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Cellular Uptake of DNA Nanoparticles and Regulation of Cell Surface NucleolinChen, Xuguang 30 July 2009 (has links)
No description available.
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Cellular Immunity in Recombinant Adeno-Associated Virus Vector Mediated Gene TherapyXu, Dan 19 October 2011 (has links)
No description available.
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MECHANISTIC UNDERSTANDING OF THE REGULATION OF LUNG RESIDENT MEMORY T CELLS INDUCED BY TB VACCINATION STRATEGIESHaddadi, Siamak January 2018 (has links)
In the recent years, it has been well established that primary respiratory viral infection-induced lung resident memory CD8 T cells (TRM) characterized by the expression of integrins CD49a and CD103, as well as the early-activation marker CD69, constitute the first line of defense against reinfection. On the other hand, viral vector-based respiratory mucosal (RM) vaccination, as well as parenteral vaccination followed by airway luminal manipulation induce lasting and protective lung T cell immunity towards pulmonary tuberculosis (TB). However, it remains poorly understood whether and how these TB vaccination strategies induce TRM in the lung. As such, within this thesis we will investigate generation of lung CD8 TRM upon different TB vaccination strategies and the underlying mechanisms regulating establishment of such cells. Here using distinct models of replication-deficient adenoviral vector-based TB vaccination, we find that RM vaccination leads to generation of lung CD8 TRM identified by the expression of CD69, CD103, and very late activation Ag 1 (VLA-1). These TRM-associated molecules are acquired by CD8 T cells in distinct tissues. In this regard, VLA-1 is acquired during T cell priming in draining mediastinal lymph nodes (dMLNs) and the others acquired after T cells entered the lung. Once in the lung, Ag-specific CD8 TRM continue to express VLA-1 at high levels through the effector/expansion, contraction, and memory phases of T cell responses. We also reveal that VLA-1 is not required for homing of these cells to the lung, but it negatively regulates them in the contraction phase. Furthermore, VLA-1 has a negligible role in the maintenance of such cells in the lung. Separately, we have observed that while parenteral intramuscular vaccination alone does not induce lung CD8 TRM, subsequent RM inoculation of an Ag-dependent, but not a non-specific inflammatory agonist induces lung CD8 TRM. Such generation of lung CD8 TRM needs CD4 T cell help. These findings not only fill the current knowledge gap, but also hold important implications in developing effective vaccination strategies towards mucosal intracellular infectious diseases such as acquired immunodeficiency syndrome (AIDS), TB and herpes virus infection. / Thesis / Doctor of Philosophy (PhD)
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Développement de procédés efficaces pour la construction et la production de vecteurs adénovirauxGagnon, David 04 1900 (has links)
L’adénovirus possède plusieurs caractéristiques faisant de ce virus un candidat de choix pour la construction de vecteurs utiles dans les études de génomique fonctionnelle. Dans la majorité de ces applications, on a recours à un vecteur adénoviral de première génération délété de sa région E1. L’utilisation de vecteurs adénoviraux comprend deux maillons faibles : la construction du vecteur et la production subséquente de ce dernier. Le développement de méthodes alternatives est donc nécessaire pour renforcer ces deux maillons, permettant ainsi une utilisation étendue de ces vecteurs. Ce développement va s’articuler sur deux axes : l’ingénierie du vecteur de transfert pour la construction de l’adénovirus recombinant et l’ingénierie d’une lignée cellulaire pour la production du vecteur.
En utilisant un vecteur de transfert adénoviral co-exprimant, à partir d’un promoteur régulable à la tétracycline, la protéase de l’adénovirus et une protéine de fluorescence verte (GFP) par l’intermédiaire d’un site d’entrée ribosomal interne (IRES), notre groupe a établi que la sélection positive, via l’expression ectopique de la protéase, est un processus efficace pour la création de librairie d’adénovirus recombinants. Par contre, la diversité atteinte dans ce premier système est relativement faible, environ 1 adénovirus recombinant par 1 000 cellules. Le travail effectué dans le cadre de cette thèse vise à construire un nouveau transfert de vecteur dans lequel l’expression de la protéase sera indépendante de celle du transgène permettant ainsi d’optimiser l’expression de la protéase. Ce travail d’optimisation a permis de réduire le phénomène de transcomplémentation du virus parental ce qui a fait grimper la diversité à 1 virus recombinant par 75 cellules. Ce système a été mis à l’épreuve en générerant une librairie adénovirale antisens dirigée contre la GFP. La diversité de cette librairie a été suffisante pour sélectionner un antisens réduisant de 75% l’expression de la GFP.
