Global ETD Search

1	Comparing the silencing efficacy of dicer-independent and dependent shRNAs Nhlabatsi, Neliswa 22 April 2015 (has links) A dissertation submitted to the Faculty of Science, University of the Witwatersrand, Johannesburg, in fulfilment of the requirements for the degree of Master of Science. Johannesburg, 2014. / RNA interference (RNAi) is a highly conserved gene regulatory mechanism triggered by the presence of double-stranded RNAs and results in post-transcriptional and transcriptional gene silencing. RNAi has been demonstrated to have therapeutic potential to treat chronic viral infections including HIV-1. Due to the side effects of and eventual drug resistance to highly active antiretroviral therapy, a novel anti-HIV-1 therapy is required. The most suitable exogenous RNAi triggers to use in anti-HIV-1 RNAi-based therapy are expressed short hairpin RNAs (shRNAs). Despite being highly developed, shRNA systems still pose safety concerns. Highly expressed shRNAs are at risk of over-saturating the endogenous RNAi pathway, inducing an innate immune response or silencing off-target mRNA. The purpose of this study was to minimise shRNA-associated off-target effects and simultaneously maximise the potency and specificity of expressed shRNAs for potential therapeutic application. ShRNAs shorter than 19 base pairs are not recognised by the endonuclease Dicer, which is an important component of the RNAi pathway, but miR-451 is Dicer-independent. Smaller shRNAs that retain their potency would be easier to deliver into a disease model. For this study, 25mers and miR-451-mimicking 19mers were generated. The shRNA pairs exhibited significant knockdown of their respective targets in dual-luciferase assays. The 19mers are more specific gene silencers compared to the 25mers. A 19mer that is more potent than its 25mer counterpart was identified. None of the hairpins induced an innate immune response, caused cytotoxic effects or saturated the endogenous RNAi pathway. This study concludes that the 19mers were processed in a manner similar to miR-451 resulting in a single ~30 nt mature RNA product. We dubbed these miR-451-mimicking 19mers, guide shRNAs. The single RNA strand of mature guide shRNAs abolishes the risk sense strand-associated off-targeting thus improving shRNA specificity. These revolutionary guide shRNAs can be developed into highly potent activators of the RNAi pathway in a therapeutic setting. RNA-Induced Silencing Complex RNA Interference Antiviral Agents Viruses
2	Small RNA pathways and the roles of tudor nucleases in gene silencing and DNA deletion in Tetrahymena thermopila / Howard-Till, Rachel A. January 2006 (has links) Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 90-99).
3	Autophagy Regulates Expression of Argonaute 2, a Critical Regulator of the MicroRNA Silencing Pathway Sibony, Michal 15 November 2013 (has links) Genome-wide association studies have implicated autophagy in Crohn’s Disease (CD) pathogenesis. The functional relevance of autophagy in CD remains unknown. I hypothesized that autophagy is involved in microRNA silencing, another process implicated in CD pathogenesis. MicroRNAs are short non-coding RNAs that are loaded onto RNA-induced silencing complex (RISC) and promote degradation and/or repress translation of target mRNAs. RISC formation and turnover occurs on endosomal membranes. Since autophagosomes and endosomes are closely related and RISC components are downstream effectors of microRNA silencing, I hypothesized that autophagy affects RISC, hence modulates microRNA expression. Using immunoblotting and immunofluorescence, I showed that Ago2, a critical component of RISC, is increased in cells with defective autophagy. Using microarray technology, I discovered 5 microRNAs that are differentially expressed in these cells. Taken together, my results propose a compelling mechanism by which autophagy regulates Ago2, thereby affects miRNA expression, which is implicated in the development of CD. Autophagy microRNA Crohn's Disease Argonaute 2 RNA-induced Silencing Complex 0719
4	Autophagy Regulates Expression of Argonaute 2, a Critical Regulator of the MicroRNA Silencing Pathway Sibony, Michal 15 November 2013 (has links) Genome-wide association studies have implicated autophagy in Crohn’s Disease (CD) pathogenesis. The functional relevance of autophagy in CD remains unknown. I hypothesized that autophagy is involved in microRNA silencing, another process implicated in CD pathogenesis. MicroRNAs are short non-coding RNAs that are loaded onto RNA-induced silencing complex (RISC) and promote degradation and/or repress translation of target mRNAs. RISC formation and turnover occurs on endosomal membranes. Since autophagosomes and endosomes are closely related and RISC components are downstream effectors of microRNA silencing, I hypothesized that autophagy affects RISC, hence modulates microRNA expression. Using immunoblotting and immunofluorescence, I showed that Ago2, a critical component of RISC, is increased in cells with defective autophagy. Using microarray technology, I discovered 5 microRNAs that are differentially expressed in these cells. Taken together, my results propose a compelling mechanism by which autophagy regulates Ago2, thereby affects miRNA expression, which is implicated in the development of CD. Autophagy microRNA Crohn's Disease Argonaute 2 RNA-induced Silencing Complex 0719
5	Molecular and diagnostic aspects of the protein p41 of HHV-6 and silencing of the CD46 receptor by RNA interference / Xu, Yunhe, January 2003 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2003. / Härtill 4 uppsatser.
