Global ETD Search

71	Caracterização de uma nanopartícula lipídica semelhante à LDL (LDE) como vetor para RNA de interferência / Characterization of an lipid nanoparticle resembles LDL (LDE) with vector for interference RNA Ruiz, Jorge Luis Maria 16 March 2011 (has links) As nanopartículas são consideradas promissores vetores para a liberação eficaz e segura de ácidos nucléicos para tipos específicos de célula ou tecido, proporcionando uma alternativa aos vetores virais para terapia gênica. No entanto, com a maioria destes sistemas não torna possível a entrega de oligonucleotídeos nas células in vivo de forma especifica. O uso de uma nanoemulsão funcionalmente semelhante à lipoproteina de baixa densidade poderia resolver esse problema, pois esta particula é capaz de direcionar o transporte das moléculas para a internalização celular através de receptores de LDL. Aqui, descreve-se um sistema lipidico semelhante à lipoproteína de baixa densidade, LDE, capaz de direcionar e liberar RNA de interferência (RNAi) para as células tumorais in vitro e in vivo em um modelo celular que expressa resistência a múltiplas drogas (células de sarcoma uterino; MESSA/ Dx5). Estudou-se também as caracteristicas de captação do complexo LDE-RNAi e a regulação especifica do gene mdr-1. Os resultados sugerem que a LDE é estavel e liga-se com alta afinidade aos RNAis permitindo que eles entrem nas células tumorais, com localização citoplasmática. Em conclusão, a LDE, por direcionar o RNAi a receptores de LDL favorece o silenciamento do gene mdr-1 por RNAi nas células MES-SA/Dx5 aumentando sua sensibilidade a quimioterápicos / Nanoparticles are considered promising vectors for efficient and safe delivery of nucleic acids to specific types of cell or tissue, providing an alternative to viral vectors for gene therapy. However, most of these systems cannot target and deliver oligonucleotides to specific cells in vivo. The use of nanoemulsion functionally resemble low density emulsion could solve this problem, once particle is capable of direct the molecules transport to the cell through internalization in LDL receptors. Here, we describe a lipid system similar to low density lipoprotein, LDE, capable of targeting and release small interfering RNA (siRNA) to tumor cells in vitro and in vivo in a cell model that expresses multidrug resistance (sarcoma uterine cell line; MES-SA/Dx5). Were also studied the characteristics of uptake of the complex LDE-siRNA, as well as the downregulation of mdr-1 gene. The results suggest that LDE is stable and bind with high affinity to siRNAs allowing them to enter tumor cells, with cytoplasmic localization enhanced. In conclusion, LDE, binds to siRNA through LDL receptors, and promotes mdr-1 silenciament by RNAi in MES-sa/Dx5 cells, increasing their sensitivity to chemotherapeutics agents Gene therapy Genetic vectors Interference RNA Interferência de RNA Lipídeos Lipids Multiple drug resistance Neoplasias Neoplasm Resistência a múltiplos medicamentos Terapia de genes Vetores genéticos
72	Reversão do fenótipo de resistência a múltiplas drogas em células de sarcoma uterino humano. Utilização de emulsão lipídica como veículo de oligonucleotídeos antissenso / Reversion of the multiple drug resistance phenotype in a human sarcoma cell line. Lipid emulsion as antisense oligonucleotide vector Levy, Débora 16 August 2007 (has links) O objetivo deste trabalho foi estudar a utilização de uma nanoemulsão lipídica (LDE) como vetor de oligonucleotídeos antissenso (OAS). A LDE é uma nanoemulsão constituída por 48% de éster de colesterol, 47,8% de fosfolipídeos, 2,3% de triglicérides e 1,9% de colesterol não-esterificado. É capaz de adquirir apoE de HDL e, desta forma, a emulsão pode interagir com o receptor B/E. O comportamento metabólico da LDE se assemelha ao da LDL. OAS agem como inibidores da função de genes, ligando-se à fita oposta (complementar) do RNA mensageiro (mRNA) ou à dupla fita do DNA. Previnem que o mRNA codifique uma proteína funcional. Os mecanismos celulares de resistência a drogas representam diversas formas de proteção da célula e do organismo e estão presentes na maioria das células normais, exercendo funções fisiológicas. Infelizmente, muitos tumores utilizam esses mecanismos para sua própria proteção. A proteína codificada