L’amplification de ce vecteur adénoviral de première génération doit se faire dans une lignée cellulaire exprimant la région E1 telle que les cellules 293. Par contre, un adénovirus de première génération se répliquant dans les cellules 293 peut échanger, par recombinaison homologue, son transgène avec la région E1 de la cellule créant ainsi un adénovirus recombinant réplicatif (RCA), compromettant ainsi la pureté des stocks. Notre groupe a déjà breveté une lignée cellulaire A549 (BMAdE1) exprimant la région E1, mais qui ne peut pas recombiner avec le transgène du virus. Par contre, le niveau de réplication de l’adénovirus dans les BMAdE1 est sous-optimal, à peine 15-30% du niveau obtenu dans les cellules 293. Le travail fait dans le cadre de cette thèse a permis de mettre en évidence qu’une expression insuffisante d’E1B-55K était responsable de la mauvaise réplication du virus dans les BMAdE1. Nous avons produit de nouveaux clones à partir de la lignée parentale via une transduction avec un vecteur lentiviral exprimant E1B-55K. Nous avons confirmé que certains clones exprimaient une plus grande quantité d’E1B-55K et que ces clones amplifiaient de manière plus efficace un vecteur adénoviral de première génération. Ce clone a par la suite été adapté à la culture en suspension sans sérum. / The adenovirus has numerous interesting characteristics making this particular virus an ideal candidate for the construction of vector for conducting studies in functional genomics. The vast majority of those applications rely on a so-called “first-generation vector” in which the E1 region is replaced by a transgene. Despite all their advantages, there are 2 weak links associated with first-generation vector: the efficient construction of the actual vector and its production. Therefore, the development of alternative methods for construction and production is necessary to ensure their usefulness. The development will involve 2 axes: the reengineering of the transfer vector for the construction of recombinant adenovirus and the reengineering of the cell line capable of producing the vector.
Using a transfer vector co-expressing the adenoviral protease (PS) gene and GFP by using an IRES under the control of a tetracycline-regulated promoter, our laboratory previously established the proof of concept that positive selection of recombinant adenovirus through ectopic expression of the PS gene was an efficient approach to generate adenoviral libraries. However, the diversity achieved was quite low, around 1 recombinant adenovirus per 1,000 cells. The goal of this thesis was to design a new transfer vector in which the PS expression was independent from the expression of the transgene in order to be able to optimize its expression independently. We also improved library diversity by lowering the amount of PS in order to reduce the the trans-complementation from the transfer vector. Using this method, at least 1 recombinant adenovirus per 75 cells was generated with 100% of the plaques being recombinant. This system was successfully used to generate an antisense library targeting GFP. The diversity of the library was high enough to allow the selection of an antisense that inhibited 75% of GFP expression.
Amplification of those first-generation recombinant adenoviruses must take place in an E1-expressing cell such as 293 cells. However, when replicating in 293 cells, the recombinant adenovirus can exchange their transgene with the E1 region of the cell by homologous recombination, which results in the generation of a fully replicative adenovirus (RCA), a situation that compromises the purity of the viral preparation. Our laboratory has previously patented an A549 cell line expressing the E1 region and producing RCA-free recombinant adenovirus (BMAdE1). However, the replication of E1-deleted adenovirus in BMAdE1 cells was sub-optimal, in the range of 15-30% the level obtained in 293 cells. The work done in this thesis establishes that the low level of E1B-55K could be responsible for the lower productivity of BMAdE1 cells. Thus, we have derived new clones following lentiviral transduction in order to increase E1B-55K expression. Western blot confirmed that some clones expressed more E1B-55K than BMAdE1, and this correlated with a more robust replication of a recombinant adenovirus in those clones. This newly optimized BMAdE1 cell line was adapted to serum-free suspension culture.
