Different antigen-presenting cells differ in their capacity to induce lymphokine production and proliferation of an apo-cytochrome c-specific T cell clone.

The activation of an apo-cytochrome c-specific T cell clone was found to differ, depending on the antigen-presenting cell population. Whereas total syngeneic spleen cells and bone marrow macrophages could be shown to trigger proliferation, IL 2, and MAF production by the T cell clone, a B cell lymphoma only induced MAF secretion. Further studies demonstrated that this effect was not due to a different antigen processing by the B lymphoma or to limiting amounts of Ia and antigen molecules on the B lymphoma cell surface. The dissociation of induction of MAF production from IL-2 production/proliferation found with the different antigen-presenting cells indicates strongly that molecules other than Ia and antigen may be required for the complete functional activation of antigen-specific T cell clones.

Isolation of a cotton NADP(H) oxidase homologue induced by drought stress

The aim of this study was to identify and isolate genes that are differentially expressed in four selected cotton (Gossypium hirsutum L.) genotypes contrasting according to their tolerance to water deficit. The genotypes studied were Siokra L-23, Stoneville 506, CS 50 and T-1521. Physiological, morphological and developmental changes that confer drought tolerance in plants must have a molecular genetic basis. To identify and isolate the genes, the mRNA Differential Display (DD) technique was used. Messenger RNAs differentially expressed during water deficit were identified, isolated, cloned and sequenced. The cloned transcript A12B15-5, a NADP(H) oxidase homologue, was up regulated only during the water deficit stress and only in Siokra L-23, a drought tolerant genotype. Ribonuclease protection assay confirmed that transcription.

T-cell hybridoma specific for a cytochrome c peptide: specific antigen binding and interleukin 2 production.

T-cell hybridomas were obtained after fusion of BW 5147 thymoma and long-term cultured T cells specific for cytochrome c peptide 66-80 derivatized with a 2,4-dinitroaminophenyl (DNAP) group. The resulting hybridomas were selected for their capacity to specifically bind to soluble radiolabeled peptide antigen. One T-cell hybrid was positive for antigen binding. This hybrid T cell exhibits surface phenotypic markers of the parent antigen-specific T cells. The binding could be inhibited either by an excess of unlabeled homologous antigen or by cytochrome c peptide 11-25 derivatized with a 2-nitrophenylsulfenyl group. Several other peptide antigens tested failed to inhibit binding of the radioactive peptide. This suggests that a specific amino acid sequence, modified by a DNAP group, is the antigenic structure recognized by the putative T-cell receptor. In addition, direct interaction of DNAP-66-80 peptide with the hybridoma cell line induced production of the T-cell growth factor interleukin 2. Furthermore, supernatants derived from syngeneic macrophages pulsed with the relevant peptide also induced the antigen-specific hybridoma to produce interleukin 2.

Cholesterol oxidase interference on the emergence and viability of cotton boll weevil larvae

The aim of this work was to evaluate the influence of the enzyme cholesterol oxidase (Coase) on emergence and viability of larvae of the cotton boll weevil (Anthonomus grandis Boheman, 1843). A series of bioassays was performed with eggs and neonate larvae exposed to different enzyme concentrations in artificial diet. Larval survival was affected at all enzyme concentrations tested, and the six-day LD50 was 53 mug/mL (CI 95%: 43-59). Coase also interfered with hatching of larvae after eggs were floated for 15 min in Coase solution at different concentrations. Observations at the light and electronic microscopic level of midguts from larvae fed on artificial diet containing 53 mug/mL of Coase and collected at six days revealed highly vacuolated regions in the epithelial cells as well as partial degradation of the basal membrane and microvilli.

Association between bipolar disorder and monoamine oxidase A gene polymorphisms: results of a multicenter study

OBJECTIVE: Although genetic factors have been implicated in the etiology of bipolar disorder, no specific gene has been conclusively identified. Given the link between abnormalities in serotonergic neurotransmission and bipolar disorder, a candidate gene association approach was applied to study the involvement of the monoamine oxidase A (MAOA) gene, which codes for a catabolic enzyme of serotonin, in the susceptibility to bipolar disorder. METHOD: In France and Switzerland, 272 patients with bipolar disorder and 122 healthy subjects were typed for three polymorphic markers of the MAOA gene: the MAOA-CA repeat, the MAOA restriction fragment length polymorphism (RFLP), and a repeat directly adjacent to the variable number of tandem repeats (VNTR) locus. RESULTS: A significant difference in the distribution of the alleles for the MAOA-CA repeat was observed between the female bipolar patients and comparison group. CONCLUSIONS: The results obtained in the French and Swiss population confirm findings from two studies conducted in the United Kingdom.

