Global ETD Search

41	Fonction des aquaporines de la membrane plasmique dans les mouvements stomatiques chez Arabidopsis thaliana / Function of plasma membrane aquaporins in stomatal movements in Arabidopsis thaliana Grondin, Alexandre 10 May 2011 (has links) Les mouvements stomatiques sont dus à des changements importants du volume des cellules de garde. Un rôle des canaux hydriques membranaires (aquaporines) dans ces processus a été proposé mais n'a jamais été démontré. Des analyses transcriptomiques indiquent que plusieurs aquaporines de la membrane plasmique (PIPs), dont AtPIP1;2 et AtPIP2;1, sont exprimées dans la cellule de garde. Dans ce travail, nous avons étudié la fonction de ces deux aquaporines dans les mouvements stomatiques. Les stomates des mutants d'insertion pip1;2 et pip2;1 montrent une ouverture normale à la lumière et aux faibles concentrations en CO2, une fermeture normale en réponse à l'obscurité et aux fortes concentrations en CO2, mais sont quasiment insensibles à la fermeture induite par l'ABA. Le rôle d'AtPIP1;2 et d'AtPIP2;1 dans le transport d'eau a été testé en mesurant la perméabilité hydrique de protoplastes (Pf) à l'obscurité, à la lumière ou à la lumière et en présence d'ABA. Le Pf des protoplastes de cellules de garde de pip2;1 est réduit de façon significative, spécifiquement en présence d'ABA. Comme la production extracellulaire de peroxyde d'hydrogène (H2O2) est essentielle pour la signalisation intracellulaire de l'ABA, nous avons également étudié la possibilité qu'AtPIP1;2 et AtPIP2;1 facilitent la diffusion de l'H2O2 à l'intérieur des cellules de garde en réponse à l'ABA. La cinétique d'accumulation d'espèces réactives de l'oxygène est abolie dans les cellules de garde chez pip2;1, mais pas chez pip1;2. Par ailleurs, dans d'autres types d'approches, nous avons étudié la régulation de ces deux aquaporines après production en levure Pichia pastoris et reconstitution fonctionnelle en protéoliposomes. Une analyse structure fonction a été réalisée avec succès pour AtPIP2;1. Elle montre que le résidu His199 est impliqué dans l'inhibition de l'activité de cette isoforme par les protons et les cations divalents. A l'inverse, le résidu Arg124 rend AtPIP2;1 complètement insensible au calcium, mais n'altère pas sa sensibilité aux protons. La surexpression de formes dérégulées d'AtPIP1;2 et d'AtPIP2;1 dans, respectivement, les mutants pip1;2 et pip2;1, indique que les régulations de l'activité intrinsèque de ces isoformes sont importantes pour leurs fonctions stomatiques. L'ensemble des résultats suggère qu'AtPIP1;2 et AtPIP2;1 ont des fonctions majeures et distinctes dans le transport d'eau et d'H2O2 lors de la fermeture stomatique induite par l'ABA chez Arabidopsis thaliana. / Stomatal movements are mediated by drastic changes in guard cell volume. A role in these processes for water channel proteins named aquaporins has been proposed but not demonstrated. Transcriptome analyses have indicated that several plasma membrane aquaporins (PIPs) including AtPIP1;2 and AtPIP2;1 are expressed in Arabidopsis thaliana guard cells. In the present work, we investigated the function of these two aquaporins in stomatal movements. The stomata of pip1;2 and pip2;1 knock-out mutants showed a normal opening response to light and low CO2, a normal closing response to darkness and high CO2, but were almost insensitive to abscisic acid (ABA)-induced stomatal closure. A direct role of AtPIP1;2 and AtPIP2;1 in water transport was investigated by measurement of guard cell protoplast water permeability (Pf) under darkness, light and light with ABA. The Pf of pip2;1 guard cell protoplasts was significantly reduced, specifically in the presence of ABA. As extracellular hydrogen peroxyde (H2O2) production is essential for intracellular ABA signalling, we also investigated the possibility that AtPIP1;2 and AtPIP2;1 facilitate the diffusion of H2O2 through the guard cell plasma membrane. Time-dependent accumulation of reactive oxygen species in response to ABA was abolished in pip2;1 but not pip1;2 guard cells. In another type of approach, the regulation of the two aquaporins was investigated after production in the yeast Pichia pastoris and functional reconstitution in proteoliposomes. Structure-function analysis was achieved in the case of AtPIP2;1, showing that cytoplasmic residue His199 is involved in both divalent-cation- and proton-mediated gating. In contrast, mutation of Arg124 rendered AtPIP2;1 largely insensitive to calcium while remaining fully sensitive to protons. Over-expression of deregulated forms of AtPIP1;2 and AtPIP2;1 in pip1;2 and pip2;1, respectively, indicated that the gating regulation of these proteins may play an important role in their guard cells functions. Altogether, our results suggest that AtPIP2;1, and to a lesser extent AtPIP1;2, play important and distinct roles in water and H2O2 fluxes during ABA-induced stomatal closure in Arabidopsis thaliana. Arabidopsis thaliana Cellule de garde Acide abscissique Aquaporine Eau Peroxyde d'hydrogène Arabidopsis thaliana Guard cell Abscisic acid Aquaporin Water Hydrogen peroxyde
