Functional redox compartmentation of GSH in the yeast Saccharomyces cerevisiae / Compartimentalisation du glutathion dans les cellules de levure S. cerevisiae et de ses conséquences fonctionnelles

Igbaria, Aeid

23 September 2011

L'oxydation des résidus cystéines est une modification biochimique très répandue survenant dans tous les compartiments des cellules eucaryotes. Ce phénomène sert le repliement oxydatif des protéines dans le réticulum endoplasmique (RE), l'importation de protéines dans l'espace intermembranaire de la mitochondrie (IMS). De plus, il a un rôle régulateur dans la matrice mitochondriale et dans le cytosol où il contrôle l’activité des enzymes et des protéines de signalisation et de régulation. Dans tous ces procédés, la réversibilité de l'oxydation des résidus Cys est une caractéristique essentielle. Deux systèmes oxydoréductase puissants existent : les voies de glutathion (GSH) et la thiorédoxine ; ils catalysent la réduction des ponts disulfure, et contrôlent la plupart des processus cellulaires thiol-redox dépendant. Cependant, en dépit d'énormes connaissances portant sur leur enzymologie, peu est connu sur les caractéristiques physiologiques de ces systèmes chez les eucaryotes. Pour déterminer l'importance physiologique de ces systèmes et indiquer lequel est à la base de l'exigence du GSH pour la viabilité, nous avons effectué une analyse complète des cellules de levure épuisée ou contenant des niveaux toxiques de GSH. Les deux conditions déclenchent une réponse « iron-starvation-like » et une altération de l'activité des enzymes d’assemblage des centres fer-soufre (Iron sulfure cluster : ISC) extra-mitochondriales. Cependant, elles n’ont pas d'impact sur l’entretien thiol redox, à l’exception des niveaux élevés de glutathion qui ont altéré le repliement oxydatif des protéines dans le reticulum endoplasmique. Alors que le fer sauve partiellement la maturation des ISC et les défauts de croissance des cellules appauvries eh GSH, des expériences génétiques ont indiqué que, contrairement à la thiorédoxine, le glutathion ne peut pas assurer par lui-même les fonctions thiol-redox de la cellule. Nous proposons que le glutathion soit essentiel par son exigence dans l’assemblage des centres fer-soufre, mais ne serve comme backup que pour maintenir l’état thiol-redox de la cellule. Des niveaux physiologiques élevés de GSH sont ainsi destinés à isoler sa fonction dans le métabolisme du fer des variations de sa concentration pendant le stress redox, ce qui constitue un modèle contestant la vision traditionnelle du GSH comme acteur primordial du contrôle thiol-redox cytosolique.Nos données préliminaires sur la distribution de GSH dans les cellules recueillies par lasurveillance de l'état redox de rxYFP ciblée pour différents compartiments cellulaires (RE,Matrice, cytosol et IMS) dans les cellules HGT1 indiquent un transport spécifique du GSH vers le RE et l'exportation de GSSG de ce compartiment. Nous avons pu caractériser deuxtransporteurs ABC dont la suppression modifie le RE plus oxydant et entraîne une accumulation de GSSG par rapport aux cellules sauvages. Ces données ont été confirmées par le suivi de l'état redox de PDI1 et ERO1 (WT et hyper active). Elles suggèrent un rôle de ces transporteurs dans l'exportation du GSSG du la RE, et que le flux de GSH entre les différents compartiments est très régulé. / Cys residue oxidation is a widespread biochemical modification occurring in all eukaryotic cells compartments. It serves oxidative protein folding in the endoplasmic reticulum (ER), protein import in the intermembrane space of mitochondria (IMS), and it has a regulatory role in the mitochondrial matrix and in the cytosol where it controls enzymes and signaling regulatory proteins activity. In all these processes, reversibility of Cys residue oxidation is a crucial feature. Two potent oxidoreductase systems, the glutathione (GSH) and thioredoxin pathways, catalyze disulfide bond reduction, and presumably control most thiol-redox-dependent cellular processes. However, despite tremendous knowledge of their enzymology, little is known about the physiological features of these systems in eukaryotes. To determine the physiologic importance of these functions and sort out which of them accounts for the GSH requirement for viability, we performed a comprehensive analysis of yeast cells depleted of or containing toxic levels of GSH. Both conditions triggered an intense iron-starvation-like response and impaired the activity of extra-mitochondrial ISC enzymes, but did not impact thiol-redox maintenance, except high glutathione levels that altered oxidative protein folding in the endoplasmic reticulum. While iron partially rescued the ISC maturation and growth defects of GSH-depleted cells, genetic experiments indicated that unlike thioredoxin, glutathione could not support by itself the thiolredox duties of the cell. We propose that glutathione is essential by its requirement in ISC assembly but only serves as a thioredoxin back up in cytosolic thiol-redox maintenance. Glutathione high physiologic levels are thus meant to insulate its function in iron metabolism from variations of its concentration during redox stresses, a model challenging the traditional view of it as prime actor in cytosolic thiol-redox control.Our preliminary data on the distribution of GSH inside cells collected by monitoring the redox state of rxYFP targeted to different cell compartments (ER, Matrix, Cytosol and IMS) in HGT1 cells indicate a specific transport of GSH into the ER and export of GSSG out of it. We were able to characterize two ABC transporters on which their deletion modify the redox state of the ER to more oxidizing and result in accumulation of higher GSSG content compared to WT. These data were confirmed by looking to the redox state of the PDI1 and ERO1 (WT and hyper active), all together suggest a role of these transporters in GSSG export from the ER, and that GSH flux between the different compartments is highly regulated.

