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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

Influencia do fator de transcrição MEF2C na hipertrofia miocardica induzida por sobrecarga pressorica em camundongos / Influence of the transcription factor MEF2 in cardiac hypertrophy induced by overload pressure in mice

Pereira, Ana Helena Macedo, 1980- 08 May 2008 (has links)
Orientador: Kleber Gomes Franchini / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciencias Medicas / Made available in DSpace on 2018-08-11T20:15:36Z (GMT). No. of bitstreams: 1 Pereira_AnaHelenaMacedo_M.pdf: 6567293 bytes, checksum: b9a8c070b3b65fe7a4fb095ccfc59d42 (MD5) Previous issue date: 2008 / Resumo: Doenças do coração são freqüentemente associadas à hipertrofia miocárdica. Estímulos mecânicos induzem o crescimento hipertrófico e contribuem para a degeneração e morte dos miócitos cardíacos. Dentre os fatores de transcrição envolvidos no processo de hipertrofia miocárdica, estão os da família MEF2 (Myocyte Enhancer Factor-2), que é composto por 4 membros, MEF2A, B, C e D. O MEF2C é descrito como o principal transcrito no miocárdio. Tanto a deleção quanto a hiperexpressão de seu gene causam efeitos deletérios na formação e na função do músculo cardíaco. Estudos anteriores do nosso laboratório demonstraram que o MEF2 é ativado por estiramento de cardiomiócitos e influencia a expressão de genes do programa hipertrófico. O presente estudo tem como objetivo avaliar os efeitos do silenciamento gênico do MEF2C nas alterações estruturais e funcionais do ventrículo esquerdo de camundongos submetidos à sobrecarga pressórica. Para isso, utilizamos a técnica de interferência por RNA para o MEF2C. A padronização constituiu de: 1) avaliação do silenciamento do MEF2C em cultura de células C2C12 e no ventrículo esquerdo de camundongos Swiss; 2) determinação da dose necessária de siRNA para o silenciamento da expressão protéica do MEF2C; 3) determinação do curso temporal do silenciamento; 4) avaliação dos efeitos do tratamento com molécula irrelevante de siRNA direcionada para a proteína exógena GFP; 5) avaliação da especificidade do silenciamento (off-targets) pela análise do RNAm para o MEF2A e das proteínas FAK, GAPDH, JNK1/2 e SHP2; 6) avaliação do silenciamento em outros órgãos, como pulmão e rim; 7) avaliação da efetividade do silenciamento de MEF2C em miócitos cardíacos isolados do ventrículo esquerdo de camundongos. O tratamento com siRNA diminuiu a expressão protéica do MEF2 em 70% das células C2C12. Também verificamos que o tratamento com siRNA silenciou 85% da expressão protéica e do RNAm do MEF2C no ventrículo esquerdo de camundongos em até 4 dias de seguimento. Não foi verificada alteração na expressão de RNAm para o MEF2A e das proteínas FAK, GAPDH, JNK1/2 e SHP2. O silenciamento foi efetivo no pulmão e nos cardiomiócitos isolados do ventrículo esquerdo de camundongos tratado com siRNAMEF2C. Após a padronização do silenciamento, procedeu-se à determinação dos efeitos do silenciamento na estrutura e na função do ventrículo esquerdo de camundongos submetidos à sobrecarga pressórica crônica. Para isso, realizaram-se as análises ecocardiográfica, hemodinâmica, gravimétrica e morfométrica do ventrículo esquerdo de camundongos submetidos à coarctação da aorta com seguimento de 15 dias. Demonstramos que o tratamento com siRNAMEF2C atenuou a hipertrofia cardíaca nos animais coarctados. Esta conclusão foi baseada em dados de ecocardiografia que revelaram menor espessura da parede posterior (30% menor) e por gravimetria que revelou atenuação de aproximadamente 45% da massa do ventrículo esquerdo. Apesar de ter havido aumento do gradiente sistólico nos animais coarctados, a pressão arterial sistêmica não apresentou diferença estatisticamente significativa com o tratamento do siRNAMEF2C. Morfologicamente, o siRNA atenuou a fração de colágeno no ventrículo