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Bioluminescence Imaging of Transgene Expression in Intact Porcine Ovarian Follicles in VitroJung, Song-yi 14 December 2013 (has links)
The porcine antral follicle, which consists of an oocyte and surrounding follicular components, including theca, granulosa, and cumulus cells and follicular fluid, is an essential microenvironment for oocyte development and maturation. Investigating cellular and molecular events in the context of the whole follicle will aid in our understanding of interactions between the oocyte and the follicular components. The objective of this dissertation was to develop a novel bioluminescent imaging model to visualize and measure cellular and molecular events in living intact ovarian follicles in vitro. Bioluminescence imaging was employed to facilitate noninvasive, dynamic, and real-time transgene analysis in living intact follicles. The time courses of luciferase-luciferin reactions, effective plasmid DNA and D-luciferin doses and their combinations were determined as the first step toward developing a new real-time bioluminescence imaging model. In addition, the efficient nonviral gene delivery methods: cationic lipid mediated gene transfer (chemical) and electroporation (physical) for the living intact follicles were determined. For the cationic lipid mediated gene transfer method, the 1:3 DNA lipid ratio was optimal. It was also found that the optimal condition of electroporation (4 electric pulses with 100 ms duration at field strength of 100 V/cm) resulted in 15 times higher luciferase activity and increased granulosa cell viability over the cationic lipid mediated gene transfer method. Moreover, increased granulosa cell viability, increased follicular fluid progesterone content, and oocytes with expanded cumulus cells were observed in intact follicles transfected by electroporation at a field strength of 100 V/cm. Finally, bioluminescence imaging was applied to quantify functional and ligand-activated estrogen receptor (ER) activity within living intact follicles. The functional ERs were differentially activated during the different stages of the estrous cycle in the mature sow; the levels of functional ER activity in cultured granulosa cells and intact follicles in vitro were increased from late luteal phase to early follicular phase and then significantly decreased at late follicular phase. The methodology developed herein can be applicable to further our understanding of oocyte and follicle development and oocyte maturation.
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Imidazole-Containing Polymerized Ionic Liquids for Emerging Applications: From Gene Delivery to Thermoplastic ElastomersAllen, Michael H. Jr. 07 January 2013 (has links)
Novel imidazole-containing polyelectrolytes based on poly(1-vinylimidazole) (poly(1VIM)) were functionalized with various hydroxyalkyl-substituents to investigate the influence of charge density and hydrogen bonding on nonviral DNA delivery. Copolymers with higher charge densities exhibited increased cytotoxicity, whereas increased hydroxyl concentrations remained nontoxic. DNA binding affinity increased with increased charge densities and increased hydroxyl content. Dynamic light scattering determined the copolymers which delivered DNA most effectively maintained an intermediate binding affinity between copolymer and DNA. Copolymers containing higher charge densities or hydroxyl concentrations bound DNA too tightly, preventing its release inside the cell. Copolymers with lower charge densities failed to protect the DNA from enzymatic degradation. Tuning hydrogen bonding concentration allowed for a less toxic and more effective alternative to conventional, highly charged polymers for the development of nonviral DNA delivery vehicles. The synthesis of amine-containing imidazolium copolymers functionalized with low concentrations of folic acid enabled the investigation of additional polymer modifications on nonviral gene delivery.
Functionalization of 1VIM with various hydroxyalkyl and alkyl groups and subsequent conventional free radical polymerization afforded a series of imidazolium-containing polyelectrolytes. Hydroxyl-containing homopolymers exhibited higher thermal stabilities and lower T<sub>g</sub>'s compared to the respective alkyl-analog. X-ray scattering demonstrated the polarity of the hydroxyl group facilitated solvation of the electrostatic interactions disrupting the nanophase-separated morphology observed in the alkylated systems. Impedance spectroscopy determined hydroxyl-containing imidazolium homopolymers displayed higher ionic conductivities compared to the alkyl-containing analogs which was attributed to increased solvation of electrostatic interactions in the hydroxyl analogs.