GSH

Thiorédoxine

Centres fer-soufre

UPR

Repliement oxydatif des protéines

Thiol-redox

Cystéines

GSH

Thioredoxin

Iron sulfur cluster

UPR

Oxidative Protein folding

Thiol-redox

Cysteine

Régulation du métabolisme secondaire de l'arginine et de la cystéine par l'acide alpha-linolénique. Implication dans la physiopathologie du syndrome métabolique / Regulation of the secondary metabolism of arginine and cysteine by linolenic acid. Implication in the physiopathology of the metabolic syndrome

Guelzim, Najoua

22 November 2011

Si l'intérêt nutritionnel des acides gras polyinsaturés (AGPI) n-3 dans la prise en charge et la prévention des dysfonctions associées au syndrome métabolique, est bien établi. Les mécanismes d'action spécifiques sous-jacents aux effets bénéfiques de cette famille d'acides gras sont encore en cours d'étude. L'objectif de ces travaux était d'explorer le rôle de l'acide alpha-linolénique ALA ou 18 :3 n-3, dans la modulation des voies affectant l'homéostasie de molécules bioactives dérivant du métabolisme secondaire des acides aminés (le monoxyde d'azote -NO- et le glutathion). L'hypothèse sous-jacente est que ces modulations pourraient expliquer, du moins en partie, le rôle des AGPI n-3 dans le maintien des fonctions biologiques contrôlées par ces métabolites (telles que la fonction endothéliale et le statut oxydant) et impliquées de près dans la physiopathologie du syndrome métabolique. Notre intérêt a porté particulièrement sur la voie de régulation génique via le PPARα et sur son implication dans le contrôle des gènes du métabolisme des acides aminés par l'ALA. Nous avons exploré chez la souris de type sauvage et invalidée pour le PPARα, l'effet de l'apport alimentaire d'ALA dans le cadre de régime normo- ou hyper-lipidiques sur les voies du métabolisme secondaire de l'arginine et de la cystéine. En parallèle nous nous sommes focalisés sur les effets de l'ALA au niveau vasculaire en utilisant un modèle de cellules endothéliales bovines en cultures. De ce travail de thèse s'est dégagé que l'ALA module effectivement le métabolisme secondaire de l'arginine et de la cystéine. L'apport d'ALA (à hauteur de 11% et 42% de l'apport énergétique) augmente la production de NO sans affecter l'expression hépatique des enzymes contrôlant l'utilisation de l'arginine (NOS et ARG). L'apport d'ALA (11%) augmente le pool hépatique du glutathion, alors que les plus forts apports d'ALA (42%) modulent l'expression des principales enzymes impliquées dans les voies d'utilisation de la cystéine (γGCL et CDO). Le PPARα ne semble pas être directement impliqué dans les effets observés de l'ALA, néanmoins, l'invalidation du PPARα rend le métabolisme secondaire des acides aminés plus sensible à la nature des acides gras alimentaire. Une meilleure biodisponibilité du NO et du glutathion suite à l'apport alimentaire d'ALA serait bénéfique pour la physiopathologie du syndrome métabolique. Il semble donc intéressant, à l'issus de ce travail, d'élaborer des études nutritionnelles validant ces effets de l'ALA chez l'homme dans une perspective de recommandations nutritionnelles. / *

Acide alpha-linolénique

Acides aminés

Acide gras polyinsaturés

Cystéine

Arginine

Syndrome métabolique

Linolenic acid

Polyunsaturated fatty acids

Amino acids

Cysteine

Arginine

Metabolic syndrome

616.39

Rôle et évolution de facteurs de virulence impliqués dans une interaction hôte-parasitoïde