pelo gene MDR1 (ABCB1), a P-gp, é uma glicoproteína de membrana com peso molecular de 170Kda, que funciona como uma bomba orgânica catiônica. Neste trabalho foi observado que o OAS se ligam à LDE, sendo a constante de ligação de 4,2 X 10-3M-1. O complexo OAS/LDE foi capaz de se ligar especificamente ao receptor de LDL e através desta via ser internalizado, pelas células de sarcoma uterino resistentes a doxorrubicina. Os OAS apresentaram após 24 horas distribuição citoplasmática e nuclear e após 48 horas, somente distribuição citoplasmática. Utilizando-se dois diferentes OAS, verificou-se que ambos foram capaz de inibir (70%) a expressão do gene de resistência a múltiplas drogas após 48 horas de incubação, tornando as células mais susceptíveis à ação da doxorrubicina. Assim, o complexo OAS/LDE é um sistema potencialmente promissor para ser utilizado em terapia gênica. / The objective of this study was to evaluate the usefulness of a nanolipid emulsion (LDE) as a vector to carry antisense oligonucleotides (OAS). LDE is a nanoemulsion consisting of 48% cholesterol esters, 47,8% phospholipid, 2,3% triglycerides and 1,9% unesterified cholesterol. It is able to obtain apoE from HDL and interact with B/E receptor. The metabolic behavior of LDE is similar to LDL. OAS are able to inhibit specific gene expression since they bind to a complementary sequence in the mRNA or in the DNA. This binding impairs the synthesis of a functional protein. The cell resistance mechanisms are present in most of normal cells, been involved in physiological process. Tumors are able to use these mechanisms to their own protection. The protein P-gp (MDR1 gene) is a glycoprotein with 170Kda that works as an organic cationic pump. We have observed that LDE was able to bind to the OAS; the binding constant was 4,2 X 10-3M-1. The complex was shown to bind to LDL receptors and then been internalized into a human sarcoma cell line resistant to doxirrubicine. After 24 hours the complex have shown citoplasmatic and nuclear distribution, after 48 hours only citoplasmatic distribution was observed. Two OAS were used. Both OAS strongly inhibited (by 70%) the cell MDR-1 gene expression after 48 hours of incubation and cells turned out to be more susceptible to doxorrubicine action. Therefore, OAS/LDE is promising complex to be used in gene therapy studies. Antisenso oligonucleotides Emulsion Emulsões Gene silecing Genes MDR Genes MDR Genetic vectors Inativação gênica Multiple drug resistance Oligonucleotídeos anti-senso Resistência a múltiplas drogas Vetores genéticos
73	Gene Therapy for Very Long Chain Acyl-coA Dehydrogenase Deficiency Using Adeno-Associated Virus Vectors: A Dissertation Keeler, Allison M. 10 April 2012 (has links) Very long chain acyl-coA dehydrogenase (VLCAD) is the rate-limiting step in mitochondrial fatty acid oxidation. VLCAD deficient mice and patients’ clinical symptoms stem from not only an energy deficiency but also long-chain metabolite accumulations. VLCAD deficient mice were treated systemically with 1x10 12 vector genomes of rAAV9-VLCAD. Expression was detected in the liver, heart and muscle. Also substantial expression of VLCAD was noted in the brain, where it was expressed across different sections of the brain and in different cell types with different morphologies. Biochemical correction was observed in vector-treated mice beginning two weeks post-injection, as characterized by a significant drop in long chain fatty acyl accumulates in whole blood after an overnight fast. Changes persisted through the termination point around 20 weeks post injection. Magnetic resonance spectroscopy (MRS) and tandem mass spectrometry (MS/MS) revealed normalization of intramuscular lipids in treated animals. Correction was not observed in liver tissue extracts, but cardiac muscle extracts showed significant reduction of long chain metabolites. Disease-specific phenotypes were characterized, including thermoregulation and maintenance of euglycemia after a fasting cold challenge. Internal body temperatures of untreated VLCAD-/- mice dropped below 20°C and the mice became lethargic, requiring euthanasia. In contrast all rAAV9-treated VLCAD-/- mice and the wild-type controls maintained body temperatures. rAAV9-treated VLCAD-/- mice maintained euglycemia, whereas untreated VLCAD-/- mice suffered hypoglycemia following a fasting cold challenge. These promising results suggest rAAV9 gene therapy as a potential treatment for VLCAD deficiency in humans. Acyl-CoA Dehydrogenase Long-Chain Dependovirus Gene Therapy Genetic Vectors Amino Acids, Peptides, and Proteins Enzymes and Coenzymes Genetic Phenomena Genetics and Genomics Lipids Nutritional and Metabolic Diseases Therapeutics Viruses
