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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
161

Physicochemical characterization of DNA-based bionanocomposites using nonafibrous clay minerals : biological applications / Caractérisation physico-chimique de bionanocomposites à base d'ADN et de minéraux argileux nano-fibreux : applications biologiques

Castro Smirnov, Fidel Antonio 15 October 2014 (has links)
Parmi les différents minéraux argileux, la sépiolite, qui est un silicate fibreux naturel, est un potentiel nano-transporteur prometteur pour le transfert non-viral de biomolécules. Il a en effet été montré que la sépiolite interagissait avec des molécules biologiques telles que les lipides, les polysaccharides et les protéines. Dans ce travail, nous démontrons que la sépiolite interagit également efficacement avec différents types de molécules d'ADN (génomique, plasmidique, oligonucléotides simple et double brin), et nous présentons la première étude détaillée sur les mécanismes d'interaction entre la sépiolite et l'ADN, ainsi qu’une caractérisation physico-chimique de bionanocomposites ADN-sepiolite. Une analyse spectroscopique a montré tout d’abord que l’interaction de l'ADN avec la sépiolite était plus forte en présence de polycations, la valence de ces derniers accroissant le rendement d’absorption, et deuxièmement, que l'ADN ainsi adsorbé pouvait être récupéré avec un rendement modulé par la présence d’EDTA, la structure de l'ADN et son activité biologique étant conservées. Par spectroscopie infrarouge à transformée de Fourier (FTIR) nous avons identifié les groupes silanol externes comme les principaux sites d'interaction avec l'ADN. Nous avons ensuite prouvé qu'il est possible d'utiliser la sépiolite pour extraire l'ADN de bactéries, pour la purification de l'ADN et pour la purification de toute contamination bactérienne. En combinant la microscopie à fluorescence, la microscopie électronique à transmission (MET), la vidéo-microscopie et l’analyse par cytométrie en flux (FACS), nous avons montré que la sépiolite peut être spontanément internalisée dans des cellules de mammifère par le biais de deux voies, l’endocytose et la macropinocytose. En tant que preuve de concept, nous montrons que la sépiolite est capable de transférer de manière stable l'ADN de plasmide dans des bactéries et des cellules de mammifères. Il a également été prouvé qu’en incubant des bactéries avec des bionanocomposites ADN-sepiolite, initialement préparés en présence d'une faible concentration en cations divalents et avec de la sépiolite traitée aux ultrasons (sSep), il était possible d'augmenter l'efficacité de la transformation bactérienne 20 à 30 fois par rapport aux méthodes basées sur l'«effet Yoshida». En outre, nous montrons que l'efficacité du transfert de gènes par la sépiolite peut être optimisée : l'utilisation de sSep et l'exposition à la chloroquine augmentent d’un facteur 100 et 2, respectivement, l’efficacité de transfection. Ces résultats ouvrent la voie à l'utilisation de bionanocomposites à base de sépiolite comme de nouveaux potentiels nano-transporteurs hybrides potentiels, à la fois pour la thérapie génique et le développement de nouveaux modèles biologiques en sciences fondamentales et appliquées. / Among the various clay minerals, sepiolite, which is a natural fibrous silicate, isa potential promising nanocarrier for the non-viral transfer of bio-molecules. Indeed,sepiolite has been shown to interact with biological molecules such as lipids,polysaccharides and proteins. Here, we show that sepiolite efficiently binds differenttypes of DNA molecules (genomic, plasmid, single strand and double strandoligonucleotides), introducing the first detailed study on the interaction mechanismsbetween sepiolite and DNA, as well as the physicochemical characterization of theresulting DNA-sepiolite bionanocomposites. The interaction mechanisms aresuggested to be electrostatic interactions, van der Waals forces, cation bridges, andhydrogen bonding. Spectroscopy analysis showed that the binding of DNA to sepiolitewas increased by polycations with valence dependent efficiency, and the DNApreviously adsorbed could be recovered with an efficiency that could be modulatedusing a chelating agent (EDTA), preserving the DNA structure and biological activity.Fourier-transform infrared spectroscopy identified the external silanol groups as themain sites of interaction with the DNA. It was proved that it is possible to use sepiolitefor extracting DNA from bacteria, for DNA purification and for purification from bacterialcontamination. By combining fluorescence microscopy, transmission electronmicroscopy (TEM), time-lapse video microscopy and flow cytometry analysis (FACS),we show that sepiolite can be spontaneously internalized into mammalian cells throughboth endocytic and non-endocytic pathways. As a proof of concept, we show thatsepiolite is able to stably transfer plasmid DNA into bacteria and mammalian cells. Itwas also proved that with the incubation of bacteria with the Sep/DNAbionanocomposite initially prepared in the presence of a low concentration of divalentcation, and using sonicated sepiolite (sSep), it is possible to increase the bacterialtransformation efficiency from 20 to 30-fold compared to previously reported methodswhich are based in the “Yoshida effect”. Additionally, we show that the efficiency ofsepiolite-mediated gene transfer can be optimized: the use of sSep and the exposureto the endosome disrupter chloroquine 100-fold and 2-fold stimulated DNA transfectionefficiency, respectively. These results open the way to the use of sepiolite-basedbionanocomposites as a novel class of hybrid nanocarriers for both potential genetherapy and the development of novel biological models of interest for academic andapplied sciences.
162