esquerdo de camundongos coarctado com 15 dias de seguimento. Entretanto, o diâmetro dos miócitos e o infiltrado de células inflamatórias foram comparáveis dentre os grupos. Somente os animais coarctados por 24 horas tiveram maior expressão de ß- MHC, e quando tratados com siRNAMEF2C apresentaram menor razão ATP/ADP. Dessa forma, esses dados sugerem que o MEF2C regula múltiplos aspectos da hipertrofia cardíaca induzida por sobrecarga pressórica tais como a expressão de genes sarcoméricos e genes envolvidos na adaptação metabólica do músculo cardíaco. / Abstract: Heart diseases are frequently associated with myocardial hypertrophy. Mechanical stimuli can trigger hypertrophic growth as well as degeneration and death of the cardiac myocytes. The MEF2C family of transcription factors plays a role in the process of myocardial hypertrophy. It is composed by 4 members, MEF2A, B, C and D, and the MEF2C is the main transcript in the heart. Both the deletion and overexpression of mef2c induce deleterious effects in the formation and function of the heart. Previous studies of the our laboratory has shown that the transcription factor MEF2C is activated by mechanical stretch in cardiomyocytes and regulates the expression of genes related to cardiac hypertrophy. This study was performed to address the effects of MEF2C gene silencing in the structural and functional changes of the left ventricle (LV) induced by pressure overload in mice. To silence MEF2C, it was employed the RNA interference technique, specific siRNA target to MEF2C was administered through the mice jugular vein. To optimize the MEF2C knockdown, it was necessary to 1) analyze the MEF2C silencing in C2C12 cells, 2) determine the dose required to induce significant MEF2C silencing in LV of mice, 3) determine the time course of gene silencing, 4) assess the effects of the treatment with irrelevant siRNA target to the protein GFP, 5) evaluate the specificity of gene silencing by siRNAMEF2C through the expression analysis of the transcription factor MEF2A and other non-related proteins, 6) analyze of the MEF2C knockdown in other organs, 7) determine the effectiveness of the MEF2C silencing in cardiac myocytes harverst from the LV of mice treated systemically with siRNAMEF2C. Treatment with 100ng/mL of siRNAMEF2C induced MEF2C silencing (~70%) in C2C12 cells. Intrajugular delivery of 30µg of siRNAMEF2C in mice induced the reduction in the mRNA and protein levels (~85%) until 4 days after the injection. The treatment with siRNAMEF2C did not affect the expression of MEF2A and other non-related proteins. The MEF2C silencing was effective in lung and in cardiac myocytes harverst from LV of mice treated with siRNAMEF2C. After knockdown optimization, echocardiographic, hemodynamic, gravimetric and morphometric analysis was performed to address the effects of MEF2C silencing in the structure and function of the LV from 15 days aorticbanded mice. Myocardial MEF2C silencing attenuated the load-induced hypertrophy in banded mice, indicated by the reductions of the wall thickness and the mass (~45%) of the LV. An increase in transconstriction gradient was observed in banded mice but the systemic blood pressure did not shown a significant statistically difference with the siRNAMEF2C treatment. The siRNAMEF2C injection reduced the collagen fraction in the LV of 15 days banded mice. On the other hand, the myocytes diameter and inflammatory cells level were comparable between the groups. Only the 24 hours banded mice showed an increase in the â-MHC expression and the treatment with siRNAMEF2C reduced ATP/ADP ratio. This study indicate that MEF2C regulates many aspects of the cardiac hypertrophy induced by pressure overload, like the expression of sarcomeric genes and genes involved in metabolic adaptation of the heart muscle. / Mestrado / Medicina Experimental / Mestre em Fisiopatologia Médica
162