74	Caracterização de uma nanopartícula lipídica semelhante à LDL (LDE) como vetor para RNA de interferência / Characterization of an lipid nanoparticle resembles LDL (LDE) with vector for interference RNA Jorge Luis Maria Ruiz 16 March 2011 (has links) As nanopartículas são consideradas promissores vetores para a liberação eficaz e segura de ácidos nucléicos para tipos específicos de célula ou tecido, proporcionando uma alternativa aos vetores virais para terapia gênica. No entanto, com a maioria destes sistemas não torna possível a entrega de oligonucleotídeos nas células in vivo de forma especifica. O uso de uma nanoemulsão funcionalmente semelhante à lipoproteina de baixa densidade poderia resolver esse problema, pois esta particula é capaz de direcionar o transporte das moléculas para a internalização celular através de receptores de LDL. Aqui, descreve-se um sistema lipidico semelhante à lipoproteína de baixa densidade, LDE, capaz de direcionar e liberar RNA de interferência (RNAi) para as células tumorais in vitro e in vivo em um modelo celular que expressa resistência a múltiplas drogas (células de sarcoma uterino; MESSA/ Dx5). Estudou-se também as caracteristicas de captação do complexo LDE-RNAi e a regulação especifica do gene mdr-1. Os resultados sugerem que a LDE é estavel e liga-se com alta afinidade aos RNAis permitindo que eles entrem nas células tumorais, com localização citoplasmática. Em conclusão, a LDE, por direcionar o RNAi a receptores de LDL favorece o silenciamento do gene mdr-1 por RNAi nas células MES-SA/Dx5 aumentando sua sensibilidade a quimioterápicos / Nanoparticles are considered promising vectors for efficient and safe delivery of nucleic acids to specific types of cell or tissue, providing an alternative to viral vectors for gene therapy. However, most of these systems cannot target and deliver oligonucleotides to specific cells in vivo. The use of nanoemulsion functionally resemble low density emulsion could solve this problem, once particle is capable of direct the molecules transport to the cell through internalization in LDL receptors. Here, we describe a lipid system similar to low density lipoprotein, LDE, capable of targeting and release small interfering RNA (siRNA) to tumor cells in vitro and in vivo in a cell model that expresses multidrug resistance (sarcoma uterine cell line; MES-SA/Dx5). Were also studied the characteristics of uptake of the complex LDE-siRNA, as well as the downregulation of mdr-1 gene. The results suggest that LDE is stable and bind with high affinity to siRNAs allowing them to enter tumor cells, with cytoplasmic localization enhanced. In conclusion, LDE, binds to siRNA through LDL receptors, and promotes mdr-1 silenciament by RNAi in MES-sa/Dx5 cells, increasing their sensitivity to chemotherapeutics agents Interferência de RNA Lipídeos Neoplasias Resistência a múltiplos medicamentos Terapia de genes Vetores genéticos Gene therapy Genetic vectors Interference RNA Lipids Multiple drug resistance Neoplasm
75	Reversão do fenótipo de resistência a múltiplas drogas em células de sarcoma uterino humano. Utilização de emulsão lipídica como veículo de oligonucleotídeos antissenso / Reversion of the multiple drug resistance phenotype in a human sarcoma cell line. Lipid emulsion as antisense oligonucleotide vector Débora Levy 16 August 2007 (has links) O objetivo deste trabalho foi estudar a utilização de uma nanoemulsão lipídica (LDE) como vetor de oligonucleotídeos antissenso (OAS). A LDE é uma nanoemulsão constituída por 48% de éster de colesterol, 47,8% de fosfolipídeos, 2,3% de triglicérides e 1,9% de colesterol não-esterificado. É capaz de adquirir apoE de HDL e, desta forma, a emulsão pode interagir com o receptor B/E. O comportamento metabólico da LDE se assemelha ao da LDL. OAS agem como inibidores da função de genes, ligando-se à fita oposta (complementar) do RNA mensageiro (mRNA) ou à dupla fita do DNA. Previnem que o mRNA codifique uma proteína funcional. Os mecanismos celulares de resistência a drogas representam diversas formas de proteção da célula e do organismo e estão presentes na maioria das células normais, exercendo funções fisiológicas. Infelizmente, muitos tumores utilizam esses mecanismos para sua própria proteção. A proteína codificada pelo gene MDR1 (ABCB1), a P-gp, é uma glicoproteína de membrana com peso molecular de 170Kda, que funciona como uma bomba orgânica catiônica. Neste trabalho foi observado que o OAS se ligam à LDE, sendo a constante de ligação de 4,2 X 10-3M-1. O complexo OAS/LDE foi capaz de se ligar especificamente ao receptor de LDL e através desta via ser internalizado, pelas células de sarcoma uterino resistentes a doxorrubicina. Os OAS apresentaram após 24 horas distribuição citoplasmática e nuclear e após 48 horas, somente distribuição citoplasmática. Utilizando-se dois diferentes OAS, verificou-se que ambos foram capaz de inibir (70%) a expressão do gene de resistência a múltiplas drogas após 48 horas de incubação, tornando as células mais susceptíveis à ação da doxorrubicina. Assim, o complexo OAS/LDE é um sistema potencialmente promissor para ser utilizado em terapia gênica. / The objective of this study was to evaluate the usefulness of a nanolipid emulsion (LDE) as a vector to carry antisense oligonucleotides (OAS). LDE is a nanoemulsion consisting of 48% cholesterol esters, 47,8% phospholipid, 2,3% triglycerides and 1,9% unesterified cholesterol. It is able to obtain apoE from HDL and interact with B/E receptor. The metabolic behavior of LDE is similar to LDL. OAS are able to inhibit specific gene expression since they bind to a complementary sequence in the mRNA or in the DNA. This binding impairs the synthesis of a functional protein. The cell resistance mechanisms are present in most of normal cells, been involved in physiological process. Tumors are able to use these mechanisms to their own protection. The protein P-gp (MDR1 gene) is a glycoprotein with 170Kda that works as an organic cationic pump. We have observed that LDE was able to bind to the OAS; the binding constant was 4,2 X 10-3M-1. The complex was shown to bind to LDL receptors and then been internalized into a human sarcoma cell line resistant to doxirrubicine. After 24 hours the complex have shown citoplasmatic and nuclear distribution, after 48 hours only citoplasmatic distribution was observed. Two OAS were used. Both OAS strongly inhibited (by 70%) the cell MDR-1 gene expression after 48 hours of incubation and cells turned out to be more susceptible to doxorrubicine action. Therefore, OAS/LDE is promising complex to be used in gene therapy studies. Emulsões Genes MDR Inativação gênica Oligonucleotídeos anti-senso Resistência a múltiplas drogas Vetores genéticos Antisenso oligonucleotides Emulsion Gene silecing Genes MDR Genetic vectors Multiple drug resistance
76	Developing an Adeno-Associated Viral Vector (AAV) Toolbox for CNS Gene Therapy: A Dissertation Choudhury, Sourav Roy 07 January 2016 (has links) Neurological disorders – disorders of the brain, spine and associated nerves – are a leading contributor to global disease burden with a sizable economic cost. Adeno-associated viral (AAV) vectors have emerged as an effective platform for CNS gene therapy and have shown early promise in clinical trials. These trials involve direct infusion into brain parenchyma, an approach that may be suboptimal for treatment of neurodegenerative disorders, which often involve more than a single structure in the CNS. However, overall neuronal transduction efficiency of vectors derived from naturally occurring AAV capsids after systemic administration is relatively low. We have developed novel capsids AAV-AS and AAV-B1 that lead to widespread gene delivery throughout the brain and spinal cord, particularly to neuronal populations. Both transduce the adult mouse brain >10-fold more efficiently than the clinical gold standard AAV9 upon intravascular infusion, with gene transfer to multiple neuronal sub-populations. These vectors are also capable of neuronal transduction in a normal cat. We have demonstrated the efficacy of AAV-AS in the context of Huntington's disease by knocking