Serbielle, Céline

08 December 2008

Les associations mutualistes, en permettant l'acquisition de nouvelles fonctions, ont joué un rôle majeur dans l'évolution des espèces. Pour comprendre en quoi ces associations sont impliquées dans l'adaptation des espèces nous avons étudié un cas unique de mutualisme associant un virus de type polydnavirus et une guêpe parasitoïde. Dans cette association, le virus est injecté dans l'hôte lépidoptère lors de l'oviposition et joue un rôle majeur dans le succès parasitaire en induisant une altération des fonctions physiologiques de l'hôte. En regard du nombre d'espèces de guêpes caractérisées par cette association, le virus doit constituer une innovation adaptative majeure et jouer un rôle déterminant dans l'évolution et la diversification des espèces de guêpes. En quoi cette association joue t-elle un rôle déterminant dans l'évolution et l'adaptation des guêpes ? Quelles sont les fonctions physiologiques ciblées chez l'hôte ? Pour répondre à ces questions nous avons étudié l'évolution de deux familles de gènes codant pour des facteurs de virulence potentiels et nous avons exploré les fonctions physiologiques d'une protéine potentiellement ciblée lors du parasitisme. Nous avons mis en évidence le rôle important de la sélection naturelle dans l'évolution des familles de gènes viraux. Par modélisation de la structure tridimensionnelle d'un facteur de virulence codant pour des cystatines, nous avons montré que cette sélection agissait préférentiellement au niveau des sites d'interaction avec les protéines cibles. De plus, cette étude souligne le caractère dynamique de l'évolution des facteurs de virulence incluant de multiples évènements de duplication, caractérisés par des processus de perte et d'acquisition au cours de l'évolution de l'association. Le caractère adaptatif et dynamique de l'évolution des gènes viraux a aussi été étudié en regard de l'évolution des espèces de guêpes et de leur spectre d'hôte. Par une approche fonctionnelle, nous avons étudié le rôle physiologique de protéases à cystéine qui constituent des cibles potentielles des cystatines virales. Nous avons montré que ces protéases sont régulées spécifiquement au cours du parasitisme au niveau protéique et transcriptionnel. Nous avons également montré que l'activité de ces protéases est modifiée après parasitisme. L'évolution adaptative et dynamique des facteurs de virulence reflètent leur rôle important dans le parasitisme. Il reste maintenant à montrer comment ces facteurs interagissent sur la physiologie de l'hôte lépidoptère. Des protéases à cystéine sont spécifiquement ciblées par le parasitisme, en étudiant les mécanismes d'interaction de ces protéases avec les cystatines virales et les processus coévolutifs mis en jeu, nous

polydnavirus

guepe parasitoide

cystatine

proteine tyrosine phosphatase

proteases a<br />cysteine

evolution moleculaire

Study of the Structure and Function of CXC Chemokine Receptor 2

Kwon, Hae Ryong

01 December 2010

It has been shown that the amino terminus and second extracellular loop (EC2) of CXCR2 are crucial for ligand binding and receptor activation. The lack of an ionic lock motif in the third intracellular loop of CXCR2 focuses an investigation of the mechanism by which these two extracellular regions contribute to receptor recognition and activation. The first objective of this investigation was to predict the structure of CXCR2 based on known structures of crystallized GPCRs. Rhodopsin, β2-adrenergic receptor, CXCR4 were used for homology modeling of CXCR2 structure. Highly conserved motifs found in sequence alignments of the template GPCRs were helpful to generate CXCR2 models. We also studied solvent accessibility of residues in the EC2 of CXCR2 in the inactive state. Most of the residues in the EC2 were found to be solvent accessible in the inactive state, suggesting the residues might be involved in ligand recognition. Second, we studied the role of charged residues in the EC2 of CXCR2 in ligand binding and receptor activation using constitutively active mutants (CAM) of CXCR2, D9K and D9R. Combinatorial mutations consisting of the CAM in the amino terminus and single mutations of charged residues in the EC2 were generated to study two concepts including “attraction” and “repulsion” models. The mutant receptors were used to test their effects on cell surface expression, ligand binding, receptor activation through PLC-β3, and cellular transformation. All the mutations in the repulsion model result in CXCR2 receptors that are unable to bind ligand, suggesting that each of the Arg residues in the EC2 are important for ligand recognition. Interestingly, mutations in the attraction model partially inhibited receptor activation by the CAM D9K, suggesting that Glu198 and Asp199 residues in the EC2 are associated with receptor activation. Furthermore, a novel CAM, E198A/D199A, was identified in this study. These negatively charged residues are very close to a conserved disulfide bond linking the EC2 and the third transmembrane. In this sense, these current discoveries concerning the structural basis of CXCR2 and interdisciplinary approaches would provide new insights to investigate unknown mechanisms of interaction with its cognate ligands and receptor activation.