Gene transfer vector development to treat lung disease : the use of a dual-function lentiviral vector containing ENaC RNAi and the CFTR gene to treat Cystic Fibrosis lung disease

Harding-Smith, Rebekka January 2014 (has links)
Cystic Fibrosis (CF) is a degenerative disorder that is often associated with chronic lung disease. CF is caused by mutations in the gene encoding the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) chloride channel, which lead to defective chloride and sodium ion movement across epithelia. Subsequent dehydration of the airway surface liquid (ASL) on airway epithelia, is associated with poor mucociliary clearance and chronic lung infection. The monogenic nature of CF, along with the accessibility of the lung, makes the disease amenable to gene replacement therapy. Gene therapy clinical trials have focused on replacing the mutated CFTR with a functional copy, which has led to improved chloride transport, but has shown no significant effects on sodium transport. An alternative strategy for CF gene therapy therefore, could be to reduce the expression of the epithelial sodium channel (ENaC) in the lung, using RNA interference (RNAi), combined with CFTR delivery. Developing a dual-function gene transfer vector could potentially restore chloride and sodium levels in the ASL and help alleviate CF lung disease. The aim of this thesis was to develop a recombinant lentivirus delivery system capable of simultaneously delivering CFTR expression and knocking down ENaC expression in the airways. A modular HIV vector genome plasmid was developed to allow simple insertion of various promoter elements, transgenes and knockdown sequences, for subsequent virus production. Insertion of the CFTR transgene and a short-hairpin RNA (shRNA) sequence targeting the ENaC alpha subunit (ENaCα) resulted in significant knockdown of human ENaCα and simultaneous expression of CFTR in A549 (human lung carcinoma) cell culture. Replacement of the ENaCα shRNA with an shRNA targeting the transcription factor BACH1 resulted in target gene knockdown and concomitant HMOX1 up-regulation, confirming specific knockdown effects, and demonstrating that the dual-function rLV vector could mediate target gene knockdown irrespective of the target. Attempts were made to knock down BACH1 in primary cultures of human bronchial epithelial cells grown at the air-liquid interface (ALI), but improved transduction efficiencies from the apical surface will be required to generate successful knockdown in this experimental model. These studies provide proof-of-principle for the utility of this versatile dual-function prototype virus. The dual function vector not only has the potential for treatment of CF lung disease, but could be readily altered to target other lung diseases where combinations of prolonged target gene knockdown and gene expression/up-regulation could collectively provide an appropriate therapy. In conclusion, the focus on the rational design of gene transfer vectors for specific therapeutic effects will aid the development and translation of gene therapy approaches to human studies.
163

Investigation of an Oncolytic MeV Cell-Cell Fusion Phenomenon Induced by an siRNA

Barkley, Russell 02 December 2020 (has links)
Oncolytic measles virus is a promising cancer therapeutic in clinical trials which possesses multiple characteristics that are advantageous over traditional therapies. Currently, clinical oncolytic measles virus vectors are unmodified or express reporter transgenes that benefit its therapeutic efficacy. The next phase in its development will see genetically engineered vectors encoding transgenes that enhance its antineoplastic effects. To this end, preclinical research has focused on studying novel transgenes which favour viral replication, cytotoxicity, and the anti-cancer immune response. We sought to encode artificial micoRNAs targeting RIG-I as a strategy to interfere with innate immunity. Silencing RIG-I with multiple siRNAs yielded one which promotes measles virus syncytia formation through a mechanism that appears to be independent of RIG-I. The mechanism caused by the siRNA leads to enhanced measles virus cell-cell fusion and has peculiar characteristics which are not fully understood.
164

Molecular Characterization of Pediatric Brainstem Gliomas (DIPG) and Identification of New Therapeutic Targets / Caractérisation moléculaire des gliomes malins pédiatriques du tronc cérébral (DIPG) et identification de nouvelles stratégies thérapeutiques