42	Caractérisation fonctionnelle de protéines en interaction avec l'aquaporine PIP2;1 / Functional characterisation of proteins interacting with the aquaporin PIP2;1 Champeyroux, Chloé 29 November 2017 (has links) La conductivité hydraulique racinaire (Lpr) traduit la capacité de transport d’eau de la racine. Lors de son trajet du sol vers le xylème, l’eau diffuse au sein de l’apoplasme ou au travers des cellules (voie de cellule-à-cellule). Au niveau de l’endoderme, la diffusion apoplasmique de l’eau est bloquée par le cadre de Caspari et des lamelles de subérine. La voie de cellule-à-cellule dépend principalement de l’activité des aquaporines régulées en partie par des interactions protéiques. Ce travail caractérise de nouveaux interactants de l’aquaporine racinaire PIP2;1 : le récepteur kinase RKL1 et 4 protéines de fonction inconnue appartenant à la sous-famille 1 des Casparian Strip membrane domain Protein Like (CASPL1) (CASPL1-B1/B2/D1/D2). RKL1 est exprimée dans l’endoderme, est capable d’interagir physiquement avec PIP2;1 et stimule in vitro le transport d’eau par l’aquaporine. Cependant, l’inactivation de RKL1 n’affecte pas la Lpr sans que cela ne puisse être expliqué par une redondance fonctionnelle avec son plus proche homologue, RLK902. Une étude bibliographique suggère que l’interaction entre RKL1 et PIP2;1 interviendrait dans une voie de signalisation en réponse à une attaque pathogène. Concernant les CASPL, D1 est exprimé dans tous les tissus, alors que B1, B2 et D2 semblent uniquement exprimés dans des territoires subérisés. Ce profil suggère une implication de B1, B2 et D2 dans une régulation des aquaporines et de la subérisation. Au niveau moléculaire, D2, malgré son interaction physique avec PIP2;1, ne module pas le transport d’eau par l’aquaporine. En revanche, B1 interagit préférentiellement avec PIP2;1 sous une forme phosphorylée et stimule le transport d’eau par l’aquaporine. Au niveau de la plante entière, l’inactivation d’un ou deux gènes CASPL n’affecte ni la Lpr., ni la subérisation. Par contre, l’inactivation de PIP2;1 et PIP2;2 révèle un effet inhibiteur de ces aquaporines sur la subérisation. Cette étude a permis de décrire de nouveaux mécanismes originaux de régulation des aquaporines. Elle pose également, la question de l’existence d’une relation entre les transports d’eau par la voie apoplasmique et par les aquaporines. / The root hydraulic conductivity (Lpr) reflects the water transport capacity of the root. During its transfer from the soil to the xylem, water can diffuse in the apoplasm or through the cells (cell-to-cell pathway). At the endodermis, the apoplastic diffusion of water is blocked by the Casparian Strip and suberin lamellae. The cell-to-cell pathway mainly relies on aquaporin activity which can be regulated by protein interactions. This study aims at characterizing new interactants of the root aquaporin PIP2;1: the receptor kinase RKL1 and 4 proteins of unknown function belonging to the Casparian Strip membrane domain Protein Like 1 sub-family (CASPL1-B1/B2/D1/D2). RKL1 is expressed in the endodermis, can physically interact with PIP2;1 and stimulates its water transport function in vitro. However a loss-of-function of RKL1 does not affect the Lpr., independently of a putative functional redundancy with its closest homolog RLK902. Concerning CASPL, D1 is expressed in every tissue of the root whereas B1, B2 and D2 appear to be specifically expressed in suberized tissues. This suggests a putative role of these isoforms in aquaporin regulation and suberisation. At the molecular level, D2 does not modulate PIP2;1 water transport activity despite a physical interaction between the two partners. By contrast, B1 interacts with PIP2;1 preferentially in its phosphorylated form and enhances the water transport activity of the aquaporin. At the plant level, disrupting one or two CASPL genes neither impact the Lpr nor affect the suberisation. However, the loss of function of both PIP2;1 and PIP2;2 reveals a negative effect of these aquaporins on suberisation. In conclusion, this study, uncovered novel regulation mechanisms of aquaporins. It also raises the question of the existence of a putative relationship between water transport by the apoplastic pathway and by aquaporins. Aquaporine Interaction protéique Régulation Phosphorylation Conductivité hydraulique racinaire Subérine Aquaporin Protein interaction Regulation Phosphorylation Root hydraulic conductivity Suberin