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Développement de procédés efficaces pour la construction et la production de vecteurs adénovirauxGagnon, David 04 1900 (has links)
L’adénovirus possède plusieurs caractéristiques faisant de ce virus un candidat de choix pour la construction de vecteurs utiles dans les études de génomique fonctionnelle. Dans la majorité de ces applications, on a recours à un vecteur adénoviral de première génération délété de sa région E1. L’utilisation de vecteurs adénoviraux comprend deux maillons faibles : la construction du vecteur et la production subséquente de ce dernier. Le développement de méthodes alternatives est donc nécessaire pour renforcer ces deux maillons, permettant ainsi une utilisation étendue de ces vecteurs. Ce développement va s’articuler sur deux axes : l’ingénierie du vecteur de transfert pour la construction de l’adénovirus recombinant et l’ingénierie d’une lignée cellulaire pour la production du vecteur.
En utilisant un vecteur de transfert adénoviral co-exprimant, à partir d’un promoteur régulable à la tétracycline, la protéase de l’adénovirus et une protéine de fluorescence verte (GFP) par l’intermédiaire d’un site d’entrée ribosomal interne (IRES), notre groupe a établi que la sélection positive, via l’expression ectopique de la protéase, est un processus efficace pour la création de librairie d’adénovirus recombinants. Par contre, la diversité atteinte dans ce premier système est relativement faible, environ 1 adénovirus recombinant par 1 000 cellules. Le travail effectué dans le cadre de cette thèse vise à construire un nouveau transfert de vecteur dans lequel l’expression de la protéase sera indépendante de celle du transgène permettant ainsi d’optimiser l’expression de la protéase. Ce travail d’optimisation a permis de réduire le phénomène de transcomplémentation du virus parental ce qui a fait grimper la diversité à 1 virus recombinant par 75 cellules. Ce système a été mis à l’épreuve en générerant une librairie adénovirale antisens dirigée contre la GFP. La diversité de cette librairie a été suffisante pour sélectionner un antisens réduisant de 75% l’expression de la GFP.
L’amplification de ce vecteur adénoviral de première génération doit se faire dans une lignée cellulaire exprimant la région E1 telle que les cellules 293. Par contre, un adénovirus de première génération se répliquant dans les cellules 293 peut échanger, par recombinaison homologue, son transgène avec la région E1 de la cellule créant ainsi un adénovirus recombinant réplicatif (RCA), compromettant ainsi la pureté des stocks. Notre groupe a déjà breveté une lignée cellulaire A549 (BMAdE1) exprimant la région E1, mais qui ne peut pas recombiner avec le transgène du virus. Par contre, le niveau de réplication de l’adénovirus dans les BMAdE1 est sous-optimal, à peine 15-30% du niveau obtenu dans les cellules 293. Le travail fait dans le cadre de cette thèse a permis de mettre en évidence qu’une expression insuffisante d’E1B-55K était responsable de la mauvaise réplication du virus dans les BMAdE1. Nous avons produit de nouveaux clones à partir de la lignée parentale via une transduction avec un vecteur lentiviral exprimant E1B-55K. Nous avons confirmé que certains clones exprimaient une plus grande quantité d’E1B-55K et que ces clones amplifiaient de manière plus efficace un vecteur adénoviral de première génération. Ce clone a par la suite été adapté à la culture en suspension sans sérum. / The adenovirus has numerous interesting characteristics making this particular virus an ideal candidate for the construction of vector for conducting studies in functional genomics. The vast majority of those applications rely on a so-called “first-generation vector” in which the E1 region is replaced by a transgene. Despite all their advantages, there are 2 weak links associated with first-generation vector: the efficient construction of the actual vector and its production. Therefore, the development of alternative methods for construction and production is necessary to ensure their usefulness. The development will involve 2 axes: the reengineering of the transfer vector for the construction of recombinant adenovirus and the reengineering of the cell line capable of producing the vector.