Beyond functionalizing 1VIM monomers and homopolymers to tailor various properties, the synthesis of novel architectures in a controlled fashion remains difficult due to the radically unstable N-vinyl propagating radical. The regioisomer 4-vinylimidazole (4VIM) contains two resonance structures affording increased radical stability of the propagating radical. Nitroxide-mediated polymerization (NMP) and atom transfer radical polymerization (ATRP) failed to control 4VIM homopolymerizations; however, reversible addition-fragmentation chain transfer (RAFT) demonstrated unprecedented control. Linear pseudo-first order kinetics were observed and successful chain extension with additional 4VIM suggested preservation of the trithiocarbonate functionality.
Effectively controlling the polymerization of 4VIM enabled the design of amphoteric block copolymers for emerging applications. The design of ABA triblock copolymers with 4VIM as a high T<sub>g</sub> supporting outer block and di(ethylene glycol) methyl ether methacrylate (DEGMEMA) as a low T<sub>g</sub>, inner block, required the development of a new difunctional RAFT chain transfer agent (CTA). The difunctional CTA successfully mediated the synthesis of the ABA triblock copolymer, poly(4VIM-b-DEGMEMA-b-4VIM), which exhibited microphase separated morphologies. The amphoteric nature of the imidazole ring required substantially lower concentrations of outer block incorporation compared to traditional triblock copolymers to achieve similar mechanical properties and microphase separated morphologies. / Ph. D.
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Desenvolvimento de vetores nanotecnológicos lipídicos do sistema CRISPR/Cas9 visando à terapia gênica para Mucopolissacaridose tipo ISchuh, Roselena Silvestri January 2017 (has links)
A mucopolissacaridose tipo I (MPS I) é causada pela deficiência de alfa-L-iduronidase (IDUA), responsável pelo catabolismo de glicosaminoglicanos (GAGs), levando ao acúmulo multissistêmico de sulfato de heparano e dermatano. Este estudo tem por objetivo avaliar o potencial de sistemas lipídicos nanoestruturados como carreadores do plasmídeo do sistema CRISPR/Cas9 e um vetor doador da sequência do gene IDUA/Idua para edição gênica em fibroblastos de pacientes e em modelo murino de MPS I. Foram produzidos lipossomas (DOTAP, DOPE e DSPE-PEG) e nanoemulsões (e TCM) por homogeneização à alta pressão e microfluidização. O DNA foi associado às formulações por adsorção, ou por encapsulamento dos complexos pré-formados DNA/DOTAP no núcleo oleoso da nanoemulsão. A eficiência de transfecção dos complexos foi avaliada em fibroblastos de pacientes MPS I e ocorreu um aumento significativo da atividade de IDUA em 2, 15 e 30 dias após os tratamentos, que promoveu uma redução na quantidade de lisossomos nos fibroblastos tratados. A caracterização físico-química de formulações produzidas por microfluidização complexadas a somente um plasmídeo ou juntamente com um oligonucleotídeo foi verificada e pode-se afirmar que a capacidade de complexação e transfecção depende diretamente do tipo celular e da relação de cargas, e não há implicações quanto ao tamanho das sequências de ácidos nucleicos. Camundongos MPS I receberam os complexos lipossomais por injeção hidrodinâmica e sua biodistribuição foi detectada principalmente no pulmão, coração e fígado. A atividade sérica de IDUA normal aumentou em cerca de 6% e foi mantida por seis meses. A atividade aumentada no pulmão, coração, fígado e rim após eutanásia promoveu redução dos GAGs na urina e nos mesmos tecidos, corroborando com as análises histológicas. Em um estudo em andamento, foi realizada uma investigação mais aprofundada do efeito do tratamento lipossomal na morfologia óssea, sistemas cardiovascular e respiratório, e funções cerebrais dos animais tratados. A análise ecocardiográfica demonstrou uma melhora na hipertrofia e contratilidade do coração, porém não houve melhora na espessura das válvulas. O diâmetro da aorta foi similar ao de animais normais, porém as quebras de elastina ficaram entre o grupo normal e o não tratado. A morfologia facial dos animais tratados foi intermediária, assim como a espessura do osso zigomático. Entretanto, o osso femoral demonstrou espessura comparável ao normal. Já a resistência pulmonar apresentou uma tendência de redução nos animais tratados em relação aos animais MPS I. O conjunto de resultados demonstra