Développement d'un promoteur efficace et muscle spécifique pour la thérapie génique de la dystrophie musculaire de Duchenne

Blain, Marilyne January 2008 (has links)
Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal
163

Caractérisation fonctionnelle des variants génétiques de la région régulatrice (rSNP) des gènes du point de contrôle G1/S

Dionne, Joëlle January 2008 (has links)
Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal
164

Manipulations acoustiques de cellules pour l'ingénierie tissulaire / Acoustic cells manipulation for tissue engineering

Bouyer, Charlène 07 December 2015 (has links)
Manipuler génétiquement ou physiquement des cellules présente un très grand intérêt pour l'ingénierie tissulaire mais soulève encore de nombreux challenges. Les technologies actuelles pour la fabrication de tissus, comme l'assemblage de micro-gels, le remplissage de matrice 3D, le modelage ou l'impression biocompatible sont limités dans leur capacité à organiser spatialement des cellules, souffrent d'un temps de manipulation conséquent, d'effets secondaires potentiellement cytotoxiques et d'une grande complexité de mise en œuvre, empêchant leur utilisation à grande échelle. Nous nous sommes intéressés dans cette thèse à développer des techniques biocompatibles, faciles à implémenter, rapides et facilement transférables dans des laboratoires de biologie. Nous les avons orientées vers deux applications stimulantes car en grand essor et pour lesquelles les techniques actuelles ne permettent pas encore une utilisation grande échelle : la réparation osseuse et l'ingénierie tissulaire neuronale / Genetic or physical cells manipulation aspires to be new challenges in tissue engineering. Current technologies to generate tissues, such as micro-scale hydrogels (microgel) assembly, scaffold seeding, molding or bio-printing suffer from the difficulty to control cells organization, multi-steps time consuming procedures and/or potentially cytotoxic side effects. In this PhD, we aimed at developing cell-friendly and rapid techniques, easily transferable to biological laboratories, for two broadly challenging applications: bone healing and neural tissue engineering, for which the above-mentioned techniques cannot yet provide widely reliable models. In case of a bone critical size defect, external help is often needed for bone healing, and gold-standard for care is bone autograft. Alternatively, the fracture healing process can be stimulated and restored by the implantation at the fracture site of hydrogels embedding growth factors. Both technologies suffer however from side effects such as donor site morbidity or cells over-proliferation in the hydrogel proximity. Moreover, the kinetic of growth factors release cannot be temporally controlled. In this work, we aim at developing an alternative method using ultrasound to spatially and temporally control growth factors release within a biocompatible material: fibrin hydrogels. Towards this goal, we encapsulated, in lipoplexes, plasmids that are under the control of a heat-shock promoter. We then transfected cells, stimulate the production of the targeted protein by heat shock and reported its expression. We also optimized an encapsulation protocol for cells within fibrin gels. This proof of concept demonstrates the feasibility of transfection by lipoplexes with a plasmid under control of heat shock, and pave the way for future developments of in situ transfection of autologous cells, for a tight temporal and spatial control of therapeutic proteins expression using ultrasound-induced hyperthermia
165