ABCB1 and cytochrome P450 genotypes and phenotypes: influence on methadone plasma levels and response to treatment.

BACKGROUND AND OBJECTIVE: The in vivo implication of various cytochrome P450 (CYP) isoforms and of P-glycoprotein on methadone kinetics is unclear. We aimed to thoroughly examine the genetic factors influencing methadone kinetics and response to treatment. METHODS: Genotyping for CYP1A2, CYP2B6, CYP2C9, CYP2C19, CYP2D6, CYP3A4, CYP3A5, ABCB1, and UGT2B7 polymorphisms was performed in 245 patients undergoing methadone maintenance treatment. To assess CYP3A activity, the patients were phenotyped with midazolam. RESULTS: The patients with lower CYP3A activity presented higher steady-state trough (R,S)-methadone plasma levels (4.3, 3.0, and 2.3 ng/mL x mg for low, medium, and high activity, respectively; P = .0002). As previously reported, CYP2B6*6/*6 carriers had significantly higher trough (S)-methadone plasma levels (P = .0001) and a trend toward higher (R)-methadone plasma levels (P = .07). CYP2D6 ultrarapid metabolizers presented lower trough (R,S)-methadone plasma levels compared with the extensive or intermediate metabolizers (2.4 and 3.3 ng/mL x mg, respectively; P = .04), whereas CYP2D6 poor metabolizer status showed no influence. ABCB1 3435TT carriers presented lower trough (R,S)-methadone plasma levels (2.7 and 3.4 ng/mL . mg for 3435TT and 3435CC carriers, respectively; P = .01). The CYP1A2, CYP2C9, CYP2C19, CYP3A5, and UGT2B7 genotypes did not influence methadone plasma levels. Only CYP2B6 displayed a stereoselectivity in its activity. CONCLUSION: In vivo, CYP3A4 and CYP2B6 are the major CYP isoforms involved in methadone metabolism, with CYP2D6 contributing to a minor extent. ABCB1 genetic polymorphisms also contribute slightly to the interindividual variability of methadone kinetics. The genetic polymorphisms of these 4 proteins had no influence on the response to treatment and only a small influence on the dose requirement of methadone.

The redox state of cytochrome C modulates resistance to methotrexate in human MCF7 breast cancer cells

Background: Methotrexate is a chemotherapeutic agent used to treat a variety of cancers. However, the occurrence of resistance limits its effectiveness. Cytochrome c in its reduced state is less capable of triggering the apoptotic cascade. Thus, we set up to study the relationship among redox state of cytochrome c, apoptosis and the development of resistance to methotrexate in MCF7 human breast cancer cells. Results: Cell incubation with cytochrome c-reducing agents, such as tetramethylphenylenediamine, ascorbate or reduced glutathione, decreased the mortality and apoptosis triggered by methotrexate. Conversely, depletion of glutathione increased the apoptotic action of methotrexate, showing an involvement of cytochrome c redox state in methotrexateinduced apoptosis. Methotrexate-resistant MCF7 cells showed increased levels of endogenous reduced glutathione and a higher capability to reduce exogenous cytochrome c. Using functional genomics we detected the overexpression of GSTM1 and GSTM4 in methotrexate-resistant MCF7 breast cancer cells, and determined that methotrexate was susceptible of glutathionylation by GSTs. The inhibition of these GSTM isoforms caused an increase in methotrexate cytotoxicity in sensitive and resistant cells. Conclusions: We conclude that overexpression of specific GSTMs, GSTM1 and GSTM4, together with increased endogenous reduced glutathione levels help to maintain a more reduced state of cytochrome c which, in turn, would decrease apoptosis, thus contributing to methotrexate resistance in human MCF7 breast cancer cells.