Silva Evangelista, Cláudia 01 October 2018 (has links)
Les DIPG représentent les tumeurs cérébrales pédiatriques les plus sévères. Aucun progrès dans leur prise en charge n’a été accompli au cours des 50 dernières années et la radiothérapie ne demeure que transitoirement efficace. Récemment, une mutation somatique de l’histone H3 (K27M) spécifique des DIPG a été trouvée chez environ 95% des patients. Elle est aujourd’hui considérée comme l'événement oncogénique initiateur de ces tumeurs. Deux sous-groupes majeurs de patients présentant des programmes oncogéniques et une réponse à la radiothérapie distincts peuvent être définis en fonction du gène dans lequel l’altération survient, codant les variantes protéiques H3.1 ou H3.3. Nous avons réalisé deux cribles de létalité synthétique par ARN interférence ciblant le kinome humain afin d'identifier d’une part les gènes nécessaires à la survie des DIPG et d’autre part les gènes dont l’inhibition sensibilise ces tumeurs à la radiothérapie. Le double objectif de ce projet était de mieux comprendre la biologie sous-jacente à l’oncogenèse des DIPG et de découvrir de nouvelles cibles thérapeutiques.Nous avons mis en évidence 41 gènes requis pour la survie des DIPG sans effet délétère majeur sur des cellules contrôles normales. Parmi eux, nous avons identifié VRK3 codant une serine thréonine kinase dont les fonctions restent peu décrites à ce jour et qui n'avait jamais été associée préalablement à l'oncogenèse de DIPG. Nous avons pu confirmer par la suite que son inhibition conduit à un arrêt total de la prolifération des cellules de DIPG associé à d’importants changements morphologiques, plus particulièrement dans les tumeurs mutées pour H3.3-K27M. VRK3 constitue par conséquent une nouvelle cible thérapeutique prometteuse dans cette pathologie à l’issue fatale pour la totalité des patients.En parallèle, un crible de survie similaire a été réalisé en conjonction avec l’irradiation des cellules. Très peu d’ARN interférents ont permis de sensibiliser les cellules H3.3-K27M à la radiothérapie contrairement aux cellules H3.1-K27M. Ce travail nous a permis de mettre en évidence une différence significative de radiosensibilité des modèles vitro de DMG en fonction du sous-groupe de tumeurs considéré, H3.1- ou H3.3-K27M muté, conformément à la survie des patients observée suite à la radiothérapie. Ces résultats inédits laissent entrevoir des perspectives d’amélioration du traitement de référence des patients atteints de DIPG actuellement identique quelle que soit leur génotype. / DIPG is one of the most severe paediatric brain tumours. No progress has been made in their management over the past 50 years and radiotherapy remains only transiently effective. Recently, a specific somatic mutation in the histone H3 (K27M) has been found in approximately 95% of DIPG patients and can be considered as the oncogenic driver of these tumours. Two major subgroup of patients with distinct oncogenic program and response to radiotherapy can be defined according to the gene in which the alteration occurs, encoding the H3.1 or H3.3 protein variants. We performed two synthetic lethality screens by RNA interference targeting the human kinome in order to identify the genes responsible for DIPG cell survival, as well as those sensitizing tumour cells to radiotherapy after inhibition. The dual purpose of this project was to better understand the biology underlying oncogenesis of DIPGs and to discover new therapeutic targets.We identified 41 genes required for DIPG cell survival with no major deleterious effect on normal control cells. Among them, we identified VRK3, a serine threonine kinase never involved in DIPG oncogenesis with functions remaining poorly described to date. We have shown that its inhibition leads to a complete arrest of DIPG cell proliferation and is additionally associated with important morphological changes, more particularly in H3.3-K27M mutated tumours. VRK3 is therefore a promising new therapeutic target for all patients in this fatal pathology.In parallel, a similar survival screen was performed in conjunction to cell radiation and very few interfering RNAs enhance H3.3-K27M cell radiosensitivity, in contrast to H3.1-K27M cells. These data highlighted a significant difference in radiosensitivity of the DMG in vitro models in H3.1- versus H3.3-K27M mutated tumours, in a concordant way with patient survival following radiotherapy. These unprecedented results suggest new opportunities for improving the current treatment of DIPG patients regardless of their genotype.
165

Dynamika a mechanismus umlčování reportérového genu pro GFP v závislosti na aktivitě RDR6 a způsobu indukce RNA interference v buněčné linii tabáku BY-2 / The influence of RDR6 activity and mode of RNAi induction on dynamics and mechanism of silencing of the reporter GFP gene in tobacco cell line BY-2

Motylová, Šárka January 2015 (has links)
RNA interference (RNAi) is a process mediated by small RNAs (sRNA), which is significantly involved in the regulation of gene expression in plants. Diverse RNAi pathways can be divided into two basic mechanisms, which are post-transcriptional and transcriptional gene silencing (PTGS and TGS). Production of sRNAs is dependent on the presence of a double-stranded RNA molecule (dsRNA), which is cleaved by one of DCL proteins to produce sRNAs usually of 21-24 nt in length. One strand of the sRNA is subsequently loaded onto AGO protein. During PTGS, the AGO-sRNA complex interacts with the target RNA based on its sequence complementarity to the sRNA and cleaves it or blocks its translation. In the case of TGS, AGO interacts with plant-specific RNA Pol V and its transcripts, which are again complementary to the sRNA. This interaction allows assembling of a protein complex facilitating DNA and histone methylation inhibiting RNA Pol II transcription. There are numerous ways the dsRNA can arise. A significant part of dsRNA cell production is dependent on synthesising the complementary strand of the dsRNA by RDR6 (RNA-dependent RNA polymerase 6). RDR6 is also involved in the process of the secondary sRNA formation. The significance of RDR6 during PTGS was examined using a GFP reporter gene either during...
166