o potencial das nanoestruturas lipídicas co-complexadas com o plasmídeo CRISPR/Cas9 e um vetor doador da sequência IDUA/Idua para terapia gênica da MPS I. / Mucopolysaccharidosis type I (MPS I) is caused by the deficiency of alpha-L-iduronidase (IDUA), responsible for the catabolism of glycosaminoglycans (GAGs), leading to multisystemic accumulation of heparan and dermatan sulfate. This study aims to evaluate the potential of lipid-based nanostructures as carriers of the CRISPR/Cas9 plasmid and a vector donor of the IDUA/Idua sequence for gene editing in patients’ fibroblasts and in a murine model of MPS I. Liposomes (DOTAP, DOPE, and DSPE-PEG) and nanoemulsions (also MCT) were produced through high-pressure homogenization or microfluidization. DNA was associated with liposomes and nanoemulsions by adsorption or by encapsulation of DNA/DOTAP preformed complexes in the oil core of nanoemulsions. The transfection efficiency of complexes was evaluated in fibroblasts from MPS I patients and a significant increase in IDUA activity was demonstrated at 2, 15, and 30 days after treatments. It was also possible to observe a significant reduction in lysosomal amount in treated fibroblasts. The physicochemical characterization of liposomes and nanoemulsions produced through microfluidization complexed with a single plasmid or along with an oligonucleotide has been verified and it can be stated that the complexing and transfection capacity of the complexes depends directly on the cell type and the charge ratio, and there are no implications of the size of the nucleic acid sequences. MPS I mice received the liposomal complexes by hydrodynamic injection and their immediate biodistribution was detected mainly in the lung, heart, and liver. An increase of about 6% in normal serum IDUA activity was maintained for six months, in addition to increased lung, heart, liver, and kidney activity after euthanasia. The enhanced enzymatic activity promoted a significant GAGs reduction in urine and in the same tissues, corroborating with histological analysis. In an ongoing study, a deeper investigation was carried out on the effect of liposomal treatment on bone morphology, cardiovascular and respiratory systems, and brain function. The echocardiographic analysis showed an improvement in the parameters of hypertrophy and contractility of the heart, but there was no improvement in heart valves. Aorta diameter was similar to that of normal animals, but elastin breaks were between the normal and untreated groups. Facial morphology of treated animals was intermediate, as well as the analysis of zygomatic bone thickness. However, femoral bone showed thickness comparable to normal animals. Lung resistance, on the other hand, showed a tendency to reduction in treated animals when compared to MPS I. The set of results demonstrates the potential of the co-complexed lipid nanostructures with the CRISPR/Cas9 plasmid and a donor vector of the IDUA/Idua sequence for MPS I gene therapy.
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Desenvolvimento de vetores nanotecnológicos lipídicos do sistema CRISPR/Cas9 visando à terapia gênica para Mucopolissacaridose tipo ISchuh, Roselena Silvestri January 2017 (has links)
A mucopolissacaridose tipo I (MPS I) é causada pela deficiência de alfa-L-iduronidase (IDUA), responsável pelo catabolismo de glicosaminoglicanos (GAGs), levando ao acúmulo multissistêmico de sulfato de heparano e dermatano. Este estudo tem por objetivo avaliar o potencial de sistemas lipídicos nanoestruturados como carreadores do plasmídeo do sistema CRISPR/Cas9 e um vetor doador da sequência do gene IDUA/Idua para edição gênica em fibroblastos de pacientes e em modelo murino de MPS I. Foram produzidos lipossomas (DOTAP, DOPE e DSPE-PEG) e nanoemulsões (e TCM) por homogeneização à alta pressão e microfluidização. O DNA foi associado às formulações por adsorção, ou por encapsulamento dos complexos pré-formados DNA/DOTAP no núcleo oleoso da nanoemulsão. A eficiência de transfecção dos complexos foi avaliada em fibroblastos de pacientes MPS I e ocorreu um aumento significativo da atividade de IDUA em 2, 15 e 30 dias após os tratamentos, que promoveu uma redução na quantidade de lisossomos nos fibroblastos tratados. A caracterização físico-química de formulações produzidas por microfluidização complexadas a somente um plasmídeo ou juntamente com um oligonucleotídeo foi verificada