6	RNA Silencing Pathways in <em>Schizosaccharomyces pombe</em> and <em>Drosophila melanogaster</em>: A Dissertation Sigova, Alla A. 03 November 2006 (has links) RNA silencing is an evolutionary conserved sequence-specific mechanism of regulation of gene expression. RNA interference (RNAi), a type of RNA silencing in animals, is based on recognition and endonucleolytic cleavage of target mRNA complimentary in sequence to 21-nucleotide (nt) small RNA guides, called small interfering RNAs (siRNAs). Another class of 21-nt small RNAs, called micro RNAs (miRNAs), is endogenously encoded in eukaryotic genomes. Both production of siRNAs from long double-stranded RNA (dsRNA) and biogenesis of miRNAs from hairpin structures are governed by the ribonuclease III enzyme Dicer. Although produced as duplex molecules, siRNAs and miRNAs are assembled into effector complex, called the RNA-induced silencing complex (RISC), as single-strands. A member of the Argonaute family of small RNA-binding proteins lies at the core of all known RNA silencing effector complexes. Plants and animals contain multiple Argonaute paralogs. In addition to endonucleolytic cleavage, Argonaute proteins can direct translational repression/destabilization of mRNA or transcriptional silencing of DNA sequences by the siRNAdirected production of silent heterochromatin. The Schizosaccharomyces pombe genome encodes only one of each of the three major classes of proteins implicated in RNA silencing: Dicer (Dcr1), RNA-dependent RNA polymerase (RdRP; Rdp1), and Argonaute (Ago1). These three proteins are required for silencing at centromeres and for the initiation of transcriptionally silent heterochromatin at the mating-type locus. That only one Dicer, RdRP and Argonaute is expressed in S. pombe might reflect the extreme specialization of RNA silencing pathways regulating targets only at the transcriptional level in this organism. We decided to test if classical RNAi can be induced in S. pombe. We introduced a dsRNA hairpin corresponding to a GFP transgene. GFP silencing triggered by dsRNA reflected a change in the steady-state concentration of GFP mRNA, but not in the rate of GFP transcription. RNAi in S. pombe required dcr1, rdp1, and ago1, but did not require chp1, tas3, or swi6, genes required for transcriptional silencing. We concluded that the RNAi machinery in S. pombecould direct both transcriptional and posttranscriptional silencing using a single Dicer, RdRP, and Argonaute protein. Our findings suggest that, in spite of specialization in distinct siRNA-directed silencing pathways, these three proteins fulfill a common biochemical function. In Drosophila, miRNA and RNAi pathways are both genetically and biochemically distinct. Dicer-2 (Dcr-2) generates siRNAs, whereas the Dicer-1 (Dcr-1)/Loquacious complex produces miRNAs. Argonaute proteins can be divided by sequence similarity into two classes: in flies, the Ago subfamily includes Argonaute1 (Ago1) and Argonaute2 (Ago2), whereas the Piwi subfamily includes Aubergine, Piwi and Argonaute 3. siRNAs and miRNAs direct posttranscriptional gene silencing through effector complexes containing Ago1 or Ago2. The third class of small RNAs, called repeat-associated small interfering RNAs (rasiRNAs), is produced endogenously in the Drosophilagerm line. rasiRNAs mediate silencing of endogenous selfish genetic elements such as retrotransposons and repetitive sequences to ensure genomic stability. We examined the genetic requirements for biogenesis of rasiRNAs in both male and female germ line of Drosophilaand silencing of 8 different selfish elements, including tree LTR retrotransposons, two non-LTR retrotransposons, and three repetitive sequences. We find that biogenesis of rasiRNAs is different from that of miRNAs and siRNAs. rasiRNA production appears not to require Dicer-1 or Dicer-2. rasiRNAs lack the 2´,3´ hydroxy termini characteristic of animal siRNA and miRNA. While siRNAs derive from both the sense and antisense strands of their dsRNA precursors, rasiRNAs accumulate in antisense polarity to their corresponding target mRNAs. Unlike siRNAs and miRNAs, rasiRNAs function through the Piwi, rather than the Ago, Argonaute protein subfamily. We find that rasiRNAs silence their target RNAs posttranscriptionally: mutations that abrogate rasiRNA function dramatically increase the steady-state mRNA level of rasiRNA targets, but do not alter their rate of transcription, measured by nuclear run-on assay. Our data suggest that rasiRNAs protect the fly germ line through a silencing mechanism distinct from both the miRNA and RNAi pathways. RNA Interference RNA Small Interfering RNA-Induced Silencing Complex Schizosaccharomyces pombe Proteins Drosophila Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Fungi