Studium mechanizmů RNAi v tabákové buněčné linii BY-2 a rostlinách lilku bramboru / Study of RNAi mechanisms in tobacco BY-2 cell line and potato plants

Tyč, Dimitrij January 2020 (has links)
Knowledge of the processes of RNA interference, the regulation of gene expression by small RNAs (sRNAs), has grown at an unprecedented rate over the last 30 years. Some of the findings were literally revolutionary, as they revealed events that overturned many long-held notions. Many phenomena have been shown to be highly conserved and common to organisms of different species, but others are specific to certain lineages or have not yet been fully explored. There is also a lack of knowledge about the interconnection of numerous pathways - for example between silencing at the transcriptional (TGS, leading to the promoter methylation) and post-transcriptional levels (PTGS, affecting mRNA stability or translation). The present work summarizes the findings of two published and two unpublished works and attempts to describe some of the less known sites of RNA interference using various plant model organisms. Research on Solanum tuberosum transgenic lines has revealed the ability of 5-azacytidine to restore the expression of transcriptionally silenced transgenes at the whole plant level. De novo regeneration from leaves of such plants can lead to re-silencing of reactivated transgenes and thus serves as a selection method to exclude lines prone to spontaneous silencing. The nature of changes in the...
167

Auswirkungen des LRRK2-Knockdown durch RNA-Interferenz auf die murine dopaminerge Zelllinie MN9D

Fransecky, Lars 14 July 2009 (has links)
Mutationen im Protein LRRK2 wurden im Zusammenhang mit klinischen Symptomen beschrieben, die dem Idiopathischen Parkinsonsyndrom (IPS) nahezu gleichen. So findet sich neben vielen anderen Mutationen die häufigste pathogene Mutation für das IPS im LRRK2-Gen. Die Aufklärung der molekularbiologischen Mechanismen, die zur Pathologie der spezifischen Neurodegeneration in der Substantia nigra Pars Compacta (SNpc) und somit zur Idiopathischen Parkinsonssyndrom führen, ist mit der Hoffnung auf kausale und kurative Therapieansätze verbunden. In dieser medizinischen Doktorarbeit soll daher versucht werden, die biologische Funktion des LRRK2 in einem dopaminergen Mauszellmodell näher zu beschreiben. Hierfür soll die genetische Aktivität des LRRK2 in mesenzephalen, sogenannten MN9D-Zellen reduziert werden, indem der Mechanismus der RNA-Interferenz in vitro durch Transfektion von siRNA angestoßen wird. Durch die Reduktion der LRRK2-Aktivität sollen Veränderungen in den MN9D-Zellen induziert und diese objektiviert werden. Die Darstellung der Beobachtungen konzentriert sich auf die transkriptionelle Expression von Genen des Zellzyklus sowie der neuralen und dopaminergen Differenzierung (Tyrosinhydroxylase, Nestin und β-Tubulin) durch PCR. Die Proliferation der Zellen vor und nach den RNA-Interferenzexperimenten soll global durch MTT- und BrdU-Test gemessen werden.
168

