Global ETD Search

1	The Location and Effects of Factors Controlling Recombination in Linkage Group I of Neurospora Hargrave, Jenny Barbara 12 1900 (has links) <p> It was known, prior to this study, that there is a factor, or factors, in the centromere-proximal region of Neurospora sitophila which affect recombination near the centromere whether it is in Neurospora sitophila or transferred to Neurospora crassa. A location of this factor, or factors, was performed using tetrad and prototroph analysis. Further mapping of linkage group I of Neurospora crassa was undertaken when the Neurospora sitophila centromere-proximal region was present.</p> / Thesis / Master of Science (MSc)
2	Probing stability, specificity, and modular structure in group I intron RNAs Wan, Yaqi 03 February 2011 (has links) Many functional RNAs are required to fold into specific three-dimensional structures. A fundamental property of RNA is that its secondary structure and even some tertiary contacts are highly stable, which gives rise to independent modular RNA motifs and makes RNAs prone to adopting misfolded intermediates. Consequently, in addition to stabilizing the native structure relative to the unfolded species (defined here as stability), RNAs are faced with the challenge of stabilizing the native structure relative to alternative structures (defined as structural specificity). How RNAs have evolved to overcome these challenges is incompletely understood. Self-splicing group I introns have been used to study RNA structure and folding for decades. Among them, the Tetrahymena intron was the first discovered and has been studied extensively. In this work, we found that a version of the intron that was generated by in vitro selection for enhanced stability also displayed enhanced specificity against a stable misfolded structure that is globally similar to the native state, despite the absence of selective pressure to increase the energy gap between these structures. Further dissection suggests that the increased specificity against misfolding arises from two point mutations, which strengthen a local tertiary contact network that apparently cannot form in the misfolded conformation. Our results suggest that the structural rigidity and intricate networks of contacts inherent to structured RNAs can allow them to evolve exquisite structural specificity without explicit negative selection, even against closely-related alternative structures. To explore further how RNAs gain stability from intricate architectures, we examined a novel group I intron from red algae (Bangia). Biochemical methods and computational modeling suggest that this intron possesses general motifs of group IC1 introns but also forms an atypical tertiary contact, which has been reported previously in other subgroups and helps position the reactive helix at the active site. In the Bangia intron, the partners have been swapped relative to known group I RNAs that include this contact. This result underscores the modular nature of RNA motifs and provides insight into how structured RNAs can arrange helices and contacts in multiple ways to achieve and stabilize functional structures. / text Group I ribozyme RNA structure Structural specificity RNA folding Bangia RNA Tetrahymena Introns Group I introns
3	Predictive value of group I oral lesions in detecting HIV infection amongst patients attending PHC facilities in Gauteng Bhayat, Ahmed 15 May 2008 (has links) Abstract The utilization of oral lesions as a screening tool for HIV is not well documented. Attendees at two primary health care facilities (Khutsong and Heidelberg) were assessed to determine the predictive value of group I oral lesions for HIV infection. The objectives were to investigate the: 1) HIV prevalence amongst attendees at PHC facilities, 2) Prevalence of HIV-related oral lesions and 3) Correlation between the oral lesions and the HIV status using the Likelihood Ratio test. Methods: All patients over 12 months of age presenting at the two facilities for a curative care consultation over a one-week period (in April 2005) were included. Consent was obtained by trained counselors who also conducted a brief interview and offered pre-test counseling to patients wishing to know their HIV status. Two calibrated dentists conducted a head, neck and oral examination and administered a rapid saliva HIV test (OraQuick HIV-1/2-Rapid HIV-1/2 Antibody Test). Results: A total of 654 attendees were surveyed in the 2 facilities. There was a 100% response. The mean age of the participants was 34 years (range: 1-94), and the majority (73%) were female. HIV prevalence rates were 34% at Khutsong and 36% at Heidelberg. The HIV prevalence peaked at 46% in the 16-45 age groups. Of the 228 who tested positive for HIV, 121 (53%) patients were diagnosed with 1 or more Group I oral lesion. Oral candidiasis (46%) and oral hairy leukoplakia (19%) were the two most common oral lesions diagnosed in the HIV positive cohort. The positive predictive values and specificity values for multiple lesions ranged between 96% and 100%. Most of the likelihood ratios for multiple lesions were greater than 10 which implied that the patients who presented with these lesions were extremely likely to test positive for HIV. The sensitivity values (1% to 37%) and negative predictive values (66% to 70%) remained relatively low. Conclusion: The HIV prevalence of patients attending PHC facilities was high (34%). Oral lesions are useful markers of HIV-infection and should alert clinicians to the presence of HIV infection. Multiple group I lesions were more predictive of HIV infection compared to single lesions. HIV infection prevalence Predictive value of group I oral lesions