e pode-se afirmar que a capacidade de complexação e transfecção depende diretamente do tipo celular e da relação de cargas, e não há implicações quanto ao tamanho das sequências de ácidos nucleicos. Camundongos MPS I receberam os complexos lipossomais por injeção hidrodinâmica e sua biodistribuição foi detectada principalmente no pulmão, coração e fígado. A atividade sérica de IDUA normal aumentou em cerca de 6% e foi mantida por seis meses. A atividade aumentada no pulmão, coração, fígado e rim após eutanásia promoveu redução dos GAGs na urina e nos mesmos tecidos, corroborando com as análises histológicas. Em um estudo em andamento, foi realizada uma investigação mais aprofundada do efeito do tratamento lipossomal na morfologia óssea, sistemas cardiovascular e respiratório, e funções cerebrais dos animais tratados. A análise ecocardiográfica demonstrou uma melhora na hipertrofia e contratilidade do coração, porém não houve melhora na espessura das válvulas. O diâmetro da aorta foi similar ao de animais normais, porém as quebras de elastina ficaram entre o grupo normal e o não tratado. A morfologia facial dos animais tratados foi intermediária, assim como a espessura do osso zigomático. Entretanto, o osso femoral demonstrou espessura comparável ao normal. Já a resistência pulmonar apresentou uma tendência de redução nos animais tratados em relação aos animais MPS I. O conjunto de resultados demonstra o potencial das nanoestruturas lipídicas co-complexadas com o plasmídeo CRISPR/Cas9 e um vetor doador da sequência IDUA/Idua para terapia gênica da MPS I. / Mucopolysaccharidosis type I (MPS I) is caused by the deficiency of alpha-L-iduronidase (IDUA), responsible for the catabolism of glycosaminoglycans (GAGs), leading to multisystemic accumulation of heparan and dermatan sulfate. This study aims to evaluate the potential of lipid-based nanostructures as carriers of the CRISPR/Cas9 plasmid and a vector donor of the IDUA/Idua sequence for gene editing in patients’ fibroblasts and in a murine model of MPS I. Liposomes (DOTAP, DOPE, and DSPE-PEG) and nanoemulsions (also MCT) were produced through high-pressure homogenization or microfluidization. DNA was associated with liposomes and nanoemulsions by adsorption or by encapsulation of DNA/DOTAP preformed complexes in the oil core of nanoemulsions. The transfection efficiency of complexes was evaluated in fibroblasts from MPS I patients and a significant increase in IDUA activity was demonstrated at 2, 15, and 30 days after treatments. It was also possible to observe a significant reduction in lysosomal amount in treated fibroblasts. The physicochemical characterization of liposomes and nanoemulsions produced through microfluidization complexed with a single plasmid or along with an oligonucleotide has been verified and it can be stated that the complexing and transfection capacity of the complexes depends directly on the cell type and the charge ratio, and there are no implications of the size of the nucleic acid sequences. MPS I mice received the liposomal complexes by hydrodynamic injection and their immediate biodistribution was detected mainly in the lung, heart, and liver. An increase of about 6% in normal serum IDUA activity was maintained for six months, in addition to increased lung, heart, liver, and kidney activity after euthanasia. The enhanced enzymatic activity promoted a significant GAGs reduction in urine and in the same tissues, corroborating with histological analysis. In an ongoing study, a deeper investigation was carried out on the effect of liposomal treatment on bone morphology, cardiovascular and respiratory systems, and brain function. The echocardiographic analysis showed an improvement in the parameters of hypertrophy and contractility of the heart, but there was no improvement in heart valves. Aorta diameter was similar to that of normal animals, but elastin breaks were between the normal and untreated groups. Facial morphology of treated animals was intermediate, as well as the analysis of zygomatic bone thickness. However, femoral bone showed thickness comparable to normal animals. Lung resistance, on the other hand, showed a tendency to reduction in treated animals when compared to MPS I. The set of results demonstrates the potential of the co-complexed lipid nanostructures with the CRISPR/Cas9 plasmid and a donor vector of the IDUA/Idua sequence for MPS I gene therapy.