7	Cooperativity in Mammalian RNA Silencing: A Dissertation Broderick, Jennifer A. 26 July 2011 (has links) Argonaute proteins are the core component of an RNA silencing complex. The human genome encodes four Argonaute paralogs –Ago1, Ago2, Ago3 and Ago4– proteins that are guided to target mRNAs by microRNAs. More than 500 miRNAs are conserved between mammals, and each microRNA can repress hundreds of genes, regulating almost every cellular process. We still do not fully understand the molecular mechanisms by which miRNAs regulate gene expression. Although we understand many aspects of microRNA biogenesis and formation of the RNA-induced silencing complex, much less is known about the subsequent steps leading to target mRNA regulation. Mammalian microRNAs rarely have complete complementarity to their target mRNAs so, instead of endonucleolytic cleavage by Ago2, microRNAs destabilize or repress translation of target mRNAs. Here I explored the functional limits of Argonaute proteins bound to their targets directly and indirectly through microRNAs in mammalian cells. I revealed the different abilities for Argonaute proteins bound at multiple sites in a target to generate cooperativity in silencing based on the extent of pairing between the microRNA and target mRNA. Further, I harnessed the endogenous microRNA silencing mechanism to repress an mRNA that is not a direct target of the microRNA by tethering the RNA-induced silencing complex to the 3´ UTR of an mRNA. This strategy allows tissue-specific gene silencing due to the limited endogenous expression profile of the recruited microRNA. Efforts made herein further our mechanistic knowledge of microRNA-induced gene silencing in mammalian cells and advance microRNA-based strategies toward treating human disease. RNA Interference MicroRNAs RNA-Induced Silencing Complex Amino Acids, Peptides, and Proteins Cells Genetic Phenomena Genetics and Genomics Life Sciences Medicine and Health Sciences Neuroscience and Neurobiology Tissues
8	Understanding Assembly of AGO2 RISC: the RNAi enzyme: a Dissertation Matranga, Christian B. 17 September 2007 (has links) In 1990, Richard Jorgensen’s lab initiated a study to test if they could create a more vivid color petunia (Napoli et al. 1990). Their plan was to transform plants with the chalcone synthase transgene––the predicted rate limiting factor in the production of purple pigmentation. Much to their surprise, the transgenic plants, as well as their progeny, displayed a great reduction in pigmentation. This loss of endogenous function was termed “cosuppression” and it was thought that sequence-specific repression resulted from over-expression of the homologous transgene sequence. In 1998, Andrew Fire and Craig Mello described a phenomenon in which double stranded RNA (dsRNA) can trigger silencing of cognate sequences when injected into the nematode, Caenorhabditis elegans (Fire et al. 1998). This data explained observations seen years earlier by other worm researchers, and suggested that repression of pigmentation in plants was caused by a dsRNA-intermediate (Guo and Kemphues 1995; Napoli et al. 1990). The phenomenon––which soon after was coined RNA interference (RNAi)––was soon discovered to be a post-transcriptional surveillance system in plants and animals to remove foreign nucleic acids. RNA Interference MicroRNAs RNA Small Interfering Drosophila Proteins Methyltransferases RNA-Induced Silencing Complex RNA 3' End Processing Plants RNA Helicases RNA-Binding Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Enzymes and Coenzymes
9	Small RNA Sorting in Drosophila Produces Chemically Distinct Functional RNA-Protein Complexes: A Dissertation Horwich, Michael D. 10 June 2008 (has links) Small interfering RNAs (siRNAs), microRNAs (miRNAs), and piRNAs (piRNA) are conserved classes of small single-stranded ~21-30 nucleotide (nt) RNA guides that repress eukaryotic gene expression using distinct RNA Induced Silencing Complexes (RISCs). At its core, RISC is composed of a single-stranded small RNA guide bound to a member of the Argonaute protein family, which together bind and repress complementary target RNA. miRNAs target protein coding mRNAs—a function essential for normal development and broadly involved in pathways of human disease; small interfering RNAs (siRNA) defend against viruses, but can also be engineered to direct experimental or therapeutic gene silencing; piwi associated RNAs (piRNAs) protect germline genomes from expansion of parasitic nucleic acids such as transposons. Using the fruit fly, Drosophila melanogaster, as a model organism we seek to understand how small silencing RNAs are made and how they function. In Drosophila, miRNAs and siRNAs are proposed to have parallel, but separate biogenesis and effector machinery. miRNA duplexes are excised from imperfectly paired hairpin precursors by Dicer1 and loaded into Ago1; siRNA duplexes are hewn from perfectly paired long dsRNA by Dicer2 and loaded into Ago2. Contrary to this model we found one miRNA, miR-277, is made by Dicer1, but partitions between Ago1 and Ago2 RISCs. These two RISCs are functionally distinct—Ago2 could