43	Analyse fonctionnelle de deux nouvelles mutations récessives de l’AQP2 impliquées dans le diabète insipide néphrogénique par expression dans les ovocytes de Xenopus laevis Leduc-Nadeau, Alexandre 06 1900 (has links) Le diabète insipide néphrogénique (DIN) autosomal peut être causé par les mutations du gène codant pour le canal à eau aquaporine-2 (AQP2). Un modèle couramment utilisé pour l’étude des protéines membranaires telle l’AQP2 est l’expression hétérologue dans les ovocytes de Xenopus laevis. Malheureusement, les techniques déjà existantes de purification de membranes plasmiques sont soit trop longues, trop difficiles ou demandent trop de matériel, ne permettent pas l’analyse adéquate du ciblage des formes sauvage comme mutantes, un élément crucial de ce type d’étude. Nous avons donc dans un premier temps mis au point une technique rapide et efficace de purification de membranes plasmiques qui combine la digestion partielle de la membrane vitelline, sa polymérisation à la membrane plasmique suivi de centrifugations à basse vitesse pour récolter les membranes purifiées. Nous avons utilisé cette technique dans l’étude de deux nouveaux cas familiaux de patients hétérozygotes possédant les mutations V24A et R187C dans un cas et K228E et R187C dans le second cas. Pour chaque mutation, nous avons analysé autant les éléments de fonctionnalité que les paramètres d’expression des protéines mutantes. Les expériences de perméabilité membranaire démontrent que les ovocytes exprimant AQP2-V24A (Pf = 16.3 ± 3.5 x 10-4 cm/s, 10 ng) et AQP2- K228E (Pf = 19.9 ± 7.0 x 10-4 cm/s, 10 ng) ont des activités similaires à celle exprimant la forme native (Pf = 14.4 ± 5.5 x 10-4 cm/s, 1 ng), tandis que AQP2- R187C (Pf = 2.6 ± 0.6 x 10-4 cm/s, 10 ng) ne semble avoir aucune activité comme ce qui est observé chez les ovocytes non-injectés (Pf = 2.8 ± 1.0 x 10-4 cm/s). Les études de co-expression ont démontré un effet d’additivité lorsque AQP2-V24A et -K228E sont injectées avec la forme native et un effet s’apparentant à la dominance négative lorsque AQP2-R187C est injecté avec la forme native, avec AQP2-V24A ou avec –K228E. Les résultats obtenus par immunobuvardage représente bien ce qui a été démontré précédemment, on remarque la présence des mutations K228E, V24A et la forme sauvage à la membrane plasmique, contrairement à la mutation R187C. Cependant, lorsque les mutations sont exprimées dans des cellules mIMCD-3, il n’y a qu’une faible expression à la membrane de la forme –K228E et une absence totale des formes –V24A et –R187C à la membrane plasmique, contrairement à la forme native. Les résultats de nos études démontrent que tout dépendant du système d’expression les formes –K228E et –V24A peuvent être utiles dans l’étude des problèmes d’adressage à la membrane à l’aide de chaperonne chimique. De plus, la forme –R187C démontre des difficultés d’adressage qui devront être étudiées afin de mieux comprendre la synthèse des formes natives. / The autosomal nephrogenic diabetes insipidus (NDI) is caused by mutations of the gene coding for the water channel aquaporine-2 (AQP2). An oftenly used model for the study of membrane proteins such as AQP2 is the heterogenous expression in Xenopus laevis oocytes. Unfortunately, the existing techniques of plasma membranes purification are either too long, too difficult or require too much material, which does not allow adequate analysis of targeting of the native and mutants forms, which is crucial for this type of study. We developed a fast and effective plasma membrane purification technique which combines partial digestion of the vitellin membrane, its polymerization with the plasma membrane followed by a serie of low speed centrifugations to collect the purified membranes. We used this technique to study of two new family cases of heterozygote patients carrying the V24A and R187C mutations in a case and K228E and R187C in the second case. For each mutation, we analyzed the functionality and the parameters of expression of the mutant proteins. The membrane permeability experiments show that the oocytes expressing AQP2- V24A (Pf = 16.3 ± 3.5 x 10-4 cm/s, 10 ng) and AQP2-K228E (Pf = 19.9 ± 7.0 x 10-4 cm/s, 10 ng) have similar activities to the oocytes expressing the native form (Pf = 14.4 ± 5.5 x 10-4 cm/s, 1 ng), while AQP2-R187C (Pf = 2.6 ± 0.6 x 10-4 cm/s, 10 ng) doesn’t seem to have any activity like the un-injected oocytes (Pf = 2.8 ± 1.0 x 10-4 cm/s). The coexpression studies showed an additive effect when AQP2-V24A and -K228E are injected with the native form and an effect being associated with negative dominance when AQP2-R187C was injected with AQP2-V24A, -K228E and the native form. Western blot results confirmed what was observed in the functionality studies. However, when the mutations were expressed in mIMCD-3 cells, there was a slight expression of the K228E mutation to the plasma membrane and a total absence of the mutations –V24A and R187C at the plasma membrane. The results of our studies showed that depending on the expression system the mutations –K228E and -V24A can be used in targeting studies using chemical chaperones. Ovocyte Aquaporine-2 Diabète insipide néphrogénique mutation Oocyte Aquaporin-2 Nephrogenic diabetes insipidus mutation