G-protein-coupled receptor

CXC chemokine receptor 2

homology modeling

receptor activation

extracellular motifs

Bioinformatics

Cancer Biology

Medical Pharmacology

Molecular Biology

Mechanisms for Cadmium Lumen-to-Cell Transport by the Luminal Membrane of the Rabbit Proximal Tubule

Wang, Yanhua

04 May 2007

The lumen-to-cell transport, cellular accumulation, and toxicity of ionic cadmium (109Cd2+) and cadmium-cysteine conjugate (Cys-S-109Cd-S-Cys) were studied in isolated perfused S2 segments of the proximal tubule of the rabbit kidney. All perfusion solutions were HEPES buffered and contained 3H-L-glucose which functioned as a volume and leak marker along with 250 nM FD & C Green dye as a vital dye. When ionic cadmium, 0.73µM Cd2+, or 0.73µM cadmium-cysteine conjugate (Cys-S-109Cd-S-Cys) containing solution was perfused through the lumen of the tubule there was no visual evidence of toxicity such as blebbing of the luminal membrane, cellular vital dye uptake, and cellular swelling. Ionic Cd2+ transport was temperature dependent (87% reduction at 22°C and 100% at 11°C) and inhibited by FeCl2 (42% reduction at 10µM) and ZnCl2 (48% reduction at 20µM), and high Ca2+ concentrations (27% reduction at 1.95mM and 69% at 2.6mM). The ionic Cd2+ transport was not affected by verapamil and diltiazem. The cadmium conjugate (Cys-S-Cd-S-Cys) transport was also temperature dependent (76% reduction at 22°C and 100% at 11°C) and inhibited by the amino acids L-cystine and L-arginine (55% and 50% respectively), stimulated by L-methionine (56%), but not affected by L-aspartate, L-glutamate and Gly-Sar. 2, 3-Dimercaptopropane-1-Sulfonate (DMPS) co-perfused with Cd2+ decreased absorption of 20µM Cd2+ (39% reduction at 30 µM and 94.6% reduction at 200 µM), while DMPS added to the bathing solution has no effect on the luminal transport of Cd2+. DMPS co-perfused with 20 µM Cys-S-Cd-S-Cys substantially reduced Cd2+ transport (62% reduction at 30 µM). We conclude that cadmium can be transported at the luminal membrane of the S2 segment of the proximal tubule by multiple mechanisms, depending on the form which it is presented to membrane. Ionic cadmium appears to be transported by iron (DCT1), zinc (ZTL1) transporters and some kind of calcium-selective channel while cadmium conjugate of L-cysteine appears to be transported by L-cystine transporters (system b0+). Dipeptide transporter is not involved in the transport of cadmium. DMPS appears to be a chelator for cadmium.

isolated perfused tubule

DMPS

dipeptide

cystine

cysteine

sulfhydryl-containing amino acids

zinc

calcium

iron

kidney

cadmium

luminal membrane

transport

proximal tubule

Biology, general

Finding a needle in haystack: the Eukaryotic selenoproteome

Chapple, Charles E.

15 July 2009

Les selenoproteïnes constitueixen una família diversa de proteïnes, caracteritzada per la presència del Seleni (Se), en forma de l'amino àcid atípic, la selenocisteïna (Sec). La selenocisteïna, coneguda com l'amino àcid 21, és similar a la cisteïna (Cys) amb un àtom de seleni en lloc de sofre (S). Les selenoproteïnes són els responsables majoritaris dels efectes biològics del seleni i s'ha observat que poden estar implicades en la infertilitat masculina, el càncer, algunes malalties coronàries,l'activació de virus latents i l'envelliment. La selenocisteïna es codifica pel codó UGA, normalment codó de parada (STOP). Per a la recodificació correcta del UGA són necessaris diversos factors. A la part 3' de la regió no traduïda (UTR) dels transcrits dels gens de selenoproteïnes en organismes eucariotes s'hi troba una estructura de "stem-loop" anomenada SECIS. La proteïna SBP2 interactua amb el SECIS, així com amb el ribosoma, i forma un complex amb el factor d'elongació EFsec i el tRNA de la selenocisteïna, el tRNASec. Donat que el codó TGA normalment significa fi de la traducció, les formes tradicionals de cerca de gens no el reconeixen com a codó codificant. Per aquesta raó ha estat necessari desenvolupar una metodologia específica per a la predicció de gens de selenoproteïnes. En els últims anys, hem contribuït a la descripció del selenoproteoma eucariota amb el descobriment de noves famílies (Castellano et al., 2005), amb l'elaboració de nous mètodes (Taskov et al., 2005; Chapple et al., 2009) i l'anotació de diferents genomes (Jaillon et al., 2004; Drosophila 12 genomes Consortium, 2007; Bovine Genome Sequencing and Analysis Consortium, 2009). Finalment, hem identificat el primer animal que no té selenoproteïnes (Drosophila 12 genomes Consortium, 2007; Chapple and Guigó, 2008), un descobriment soprenent donat que, fins el moment, es creia que les selenoproteïnes eren essencials per la vida animal. / Selenoproteins are a diverse family of proteins containing the trace element Selenium (Se)in the form of the non-canonical amino acid selenocysteine (Sec). Selenocysteine, the 21st amino acid, is similar to cysteine (Cys)but with Se replacing Sulphur. In many cases the homologous gene of a known selenoprotein is present with cysteine in the place of Sec in a different genome. Selenoproteins are believed to be the effectors of the biological functions of Selenium and have been implicated in male infertility, cancer and heart diseases, viral expression and ageing. Selenocysteine is coded by the opal STOP codon (TGA). A number of factors combine to achieve the co-translational recoding of TGA to Sec. The 3' Untranslated regions (UTRs) of eukaryotic selenoprotein transcripts contain a stem-loop structure called a Sec Insertion Sequence (SECIS) element. This is recognised by the Secis Binding Protein 2 (SBP2), which binds to both the SECIS element and the ribosome. SBP2, in turn, recruits the Sec-specific Elongation Factor EFsec, and the selenocysteine transfer RNA, tRNASec. The dual meaning of the TGA codon means that selenoprotein genes are often mispredicted by the standard annotation pipelines. The correct prediction of these genes, therefore, requires the development of specific methods. In the past few years we have contributed significally to the description of the eukaryotic selenoproteome2 with the discovery of novel families (Castellano et al., 2005), the elaboration of novel methods (Taskov et al., 2005; Chapple et al., 2009) and the annotation of different genomes (Jaillon et al., 2004; Drosophila 12 genomes Consortium, 2007; Bovine Genome Sequencing and Analysis Consortium, 2009). Finally, and perhaps most importantly, we have identified the first animal to lack selenoprotein genes (Drosophila 12 genomes Consortium, 2007; Chapple and Guigó, 2008). This last finding is particularly surprising because it had previously been believed that selenoproteins were essential for animal life.

