation along the inner membrane, but not in the intermembrane space. From this pattern of localization, it is concluded that the active site of the membrane-bound enzyme could face the mitochondrial matrix similar to succinate dehydrogenase. The reliability of the applied method for the demonstration of DHOdehase oxidase was demonstrated by the addition of Brequinar sodium to the incubation medium. This quinoline-carboxylic acid derivative is a potent inhibitor of DHOdehase and has proven anti-proliferative activity. The present observations do not ascertain whether the oxidase is permanently active as a constant portion of the enzyme in vivo, similar to xanthine oxidase/dehydrogenase. However, DHOdehase should be considered as a source of radical oxygen species under pathophysiological conditions.     

Substrate specificity of thermitase,a thermostable serine proteinase fromThermoactinomyces vulgaris

The specificity of thermitase (EC 3.4.21.14), a microbial thermostable serine proteinase fromThermoactinomyces vulgaris, with several oligo- and polypeptide substrates was investigated. Preferred hydrolysis of peptide bonds with a hydrophobic amino acid at the carboxylic site was observed. The proved carboxypeptidolytic splitting of Leu⁵-enkephalin and bradykinin, as well as the noncleavability of casomorphins by thermitase, can be explained by the position of the glycine and proline residues in these substrates. Major cleavage sites in the oxidized insulin B chain in a 15-min incubation with thermitase at Gln⁴-His⁵, Ser⁹-His¹⁰, Leu¹¹-Val¹², Leu¹⁵-Tyr¹⁶ and in the oxidized insulin A chain at Cys SO₃H¹¹-Ser¹², Leu¹³-Tyr¹⁴, and Leu¹⁶-Glu¹⁷ were observed. Additional cleavages of the bonds His⁵-Leu⁶, Arg²²-Gly²³, Phe²⁴-Phe²⁵, Phe²⁵-Tyr²⁶, and Tyr²⁶-Thr²⁷ in the oxidized B chain and Cys SO₃H⁶-Cys SO₃H⁷ and Tyr¹⁹-Cys SO₃H²⁰ in the oxidized A chain in 2-h incubations with thermitase were also noted. Hydrolysis of salmine A I component in a 10-min incubation was observed mainly at four peptide bonds: Arg⁵-Ser⁶, Ser⁶-Ser⁷, Arg¹⁸-Val¹⁹, and Gly²⁷-Gly²⁸. The cleavage sites of thermitase in both insulin chains were similar to those reported in the studies of subtilisins.     

Use of microbial peptide inhibitors for characterization of the substrate specificity of thermitase,a thermostable serine protease fromThermoactinomyces vulgaris

Seven microbial peptide inhibitors—chymostatin, antipain, elastatinal, leupeptin, pepstatin, bestatin, and phosphoramidon—were tested for their efficiency to inhibit thermitase, a thermostable serine protease fromThermoactinomyces vulgaris. Chymostatin and antipain were the most effective inhibitors, with K_i values of 7×10^–8 M and 2×10^–7 M, respectively. Except for leupeptin, all inhibitors resist hydrolysis by thermitase. Leupeptin, however, is cleaved by thermitase between the two leucylresidues. Further, a close relationship in specificity between thermitase and subtilisin BPN and their distinct discrimination from elastase specificity was demonstrated by using these inhibitors.     

Interaction of metabolic inhibitors with actin fibrils

Summary The dependence of the arrangement of fibrillar actin in cultured endothelial cells on metabolic conditions was investigated with cellular elements derived from the heart of Xenopus laevis tadpoles. Either primary culture or an established cell line (XTH-2) were used in these studies The metabolic stage of the cells was influenced by inhibiting respiration and lactate production. The actin pattern was revealed either by indirect immunofluorescence or by tetramethylrhodaminyl (TRITC)-phalloidin fluorescence. Total block of energy supply causes in all cases a distinct loss of actin fibrils, while inhibition of respiration alone increases the variability of actin organization. In primary XTH cells but not in XTH-2 cells cyanide disintegrates most of the actin fibres during 3 h of treatment. This effect is independent of the inhibition of respiration, since actin gels prepared from skeletal muscle also undergo destruction in the presence of cyanide. It is concluded that the actin fibrils of the primary cells and the established line behave differently to changing metabolic conditions and to application of KCN.     

Ultrastruktur und Differenzierung der prostatoiden Organe von Polystyliphora filum (Plathelminthes,Proseriata)

Zusammenfassung Polystyliphora filum besitzt neben einem dem männlichen Begattungsorgan angeschlossenen Stilett eine Vielzahl gleichartiger prostatoider Organe, stets caudal des Begattungsorgans serial angeordnet. Jedes dieser prostatoiden Organe besteht aus einem Stilett, das in ein Atrium reicht, und einem caudal anschließenden Bulbus. Das Stilett hat die Form eines gebogenen Trichterrohres mit einem plattenförmigen Fortsatz in der Mitte; Trichterrohr und Fortsatz werden zusammen in einer einzelnen Zelle ausdifferenziert. In einer frühen Bildungsphase wird in der basalen Hälfte zunächst ein Gerüst aus Mikrotubuli angelegt, an das sich elektronendichtes Material anlagert. In einem späteren Bildungsstadium werden teilweise die Zwischenräume zwischen der entstehenden Hartstruktur und der Außenmembran der Bildungszelle mit elektronendichtem Material ausgefüllt. Die Spitze des Stiletts wird durch Anlagerung elektronendichten Materials an die Außenmembran gebildet. Die Differenzierung der gesamten Hartstruktur erfolgt simultan und intrazellulär. Gleichzeitig wird auch die gesamte Muskulatur des prostatoiden Organs ausgebildet. Die vollständig ausdifferenzierten prostatoiden Organe enthalten keine Spermien, sondern nur große Mengen eines grobscholligen Sekretes.

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Ultrastructure and differentiation of the prostatoid organs of Polystyliphora filum (Plathelminthes, Proseriata)

Summary In addition to a male copulatory organ containing a stylet, Polystyliphora filum has numerous uniform prostatoid organs which are arranged in series caudally to the copulatory organ. Each of these prostatoid organs consists of a stylet, extending into an atrium, and caudal to this a bulb. The stylet is funnel-shaped with a curved distal part and a flattened projection in the middle; funnel and projection are differentiated together in a single cell. In an early phase of differentiation, a framework of microtubules is built in the basal part, and this becomes enveloped by electron-dense material. In a later phase, the space between the formed hard structure and the outer membrane of the style building cell is partially filled up with electrondense material. The distal part of the stylet if formed by electron-dense material taken up to the outer membrane. The whole hard structure is differentiated simultaneously and intracellularly. At the same time the whole muscular system of the prostatoid organ is formed. The completed prostatoid organs do not contain sperm, but much coarsegrained medium electron-dense secretion.

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Abkürzungen am Atriummuskulatur - bl Basallamina - bm Bulbusmuskulatur - bmk Kernregion einer Bulbusmuskelzelle - bz Stilettbildungszelle - cw Cilienwurzel - ep Epidermis - fz Füllzelle - hz Hüllzelle - mv Mikrovilli - n Nerv - p Protraktor - pa Protraktoransatz - r ciliärer Rezeptor - s Stilett - sd Septatdesmosomen - sm Schließmuskel - sz Sekretzelleg