44	Marginally hydrophobic transmembrane α-helices shaping membrane protein folding de Marothy, Tuuli Minttu Virkki January 2014 (has links) Most membrane proteins are inserted into the membrane co-translationally utilizing the translocon, which allows a sufficiently long and hydrophobic stretch of amino acids to partition into the membrane. However, X-ray structures of membrane proteins have revealed that some transmembrane helices (TMHs) are surprisingly hydrophilic. These marginally hydrophobic transmembrane helices (mTMH) are not recognized as TMHs by the translocon in the absence of local sequence context. We have studied three native mTMHs, which were previously shown to depend on a subsequent TMH for membrane insertion. Their recognition was not due to specific interactions. Instead, the presence of basic amino acids in their cytoplasmic loop allowed membrane insertion of one of them. In the other two, basic residues are not sufficient unless followed by another, hydrophobic TMH. Post-insertional repositioning are another way to bring hydrophilic residues into the membrane. We show how four long TMHs with hydrophilic residues seen in X-ray structures, are initially inserted as much shorter membrane-embedded segments. Tilting is thus induced after membrane-insertion, probably through tertiary packing interactions within the protein. Aquaporin 1 illustrates how a mTMH can shape membrane protein folding and how repositioning can be important in post-insertional folding. It initially adopts a four-helical intermediate, where mTMH2 and TMH4 are not inserted into the membrane. Consequently, TMH3 is inserted in an inverted orientation. The final conformation with six TMHs is formed by TMH2 and 4 entering the membrane and TMH3 rotating 180°. Based on experimental and computational results, we propose a mechanism for the initial step in the folding of AQP1: A shift of TMH3 out from membrane core allows the preceding regions to enter the membrane, which provides flexibility for TMH3 to re-insert in its correct orientation. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p> membrane protein folding hydrophobicity translocon transmembrane helix orientational preference positive inside rule aquaporin 1
45	Computational Studies of Small Molecule Permeation across Membrane Channels Ariz Extreme, Igor 07 August 2018 (has links) No description available. 570 Molecular Dynamics Fluc channel 3D-RISM Free energy calculations Ion channel Permeation Membrane channels Urea Transporter Aquaporin Biologie (PPN619462639)
46	Espectro da neuromielite óptica : estudo clínico, imunológico e de neuroimagem / Neuromyelitis optica spectrum disorders : study of the clinical, immunological and neuroimaging aspects Silva, Felipe von Glehn, 1978- 22 August 2018 (has links) Orientadores: Leonilda Maria Barbosa dos Santos, Benito Pereira Damasceno / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-22T19:26:19Z (GMT). No. of bitstreams: 1 Silva_FelipevonGlehn_D.pdf: 6687964 bytes, checksum: 5e92607a118fbc6e4c8085aa93b540a0 (MD5) Previous issue date: 2013 / Resumo: A Neuromielite óptica (NMO) é uma doença inflamatória e desmielinizante do SNC, de natureza autoimune, caracterizada por surtos graves de neurite óptica e mielite transversa, de evolução mais freqüente na forma recidivante-remitente, com pouca remissão dos déficits entre as crises, altamente incapacitante. A presença do anticorpo anti-aquaporina 4 (anti-AQP4) foi descrito em 73% a 91% dos pacientes com diagnóstico de NMO. Doenças autoimunes podem frequentemente ser desencadeadas após infecções por micro-organismos, como agentes virais. A NMO e a infecção pelo HTLV-1 possuem prevalência coincidentemente elevada em certas áreas do globo, como o Brasil. Com o objetivo de avaliar a associação do HTLV-1 com a NMO, foi pesquisada a presença de anti-AQP4 e anti-HTLV-1 em 34 pacientes com DENMO, 43 pacientes infectados com HTLV-1, assintomáticos ou com a doença mielopatia associada ao HTLV-1 (HAM/TSP) e 23 controles sadios. Nenhum paciente com DENMO apresentou sorologia positiva para HTLV-1. Nenhum paciente infectado pelo HTLV-1 apresentou soropositividade para anti-AQP4. 