Adenosine A1 receptor activation is arrhythmogenic in the developing heart through NADPH oxidase/ERK- and PLC/PKC-dependent mechanisms.

Whether adenosine, a crucial regulator of the developing cardiovascular system, can provoke arrhythmias in the embryonic/fetal heart remains controversial. Here, we aimed to establish a mechanistic basis of how an adenosinergic stimulation alters function of the developing heart. Spontaneously beating hearts or dissected atria and ventricle obtained from 4-day-old chick embryos were exposed to adenosine or specific agonists of the receptors A(1)AR (CCPA), A(2A)AR (CGS-21680) and A(3)AR (IB-MECA). Expression of the receptors was determined by quantitative PCR. The functional consequences of blockade of NADPH oxidase, extracellular signal-regulated kinase (ERK), phospholipase C (PLC), protein kinase C (PKC) and L-type calcium channel (LCC) in combination with adenosine or CCPA, were investigated in vitro by electrocardiography. Furthermore, the time-course of ERK phosphorylation was determined by western blotting. Expression of A(1)AR, A(2A)AR and A(2B)AR was higher in atria than in ventricle while A(3)AR was equally expressed. Adenosine (100μM) triggered transient atrial ectopy and second degree atrio-ventricular blocks (AVB) whereas CCPA induced mainly Mobitz type I AVB. Atrial rhythm and atrio-ventricular propagation fully recovered after 60min. These arrhythmias were prevented by the specific A(1)AR antagonist DPCPX. Adenosine and CCPA transiently increased ERK phosphorylation and induced arrhythmias in isolated atria but not in ventricle. By contrast, A(2A)AR and A(3)AR agonists had no effect. Interestingly, the proarrhythmic effect of A(1)AR stimulation was markedly reduced by inhibition of NADPH oxidase, ERK, PLC, PKC or LCC. Moreover, NADPH oxidase inhibition or antioxidant MPG prevented both A(1)AR-mediated arrhythmias and ERK phosphorylation. These results suggest that pacemaking and conduction disturbances are induced via A(1)AR through concomitant stimulation of NADPH oxidase and PLC, followed by downstream activation of ERK and PKC with LCC as possible target.

Targeting vascular NADPH oxidase 1 blocks tumor angiogenesis through a PPARα mediated mechanism.

Reactive oxygen species, ROS, are regulators of endothelial cell migration, proliferation and survival, events critically involved in angiogenesis. Different isoforms of ROS-generating NOX enzymes are expressed in the vasculature and provide distinct signaling cues through differential localization and activation. We show that mice deficient in NOX1, but not NOX2 or NOX4, have impaired angiogenesis. NOX1 expression and activity is increased in primary mouse and human endothelial cells upon angiogenic stimulation. NOX1 silencing decreases endothelial cell migration and tube-like structure formation, through the inhibition of PPARα, a regulator of NF-κB. Administration of a novel NOX-specific inhibitor reduced angiogenesis and tumor growth in vivo in a PPARα dependent manner. In conclusion, vascular NOX1 is a critical mediator of angiogenesis and an attractive target for anti-angiogenic therapies.

Evidence of systematic and proportional error in a widely used glucose oxidase analyser: Impact for clinical research?

Real time glycemia is a cornerstone for metabolic research, particularly when performing oral glucose tolerance tests (OGTT) or glucose clamps. From 1965 to 2009, the gold standard device for real time plasma glucose assessment was the Beckman glucose analyzer 2 (Beckman Instruments, Fullerton, CA), which technology couples glucose oxidase enzymatic assay with oxygen sensors. Since its discontinuation in 2009, today's researchers are left with few choices that utilize glucose oxidase technology. The first one is the YSI 2300 (Yellow Springs Instruments Corp., Yellow Springs, OH), known to be as accurate as the Beckman(1). The YSI has been used extensively for clinical research studies and is used to validate other glucose monitoring devices(2). The major drawback of the YSI is that it is relatively slow and requires high maintenance. The Analox GM9 (Analox instruments, London), more recent and faster, is increasingly used in clinical research(3) as well as in basic sciences(4) (e.g. 23 papers in Diabetes or 21 in Diabetologia). This article is protected by copyright. All rights reserved.