Using a transfer vector co-expressing the adenoviral protease (PS) gene and GFP by using an IRES under the control of a tetracycline-regulated promoter, our laboratory previously established the proof of concept that positive selection of recombinant adenovirus through ectopic expression of the PS gene was an efficient approach to generate adenoviral libraries. However, the diversity achieved was quite low, around 1 recombinant adenovirus per 1,000 cells. The goal of this thesis was to design a new transfer vector in which the PS expression was independent from the expression of the transgene in order to be able to optimize its expression independently. We also improved library diversity by lowering the amount of PS in order to reduce the the trans-complementation from the transfer vector. Using this method, at least 1 recombinant adenovirus per 75 cells was generated with 100% of the plaques being recombinant. This system was successfully used to generate an antisense library targeting GFP. The diversity of the library was high enough to allow the selection of an antisense that inhibited 75% of GFP expression.
Amplification of those first-generation recombinant adenoviruses must take place in an E1-expressing cell such as 293 cells. However, when replicating in 293 cells, the recombinant adenovirus can exchange their transgene with the E1 region of the cell by homologous recombination, which results in the generation of a fully replicative adenovirus (RCA), a situation that compromises the purity of the viral preparation. Our laboratory has previously patented an A549 cell line expressing the E1 region and producing RCA-free recombinant adenovirus (BMAdE1). However, the replication of E1-deleted adenovirus in BMAdE1 cells was sub-optimal, in the range of 15-30% the level obtained in 293 cells. The work done in this thesis establishes that the low level of E1B-55K could be responsible for the lower productivity of BMAdE1 cells. Thus, we have derived new clones following lentiviral transduction in order to increase E1B-55K expression. Western blot confirmed that some clones expressed more E1B-55K than BMAdE1, and this correlated with a more robust replication of a recombinant adenovirus in those clones. This newly optimized BMAdE1 cell line was adapted to serum-free suspension culture.
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Immune responses to vaccines against malariaBliss, Carly May January 2017 (has links)
The development of a malaria vaccine is necessary for disease eradication. Successful vaccine candidates to date have targeted the asymptomatic, pre-erythrocytic stage of the disease, however even the most efficacious vaccines are only partially protective. Research undertaken in our laboratory has demonstrated that one such regimen, using an 8 week prime-boost viral vector approach of ChAd63 ME-TRAP and MVA ME-TRAP, induces sterile efficacy in 21% of vaccinees, with a key role identified for TRAP-specific CD8<sup>+</sup> T cells. The work described in this thesis explores the most immunogenic regimen by which to administer these two pre-erythrocytic malaria vaccines. A shortening of the prime-boost interval from 8 to 4 weeks, and the addition of an extra ChAd63 ME-TRAP priming vaccination, both demonstrated improved T cell immunogenicity over the standard 8 week regimen. Further to this, novel assays were developed to aid the evaluation of vaccine-induced immune responses. Adaptations of the existing methodology for ELISpot analysis and to whole blood flow cytometry techniques, enabled more detailed analyses of paediatric vaccine-induced T cell responses in The Gambia. This work also permitted the comparison of vaccine immunogenicity in this paediatric population, with malaria-naïve and malaria-exposed adult vaccinees. The results suggest that vaccine-induced T cell responses in infants of 8 weeks and older are comparable to that of adults. A second approach involved the development of a novel functional assay. This assay quantitatively measured the in vitro inhibition of intrahepatic Plasmodium parasite development using T cells from ChAd63.MVA ME-TRAP vaccinated volunteers. The assay demonstrated the ability of CD8<sup>+</sup> T cells to inhibit parasite development in a TRAP-specific manner, and provides a platform with which to further explore pre-erythrocytic immune responses.