60% dos casos de DENMO foram positivos para anti-AQP4. Esses resultados sugerem que a mielopatia associada à variante aguda da HAM/TSP e aquela associada ao anticorpo anti-AQP4 são entidades clínicas distintas, e provalvemente, não relacionadas de forma patogênica ao HTLV-1 em nosso meio. O cérebro humano expressa amplamente AQP4, mas estudos anatomopatológicos e de neuroimagem não detectaram lesões corticais desmielinizantes ou infiltrados inflamatórios no DENMO. A fim de avaliar melhor a presença de alterações estruturais nas substâncias cinzenta e branca encefálicas no DENMO, foram estudados 34 pacientes por RNM de 3T e tomografia de coerência óptica retiniana pareados com controles sadios, divididos nas apresentações NMO, mielite transversa longitudinal extensa (MTLE) e neurite óptica (NO), além de soropositivos versus soronegativo para anti-AQP4 e 5 anos ou menos de doença versus mais de 5 anos de doença. Houve maior grau de atrofia retiniana nos grupos NMO e NO, além dos grupos anti-AQP4+ e mais de 5 anos de doença. Foi constatado maior grau de atrofia cortical cerebral e estruturas da substância branca nos grupos NMO e MTLE, anti-AQP4+ e mais de 5 anos de doença. A atrofia retiniana se correlacionou positivamente com a atrofia do lobo occipital. Esses dados sugerem que o DENMO está associado à atrofia de estruturas das substâncias cinzenta e branca cerebrais; que a atrofia não se limita apenas às áreas das vias sensorial, motora e visual, mas é mais difusa; que quanto maior o tempo de doença e a presença do anticorpo anti-AQP4, maior é o grau de atrofia cortical, configurando estes fatores, tempo e anti-AQP4+, como de pior prognóstico; e a correlação positiva entre atrofia da camada de fibras nervosas retinianas e atrofia pericalcarina, além da escala de incapacidade funcional expandida (EDSS), sugere que a degeneração neuronal retrógrada e/ou anterógrada do tipo Walleriana é um importante causador da atrofia cortical no DENMO / Abstract: Neuromyelitis optica (NMO) is an inflammatory disease of the central nervous system (CNS) of putative autoimmune aetiology, which is characterized by severe attacks of myelitis and optic neuritis (ON). A relapsing course with rapid accumulation of neurological deficits with little or no remission is common. The NMO is autoimmune in nature and antibodies to Aquaporin 4 (AQP4) are associated with the development of the disease. AQP4 is the most common water channel protein of CNS; present in astrocytes processes, endothelium and piamater meninges. It predominates at some sites of the CNS, as optic nerve, brain stem and gray matter of medulla, the same sites of the usual inflammatory lesions. Autoimmune diseases may be triggered by microorganism infections and NMO and HTLV-1 infection have coincidentally high prevalence in certain areas of the world including Brazil. To study a possible relationship between these two diseases, we determined the seroprevalence of antibodies to AQP4 in 43 patients with HTLV-1 infection, asymptomatic or with HTLV-1 associated myelopathy (HAM/TSP) and that of HTLV-1 antibodies in patients with neuromyelitis optica spectrum disorders (NMOSD). AQP4ab positivity was found in 60% of NMOSD patients, but in none of the HAM/TSP patients and none of the asymptomatic HTLV-1 infected individuals. Conversely, all AQP4-Ab-positive NMOSD patients were negative for HTLV-1 antibodies. The results argue both against a role of antibodies to AQP4 in the pathogenesis of HAM/TSP and against an association between HTLV-1 infection and the development of AQP4-Ab. Moreover, the absence of HTLV-1 in all patients with NMOSD suggests that HTLV-1 is not a common trigger of acute attacks in patients with AQP4-Ab positive NMOSD in populations with high HTLV-1 seroprevalence. Although AQP4 is also expressed widely in the human brain cortex, beyond the common sites of lesions in NMO, recent studies have found no MRI or histopathological evidence for cortical demyelination. To investigate magnetic resonance imaging (MRI) patterns of gray matter (GM) and white matter (WM) abnormalities in patients with NMO and its incomplete forms, isolated longitudinally extensive transverse myelitis and optic neuritis, and to assess the prognostic impact of GM and WM abnormalities in these conditions, we performed both 3T high-resolution T1-weighted and diffusion tensor MRI in thirty-four patients with NMO spectrum disorders (NMOSD) and 34 matched healthy controls. Voxel-based morphometry (SPM8/MATLAB2012b), cortical analyses (Freesurfer), and diffusion tensor imaging analyses (TBSS-FSL) were used to investigate brain abnormalities. In addition, retinal nerve fiber layer was measured by means of optic coherence tomography (OCT). These analyses resulted in following findings: (1) NMOSD is associated with GM and WM atrophy, which encompasses more brain structures than the motor, sensory, and visual pathways; (2) this atrophy is more widespread in patients with NMO and LETM than in patients with ON; (3) the extent of GM atrophy correlates with disease duration, and (4) GM/WM atrophy in NMOSD is more pronounced in AQP4 antibody-seropositive than in -seronegative patients. Furthermore, it was demonstrated for the first time in NMOSD a correlation between RNFL atrophy and GM atrophy in the occipital lobes as assessed by OCT, indicating a role for retrograde degeneration in GM atrophy and suggesting that the extent of brain GM/WM atrophy may be of prognostic relevance in NMOSD / Doutorado / Neurologia / Doutor em Ciências Médicas Neuromielite óptica Paraparesia espástica tropical Aquaporina 4 Neurite óptica Neuroimagem Neuromyelitis optica Paraparesis, Tropical spastic Aquaporin 4 Optic neuritis Neuroimaging