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Desenvolvimento de vetores nanotecnológicos lipídicos do sistema CRISPR/Cas9 visando à terapia gênica para Mucopolissacaridose tipo ISchuh, Roselena Silvestri January 2017 (has links)
A mucopolissacaridose tipo I (MPS I) é causada pela deficiência de alfa-L-iduronidase (IDUA), responsável pelo catabolismo de glicosaminoglicanos (GAGs), levando ao acúmulo multissistêmico de sulfato de heparano e dermatano. Este estudo tem por objetivo avaliar o potencial de sistemas lipídicos nanoestruturados como carreadores do plasmídeo do sistema CRISPR/Cas9 e um vetor doador da sequência do gene IDUA/Idua para edição gênica em fibroblastos de pacientes e em modelo murino de MPS I. Foram produzidos lipossomas (DOTAP, DOPE e DSPE-PEG) e nanoemulsões (e TCM) por homogeneização à alta pressão e microfluidização. O DNA foi associado às formulações por adsorção, ou por encapsulamento dos complexos pré-formados DNA/DOTAP no núcleo oleoso da nanoemulsão. A eficiência de transfecção dos complexos foi avaliada em fibroblastos de pacientes MPS I e ocorreu um aumento significativo da atividade de IDUA em 2, 15 e 30 dias após os tratamentos, que promoveu uma redução na quantidade de lisossomos nos fibroblastos tratados. A caracterização físico-química de formulações produzidas por microfluidização complexadas a somente um plasmídeo ou juntamente com um oligonucleotídeo foi verificada e pode-se afirmar que a capacidade de complexação e transfecção depende diretamente do tipo celular e da relação de cargas, e não há implicações quanto ao tamanho das sequências de ácidos nucleicos. Camundongos MPS I receberam os complexos lipossomais por injeção hidrodinâmica e sua biodistribuição foi detectada principalmente no pulmão, coração e fígado. A atividade sérica de IDUA normal aumentou em cerca de 6% e foi mantida por seis meses. A atividade aumentada no pulmão, coração, fígado e rim após eutanásia promoveu redução dos GAGs na urina e nos mesmos tecidos, corroborando com as análises histológicas. Em um estudo em andamento, foi realizada uma investigação mais aprofundada do efeito do tratamento lipossomal na morfologia óssea, sistemas cardiovascular e respiratório, e funções cerebrais dos animais tratados. A análise ecocardiográfica demonstrou uma melhora na hipertrofia e contratilidade do coração, porém não houve melhora na espessura das válvulas. O diâmetro da aorta foi similar ao de animais normais, porém as quebras de elastina ficaram entre o grupo normal e o não tratado. A morfologia facial dos animais tratados foi intermediária, assim como a espessura do osso zigomático. Entretanto, o osso femoral demonstrou espessura comparável ao normal. Já a resistência pulmonar apresentou uma tendência de redução nos animais tratados em relação aos animais MPS I. O conjunto de resultados demonstra o potencial das nanoestruturas lipídicas co-complexadas com o plasmídeo CRISPR/Cas9 e um vetor doador da sequência IDUA/Idua para terapia gênica da MPS I. / Mucopolysaccharidosis type I (MPS I) is caused by the deficiency of alpha-L-iduronidase (IDUA), responsible for the catabolism of glycosaminoglycans (GAGs), leading to multisystemic accumulation of heparan and dermatan sulfate. This study aims to evaluate the potential of lipid-based nanostructures as carriers of the CRISPR/Cas9 plasmid and a vector donor of the IDUA/Idua sequence for gene editing in patients’ fibroblasts and in a murine model of MPS I. Liposomes (DOTAP, DOPE, and DSPE-PEG) and nanoemulsions (also MCT) were produced through high-pressure homogenization or microfluidization. DNA was associated with liposomes and nanoemulsions by adsorption or by encapsulation of DNA/DOTAP preformed complexes in the oil core of nanoemulsions. The transfection efficiency of complexes was evaluated in fibroblasts from MPS I patients and a significant increase in IDUA activity was demonstrated at 2, 15, and 30 days after treatments. It was also possible to observe a significant reduction in lysosomal amount in treated fibroblasts. The physicochemical characterization of liposomes and nanoemulsions produced through microfluidization complexed with a single plasmid or along with an oligonucleotide has been verified and it can be stated that the complexing and transfection capacity of the complexes depends directly on the cell type and the charge ratio, and there are no implications of the size of the nucleic acid sequences. MPS I mice received the liposomal complexes by hydrodynamic injection and their immediate biodistribution was detected mainly in the lung, heart, and liver. An increase of about 6% in normal serum IDUA