RNAi Knockdown of Par-4 Inhibits Neurosynaptic Degeneration in ALS-Linked Mice

Xie, Jun, Awad, Keytam S., Guo, Qing 01 January 2005 (has links)
Evidence from human amyotrophic lateral sclerosis (ALS) patients and ALS-linked Cu/Zn superoxide dismutase (Cu/Zn-SOD) transgenic mice bearing the mutation of glycine to alanine at position 93 (G93A) suggests that the pro-apoptotic protein prostate apoptosis response-4 (Par-4) might be a critical link in the chain of events leading to motor neuron degeneration. We now report that Par-4 is enriched in synaptosomes and post-synaptic density from the ventral horn of the spinal cord. Levels of Par-4 in synaptic compartments increased significantly during rapid and slow declining stages of muscle strength in hSOD1 G93A mutant mice. In the pre-muscle weakness stage, hSOD1 G93A mutation sensitized synaptosomes from the ventral horn of the spinal cord to increased levels of Par-4 expression following excitotoxic and apoptotic insults. In ventral spinal synaptosomes, Par-4-mediated production of pro-apoptotic cytosolic factor(s) was significantly enhanced by the hSOD1 G93A mutation. RNA interference (RNAi) knockdown of Par-4 inhibited mitochondrial dysfunction and caspase-3 activation induced by G93A mutation in synaptosomes from the ventral horn of the spinal cord, and protected spinal motor neurons from apoptosis. These results identify the synapse as a crucial cellular site for the cell death promoting actions of Par-4 in motor neurons, and suggest that targeted inhibition of Par-4 by RNAi may prove to be a neuroprotective strategy for motor neuron degeneration.
169

The Study of Two Strategies for Decreasing Mutant Huntingtin: Degradation by Puromycin Sensitive AminoPeptidase and RNA Interference: A Dissertation

Chaurette, Joanna 22 May 2013 (has links)
Huntington’s disease (HD) is a fatal neurodegenerative disease caused by a CAG repeat expansion in exon 1 of the huntingtin gene, resulting in an expanded polyglutamine (polyQ) repeat in the huntingtin protein. Patients receive symptomatic treatment for motor, emotional, and cognitive impairments; however, there is no treatment to slow the progression of the disease, with death occurring 15-20 years after diagnosis. Mutant huntingtin protein interferes with multiple cellular processes leading to cellular dysfunction and neuronal loss. Due to the complexity of mutant huntingtin toxicity, many approaches to treating each effect are being investigated. Unfortunately, addressing one cause of toxicity might not result in protection from other toxic insults, necessitating a combination of treatments for HD patients. Ideally, single therapy targeting the mutant mRNA or protein could prevent all downstream toxicities caused by mutant huntingtin. In this work, I used animal models to investigate a potential therapeutic target for decreasing mutant huntingtin protein, and I apply bioluminescent imaging to investigate RNA interference to silence mutant huntingtin target sites. The enzyme puromycin sensitive aminopeptidase (PSA) has the unique property of degrading polyQ peptides and been implicated in the degradation of huntingtin. In this study, we looked for an effect of decreased PSA on the pathology and behavior in a mouse model of Huntington’s disease. To achieve this, we crossed HD mice with mice with one functional PSA allele and one inactivated PSA allele. We found that PSA heterozygous HD mice develop a greater number of pathological inclusion bodies, representing an accumulation of mutant huntingtin in neurons. PSA heterozygous HD mice also exhibit worsened performance on the raised-beam test, a test for balance and coordination indicating that the PSA heterozygosity impairs the function of neurons with mutant huntingtin. In order to test whether increasing PSA expression ameliorates the HD phenotype in mice we created an adeno-associated virus (AAV) expressing the human form of PSA (AAV-hPSA). Unexpectedly, testing of AAV-hPSA in non-HD mice resulted in widespread toxicity at high doses. These findings suggest that overexpression of PSA is toxic to neurons in the conditions tested. In the second part of my dissertation work, I designed a model for following the silencing of huntingtin sequences in the brain. Firefly luciferase is a bioluminescent enzyme that is extensively used as a reporter molecule to follow biological processes in vivo using bioluminescent imaging (BLI). I created an AAV expressing the luciferase gene containing huntingtin sequences in the 3'-untranslated region (AAV-Luc-Htt). After co-injection of AAV-Luc-Htt with RNA-silencing molecules (RNAi) into the brain, we followed luciferase activity. Using this method, we tested cholesterol-conjugated siRNA, un-conjugated siRNA, and hairpin RNA targeting both luciferase and huntingtin sequences. Despite being able to detect silencing on isolated days, we were unable to detect sustained silencing, which had been reported in similar studies in tissues other than the brain. We observed an interesting finding that co-injection of cholesterol-conjugated siRNA with AAV-Luc-Htt increased luminescence, findings that were verified in cell culture to be independent of serotype, siRNA sequence, and cell type. That cc-siRNA affects the expression of AAV-Luc-Htt reveals an interesting interaction possibly resulting in increased delivery of AAV into cells or an increase in luciferase expression within the cell. My work presents a method to follow gene silencing of huntingtin targets in the brain, which needs further optimization in order to detect sustained silencing. Finally, in this dissertation I continue the study of bioluminescent imaging in the brain. We use mice that have been injected in the brain with AAV-Luciferase (AAV-Luc) to screen 34 luciferase substrate solutions to identify the greatest light-emitting substrate in the brain. We identify two substrates, CycLuc1 and iPr-amide as substrates with enhanced light-emitting properties compared with D-luciferin, the standard, commercially available substrate. CycLuc1 and iPr-amide were tested in transgenic mice expressing luciferase in dopaminergic neurons. These novel substrates produced luminescence unlike the standard substrate, D-luciferin which was undetectable. This demonstrates that CycLuc1 and iPr-amide improve the sensitivity of BLI in low expression models. We then used CycLuc1 to test silencing of luciferase in the brain using AAV-shRNA (AAV-shLuc). We were unable to detect silencing in treated mice, despite a 50% reduction of luciferase mRNA. The results from this experiment identify luciferase substrates that can be used to image transgenic mice expressing luciferase in dopaminergic neurons. My work contributes new data on the study of PSA as a modifier of Huntington’s disease in a knock-in mouse model of Huntington’s disease. My work also makes contributions to the field of bioluminescent imaging by identifying and testing luciferase substrates in the brain to detect low level of luciferase expression.
170