47	Clonagem e expressão da aquaporina-4 recombinante em E. coli para aplicação no imunodiagnóstico da neuromielite ótica / Cloning and expression of recombinant aquaporin-4 in E. coli for neuromyelitis optica imunnodiagnosis Medici, Marcela dos Anjos, 1985- 23 August 2018 (has links) Orientador: Marcelo Brocchi / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-23T06:15:21Z (GMT). No. of bitstreams: 1 Medici_MarceladosAnjos_M.pdf: 9527499 bytes, checksum: 3e5801335af84a91e3a95359e36cb43b (MD5) Previous issue date: 2013 / Resumo: A neuromielite ótica (NMO) é uma doença inflamatória do sistema nervoso central. Por muito tempo, a NMO foi considerada uma variante da Esclerose Múltipla (EM). Atualmente, as duas doenças são distinguidas por meio de exames da neuroimagem e achados laboratoriais. Em 2004, mostrou-se a presença de um anticorpo, inicialmente nomeado de anti-NMO, em 85% dos pacientes portadores de NMO. Pacientes com EM clássica não apresentam esse anticorpo em seu soro. Através de técnicas de imunofluorescência indireta, em que o soro do paciente entra em contato com tecido de SNC de camundongos ou de macacos, mostrou-se que o alvo desse anticorpo era a aquaporina-4 (AQP4). Alguns pacientes podem apresentar também autoanticorpos que reconhecem a mielina de oligodendrócito (MOG). A obtenção da AQP4 recombinante seria de grande importância para aplicação em imunodiagnóstico e pesquisa científica. Como a AQP4 é uma proteína transmembrânica, visamos nesse trabalho melhorar o rendimento e a solubilização da proteína recombinante. Buscando maximizar o processo de expressão da AQP4 em E. coli, foram escolhidos vetores de expressão e linhagens apropriadas para expressão de proteínas heterólogas recombinantes. Ainda, foram utilizados alguns artifícios moleculares, como a utilização de proteínas e tags de fusão e o aprimoramento do processo de extração protéica. Desta forma, neste estudo descrevemos a clonagem e expressão da AQP4 humana e a detecção de anticorpos anti-MOG no soro de pacientes com diagnóstico de NMO / Abstract: Neuromyelitis optica (NMO) is an inflammatory disease of the central nervous system (CNS). For a long time, NMO was considered a Multiple Sclerosis (MS) variant. Nowadays, the two diseases are differentiated by neuroimaging exams and laboratorial findings. In 2004 was shown the presence of an antibody, initially named anti-NMO, in 85% of NMO patients. Classic MS patients were tested seronegative for this antibody. Through indirect immunofluorescence techniques, in which patient's serum and CNS tissue from mice and monkeys are in contact with each other, was shown that the antibody's target was aquaporin-4 (AQP4). Some patients can also present autoantibodies against myelin oligodendrocyte protein (MOG). The attainment of recombinant AQP4 would be of great importance for immunodiagnosis and scientific research applications. As the AQP4 is a transmembranic protein, the improvement of the recombinant protein yields and its solubility were envisioned for this study. Seeking to maximize the AQP4 expression process in E. coli, we chose expression vectors and specific safe lineages for heterologous recombinant protein expression. Moreover, molecular artifice was utilized, as fusion proteins and tags and the enhancement of protein extraction process. Therefore, the purpose of this study was to clone and express human AQP4 and the detection of anti-MOG antibodies in NMO patients' serum / Mestrado / Imunologia / Mestra em Genética e Biologia Molecular Neuromielite óptica Aquaporina 4 Proteinas recombinantes Clonagem Genetica - Expressão Neuromielite óptica Aquaporin 4 Recombinant proteins Cloning Gene expression
48	Pathophysiology of edema and macrophage invasion in brain inflammation / Physiopathologie de l’œdème et de l’infiltration cellulaire dans les lésions inflammatoires cérébrales Tourdias, Thomas 16 December 2011 (has links) De très nombreuses pathologies cérébrales s’accompagnent de phénomènes inflammatoires soit primitifs comme dans la sclérose en plaques (SEP), soit secondaires comme après un infarctus cérébral ou un traumatisme crânien. Dans tous les cas on observe la présence d’œdème vasogénique et de cellules inflammatoires.Dans une première approche chez l’animal, nous avons étudié la régulation et le rôle de la protéine canal aquaporine 4 (AQP4) dans l’œdème associé à l’inflammation et dans la sévérité de l’inflammation elle-même. Nous avons, de plus, validé un modèle de lésion inflammatoire focale type SEP pour étudier l’œdème et l’inflammation en fonction du microenvironnement, soit dans la substance blanche (SB), soit dans la substance grise (SG). Dans une seconde approche translationnelle chez les patients SEP, nous avons combiné un marqueur IRM d’altération de la barrière hémato-encéphalique (gadolinium) avec un marqueur plus spécifique de la