Improved Nanoparticle Preparation and Delivery Technology for DOTAP and Oligonucleotide Based Lipoplexes

Terp, Megan Cavanaugh 25 June 2012 (has links)
No description available.
166

Automated image-based recognition and targeted laser transfection techniques for drug development and stem cell research

Yapp, Clarence Han-Wei January 2011 (has links)
Advances in several areas of scientific research is currently hampered by the slow progress in developing a non-viral, high precision technique capable of safely and efficiently injecting targeted single cells with impermeable molecules. To date, one of the most promising techniques employs the laser to temporarily create a pore in the cell membrane to allow the entry of exogenous molecules. This technique has potentially wide applications. In this thesis, I utilised the precision of laser transfection, also known as optoporation, to deliver two histone demethylase inhibitors (8-hydroxyquinoline and FMF1293) of the JmjC-domain protein JMJD3 into vital cells. The enzyme, JMJD3, demethylates histone H3 lysine K27, the methylation state of which has been shown in previous studies to regulate genes in such a way as to play a key role in the formation of tumours and even maintenance of stem cell pluripotency. The research here shows proof of principle that optoporation can be employed to quickly screen and test the efficacy of novel drugs by delivering them into cells at significantly low concentrations while still maintaining inhibition activity. I also used optoporation to deliver relatively large proteins such as bovine serum albumin (BSA), phalloidin and novel synthetic antibodies into living cells without fixatives. This offers the possibility of using reporter systems to monitor living cells over time. Finally, an attempt was made to generate iPS colonies by optoporating plasmid DNA into somatic cells, however, I find that this technique was unable to efficiently transfect and reprogram primary cells. Two automated image-based systems that can be integrated into existing microscopes are presented here. First, an image processing algorithm that can quickly identify stem cell colonies non-invasively was implemented. When tested, the algorithm’s resulting specificity was excellent (95 – 98.5%). Second, because optoporation is a manual and time consuming procedure, an algorithm to automate optoporation by using image processing to locate the position of cells was developed. To my knowledge, this is the first publication of a system which automates optoporation of human fibroblasts in this way.
167

La régulation du gène P450aromatase dans les cellules de granulosa bovine in vitro

Sahmi, Malha January 2004 (has links)
Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
168

Étude moléculaire et cellulaire des mutants de la protéine de Tamm-Horsfall (THP) dans la néphropathie hyperuricémique familiale juvénile (NHFJ)

Gasiorek, Jadwiga January 2005 (has links)
Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.
169

Příprava transgenní kultury testikulárních kmenových buněk Xenopus tropicalis. / Preparation of Xenopus tropicalis transgenic testicular stem cell culture.

Vegrichtová, Markéta January 2014 (has links)
Testicular stem cells (TSCs) are relatively accessible potential source of pluripotent cells, which are particularly important for their application in regenerative medicine. Xenopus tropicalis is a useful model organism to study the migration and differentiation potential of stem cells. This amphibian is characteristic by outer fecundation and embryonic development of a great amount of embryos after fertilization. Oocytes and embryos are large enough (about 1 mm) to be suitable for micromanipulation micromanipulations. Laboratory of Developmental Biology, Faculty of Science, Charles University in Prague succeeded in the establishment of a mixed cell culture of TSCs growing on feeder layer of pre- Sertoli cells. This culture was derived from the testes of juvenile Xenopus tropicalis male. In the study of their differentiation potential it was found, that leukemia inhibitory factor (LIF) is the decisive factor allowing rapid proliferation of stem cells and their forming into characteristic colonies. This protein is produced by both types of cells which are present in the culture. The mouse LIF has the same positive effect on the proliferative potential of stem cells, which points at the evolutionary conservation of metabolic pathways associated with the maintenance of the stemness. RT-PCR analysis...
170