Métabolisme d'antidépresseurs dans différentes espèces : aspects méthodologiques et pharmacogénétiques, perspectives cliniques

Résumé pour large public Unité de Biochimie et Psychopharmacologie Clinique, Centre de neurosciences Psychiatrique, Département de Psychiatrie Adulte, Faculté de Biologie et de Médecine, Université de Lausanne Lors de la prise d'un médicament, celui-ci va passer par différentes étapes que sont l'absorption, la distribution, le métabolisme et enfin l'élimination. Ces quatre étapes sont regroupées sous le nom de pharmacocinétique. A noter que ces quatre paramètres sont dynamiques et en constante évolution. Durant cette thèse, nous avons investigué différents aspects de la pharmacocinétique, tout d'abord par une revue de la littérature sur la glycoprotéine-P (Pgp). Récemment découverte, cette protéine de membrane est située aux endroits stratégiques de l'organisme comme la barrière hématoencéphalée, le placenta ou les intestins où elle influencera l'entrée de différentes substances, en particulier les médicaments. La Pgp serait impliquée dans les phénomènes de résistances aux agents thérapeutiques en oncologie. La Pgp influence donc l'absorption des médicaments, et son impact en clinique, en termes d'efficacité de traitement et de toxicité prend chaque jour plus d'importance. Ensuite nous avons mis au point une méthode d'analyse quantitative d'un antidépresseur d'une nouvelle génération : la mirtazapine (Remeron®). La nouveauté réside dans la façon dont la mirtazapine interagit avec les neurotransmetteurs impliqués dans la dépression que sont la sérotonine et la noradrénaline. Cette méthode utilise la chromatographie liquide pour séparer la mirtazapine de ses principaux métabolites dans le sang. La spectrométrie de masse est utilisée pour les détecter et les quantifier. Les métabolites sont des substances issues de réactions chimiques entre la substance mère, la mirtazapine, et généralement des enzymes hépatiques, dans le but de rendre cette substance plus soluble en vue de son élimination. Cette méthode permet de quantifier la mirtazapine et ses métabolites dans le sang de patients traités et de déterminer la variation des taux plasmatiques chez ces patients. Puis nous avons étudié le métabolisme d'un autre antidépresseur, le citalopram, qui a un métabolisme complexe. Le citalopram est un racémate, c'est-à-dire qu'il existe sous forme de deux entités chimiques (R-(-) et S-(+) citalopram) qui ont le même nombre d'éléments mais arrangés différemment dans l'espace. La voie métabolique cérébrale du citalopram est sous le contrôle d'une enzyme, la monoamine oxydase (MAO), conduisant à une forme acide du citalopram (l'acide propionique du citalopram). La MAO existe sous deux formes : MAO-A et MAO-B. Nous avons utilisé des souris déficientes d'un gène, celui de la MAO-A, pour mieux en comprendre le métabolisme en les comparants à des souris sauvages (sans déficience de ce gène). Nous avons utilisé le citalopram et deux de ses métabolites (le déméthylcitaloprarn et le didéméthyícitalopram) comme substrats pour tester la formation in vitro de l'acide propionique du citalopram. Nos résultats montrent que la MAO-A favorise la formation de l'entité R-(-) et présente une plus grande affinité pour le citalopram, tandis que la MAO-B métabolise préférentiellement l'entité S-(+) et a une plus grande affinité pour les deux métabolites déméthylés. De plus, la déficience en MAO-A est partiellement compensée parla MAO-B chez les souris déficientes du gène de la MAO-A. Enfin, nous avons étudié une deuxième voie métabolique du citalopram qui s'est avérée toxique chez le chien Beagle. Celle-ci est catalysée par une autre famille d'enzymes, les cytochromes P-450, et mène aux métabolites déméthylés et didéméthylés du citalopram. Nous avons utilisé des tissus hépatiques de chiens Beagle. Plusieurs cytochromes P-450 sont impliqués dans le métabolisme du citalopram menant à sa forme déméthylée, ceci tant chez l'homme que chez le chien. Par contre, dans le métabolisme de la forme déméthylée menant à 1a forme didéméthylée, un seul cytochrome P-450 serait impliqué chez l'Homme, tandis qu'ils seraient plusieurs chez le chien. L'activité enzymatique produisant la forme didéméthylée est beaucoup plus importante chez le chien comparé à l'homme. Cette observation soutien l'hypothèse