composante cellulaire (USPIO) pour détecter les lésions « actives » et déterminer leur pronostic.Nous avons d’abord montré qu’AQP4 était surexprimée en situation d’œdème vasogénique associé à l’inflammation. Plus précisément, la surexpression d’AQP4 était plus marquée lors de la phase de résorption que lors de la phase de formation de l‘œdème. De plus, le fait d’inhiber AQP4 aggravait la sévérité de l’œdème et de l’inflammation dans la SB et dans la SG. Nous avons conclu au rôle protecteur d’AQP4 en situation d’inflammation en accord avec les données sur l’implication d’AQP4 dans la résorption de l’œdème et la mise en place de la cicatrice gliale. La surexpression d’AQP4, en tant que mécanisme protecteur, semblait insuffisante pour contrer la phase initiale de l’inflammation car elle ne devenait importante que secondairement. Deuxièmement, lorsque l’on induisait la même attaque inflammatoire dans la SB et dans la SG (modèle focal de SEP), les différences de microenvironnement ne permettaient pas d’induire de différence en termes de sévérité de l’œdème et de l’inflammation. Cette observation suggère de rechercher des différences de physiopathologie entre les lésions de la SB et celles de la SG pour expliquer le caractère faiblement inflammatoire et œdémateux des lésions de la SG chez les patients SEP. Pour finir, nous avons montré que l’observation de la composante cellulaire de l’inflammation in vivo grâce aux USPIO augmentait la sensibilité pour la détection des lésions actives de SEP. Les USPIO montraient également la faible inflammation résiduelle dans les formes chroniques de SEP. L’association des USPIO et du gadolinium augmentait également la spécificité en identifiant un sous-groupe de lésions se rehaussant avec les deux agents et apparaissant plus sévère.Nous avons apporté des connaissances nouvelles sur la physiopathologie de l’œdème et de la composante cellulaire de l’inflammation. Si nos résultats se confirment chez l’homme, l’AQP4 pourrait devenir une nouvelle cible thérapeutique. La meilleure compréhension des différences entre les lésions de la SB et de la SG dans la SEP est également une étape importante pour des thérapeutiques plus ciblées. Un bio-marqueur utilisable in vivo reflétant la composante cellulaire de l’inflammation (USPIO) améliore la sensibilité et la spécificité et pourrait aider à évaluer les nouvelles thérapeutiques. / Inflammation is a contributing factor in many diseases of the brain, including primary inflammatory disorders such as multiple sclerosis (MS) and secondary inflammation following stroke, brain trauma or even tumors. Vasogenic edema and white blood cell infiltration are common features of all inflammatory reaction subtypes. We first performed experimental studies in rodent animal models to better understand the regulation and role of the water channel protein aquaporin 4 (AQP4) in edema associated with inflammation and in the severity of the inflammation itself. We further validated a focal animal model of MS-like lesions to explore whether inflammation and edema differed according to the microenvironment either in gray matter (GM) or white matter (WM). In a second approach in MS patients, we combined a MR marker of blood brain barrier alteration (gadolinium) with a more specific marker of the cellular component of inflammation (USPIO) to detect active lesions and address their prognosis.First, we found that AQP4 was upregulated under conditions associated with vasogenic edema such as inflammation. Specifically, AQP4 upregulation was more important in the edema resolution phase than in the edema build-up phase. Furthermore, silencing AQP4 aggravated the severity of edema and inflammation in both WM and GM. We concluded that AQP4 has a protective role under inflammatory conditions, in agreement with the previously demonstrated role of AQP4 in edema resolution and glial scar formation. AQP4 upregulation, a potential protective mechanism, seems insufficient to counter the initial phase of inflammation because it reached a maximum only after a delay. Second, the severity of the edema and inflammation in WM and GM was not significantly different according to the microenvironment (either WM or GM) upon induction by the same inflammatory attack. This suggests that the pathogenesis in WM and GM is different and should be further explored to explain why little inflammation and edema is encountered in GM lesions of MS patients. Finally, we found that tracking the cellular macrophage component of inflammation with USPIO increased the sensitivity to active lesions in MS patients. It could even detect mild residual inflammation in patients with a progressive MS. Combining USPIO and gadolinium also increased the specificity; the subgroup of lesions that were enhanced with both contrast agents had more severe features. We have provided a better understanding of edema and the cellular component of inflammation. If confirmed in humans, AQP4 could be a new target for medication of edema. A better understanding of the WM/GM difference in MS is also a first step in developing more specific therapeutic strategies. Finally, the in vivo marker of the cellular component of inflammation (USPIO) provides more sensitive and specific information that could be useful in monitoring the efficacy of treatments. Aquaporine 4 Agents de contraste Œdème Inflammation Sclérose en plaque IRM Aquaporin 4 Contrast agents Edema Inflammation Multiple Sclerosis MRI