activity was maintained for six months, in addition to increased lung, heart, liver, and kidney activity after euthanasia. The enhanced enzymatic activity promoted a significant GAGs reduction in urine and in the same tissues, corroborating with histological analysis. In an ongoing study, a deeper investigation was carried out on the effect of liposomal treatment on bone morphology, cardiovascular and respiratory systems, and brain function. The echocardiographic analysis showed an improvement in the parameters of hypertrophy and contractility of the heart, but there was no improvement in heart valves. Aorta diameter was similar to that of normal animals, but elastin breaks were between the normal and untreated groups. Facial morphology of treated animals was intermediate, as well as the analysis of zygomatic bone thickness. However, femoral bone showed thickness comparable to normal animals. Lung resistance, on the other hand, showed a tendency to reduction in treated animals when compared to MPS I. The set of results demonstrates the potential of the co-complexed lipid nanostructures with the CRISPR/Cas9 plasmid and a donor vector of the IDUA/Idua sequence for MPS I gene therapy.
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Molecularly Engineered Acid-Responsive Polymers for Nucleic Acid DeliveryShim, Min Suk 21 March 2011 (has links)
No description available.
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Biochemical Characterization of Polycationic Nucleic Acid Delivery VectorsFichter, Katye M. 25 August 2008 (has links)
No description available.
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Desenvolvimento e caracterização de vetores não virais para entrega gênica baseados em proteínas e lipossomas. / Development and characterization of non-viral vectors based in proteins and liposomes to gene delivery.Alves, Rafael Ferraz 24 October 2013 (has links)
Um dos principais limitantes do desenvolvimento de protocolos eficientes de terapia gênica e vacinação com DNA provém da baixa eficiência de transferência gênica por parte dos vetores não-virais. Isso surge, principalmente, pela dificuldade de transporte de DNA estrangeiro do exterior para o núcleo das células alvo, devido à presença de inúmeras barreiras. O principal objetivo do trabalho realizado foi o desenvolvimento e caracterização de novos vetores não virais multifuncionais, capazes de realizar eficientemente a entrega de material genético (DNA plasmidial, pDNA) ao núcleo de células de mamífero (HeLa). Para esse fim, complexos binários (CBs) foram formados combinando-se pDNA à protamina ou proteínas recombinantes (TRP3) anteriormente desenvolvidas por nosso grupo. Foi também estudado o encapsulamento destes CBs em lipossomas catiônicos, formados pelos lipídios EPC:DOPE:DOTAP, gerando então complexos pseudo-ternários (CPTs). Os estudos com a protamina revelaram que os CPTs formados apresentavam tamanhos relativamente pequenos (< 123 nm) e com valores de potencial zeta, variando de +22,8 mV a +36,3 mV, nas várias relações mássicas (pDNA:protamina) estudadas (1:0,5; 1:0,7, 1:0,9 e 1:1). Os ensaios de transfecção mostraram que o CPT na relação 1:0,5 (CB) obteve o melhor nível de transfecção das células (17,1%) com um nível de viabilidade celular de 73,2%. Os ensaios utilizando a TRP3 mostraram que os CPTs formados adquiriram tamanhos pequenos (< 134 nm) e valores de potencial zeta entre +36,8 mV e +11,9 mV dependendo da relação mássica do CB (1:1, 1:30 e 1:60). Os ensaios de transfecção mostram que os CPTs formados com a TRP3 aumentaram o nível de transfecção em todas as relações de pDNA-TRP3 usadas (1:1; 1:30 e 1:60). Vale ressaltar que nas relações mássicas 1:30 e 1:60 houve um aumento significativo na transfecção (25,2% e 24,5%, respectivamente). Os ensaios de citotoxicidade mostram que os CBs não afetaram a viabilidade célular, entretanto quando combinada ao lipossoma foi observado aumento da citotoxicidade. Finalmente, os resultados indicam que a TRP3 associada ao lipossoma (CPTs) aumenta a eficiência de entrega de pDNA sugerindo um efeito sinérgico entre essas duas moléculas na superação das várias barreiras físicas, químicas e difusionais encontradas na célula. / One of the major challenges on the development of efficient protocols for gene therapy and DNA vaccination is the low efficiency of gene transfer by non viral vectors. This is mainly attributed to the fact that, during the traffic to target cells nuclei, plasmid vectors must overcome a series of physical, enzymatic and diffusional barriers. The objective of this work was the development and characterization of new multifunctional non-viral