4	Self-splicing of Group I Intron of the Mitochondrial Genome of the Sponge, Cinachyrella australiensis Chan, Hui-mei 19 August 2009 (has links) Intragenic regions (introns) are found in all classes of organism. Transcription of such genes must undergo a splicing reaction to produce the mature, functional form of RNAs. Introns can be divided into four categories by their splicing mechanisms, namely Group I, Group II, spliceosomal, and nuclear tRNA introns. The former two are self-splicing introns. Group I introns are ubiquitous, however, most metazoan mitochondrial genomes lack introns. A novel group I intron in the mitochondrial cytochrome oxidase I gene (cox1) of Cinachyrella auctraliensis, which belongs to the IB2 subgroup, encodes a putative homing endonuclease with two amino acid motifs of the LAGLIDADG family. The homing endonuclease may perform intron translocation. Splicing in the cox1 of the sponge was demonstrated by comparing the length of DNA and RNA sequences. The intron was spliced in vivo or in vitro as revealed by RT-PCR and sequencing. Group I introns are classified as ribozymes. The pre-mRNAs fold into specific configurations that facilitate attacks of free guanosine followed by two consecutive trans-esterification steps to remove the introns. The excised cox1 intron was found to form a circle with the 5¡¦-end linked to the 3¡¦-end. Two other forms of lariats were also found with the 5¡¦-end linked to the inside sequence of the intron. Mutagenesis of a key nucleotide, which participates base pairing of RNA secondary structure, in P7 region decreased the splicing activity of the intron. group I intron cyclization self-splicing C. australiensis homing endonuclease
5	Mechanistic studies of the RNA chaperone activities of the DEAD-box RNA helicase CYT-19 Jarmoskaite, Inga 07 July 2014 (has links) Structured RNAs are pervasive in biology, spanning a functional repertoire that includes messengers, regulators of gene expression and catalysts of translation and splicing. From the relatively simple tRNAs and riboswitches to the highly structured ribosomal RNAs, the ability of RNAs to function is dependent on well-defined secondary and tertiary structures. However, studies of RNA folding in vitro have revealed an extreme propensity to form alternative structures, which can be long-lived and interfere with function. In the cell, a diverse array of RNA binding proteins and RNA chaperones guide RNAs towards the correct structure and disrupt misfolded intermediates. Among these proteins, DEAD-box protein family stands out as one of the largest groups, with its members ubiquitously involved in RNA metabolism across all domains of life. DEAD-box proteins can function as both specific and general RNA chaperones by disrupting RNA structures in an ATP-dependent manner. Here I describe my work studying the general RNA chaperone mechanism of the Neurospora crassa protein CYT-19, a model DEAD-box protein and a biological RNA chaperone that is required for efficient folding of self-splicing group I intron RNAs in vivo. After an introduction to DEAD-box proteins and their mechanisms as RNA remodelers (Chapter 1), I will first describe studies of group I intron unfolding by CYT-19, focusing on the effects of RNA tertiary structure stability on CYT-19 activity and targeting to RNA substrates (Chapter 2). I will then describe the characterization of ATP-dependent mechanisms during CYT-19-mediated refolding of the misfolded group I intron (Chapter 3). In Chapter 4, I will present small-angle X-ray scattering (SAXS) studies of structural features of DEAD-box proteins that allow them to efficiently interact with large structured RNA substrates. Finally, I will turn to studies of DEAD-box protein involvement during early steps of RNA compaction and folding, using SAXS and activity-based approaches (Chapter 5). I will conclude with a general discussion of superfamily 2 RNA helicases, which include DEAD-box and related proteins, and their functions and mechanisms as remodelers of structured RNAs and RNPs. / text RNA folding Group I intron Tertiary structure ATP utilization SAXS
6	EVOLUTION OF GROUP I INTRONS IN THE NUCLEAR RIBOSOMAL RNA GENES OF DOTHIDEOMYCETES Chen, Xing 12 November 2010 (has links) No description available. Biology Group I intron Secondary Structure Phylogenetic tree
7	Characterization of Group I Introns in the Ribosomal RNA Internal Transcribed Spacers of Eight Orders of Sharks Patil, Veena P. 17 November 2011 (has links) No description available. Molecular Biology Group I introns Ribosomal RNA Internal transcribed spacers