que des taux élevés de la forme didéméthylée participent à la toxicité spécifique du citalopram chez le chien. Nous pouvons conclure que plusieurs famille d'enzymes sont impliquées tant au niveau cérébral qu'hépatique dans la métabolisation de médicaments psychotropes. Sachant que les enzymes peuvent être stimulées ou inhibées, il importe de pouvoir suivre au plus prés les taux plasmatiques des différents psychotropes et de leurs métabolites. Résumé Unité de Biochimie et Psychopharmacologie Clinique, Centre de neurosciences Psychiatrique, Département de Psychiatrie Adulte, Faculté de Biologie et de Médecine, Université de Lausanne La plupart des médicaments subissent une transformation enzymatique dans l'organisme. Les substances issues de cette métabolisation ne sont pas toujours dotées d'une activité pharmacologique. Il s'est avéré par conséquent indispensable de suivre les taux plasmatiques d'une substance et de ses métabolites et d'établir ou non l'existence d'une relation avec l'effet clinique observé. Ce concept nommé « therapeutic drag monitoring » (TDM) est particulièrement utile en psychiatrie ou un manque de compliance des patients est fréquemment observé. Les médicaments psychotropes ont un métabolisme principalement hépatique (cytochromes P-450) et parfois cérébral (monoamines oxydases), comme pour le citalopram par exemple. Une méthode stéréosélective de chromatographie liquide couplée à la spectrométrie de masse a été développée pour analyser les énantiomères R-(-) et S-(+) d'un antidépresseur agissant sur les récepteurs noradrénergiques et sérotoninergiques, la mirtazapine et de ses métabolites déméthylmirtazapine et 8-hydroxymirtazapine. Les données préliminaires obtenues dans les plasmas dosés suggèrent que les concentrations de R-(-)-mirtazapine sont plus élevées que celles de S-(+)-mirtazapine, à l'exception des patients qui auraient comme co-médication des inhibiteurs du CYP2D6, telle que la fluoxétine ou la thioridazine. Il y a une enantiosélectivité du métabolisme de la mirtazapine. En particulier pour la 8-hydroxymirtazapine qui est glucuroconjuguée et pour laquelle le ratio S/R varie considérablement. Cette méthode analytique présente l'avantage d'être utilisable pour le dosage stéréosélectif de la mirtazapine et de ses métabolites dans le plasma de patients ayant d'autres substances en co-médication. La glycoprotéine P fonctionne comme une pompe transmembranaire transportant les xénobiotiques depuis le milieu intracellulaire vers le milieu extracellulaire. Son induction et son inhibition, bien que moins étudiées que pour les cytochromes P-450, ont des implications cliniques importantes en termes d'efficacité de traitement et de toxicité. Cette glycoprotéine P a fait l'objet d'une recherche bibliographique. Nous avons étudié le métabolisme du citalopram, un antidépresseur de la classe des inhibiteurs spécifiques de la recapture de la sérotonine chez la souris et chez le chien. Cette substance subit un métabolisme complexe. La voie de métabolisation conduisant à la formation de l'acide propionique du citalopram, catalysée par les monoamines oxydases, a été étudiée in vitro dans les mitochondries cérébrales chez la souris déficiente du gène de la MAO-A (Tg8). La monoamine oxydase A catalyse la formation de l'énantiomère R-(-) et présente une plus grande affinité pour les amines tertiaires, tandis que la monoamine oxydase B favorise la formation de la forme S-(+) et a une affinité plus marquée pour les amines secondaires et primaires. L'étude du citalopram chez la souris Tg8 adulte a montré que la monoamine oxydase B compense la déficience de la monoamine oxydase A chez ces souris génétiquement modifiées. Une autre voie de métabolisation du citalopram conduisant à la formation de didéméthylcitalopram, catalysée par les cytochromes P-450, a été étudiée in vitro dans des microsomes hépatiques de chiens Beagle. Nos études ont montré que les cinétiques de N-déméthylation du citalopram sont biphasiques chez le chien. Les orthologues canins impliqués dans la première N-déméthylation semblent être identiques aux cytochromes P-450 humains. Par contre, dans la deuxième Ndéméthylation, un seul cytochrome P-450 semble être impliqué chez l'homme (CYP2D6), tandis qu'on retrouve jusqu'à cinq orthologues chez le chien. Le CYP2D15, orthologue canin du CYP2D6, est