amino acid sequence - data processing

cysteine - genetic aspects

selenium - genetic aspects

selenocisteïna -- aspectes genètics

575

Studies into sulfur amino acid and bile salt metabolism in pancreatic and liver diseases : profiles of sulfur amino acids and glutathione in acute pancreatitis : method development for total and oxidized glutathione by liquid chromatography : bile salt profiles in liver disease by liquid chromatography-mass spectrometry

Srinivasan, Asha R.

January 2010

Sulfur amino acids have critical function as intracellular redox buffers and maintain homeostasis in the external milieu by combating oxidative stress. Synthesis of glutathione (GSH) is regulated at a substrate level by cysteine, which is synthesized by homocysteine via the transsulfuration pathway. Oxidative stress and diminished glutathione pools play a sustained role in the pathogenesis of acute pancreatitis. One of the aims of this study was to experimentally address the temporal relationship between plasma sulfur amino acid levels in patients suffering from acute pancreatitis. The data indicated low concentration of cysteine initially, at levels similar to those of healthy controls. Glutathione was found reduced whilst cysteinyl-glycine and γ- glutamyl transpeptidase activity were increased in both mild and severe attacks. As the disease progressed, glutathione and cysteinyl-glycine were further increased in mild attacks and cysteine levels correlated with homocysteine and γ-glutamyl transpeptidase activity. The progress of severe attacks was associated with glutathione depletion, reduced γ-glutamyl transpeptidase activity and increased cysteinyl-glycine, that correlated with glutathione depletion. The corollary that ample supply of cysteine and cysteinly-glycine does not contribute towards glutathione synthesis in acute pancreatitis poses an important issue that merits resolution. Heightened oxidative stress and depletion of glutathione rationalized the progression of disease in severe attacks. An upsurge that reactive oxygen species can shift redox state of cells is determined by the ratio of the abundant redox couples reduced and oxidized glutathione (GSH: GSSG) in cell. The study reported a novel methodology for quantification of total oxidized glutathione (tGSSG) and total glutathione (tGSH) in whole blood using reverse phase high performance liquid chromatography. The novelty of the method is ascertained by the use of a mercaptan scavenger 1, methyl-2-vinyl-pyridinium trifluromethanesulfonate for the total oxidized glutathione determination. The results reported permit quantitation of tGSSG and tGSH and was applied to a control group. Finally, the study was also focussed in developing a liquid chromatography-mass spectrometric method to evaluate free and conjugated bile acids in patients suffering from various degrees of cholestatic-hepatobiliary disorders. The study reported low levels of ursodeoxycholic acid (UDCA) and slightly high levels of lithocholic acid (LCA). All the primary bile acids seem to be conjugated with glycine and taurine amino acid.