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Estudo físico-químico de nanopartículas de DNA com derivado de quitosana contendo grupos fosforilcolina /Picola, Isadora Pfeifer Dalla. January 2009 (has links)
Orientador: Marcio José Tiera / Banca: Marcelo Henrique Gehlen / Banca: Rose Mary Zumstein Georgetto Naal / Resumo: Na presente dissertação, foram preparadas quitosanas com diferentes massas molares, 16 kDa, 18 kDa e 29 kDa, e com diferentes graus de substituição de fosforilcolina (PC). As quitosanas de baixa massa molecular foram obtidas pela degradação de quitosana desacetilada. Essas quitosanas foram purificadas com membranas de diálise de tamanho de exclusão apropriadas e caracterizadas por meio de titulação potenciométrica, H-RMN e Cromatografia de permeação em gel (GPC). O estudo físico-químico da interação das quitosanas com DNA foi realizado utilizando-se as técnicas de fluorescência, eletroforese, microscopia óptica, microscopia eletrônica de transmissão e espalhamento de luz dinâmico. As propriedades avaliadas foram a eficiência de interação, a estabilidade dos complexos, potencial zeta e tamanho de poliplexos. Os experimentos foram conduzidos variando-se a força iônica, pH do meio, massa molar de policátion e razão de cargas para quitosanas com diferentes conteúdos de grupos PC. Além das quitosanas preparadas durante o projeto, também se utilizou quitosanas de diferentes massas molares, de 5 e 150 kDa, para estudo dos poliplexos em diferentes forças iônicas. Os resultados mostraram que a eficiência de interação entre quitosana e DNA é reduzida com a presença do grupo PC. Nos estudos de DLS, verificou-se que, em baixos valores de pH, o método de coacervação permite a obtenção de nanopartículas de 150 a 300 nm. A força de interação, o tamanho e a estabilidade das nanopartículas dependem do pH do meio, da força iônica da solução, da massa molar e do conteúdo de fosforilcolina. Em pHs mais elevados, os poliplexos são mais estáveis quanto maior a massa molar ou quando há a presença de grupo fosforilcolina. O trabalho permitiu ampliar os estudos sobre os efeitos da força iônica, do pH, da massa molar e conteúdos de PC e como, tais parâmetros... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: In this work chitosans with different molecular weights and their derivatives containing different amounts of phosphorylcholine (PC) were prepared. The low molecular weights chitosans were obtained by degradation of deacetylated chitosan. These chitosans were purified by dialysis membranes of appropriate sizes of exclusion and characterized by potentiometric titration, H-NMR and gel permeation chromatography (GPC) techniques. The physico-chemical study of the interaction between chitosan and DNA was performed using the ethidium bromide fluorescence assay, gel electrophoresis, optical microscopy, transmission electron microscopy and dynamic light scattering techniques. The experiments were carried out at varying experimental conditions as ionic strength, pH, and charge ratio with chitosans of different molecular weights and phosphorylcholine contents. The results showed that the efficiency of the interaction between chitosan and DNA was reduced with the incorporation of PC on the chitosan chain. The results showed that at low pH values the sizes of the nanoparticles obtained by the coacervation method varied from 150 to 300 nm. The strength of the interaction and the size of the nanoparticles were shown to be dependent of pH, ionic strength, chitosan molecular weight and of the phosphorylcholine contents. The study at high pH values showed that more stable nanoparticles were formed with chitosans having the higher molecular weights. The attaching of phosphorylcholine groups to the chitosan main chain allows obtaining more stable particles at high pH values. In this work we provide new insights on the effects of molecular weight, pH, ionic strength and PC contents on both the chitosan-DNA interaction and the stability of formed nanoparticles / Mestre
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Evaluation of neurochemical and functional effects of glial cell-derived neurotrophic factor gene delivery using a tetracycline-regulatable adeno-associated viral vectorYang, Xin 24 June 2011 (has links)