majoritairement impliqué. De plus, l'activité enzymatique, reflétée par les clairances intrinsèques, dans la première N-déméthylation est jusqu'à 45 fois plus élevée chez le chien comparé à l'homme. Ces différentes observations soutiennent l'hypothèse que des taux élevés de didéméthylcitalopram sont responsables de la toxicité du citalopram chez le chien. Nous pouvons conclure que plusieurs famille d'enzymes sont impliquées tant au niveau cérébral qu'hépatique dans la métabolisation de médicaments psychotropes. Sachant -que les enzymes peuvent être induits ou inhibés, il importe de pouvoir suivre au plus près les taux plasmatiques des différents psychotropes et de leurs métabolites. Summary Most of the drugs are metabolized in the organism. Substances issued from this metabolic activity do not always show a pharmacological activity. Therefore, it is necessary to monitor plasmatic levels of drugs and their metabolites, and establish the relationship with the clinical effect. This concept named therapeutic drug monitoring is very useful in psychiatry where lack of compliance is commonly observed. Antidepressants are mainly metabolized in the liver (cytochrome P-450) and sometimes in the brain (monoamine oxidase) like the citalopram, for exemple. A LC-MS method was developed, which allows the simultaneous analysis of R-(-) and S-(+) enantiomers of mirtazapine, an antidepressant acting specifically on noradrenergic and serotonergic receptors, and its metabolites demethylmirtazapine and 8-hydroxymirtazapine in plasma of mirtazapine treated patients. Preliminary data obtained suggested that R-(-) mirtazapine concentrations were higher than those of S-(+) mirtazapine, except in patients comedicated with CYP2D6 inhibitors such as fluoxetine or thioridazine. There is an enantioselectivity in the metabolism of mirtazapine. In particular for the 8-hydroxymirtazapine, which is glucuroconjugated and S/R ratio varies considerably. Therefore this method seems to be suitable for the stereoselective assay of mirtazapine and its metabolites in plasma of patients comedicated with mirtazapine and other drugs for routine and research purposes. P-glycoprotein is working as an efflux transporter of xenobiotics from intracellular to extracellular environment. Its induction or inhibition, although less studied than cytochrome P-450, has huge clinical implications in terms of treatment efficacy and toxicity. An extensive literature search on P-glycoprotein was performed as part of this thesis. The study of citalopram metabolism, an antidepressant belonging to the class of selective serotonin reuptake inhibitors. This substance undergoes a complex metabolism. First metabolization route leading to citalopram propionic acid, catalyzed by monoamine oxidase was studied in vitro in mice brain mitochondria. Monoamine oxidase A catalyzed the formation of R-(-) enantiomer and showed greater affinity for tertiary amines, whereas monoamine oxidase B triggered the formation of S-(+) enantiomer and demonstrated higher affinity for primary and secondary amines. citalopram evaluation in adult Tg8 mice showed that monoamine oxidase B compensated monoamine oxidase A deficiency in those genetically transformed mice. The second metabolization route of citalopram leading to didemethylcitalopram and catalyzed by cytochrome P-450 was studied in vitro in Beagle dog's livers. Our results showed that citalopram N-demethylation kinetics are biphasic in dogs. Canine orthologs involved in the first N-demethylation seemed to be identical to human cytochromes P-450. However, in the second N-demethylation only one cytochrome P-450 seemed to be involved in human (CYP2D6), whereas up to five canine orthologs were found in dogs. CYP2D15 canine ortholog of CYP2D6 was mainly involved. In addition, enzymatic activity reflected by intrinsic clearance in the first N-demethylation was up to 45 fold higher in dogs compared to humans. Those observations support the assumption that elevated rates of didemethylcitalopram are responsible for citalopram toxicity in dogs. We can conclude that several enzymes groups are involved in the brain, as well as in the liver, in antidepressant metabolization. Knowing that enzymes may be induced or inhibited, it makes sense to closely monitor plasmatic levels of antidepressants and their metabolites.