8	RNA BINDING PROPERTIES OF A TRANSLATIONAL ACTIVATOR THAT ALSO FUNCTIONS IN GROUP I INTRON SPLICING Kaspar, Ben J. 16 July 2008 (has links) No description available. Biology Biomedical Research Pet54 group I intron splicing mitochondrial translation
9	IN VITRO AND IN VIVO CHARACTERIZATION OF A TRANS EXCISION-SPLICING RIBOZYME Baum, Dana Ann 01 January 2005 (has links) Group I introns are catalytic RNAs with the ability to splice out of RNA transcripts, often without the aid of proteins. These self-splicing introns have been reengineered to create ribozymes with the ability to catalyze reactions. One such ribozyme, derived from a Pneumocystis carinii group I intron, has been engineered to sequence specifically remove a targeted segment from within an RNA substrate, which is called the trans excision-splicing reaction.The two catalytic steps of the trans excision-splicing reaction occur at positions on the substrate known as the 5' and 3' splice sites. Strict sequence requirements at these sites could potentially limit the target choices for the trans excision-splicing ribozyme, so the sixteen possible base pair combinations at the 5' splice site and the four possible nucleotides at the 3' splice site were tested for reactivity. All base pair combinations at the 5' splice site allow the first reaction step (5' hydrolysis) to occur and several combinations allow the second step to occur, resulting in trans excision-splicing product formation. Moreover, we found that non-Watson-Crick base pairs are important for 5' splice site recognition and prevent product degradation via hydrolysis at other sequence positions. The sequence requirement at the 3' splice site is absolute, as guanosine alone produced complete product.To date, the experiments with the trans excision-splicing ribozyme have been conducted in vitro. The further development of this ribozyme as a biochemical tool and as a potential therapeutic agent requires in vivo reactivity. Thus, a prokaryotic system was designed and tested to assess the catalytic potential of the trans excision-splicing ribozyme. We show that the ribozyme successfully excised a single, targeted nucleotide from a mutated green fluorescent protein transcript in Escherichia coli. On average, 12% correction was observed as measured by fluorescence and approximately 1.2% correction was confirmed through sequence analysis of isolated transcripts.We have used these studies to further characterize trans excision-splicing ribozymes in vitro and to pave the way for future development of this ribozymereaction in vivo. These results increase our understanding of this ribozyme and advance this reaction as a biochemical tool with potential therapeutic applications.
10	MECHANISTIC INVESTIGATIONS OF THE TRANS EXCISION-SPLICING AND TRANS INSERTION-SPLICING REACTION Dotson, Perry Patrick, II 01 January 2008 (has links) Group I intron-derived ribozymes are catalytic RNAs that have been engineered to catalyze a variety of different reactions, in addition to the native self-splicing reaction. One such ribozyme, derived from a group I intron of Pneumocystis carinii, can modify RNA transcripts through either the excision or insertion of RNA sequences. These reactions are mediated through the trans excision-splicing (TES) or trans insertionsplicing (TIS) reaction pathways. To increase our current understanding of these reactions, as well as their general applicability, a mechanistic and kinetic framework for the TES reaction was established. Furthermore, additional ribozymes were investigated for their ability to catalyze the TES reaction. Lastly, the development of the TIS reaction into a viable strategy for the manipulation of RNA transcripts was investigated. The TES reaction proceeds through two reaction steps: substrate cleavage followed by exon ligation. Mechanistic studies revealed that substrate cleavage is catalyzed by the 3’ terminal guanosine of the Pneumocystis ribozyme. Moreover, kinetic studies suggest that a conformational change exists between the individual reaction steps. Intron-derived ribozymes from Tetrahymena thermophila and Candida albicans were also investigated for their propensity to catalyze the TES reaction. The results showed that each ribozyme could catalyze the TES reaction; however, Pneumocystis carinii is the most effective using the model constructs. Investigations of the TIS reaction focused on developing a new strategy for the insertion of modified oligonucleotides into an RNA substrate. These studies used oligonucleotides with modifications to the sugar, base, and backbone positions. Each of the modified oligonucleotides was shown to be an effective TIS substrate. These results demonstrate that TIS is a viable strategy for the incorporation of modified oligonucleotides, of varying composition, into an intended RNA target. The results from these studies show that group I introns are highly adaptable for catalyzing non-native reactions, including the TES and TIS reactions. Furthermore, group I introns are capable of catalyzing these unique reactions through distinct reaction pathways. Overall, these results demonstrate that group I introns are multi-faceted catalysts. Chemistry

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