Gene transfer to the brain is a promising therapeutic strategy for a variety of neurodegenerative disorders including Parkinson‟s disease (PD). PD is the second most common neurodegenerative disease. Although many drugs have been developed and introduced into the market to provide symptomatic treatment, there is still no cure for PD. Glial cell line-derived neurotrophic factor (GDNF) is a potent survival factor for injured nigrostriatal dopamine neurons and is currently being evaluated as a potential treatment for PD. Gene therapy allows localized, long-term and stable transgene expression after a single intervention to obtain a therapeutic effect. Regulatable promoters for transgene expression furthermore allow optimizing GDNF concentration to avoid undesirable biological activity and clinical side effects. In the first part of the study, an autoregulatory tetracycline-inducible recombinant adeno-associated viral vector (rAAV-pTetbidiON) utilizing the rtTAM2 reverse tetracycline transactivator (rAAV-rtTAM2) was used to conditionally express the human GDNF cDNA. Eight weeks after a single intrastriatal injection of the rAAV-rtTAM2-GDNF vector encapsidated into AAV serotype 1 capsids (rAAV2/1), the GDNF protein level was respectively 15 fold higherand undistinguishable from the endogenous level in doxycycline(Dox) treated and untreated animals. However, a residual GDNF expression in the uninduced animals was evidenced by a sensitive immunohistochemical staining. As compared to rAAV2/1-rtTAM2-GDNF, the rAAV2/1-rtTAM2-WPRE-GDNF vector harboring a woodchuck hepatitis post-transcriptional regulatory element, which increases and stabilizes the transgene transcript, expressed a similar concentration of GDNF in the induced state but a basal level ~2.5-fold higher than the endogenous striatal level. However, the distribution of GDNF in the striatum in induced state was more widespread using the rAAV2/1-rtTAM2-WPRE-GDNF vector as compared to rAAV2/1-rtTAM2- GDNF. As a proof for biological activity, for both vectors, downregulation of tyrosine hydroxylase (TH) was evidenced in dopaminergic terminals of Dox-treated but not untreated animals. In the second part of my study, functional (behavioural) and neurochemical changes mediated by delayed intrastriatal GDNF gene delivery in the partial Parkinson‟s disease rat model were investigated. The rAAV2/1-rtTAM2-WPRE-GDNF vector (3.5 108 viral genomes) was administered unilaterally in the rat striatum 5 weeks after intrastriatal injection of 6-hydroxydopamine (6-OHDA) which produces a partial and progressive lesion of the nigro-striatal dopaminergic pathway. Rats were treated with Dox or untreated from the day of vector injection until sacrifice at 4 or 14 weeks (continuous treatment). A sub-group was Dox-treated for 7 weeks (temporary treatment) then untreated until 14 weeks. In the absence of Dox, the GDNF tissue concentration was found to be equivalent to the endogenous level in 6-OHDA-lesioned rats. In the presence of Dox, it was ~10-fold higher. Dox-dependent behavioral improvements were demonstrated 4 weeks post-vector injection. At later time points, spontaneous partial recovery was observed in all rats, but no further improvement was found in Dox-treated animals. Moreover GDNF gene delivery only transiently improved dopaminergic function. Over the long term, TH was more abundant, but not functional, and the increase was lost when GDNF gene expression was switched off. The third part of my study consisted in the evaluation of the respective dose-range of therapeutical and undesirable effects of GDNF. Functional effects appeared after delivery of 3.5 108 viral particles which produced 200-300 pg/mg protein of GDNF in the lesioned rat striatum (see above). In order to evaluate the viral dose producing undesirable effects, we compared two different doses of vector: 3.5x108 and 4.4x109 viral genome. In the low dose group, the GDNF concentration in the striatum was ~300 pg/mg protein in the Dox-treated animals and equivalent to the endogenous level in untreated animals (~20 pg/mg protein). In contrast, in the high dose group, GDNF levels reached ~1200 pg/mg protein in induced animals but up to ~300 pg/mg protein in uniduced animals. In the low dose group, Dox-dependent downregulation of TH but no asymetrical behaviour was evidenced. In the high dose group, TH downregulation was observed in both Dox+ and Dox-rats. In addition, amphetamine-induced rotational behaviour was evidenced in Dox+ but not in Dox-rats. These data suggest that low doses of virus are sufficient to induce therapeutically-relevant but not undesirable functional effects of GDNF. Nevertheless,a neurochemical effect of GDNF (TH down-regulation) did appear at low dose. In order to understand the GDNF-induced motor asymmetry, we investigated the anatomical pattern of TH down regulation in striatum. Strikingly, there was a greater loss of TH labeling in striosomes than in the surrounding matrix. Receptors which are known to be differentially expressed in the striosomes i.e. µ-opioid receptor(MOR-1) and N-methyl-D-aspartic acid (NMDA) receptor 1 (NR1) as compared to the matrix were analyzed in the high-dose group of animals. MOR-1 was not affected by GDNF gene delivery. In contrast, NR1 was down regulated. The potential relationship between TH and NR1 down-regulation as well as other previously described neurochemical effects of GDNF (as enhancement of DA release and metabolism, of DA neurons excitability or of TH phosphorylation) and behavioural asymmetry remains to be clarified. As summary, our data suggest that behavioural and neurochemical effects of striatal delivery of GDNF can be controlled by Dox by using the autoregulatory rAAV2/1-TetON- GDNF vector, provided the dose range of gene delivery is carefully adjusted. / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished
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Generation of complex recombinant fowlpox virus 9 (FP9) encoding simian immunodeficiency virus (SIVmac239) sequences as a model HIV vaccine candidateAlsafi, Radi Taha M. January 2016 (has links)
The development of a safe and effective HIV vaccine remains challenging due to its high antigenic variability. Poxviruses are large, stable, and have a track record of use as human vaccine candidates. Recombinant fowlpox virus 9 (rFP9), a highly attenuated host range-restricted poxvirus strain, has been safely administered to humans with no ill effects, and is known to be immunogenic. This thesis describes the construction of complex rFP9 encoding various sequences of SIVmac239. The SIVmac239/macaque model is widely used for HIV vaccine development. The ultimate aim of this work was to combine the advantages of FP9 with those of live attenuated SIV to produce a safe yet hopefully effective model HIV vaccine candidate. Transfer plasmids for five different insertion sites within the FP9 genome were designed and constructed. Homologous recombination (HR) of adjacent FP9 sequences was employed to facilitate the integration of SIVmac239 sequences into the FP9 genome. Positive rFP9 were identified by blue colouration in presence of X-gal using a transient colour selection (TCS) technique, and the final markerless pure recombinants were confirmed by PCR. Expression of the target SIV proteins in the presence of T7 polymerase has been demonstrated by immunocytochemical (ICC) staining and Western blotting (WB) assays. Expression was also quantified by enzyme-linked immunosorbent assay (ELISA) in various cell lines at multiple time points. Five different unique rFP9 have been constructed through this project. All SIVmac239 open reading frames (ORFs) save nef have been integrated into the FP9 genome, and protein expression demonstrated where possible. Moreover, a single rFP9 vector expressing the defective SIVmac239 genome driven by T7 RNA polymerase has been successfully constructed and validated using a green fluorescent protein marker.rFP9 showed appropriate transgene expression in both avian and mammalian cells, although at different levels. The expression efficiency of rFP9 was finally compared to another attenuated poxvirus vector, modified vaccinia Ankara (MVA). Comparing the protein expression levels between rFP9 and rMVA was quite difficult because different poxvirus promoters (early/late in rFP9; intermediate in rMVA) were used to direct the transcription of the T7 RNA gene. Given this limitation, although generally higher levels of expression were seen with rFP9, this cannot be attributed to the FP9 with any certainty.
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Interakce virové RNA s kapsidovým proteinem v prostředí in vivo a biotechnologické využití vzniklých částic / Coat protein-RNA interaction in vivo and the biotechnological use of VLPsKratochvílová, Kateřina January 2018 (has links)
The Tobacco mosaic virus (TMV) is a simple and frequently used model virus which has been studied already more over than 130 years. Due to the intensive study of this virus the details of its infectious cycle, genomic information and also the structure of the created viral particle as well as the mechanism of its creation are known today. The process of encapsidation (viral particle formation) is sufficiently described in the in vitro conditions. In the in vitro conditions the origin of assembly (OAS) was also described. The OAS was identified in the coding sequence of the gene for the movement protein (MP). The importance of replication centers (replication factories) has also been supposed. The aim of the diploma thesis was to study the specificity of the interaction of RNA and coat protein in the process of the particle assembly taking place directly inside the plants. The experiments were performed to verify the necessity of presence of OAS sequence in process of initiation of viral encapsidation. The effect of the cell compartmentation on this process has also been studied. Based on several viral systems (the Tobacco mosaic virus, the Potato virus X, the Bean yellow dwarf virus and Cowpea mosaic virus) gene constructs were created. These constructs enables to study this idea at the molecular...
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