down huntingtin mRNA 33-50% after a single intravenous injection, which is better than what can be achieved by AAV9 at the particular dose. AAVB1 additionally transduces muscle, beta cells, pulmonary alveoli and retinal vasculature at high efficiency, and has reduced sensitivity to neutralizing antibodies in human sera. Generation of this vector toolbox represents a major step towards gaining genetic access to the entire CNS, and provides a platform to develop new gene therapies for neurodegenerative disorders. Genetic Therapy Genetic Vectors Huntington Disease Central Nervous System Diseases Dependovirus Dissertations, UMMS Genetics Molecular Genetics Nervous System Diseases Neurology Therapeutics
77	Altering the Tropism of Retroviral Vectors For In Vivo Gene Therapy: Pseudotyped Virus Targeting by Ligand-Receptor Interactions: A Dissertation Gollan, Timothy J. 02 June 2002 (has links) A potential approach to in vivo gene therapy is to target retrovirus to specific receptors through a ligand-receptor interaction. Previous studies have placed a ligand at or close to the N-terminus of the ecotropic Moloney murine leukemia virus envelope and require co-expression of a wild type envelope on the pseudotyped virus for successful transduction of human cells. In this study, over forty chimeric envelopes were generated, which have single or multiple insertions of a 13 or 21 amino acid RGD containing sequence, flanked by cysteine residues, that target the cellular integrin receptors (Chapter III). Virus displaying only the chimeric envelopes was generated from packaging cell lines that express the gag and pol genes. Many of the mutant envelopes demonstrated the formation of syncytia when they were transfected into the XC indicator cell line, which is frequently used to determine envelope binding and fusion capabilities. Pseudotyped virus for several of the chimeric envelopes, transduced both NIH 3T3 mouse fibroblasts and human A375 melanoma cells. Ligands placed in the N-terminal region, within the VRA variable domain, and close to the N-terminus of the proline-rich region (PRR), demonstrated transduction into human melanoma cells. Ligands placed within the PRR and the C-terminus of the envelope did not demonstrate transduction into melanoma cells, although host cell transduction was demonstrated. Pseudotyped virus expressing an RGE containing target sequence, replacing the RGD sequence, had significantly lower transduction efficiency of melanoma cells. These data indicate that the MLV envelope tropism can be altered by insertion of short ligands at various locations throughout the envelope. These initial results were promising and helped to define regions within the envelope that could accommodate the insertion of small targeting ligands, that could redirect the tropism of pseudo typed virus to human cells. In the second part of this study, the focus shifted to targeting receptors that were expressed on specific cells, such as carcinoma cells. We inserted short ligands, flanked with cysteines, into the envelope to generate numerous targeting constructs that bind to receptors over-expressed on a variety of carcinoma cells. These pseudotyped retroviral vectors were generated by packaging cell lines that express only the viral Gag and Pol genes, with no wild-type envelope present. Select chimeric envelopes that express the 21 amino acid bombesin (BN)/gastrin releasing protein (GRP) binding sequence successfully transduced human melanoma cells, breast cancer cells, and cells that express the cloned GRP receptor gene. Nine additional chimeric envelopes were generated, that express a modified 56 amino acid heregulin sequence (HRG), that targets c-rbB-3 (Her-3) and c-erbB-4 (Her-4) receptors on breast carcinoma cells. Pseudotyped virus expressing only the BN/GRP mutant envelopes, transduced NIH 3T3 host cells, and two human carcinoma cell lines; A375 melanoma and MDA-MB-231 breast cells. The HRG chimeric envelopes demonstrated transduction of NIH 3T3 cells and human MDA-MB-453 breast carcinoma cells. Finally, a pseudotyped virus that expressed the chimeric BN/GRP envelopes and packaged the thymidine kinase gene, transduced melenoma and breast carcinoma cells and demonstrated ganciclovir cytotoxicity. Collectively, these data indicate that ligands of various sizes can be used to target pseudotyped virus to a variety of human cancer cells and transfer genes of interest. These findings may expand the feasibility and potential scope of gene therapy. Gene Therapy Retroviridae Ligands Receptors, Cell Surface Viral Envelope Proteins Transduction, Genetic Genetic Vectors Academic Dissertations Dissertations, UMMS Life Sciences Medicine and Health Sciences