vectors, based on lipids and proteins, able to delivery efficiently the foreign pDNA (plasmid DNA) to the nucleus of mammalian cells. A model pDNA containing the reporter gene GFP was complexed to protamine or the recombinant protein (TRP3), forming binary complexes (BC). In addition, we studied the ability of the cationic liposomes (EPC:DOPE:DOTAP) to encapsulate this binary complexes to form pseudo-ternary complexes (PTCs). The studies of size (DLS) and zeta potential revealed that both proteins were able to condense pDNA to form small complexes (BCS and PTCs) (~100 nm) and positively charged (+11,9 mV a +36,8 mV), both interesting characteristics for transfections. However, the CPTs formed by TRP3 was that showed the highest transfections level (25,3%). The cytotoxicity assays indicated the BCs had a low effect on the cell viability. On the other hand, the biggest effect on cell death was found when PTCs were used. The results indicated the TRP3 associated to liposomes (PTCs) increased the delivery efficiency due to differences in the intracellular trafficking, suggesting a synergic effect between these different molecules in the vector in order to overcome the barriers found inside the cell.
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Layered Double Hydroxide (LDH) Nanoparticle-Based Nucleic Acid Delivery SystemYunyi Wong Unknown Date (has links)
There has been much interest in the use of therapeutics based on ribonucleic acid interference(RNAi) to inhibit synthesis of mutant proteins ever since Elbashir et al. (Elbashir, S. M., Harborth, J., Lendeckel, W., Yalcin, A., Weber, K. and Tuschl, T., 2001. Duplexes of 21-nucleotide RNAs mediate RNA interference in cultured mammalian cells. Nature. 411, 494-498.) found that synthetic double stranded small interfering ribonucleic acids (siRNAs) can initiate this evolutionarily conserved process in mammalian cells. Since RNAi is able to target single genes and therefore mitigate the underlying molecular pathology of diseases, RNAi-based therapeutics will most likely benefit monogenic neurodegenerative diseases such as Huntington’s disease. It is however particularly difficult to deliver exogenous materials such as siRNAs into neurons in vivo as the blood-brain barrier (BBB) isolates the brain from the vascular system and prevents permeation of most materials. Neurons also do not take up exogenous materials readily. Therefore, effective delivery of siRNAs into the brain remains one of the biggest challenges impeding their use as a potential neurotherapeutic. Layered double hydroxide (LDH) nanoparticles are a class of anionic clay materials that have demonstrated great potential as a DNA (deoxyribonucleic acid) delivery system for a variety of mammalian cell lines due to their unique physiochemical properties. This thesis examined the feasibility of LDH as a siRNA delivery system for cultured neurons and demonstrated that the delivered siRNAs are able to effectively down-regulate synthesis of a target protein with minimal toxicity. Experiments were conducted using double stranded DNAs (dsDNAs) initially, and siRNAs were then used to verify these results. It was shown that nucleic acids(dsDNAs and siRNAs) could successfully intercalate into pristine LDHs to form nucleic acid-LDH complexes that had properties suitable for use as a delivery system in mammalian cells. These studies established that LDHs and nucleic acid-LDH complexes were biocompatible with neurons isolated from embryonic day 17.5 mouse cerebral cortex, suggesting that LDH can be used for nucleic acid delivery into cultured neurons. LDHs were also shown to successfully deliver nucleic acids into a non-neural mammalian cell line (NIH 3T3 cells). Finally, this thesis demonstrated for the first time that LDHs were able to deliver siRNAs into neurons, providing encouraging preliminary evidence that sequence specific gene silencing of the Mus Musculus Deleted in Colorectal Cancer (DCC) gene had occurred. However, down-regulation of the DCC protein did not occur consistently, suggesting that further optimisation is needed to improve the efficacy of siRNA-LDH complexes to inhibit expression of target protein in neurons. In future, LDHs should be further developed as an efficient siRNA delivery system for therapeutic gene silencing in the central nervous system using a neurodegenerative disease model such as the Huntington’s disease mouse model, which closely phenocopies the human disease. This model will allow the in vivo efficacy of these nanoparticles to be tested and subsequently improved in order to deliver siRNAs locally and systematically into the brain.