615.1

Mécanismes moléculaires d’activation du récepteur A des peptides natriurétiques

Parat, Marie

08 1900

Le récepteur A des peptides natriurétiques (NPRA) fait partie de la famille des guanylates cyclases membranaires. L’activation du NPRA par ses agonistes naturels, ANP et BNP, induit une production de GMPc qui est responsable de leur rôle dans l’homéostasie cardiovasculaire, l’inhibition de l’hypertrophie et de la fibrose cardiaques et la régulation de la lipolyse. Le NPRA est un homodimère non covalent composé d’un domaine extracellulaire de liaison du ligand (ECD), d’un unique domaine transmembranaire (TM), d’un domaine d’homologie aux kinases et d’un domaine guanylate cyclase. Bien que le NPRA ait un rôle physiologique important, les mécanismes moléculaires régissant son processus d’activation restent inconnus. Nous avons donc analysé les premières étapes du processus d’activation du NPRA. Nous avons d'abord étudié le rôle de la dimérisation des ECD dans l’activation du récepteur. Nous avons utilisé les techniques de liaison de radioligand, de FRET et de modélisation moléculaire, pour caractériser la liaison à l’ECD des agonistes naturels, d’un superagoniste et d’un antagoniste. L’ANP se lie à un dimère d’ECD préformé et la dimérisation spontanée est l’étape limitante du processus de liaison. De plus, comme le démontrent nos études de FRET, tous les peptides, incluant l’antagoniste, stabilisent le récepteur sous sa forme dimérique. Cependant, l’antagoniste A71915 stabilise le dimère d’ECD dans une conformation différente de celle induite par l’ANP. La dimérisation du NPRA semble donc nécessaire, mais non suffisante à l’activation du récepteur. L’état d’activation du NPRA dépend plutôt de l’orientation des sous unités dans le dimère. Nous avons ensuite étudié le mécanisme moléculaire de transduction du signal à travers la membrane. Plusieurs études ont suggéré que l’activation du NPRA implique un changement de conformation du domaine juxtamembranaire (JM). Cependant, les études de cristallographie de l’ECD soluble de NPRA n’ont pas permis de documenter la structure du JM et le changement de conformation impliqué dans la transduction du signal reste inconnu. Pour analyser ce changement de conformation, nous avons d’abord séquentiellement substitué les neuf acides aminés du JM par une cystéine. En étudiant la capacité des mutants à former des dimères covalents de façon constitutive ou induite par l’ANP, nous avons pu évaluer la proximité relative des résidus du JM, avant et après activation du NPRA. Ces résultats ont démontré la proximité élevée de certains résidus spécifiques et sont en contradiction avec les données cristallographiques. Nous avons également démontré que le domaine intracellulaire impose une contrainte conformationnelle au JM à l’état de base, qui est levée après liaison de l’ANP. En introduisant de 1 à 5 alanines dans l’hélice-α transmembranaire, nous avons montré qu’une rotation des TM de 40° induit une activation constitutive du NPRA. Le signal d’activation pourrait donc être transmis à travers la membrane par un mécanisme de rotation des TM. En utilisant nos données expérimentales, nous avons généré le premier modèle moléculaire illustrant la conformation active du NPRA, où les domaines JM et TM sont représentés. Dans son ensemble, cette étude apporte une meilleure compréhension des mécanismes moléculaires régissant les premières étapes du processus complexe d’activation du NPRA. / Natriuretic peptide receptor-A (NPRA) is a member of the particulate guanylate cyclase family. NPRA activation by natural agonists, ANP and BNP, leads to cGMP production, which is responsible for their role in cardiovascular homeostasis, cardiac hypertrophy and fibrosis inhibition and lipolysis regulation. NPRA is a non covalent dimer composed of an extracellular domain (ECD) with a ligand binding site, a single transmembrane region (TM), a kinase homology domain, and a guanylyl cyclase domain. Although NPRA plays an important physiologic role, molecular mecanisms driving its activation process are yet unknown. We thus analysed the first steps of NPRA’s activation process. First, we studied the role of ECD dimerization in receptor activation and determined the sequential steps of this dimerization process. We used radioligand binding, FRET and molecular modeling to characterize the interaction of ECD with natural agonists, a superagonist and an antagonist. ANP binds to preformed ECD dimers and spontaneous dimerization is the rate-limiting step of the ligand binding process. Furthermore, like demonstrated with fluorescence homoquenching, all the studied peptides, including A71915 antagonist, stabilize a dimeric form of the receptor. However, A71915 stabilizes the ECD dimer in a conformation distinct from those induced by ANP. Thus, ECD dimerization is necessary but not sufficient for NPRA activation. The activation state of NPRA seems to depend on the orientation of the receptor subunits within the dimer. Then, we tried to identify the molecular mechanism of signal transduction through the plasma membrane. Previous studies have shown that activation of NPRA involves a conformational change of the juxtamembrane domain (JM). However, crystallographic study of the soluble ECD of NPRA has failed to document JM structure, and the conformational change involved in transmembrane signal transduction is still unknown. To analyse this conformational change, we first sequentially substituted nine amino acids of JM by a cysteine residue. By studying the mutant’s capacity to form ANP-induced or constitutive covalent disulfide dimers, we evaluated the relative proximity of JM residues, before and after NPRA activation. These results demonstrate a high proximity of specific JM residues and are in disagreement with crystallography data. We also demonstrated that intracellular domain imposes a conformational constraint on JM at basal state, which becomes relaxed upon ANP binding. We finally confirmed, with a full-length receptor, that A71915 stabilizes NPRA in a dimeric form where JM are in a conformation distinct from the basal state. By introducing 1 to 5 alanine residues in the transmembrane α-helix, we showed that a TM rotation of 40° leads to constitutive NPRA activation. Activation signal could thus be transmitted through the membrane by a TM rotation mechanism. We finally studied the role of the TM in NPRA dimerization. By using the ToxR system, we demonstrated that the last JM residues are required to stabilize the TM dimer. Using these experimental data, we generated the first molecular model illustrating the active conformation of NPRA, where JM and TM are depicted. In summary, this study allows a better understanding of molecular mecanisms driving the first steps of NPRA’s complex activation process.