78	Approaches and Considerations Towards a Safe and Effective Adeno-Associated Virus Mediated Therapeutic Intervention for GM1-Gangliosidosis: A Dissertation Weismann, Cara M. 05 August 2014 (has links) GM1 gangliosidosis is a lysosomal storage disorder caused by a deficiency in the catabolizing enzyme β-galactosidase (βgal). This leads to accumulation of GM1-ganglioside (GM1) in the lysosome inducing ER stress and cell death. GM1 gangliosidosis is primarily a disorder of the central nervous system (CNS) with peripheral organ involvement. In this work we report two major findings, 1) systemic treatment of GM1 gangliosidosis with an adenoassociated virus (AAV9) encoding mouse-βgal (mβgal) in a GM1 gangliosidosis mouse model (βGal-/-), and 2) an investigation into an intracranial injection of a therapeutic AAVrh8 encoding mβgal. Systemic treatment of GM1 gangliosidosis with AAV9 resulted in a moderate expression of enzyme in the CNS, reduction of GM1 storage, significant retention of motor function and a significant increase in lifespan. Interestingly, the therapeutic effect was more robust in females. Intracranial injections of AAVrh8 vector expressing high levels of βgal resulted in enzyme spread throughout the brain, significant retention of motor function and a significant increase in lifespan. Histological alterations were also found at the injection site in both βGal-/- and normal animals. We constructed a series of vectors with a range of decreasing enzyme expression levels to investigate the cause for the unanticipated result. Microarrays were performed on the injection site and we showed that a lower expressing AAVrh8-mβgal vector mitigated the negative response. Intracranial injection of this newly developed vector was shown to clear lysosomal storage throughout the CNS of βGal-/- mice. Taken together, these studies indicate that a combined systemic and fine-tuned intracranial approach may be the most effective in clearing lysosomal storage completely in the CNS while providing therapeutic benefit to the periphery. Dependovirus G(M1) Ganglioside GM1 Gangliosidosis Genetic Vectors Lysosomal Storage Diseases beta-Galactosidase Dissertations, UMMS Gangliosidosis, GM1 Genetics and Genomics Nervous System Diseases Neuroscience and Neurobiology Therapeutics
79	Gene Therapy for Amyotrophic Lateral Sclerosis: An AAV Delivered Artifical MicroRNA Against Human SOD1 Increases Survival and Delays Disease Progression of the SOD1<sup>G93A</sup> Mouse Model: A Dissertation Stoica, Lorelei I. 07 December 2015 (has links) Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease characterized by loss of motor neurons, resulting in progressive muscle weakness, atrophy, paralysis and death within five years of diagnosis. About ten percent of cases are inherited, of which twenty percent are due to mutations in the superoxide dismutase 1 (SOD1) gene. Since the only FDA approved ALS drug prolongs survival by just a few months, new therapies for this disease are needed. Experiments in transgenic ALS mouse models have shown that decreasing levels of mutant SOD1 protein alters and in some cases entirely prevents disease progression. We explored this potential therapeutic approach by using a single stranded AAV9 vector encoding an artificial microRNA against human SOD1 injected bilaterally into the cerebral lateral ventricles of neonatal SOD1G93A mice. This therapy extended median survival from 135 to 206 days (a 50% increase) and delayed hind limb paralysis. Animals remained ambulatory until endpoint, as defined by a sharp drop in body weight. Treated animals had a reduction of mutant human SOD1 mRNA levels in upper and lower motor neurons. As compared to untreated SOD1G93A mice, the AAV9 treated mice also had significant improvements in multiple parameters including the number of motor neurons, diameter of ventral root axons, and degree of neuroinflammation in the spinal cord. These studies clearly show that an AAV9-delivered artificial microRNA is a translatable therapeutic approach for ALS. gene therapy ALS Amyotrophic Lateral Sclerosis AAV9 vector SOD1 gene Dissertations, UMMS Superoxide Dismutase MicroRNAs Dependovirus Genetic Therapy Genetic Vectors Genetics and Genomics Molecular and Cellular Neuroscience Nervous System Diseases Therapeutics