RNA Interference by the Numbers: Explaining Biology Through Enzymology: A Dissertation

Wee, Liang Meng 02 June 2013 (has links)
Small silencing RNAs function in almost every aspect of cellular biology. Argonaute proteins bind small RNA and execute gene silencing. The number of Argonaute paralogs range from 5 in Drosophila melanogaster , 8 in Homo sapiens to an astounding 27 in Caenorhabditis elegans. This begs several questions: Do Argonaute proteins have different small RNA repertoires? Do Argonaute proteins behave differently? And if so, how are they functionally and mechanistically distinct? To address these questions, we examined the thermodynamic, kinetic and functional properties of fly Argonaute1 (dAgo1), fly Argonaute2 (dAgo2) and mouse Argonaute2 (mAGO2). Our studies reveal that in fly, small RNA duplexes sort into Argonaute proteins based on their intrinsic structures: extensively paired siRNA duplex is preferentially sorted into dAgo2 while imperfectly paired miRNA duplex is channeled into dAgo1. The sorting of small RNA is uncoupled from its biogenesis. This is exemplified by mir-277, which is born a miRNA but its extensive duplex structure licenses its entry into dAgo2. In the Argonaute protein, the small RNA guide partitions into functional domains: anchor, seed, central, 3' supplementary and tail. Of these domains, the seed initiates binding to target. Both dAgo2 and mAGO2 (more closely related to and a surrogate for dAgo1 in our studies) bind targets at astonishing diffusion-limited rates (~107–108 M−1s−1). The dissociation kinetics between dAgo2 and mAGO2 from their targets, however, are different. For a fully paired target, dAgo2 dissociates slowly (t½ ~2 hr) but for a seed-matched target, dAgo2 dissociates rapidly (t½ ~20 s). In comparison, mAGO2 does not discriminate between either targets and demonstrates an equivalent dissociation rate (t½ ~20 min). Regardless, both dAgo2 and mAGO2 demonstrate high binding affinity to perfect targets with equilibrium dissociation constants, KD ~4–20 pM. Functionally, we also showed that dAgo1 but not dAgo2 silence a centrally bulged target. By contrast, dAgo2 cleaved and destroyed perfectly paired targets 43-fold faster than dAgo1. In target cleavage, dAgo2 can tolerate mismatches, bulged and internal loop in the target but at the expense of reduced target binding affinities and cleavage rates. Taken together, our studies indicate that small RNAs are actively sorted into different Argonaute proteins with distinct thermodynamic, kinetic and functional behaviors. Our quantitative biochemical analysis also allows us to model how Argonaute proteins find, bind and regulate their targets.

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