silence a perfectly paired target, but not a centrally bulged target; Ago1 could silence a bulged target, but not a perfect target. This was surprising since both Ago1 and Ago2 have endonucleolytic cleavage activity necessary for perfect target cleavage in vitro. Our detailed kinetic studies suggested why—Ago2 is a robust multiple turnover enzyme, but Ago1 is not. Along with a complementary in vitro study our data supports a duplex sorting mechanism in which Diced duplexes are released, and rebind to Ago1 or Ago2 loading machinery, regardless of which Dicer produced them. This allows structural information embedded in small RNA duplexes to direct small RNA loading into Ago1 and/or Ago2, resulting in distinct regulatory outputs. Small RNA sorting also has chemical consequences for the small RNA guide. Although siRNAs were presumed to have the signature 2′, 3′ hydroxyl ends left by Dicer, we found that small RNAs loaded into Ago2 or Piwi proteins, but not Ago1, are modified at their 3´ ends by the RNA 2´-O-methyltransferase DmHen1. In plants Hen1 modifies the 3´ ends all small RNAs duplexs, protecting and stabilizing them. Implying a similar function in flies, piRNAs are smaller, less abundant, and their function is perturbed in hen1 mutants. But unlike plants, small RNAs are modified as single-strands in RISC rather than as duplexes. This nicely explains why the dsRNA binding domain in plant Hen1 was discarded in animals, and why both dsRNA derived siRNAs and ssRNA derived piRNAs are modified. The recent discovery that both piRNAs and siRNAs target transposons links terminal modification and transposon silencing, suggesting that it is specialized for this purpose. RNA Interference Drosophila melanogaster RNA Helicases RNA-Induced Silencing Complex RNA Small Interfering Methyltransferases MicroRNAs DNA Transposable Elements Drosophila Proteins RNA Transport Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena
10	Dissecting Small RNA Loading Pathway in <em>Drosophila melanogaster</em>: A Dissertation Du, Tingting 28 January 2008 (has links) In the preceding chapters, I have discussed my doctoral research on studying the siRNA loading pathway in Drosophila using both biochemical and genetic approaches. We established a gel shift system to identify the intermediate complexes formed during siRNA loading. We detected at least three complexes, named complex B, RISC loading complex (RLC) and RISC. Using kinetic modeling, we determined that the siRNA enters complex B and RLC early during assembly when it remains double-stranded, and then matures in RISC to generate Argonaute bearing only the single-stranded guide. We further characterized the three complexes. We showed that complex B comprises Dcr-1 and Loqs, while both RLC and RISC contain Dcr-2 and R2D2. Our study suggests that the Dcr-2/R2D2 heterodimer plays a central role in RISC assembly. We observed that Dcr-1/Loqs, which function together to process pre-miRNA into mature miRNA, were also involved in siRNA loading. This was surprising, because it has been proposed that the RNAi pathway and miRNA pathway are separate and parallel, with each using a unique set of proteins to produce small RNAs, to assemble functional RNA-guided enzyme complexes, and to regulate target mRNAs. We further examined the molecular function of Dcr-1/Loqs in RNAi pathway. Our data suggest that, in vivo and in vitro, the Dcr-1/Loqs complex binds to siRNA. In vitro, the binding of the Dcr-1/Loqs complex to siRNA is the earliest detectable step in siRNA-triggered Ago2-RISC assembly. Futhermore, the binding of Dcr-1/Loqs to siRNA appears to facilitate dsRNA dicing by Dcr-2/R2D2, because the dicing activity is much lower in loqslysate than in wild type. Long inverted repeat (IR) triggered white silencing in fly eyes is an example of endogenous RNAi. Consistent with our finding that Dcr-1/Loqs function to load siRNA, less white siRNA accumulates in loqs mutant eyes compared to wild type. As a result, loqs mutants are partially defective in IR trigged whitesilencing. Our data suggest considerable functional and genetic overlap between the miRNA and siRNA pathways, with the two sharing key components previously thought to be confined to just one of the two pathways. Based on our study on siRNA loading pathway, we also elucidated the molecular function of Armitage (Armi) protein in RNAi. We showed that armi is required for RNAi. Lysates from armi mutant ovaries are defective for RNAi in vitro. Native gel analysis of protein-siRNA complexes suggests that armi mutants support early steps in the RNAi pathway, i.e., the formation of complex B and RLC, but are defective in the production of the RISC. MicroRNAs RNA Helicases RNA Interference RNA-Binding Proteins RNA-Induced Silencing Complex Germ Cells Mutation Drosophila melanogaster Body Patterning Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Genetic Phenomena

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