Estudo dos perfis de N-glicosilação da prolactina recombinante humana expressa em células humanas HEK293 / Study of N-glycosylate profiles of human recombinant prolactin expressed in human cells HEK293

Silva, Felipe Douglas 30 July 2018 (has links)
A prolactina humana (hPRL) é um hormônio sintetizado pela hipófise com inúmeras funções tais como: lactação, reprodução e regulação osmótica. Este hormônio é frequentemente dosado em casos de problemas na lactação, infertilidade, além de estudos que elucidam sua ligação em alguns tipos de câncer (mama, próstata e útero). A hPRL é encontrada na forma não glicosilada (NG-hPRL) (23 kDa) e glicosilada (G-hPRL) (25 kDa), sendo a isoforma glicosilada um modelo ideal de análise de perfil de N-glicanos, já que possui um único sítio de glicosilação localizado na Asparagina 31. A glicosilação está relacionada diretamente à solubilidade, à estabilidade, ao enovelamento, à meia-vida e atividade biológica in vivo. As células de ovário de hamster chinês (CHO) e as células embrionárias de rim humano (HEK293) são os hospedeiros mais utilizados para expressão de proteínas recombinantes, já que podem ser cultivadas em altas densidades e por possuírem similaridade nas modificações pós-traducionais. O objetivo foi expressar, purificar e realizar uma caracterização físico-química e biológica da hPRL glicosilada de células HEK293, incluindo análise da estrutura de carboidratos. Para tanto, foi realizada uma transfecção em células HEK293T (aderidas) com o vetor pcDNA 3.4-TOPO. Foi obtida uma expressão de 21,26 ± 8,3 μg/mL de hPRL no meio condicionado sem soro. A hPRL foi purificada por cromatografia de afinidade a metais imobilizados (IMAC), eluindo 92% da hPRL em uma única fração que, analisada por HPSEC, apresentou pureza de 97%. O perfil de N-glicanos da amostra apresentou seis espécies, todas com terminação em ácido-siálico, do tipo complexo, sendo bi, tri e tetra-antenárias, com relativa predominância da espécie N2G2S1 (29,4%). A bioatividade in vitro da G-hPRL HEK293 demonstrou ser ≅ 16 vezes menor que a G-hPRL produzida em células CHO. / Human prolactin (hPRL) is a hormone synthesized by the pituitary gland with innumerable functions such as lactation, reproduction and osmotic regulation. This hormone is often determined in cases of lactation problems, infertility, and studies that elucidate its connection in some types of cancer (breast, prostate and uterus). The hPRL is found in the non-glycosylated (NG-hPRL) (23 kDa) and glycosylated (G-hPRL) (25 kDa) form, being the glycosylated isoform an ideal model for N-glycan profile analysis, since it has a single glycosylation site located in Asparagine 31. Glycosylation is directly related to solubility, stability, folding, half-life and biological activity in vivo. Chinese hamster ovary (CHO) cells and human embryonic kidney (HEK293) cells are the most widely used hosts for expression of recombinant proteins, since they can be grown at high densities and have similarity in post-translational modifications. The objective of this work was to express, purify and perform a physicochemical and biological characterization of the glycosylated hPRL from HEK293 cells, including analysis of the carbohydrate structure. For this purpose, a transfection was performed on HEK293T (adhered) cells with the 3.4-TOPO pcDNA vector. Expression of 21.26 ± 8.3 μg/mL hPRL in the serum free conditioned medium was obtained. The hPRL was purified by immobilized metal affinity chromatography (IMAC), eluting 92% of the hPRL in a single fraction which analyzed by HPSEC, showed 97% purity. The N-glycans profile of the sample showed six species, all with sialic acid termination, complex type, being bi, tri and tetra antennary, with a relative predominance of N2G2S1 (29.4%). In vitro bioactivity of G-hPRL HEK293 demonstrated to be ≅ 16-fold lower than G-hPRL produced in CHO cells.

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