Guanylate cyclase

Transduction du signal

Changement de conformation

Dimérisation

Rotation

Balayage de cystéine

FRET

Signal transduction

Conformational change

Dimerization

Cysteine-scanning

Behavioural, neurochemical, inflammatory and mitichondrial markers following social isolation rearing in rats before and after selected deug intervention / Marisa Möller

Möller, Marisa

January 2012

Purpose: Schizophrenia is a progressive degenerative illness that has been causally linked to mitochondrial dysfunction, oxidative stress and a pro-inflammatory state. Social isolation rearing (SIR) in rats models the neurodevelopmental aspects of schizophrenia. The antioxidant and glutamate modulator, N-acetyl cysteine (NAC), has demonstrated therapeutic potential in schizophrenia as adjunctive treatment, although this has not been tested in the SIR model. The purpose of this study was to assess whether SIR induces changes in mitochondrial function (adenosine triphosphate (ATP)), pro- vs. anti-inflammatory cytokine balance, tryptophan metabolism, a disturbance in cortico-striatal monoamines and related metabolites, and associated alterations in behaviors akin to schizophrenia, viz. social interaction, object recognition memory and prepulse inhibition (PPI). Moreover, I evaluated whether these bio-behavioral alterations could be reversed with sub-chronic clozapine, or NAC, and whether NAC may bolster the response to clozapine treatment. Methods: The objectives of the study were pursued through separately conducted studies. Male Sprague-Dawley (SD) rats (10 rats/group) were used in this study (Ethics number: NWU-0035-08-S5). Rats were randomly allocated to either social rearing or SIR for 8 weeks receiving either no treatment, vehicle, NAC (150 mg/kg/day), clozapine (5 mg/kg/day) or a combination of clozapine + NAC (CLZ + NAC) during the last 11 or 14 days of social rearing or SIR. After the 8 weeks, rats were tested for social interactive behaviors, object recognition memory and prepulse inhibition (PPI). Peripheral tryptophan metabolites (determined by liquid chromatography-tandem mass spectrometry (LC-MS/MS)) and pro- and anti-inflammatory cytokines (IL-4, IL-6, TNF-α, IFN-γ) (enzyme-linked immunosorbent assay (ELISA)) were determined. Cortico-striatal ATP (bioluminescence assay) and monoamines (high performance liquid chromatography (HPLC)) were also determined. Results: SIR-induced significant deficits in social interactive behaviours, object recognition memory and PPI, associated with increased peripheral kynurenine, quinolinic acid (QA), and pro-inflammatory cytokines, as well as a decrease in kynurenic acid (KYNA), neuroprotective ratio and anti-inflammatory cytokines. I also observed an increase in striatal, but reduced frontal cortical ATP, dopamine, serotonin as well as their metabolites and noradrenaline’s metabolite, with noradrenaline increased in both brain regions in SIR rats. A separate dose-response study of NAC (50, 150, 250 mg/kg/day) found 150 mg/kg to be the most appropriate dose for the NAC and CLZ + NAC studies. Clozapine, NAC as well as CLZ + NAC reversed all these changes, with NAC being less effective than CLZ alone. CLZ + NAC was found to be more effective than clozapine alone in reversing certain bio-behavioral alterations induced by SIR. In addition NAC alone dose dependently reversed most of the SIR induced alterations. Conclusion: SIR induces behavioral alterations, a pro-inflammatory state, mitochondrial dysfunction and cortico-striatal monoamine alterations, closely resembling evidence in schizophrenia. Importantly, all these bio-behavioral alterations were reversed with clozapine, NAC and CLZ + NAC treatment. However, CLZ + NAC was more effective than clozapine alone in reversing some bio-behavioral alterations, supporting the therapeutic application of NAC as adjunctive treatment in schizophrenia. In addition, NAC dose dependently reversed SIR-induced cortico-striatal serotonin, noradrenaline and metabolites, emphasizing NAC’s potential use in other anxiety and stress- related disorders. / Thesis (PhD (Pharmacology))--North-West University, Potchefstroom Campus, 2013