49	Pathological changes in Alexander disease : a comparative study in human and mice with GFAP mutations / Modifications neuropathologiques dans la maladie d'Alexander : une étude comparative chez l'homme et la souris avec des mutations GFAP Abuawad, Mohammad 29 November 2017 (has links) La maladie d'Alexander est une maladie neurodégénérative due à des mutations hétérozygotes du gène GFAP codant le principal filament intermédiaire des astrocytes matures. Nous avons étudié l'effet des mutations GFAP dans l'hippocampe d'un patient avec AxD infantile et de deux souris knockin, l'une portant une mutation dans le rod domain (p.R85C) et l'autre dans le tail domain (p.T409I). Chez le patient, nous décrivons pour la première fois: (i) des changements morphologiques sévères des cellules GFAP+ dans la zone subgranulaire du gyrus denté, qui ont perdu la plupart de leurs processus radiaux; (ii) une réactivité microgliale; (iii) et un déficit de la neurogénèse hippocampique postnatale. Nous avons trouvé des anomalies similaires dans les deux souris knockin, plus sévères chez les homozygotes. La comparaison de ces modèles a montré que ces anomalies prédominent chez les souris GFAPT409I, tandis que l’accumulation de GFAP est supérieure chez les souris GFAPR85C. La comparaison des deux modèles de souris a montré que les conséquences pathologiques dépendent la localisation de la mutation dans la GFAP. Ces résultats suggèrent qu'en plus du gain évident de fonction, d'autres dysfonctions astrocytaires dans peuvent être dues à une perte de fonction. De plus, nous avons traité les souris mutantes avec de la ceftriaxone, connu pour son effet neuroprotecteur, mais nous n'avons observé aucun effet significatif. Enfin, la mégalencéphalie étant fréquente chez les patients AxD, nous avons mesuré la quantité d'eau cérébrale chez les souris mutantes GFAP. Nous avons trouvé une augmentation significative de la teneur en eau chez les souris GFAPR85C/R85C âgées d'un an. Nous avons observé une localisation anormale de l'AQP4 dans les astrocytes des asouris mutées, pouvant participer au déséquilibre hydrique cérébral. / Alexander disease is a neurodegenerative disorder caused by heterozygous mutations of GFAP gene coding the major intermediate filament of mature astrocytes. We studied the effect of GFAP mutation in the hippocampus of infantile onset AxD patient and two novel knockin mouse models, one bearing a mutation located in the rod domain (p.R85C), and the other bearing a mutation located in the tail domain (p.T409I) of mouse Gfap. In the AxD patient, we describe for the first time: (i) obvious morphological changes of GFAP+ cells in the subgranular zone of the dentate gyrus, which have lost most of their radial processes; (ii) microglial reactivity; (iii) and deficit in postnatal hippocampal neurogenesis. We found similar abnormalities in the two knockin mouse lines, more obvious in homozygous mice. A comparison of these mouse models showed that pathological findings predominated in the GFAPT409I mice, whereas GFAP accumulated in larger amounts in the GFAPR85C mice. The comparison of the two mouse models showed that their pathological consequences depend on the location of the mutated residues in GFAP. These findings suggest that in addition to the evident gain of GFAP function, other astrocyte dysfunctions in this disease may be due to a loss of function of GFAP. In addition, we treated the mice mutants with ceftriaxone, which has been reported to have a neuroprotective effect, but we observe no significant effect. Finally, AxD patients have often megalencephaly, therefore we measured the brain water content in AxD mouse models. We found a significant increase in brain water content in the one year old GFAPR85C/R85C mice vs controls. We observed mislocalization of AQP4 in mutant mice astrocytes that can participated to water imbalance in brain. Maladie d'Alexander Astrocytopathie Réactivité microgliale Neurogenèse de l'hippocampe postnatale Aquaporine-4 Alexander disease Astrocytopathy Microglial reactivity Postnatal hippocampal neurogenesis Aquaporin 4
50	Molecular Mechanisms That Regulate the Membrane Water Channel Aquaporin 5 Kawedia, Jitesh Dalpatraj January 2007 (has links) No description available. Aquaporin 5 tight junction complex hypoxia cAMP proteasome HIF1&945 mercury, salivary glands lung water transport

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