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Layered Double Hydroxide (LDH) Nanoparticle-Based Nucleic Acid Delivery SystemYunyi Wong Unknown Date (has links)
There has been much interest in the use of therapeutics based on ribonucleic acid interference(RNAi) to inhibit synthesis of mutant proteins ever since Elbashir et al. (Elbashir, S. M., Harborth, J., Lendeckel, W., Yalcin, A., Weber, K. and Tuschl, T., 2001. Duplexes of 21-nucleotide RNAs mediate RNA interference in cultured mammalian cells. Nature. 411, 494-498.) found that synthetic double stranded small interfering ribonucleic acids (siRNAs) can initiate this evolutionarily conserved process in mammalian cells. Since RNAi is able to target single genes and therefore mitigate the underlying molecular pathology of diseases, RNAi-based therapeutics will most likely benefit monogenic neurodegenerative diseases such as Huntington’s disease. It is however particularly difficult to deliver exogenous materials such as siRNAs into neurons in vivo as the blood-brain barrier (BBB) isolates the brain from the vascular system and prevents permeation of most materials. Neurons also do not take up exogenous materials readily. Therefore, effective delivery of siRNAs into the brain remains one of the biggest challenges impeding their use as a potential neurotherapeutic. Layered double hydroxide (LDH) nanoparticles are a class of anionic clay materials that have demonstrated great potential as a DNA (deoxyribonucleic acid) delivery system for a variety of mammalian cell lines due to their unique physiochemical properties. This thesis examined the feasibility of LDH as a siRNA delivery system for cultured neurons and demonstrated that the delivered siRNAs are able to effectively down-regulate synthesis of a target protein with minimal toxicity. Experiments were conducted using double stranded DNAs (dsDNAs) initially, and siRNAs were then used to verify these results. It was shown that nucleic acids(dsDNAs and siRNAs) could successfully intercalate into pristine LDHs to form nucleic acid-LDH complexes that had properties suitable for use as a delivery system in mammalian cells. These studies established that LDHs and nucleic acid-LDH complexes were biocompatible with neurons isolated from embryonic day 17.5 mouse cerebral cortex, suggesting that LDH can be used for nucleic acid delivery into cultured neurons. LDHs were also shown to successfully deliver nucleic acids into a non-neural mammalian cell line (NIH 3T3 cells). Finally, this thesis demonstrated for the first time that LDHs were able to deliver siRNAs into neurons, providing encouraging preliminary evidence that sequence specific gene silencing of the Mus Musculus Deleted in Colorectal Cancer (DCC) gene had occurred. However, down-regulation of the DCC protein did not occur consistently, suggesting that further optimisation is needed to improve the efficacy of siRNA-LDH complexes to inhibit expression of target protein in neurons. In future, LDHs should be further developed as an efficient siRNA delivery system for therapeutic gene silencing in the central nervous system using a neurodegenerative disease model such as the Huntington’s disease mouse model, which closely phenocopies the human disease. This model will allow the in vivo efficacy of these nanoparticles to be tested and subsequently improved in order to deliver siRNAs locally and systematically into the brain.
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