80	A Walk on the Fine Line Between Reward and Risk: AAV-IFNβ Gene Therapy for Glioblastoma: A Dissertation Guhasarkar, Dwijit 22 July 2016 (has links) Glioblastoma multiforme (GBM) is the most common and aggressive primary brain tumor. The current standard-of-care treatment including surgery, radiation and temozolomide (TMZ) chemotherapy does not prolong the survival satisfactorily. Here we have tested the feasibility, efficacy and safety of a potential gene therapy approach using AAV as gene delivery vehicle for treatment of GBM. Interferon-beta (IFNβ) is a cytokine molecule also having pleiotropic anticancerous properties. Previously it has been shown by our group that AAV mediated local (intracranial) gene delivery of human IFNβ (hIFNβ) could be an effective treatment for non-invasive human glioblastoma (U87) in orthotopic xenograft mouse model.But as one of the major challenges to treat GBM effectively in clinics is its highly invasive property, in the current study we first sought to test the efficacy of our therapeutic model in a highly invasive human GBM (GBM8) xenograft mouse model. One major limitation of using the xenograft mouse model is that these mice are immune-compromised. Moreover, as IFNβ does not interact with cross-species receptors, the influence of immune systems on GBM remains largely untested. Therefore to test the therapeutic approach in an immune-competent mouse model, we next treated a syngeneic mouse GBM model (GL261) in an immune-competent mouse (C57B6) with the gene encoding the species-matched IFNβ (mIFNβ). We also tested if combination of this IFNβ gene therapy with the current standard chemotherapeutic drug (TMZ) is more effective than any one of the therapeutic modes alone. Finally, we tested the long term safety of the AAV-mIFNβ local gene therapy in healthy C57B6 mice. Next, we hypothesized that global genetic engineering of brain cells expressing secretory therapeutic protein like hIFNβ could be more beneficial for treatment of invasive, migratory and distal multifocal GBM. We tested this hypothesis using systemic delivery of AAV9 vectors encoding hIFNβ gene for treatment of GBM8 tumor in nude mice. Using in vivo bioluminescence imaging of tumor associated firefly luciferase activity, long term survival assay and histological analysis of the brains we have shown that local treatment of AAV-hIFNβ for highly invasive human GBM8 is therapeutically beneficial at an early growth phase of tumor. However, systemic delivery route treatment is far superior for treating multifocal distal GBM8 tumors. Nonetheless, for both delivery routes, treatment efficacy is significantly reduced when treated at a later growth phase of the tumor. In syngeneic GL261 tumor model study, we show that local AAV-mIFNβ gene therapy alone or in combination with TMZ treatment can provide significant survival benefit over control or only TMZ treatment, respectively. However, the animals eventually succumb to the tumor. Safety study in the healthy animals shows significant body weight loss in some treatment groups, whereas one group shows long term survival without any weight loss or any noticeable changes in the external appearances. However, histological analysis indicates marked demyelinating neurotoxic effects upon long term exposures to mIFNβ over-expressions in brain. Overall, we conclude from this study that AAV-IFNβ gene therapy has great therapeutic potential for GBM treatment in future, but the therapeutic window is small and long term continuous expression could have severe deleterious effects on health. Glioblastoma multiforme (GBM) gene therapy AAV adeno-associated virus gene delivery Interferon-beta Dissertations, UMMS Glioblastoma Genetic Therapy Gene Transfer Techniques Genetic Vectors Dependovirus Genetic Processes Genetics and Genomics Neoplasms Therapeutics

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