Social isolation

Schizophrenia

N-acetyl cysteine

Clozapine

Social interaction

Object recognition

Prepulse inhibition

Pro-inflammatory state

Neuroprotective ratio

LC-MS/MS

Behavioural, neurochemical, inflammatory and mitichondrial markers following social isolation rearing in rats before and after selected deug intervention / Marisa Möller

Möller, Marisa

January 2012

Purpose: Schizophrenia is a progressive degenerative illness that has been causally linked to mitochondrial dysfunction, oxidative stress and a pro-inflammatory state. Social isolation rearing (SIR) in rats models the neurodevelopmental aspects of schizophrenia. The antioxidant and glutamate modulator, N-acetyl cysteine (NAC), has demonstrated therapeutic potential in schizophrenia as adjunctive treatment, although this has not been tested in the SIR model. The purpose of this study was to assess whether SIR induces changes in mitochondrial function (adenosine triphosphate (ATP)), pro- vs. anti-inflammatory cytokine balance, tryptophan metabolism, a disturbance in cortico-striatal monoamines and related metabolites, and associated alterations in behaviors akin to schizophrenia, viz. social interaction, object recognition memory and prepulse inhibition (PPI). Moreover, I evaluated whether these bio-behavioral alterations could be reversed with sub-chronic clozapine, or NAC, and whether NAC may bolster the response to clozapine treatment. Methods: The objectives of the study were pursued through separately conducted studies. Male Sprague-Dawley (SD) rats (10 rats/group) were used in this study (Ethics number: NWU-0035-08-S5). Rats were randomly allocated to either social rearing or SIR for 8 weeks receiving either no treatment, vehicle, NAC (150 mg/kg/day), clozapine (5 mg/kg/day) or a combination of clozapine + NAC (CLZ + NAC) during the last 11 or 14 days of social rearing or SIR. After the 8 weeks, rats were tested for social interactive behaviors, object recognition memory and prepulse inhibition (PPI). Peripheral tryptophan metabolites (determined by liquid chromatography-tandem mass spectrometry (LC-MS/MS)) and pro- and anti-inflammatory cytokines (IL-4, IL-6, TNF-α, IFN-γ) (enzyme-linked immunosorbent assay (ELISA)) were determined. Cortico-striatal ATP (bioluminescence assay) and monoamines (high performance liquid chromatography (HPLC)) were also determined. Results: SIR-induced significant deficits in social interactive behaviours, object recognition memory and PPI, associated with increased peripheral kynurenine, quinolinic acid (QA), and pro-inflammatory cytokines, as well as a decrease in kynurenic acid (KYNA), neuroprotective ratio and anti-inflammatory cytokines. I also observed an increase in striatal, but reduced frontal cortical ATP, dopamine, serotonin as well as their metabolites and noradrenaline’s metabolite, with noradrenaline increased in both brain regions in SIR rats. A separate dose-response study of NAC (50, 150, 250 mg/kg/day) found 150 mg/kg to be the most appropriate dose for the NAC and CLZ + NAC studies. Clozapine, NAC as well as CLZ + NAC reversed all these changes, with NAC being less effective than CLZ alone. CLZ + NAC was found to be more effective than clozapine alone in reversing certain bio-behavioral alterations induced by SIR. In addition NAC alone dose dependently reversed most of the SIR induced alterations. Conclusion: SIR induces behavioral alterations, a pro-inflammatory state, mitochondrial dysfunction and cortico-striatal monoamine alterations, closely resembling evidence in schizophrenia. Importantly, all these bio-behavioral alterations were reversed with clozapine, NAC and CLZ + NAC treatment. However, CLZ + NAC was more effective than clozapine alone in reversing some bio-behavioral alterations, supporting the therapeutic application of NAC as adjunctive treatment in schizophrenia. In addition, NAC dose dependently reversed SIR-induced cortico-striatal serotonin, noradrenaline and metabolites, emphasizing NAC’s potential use in other anxiety and stress- related disorders. / Thesis (PhD (Pharmacology))--North-West University, Potchefstroom Campus, 2013

Social isolation

Schizophrenia

N-acetyl cysteine

Clozapine

Social interaction

Object recognition

Prepulse inhibition

Pro-inflammatory state

Neuroprotective ratio

LC-MS/MS