Global ETD Search

1	Characterization of D135 group II intron ribozyme dimerization Choi, Woongsoon 08 October 2013 (has links) Group II introns are highly structured RNAs that carry out self-splicing reactions. The multiple turnover version of one of these introns, termed the D135 ribozyme, is derived from the mitochondrial aI5γ intron of Saccharomyces cerevisiae and is widely studied as a model RNA for group II intron folding. An important current goal is to probe global changes during its folding with or without DEAD-box chaperone proteins. My initial experiments to study global compaction using small angle X-ray scattering (SAXS) of D135 reveal rapid initial compaction. Unexpectedly, slower increases in Rg value and forward scattering were observed and shown to result from dimerization of the ribozyme. Dimerization was also observed with native electrophoretic mobility shift assays. Here, I have characterized the dimerization process at various conditions. Dimerization requires Mg2+, with similar concentration dependence as tertiary folding, and the dimer is efficiently disrupted by the ATP-dependent activity of DEAD-box proteins. Dimerization does not affect ribozyme catalysis, as both the monomer and the dimer are shown to be fully active. Further experiments showed that dimerization results from duplex formation by an artificial 3’ tail that has extensive self-complementarity, as the deletion of this tail ablates dimerization. Constructs lacking this artificial 3’ tail are likely to simplify further study of the folding process of this ribozyme. / text Group II intron ribozyme Dimerization
2	Structural investigations of the group II intron-encoded protein GsI-IIC Rubinson, Max Edward 08 October 2013 (has links) Group II introns are a class of mobile ribozymes found in bacteria and eukaryotic organelles that self-splice from precursor RNAs. The resulting lariat intron RNA can then insert into new genomic DNA sites through a reverse splicing reaction. Collectively, this process of intron mobility is termed “retrohoming.” Mobile group II introns encode a reverse transcriptase (RT) that stabilizes the catalytically active form of the intron RNA for both the forward and reverse splicing reactions and also converts the integrated intron RNA into DNA. This work aims to elucidate the structure of bacterial group II intron-encoded RTs and ultimately determine how they function in intron mobility. Although efforts to crystallize group II introns RTs have been unsuccessful, small angle X-ray scattering studies in conjunction with homology modeling have provided new insights into the structure and function of these enzymes. / text Group II intron Reverse transcriptase SAXS
3	Structure and conformational rearrangements during splicing of the ribozyme component of group II introns Li, Cheng-Fang 27 June 2011 (has links) (PDF) Les introns de groupe II forment une classe d'ARN connus avant tout pour leur activité ribozymique, qui leur permet de catalyser leur propre réaction d'épissage. Sous certaines conditions, ces introns peuvent s'exciser des ARN précurseurs dont ils font partie et assurer la ligation des exons qui les bordent sans l'aide d'aucune protéine. Les introns de groupe II sont généralement excisés sous forme d'un lariat, semblable à celui formé par les introns des prémessagers nucléaires, dont l'épissage est assurée par le spliceosome. De telles similarités dans le mécanisme d'épissage suggèrent que les introns de groupe II et les introns des prémessagers nucléaires pourraient avoir un ancêtre évolutif commun.Malgré leurs séquences très diverses, les introns de groupe II peuvent être définis par une structure secondaire commune, hautement conservée. Celle-ci est formée de six domaines (domaine I à domaine VI ; D1-D6), émergeant d'une roue centrale. L'épissage des introns de groupe II comprend deux étapes, et autant de réactions de transestérification, qui produisent les exons liés et l'intron excisé sous forme lariat. Il est généralement admis que la structure du ribozyme subit des changements conformationnels entre les deux étapes de l'épissage et que le domaine VI est un acteur clé dans ce phénomène. Cependant, malgré l'identification d'un certain nombre d'interactions tertiaires entre domaines, ni la RMN, ni les études faisant appel à des modifications chimiques ne sont parvenues à déterminer l'environnement immédiat, au niveau du site actif du ribozyme, de l'adénosine qui sert de point de branchement de la structure en lariat, ainsi que des nucléotides qui entourent cette adénosine au sein du domaine VI. A l'aide d'analyses phylogénétiques et d'une modélisation moléculaire tridimensionnelle, nous avons identifié plusieurs sections du ribozyme susceptibles de constituer le site de fixation du domaine VI au cours de l'étape de branchement. Des mutations ont été introduites dans ces sites de fixation potentiels et la cinétique de réaction des ARN mutants résultants a été déterminée. Afin de démontrer formellement l'interaction du domaine VI avec le site récepteur le plus probable, une molécule de ribozyme dont la réaction de branchement est assurée par l'addition d'oligonucléotides ADN ou ARN qui positionnent correctement le domaine VI vis-à-vis de son partenaire a été construite. En combinant l'information apportée par différentes expériences de ce type, nous avons pu générer un modèle à résolution atomique du complexe formé par le domaine VI, son site de branchement et le reste de l'intron au moment où l'épissage est initié. Group II intron Ribozyme structure Conformational rearrangements Docking site of DVI
4	RNA and DNA Inactivation Strategies to Prevent or Inhibit HIV-1 Replication via Gene Therapy Nazari, Reza 20 January 2009 (has links) AIDS is caused by a lentivirus, HIV-1. In addition to antiretroviral drugs that are currently in use for HIV/AIDS therapy, a number of gene therapy strategies have been designed as alternative therapies. Most of these therapies target HIV RNA/proteins, which are subject to high rate of mutation, resulting in escape mutants. Viral entry is mediated by CCR5 co-receptor in most routes of transmission. To downregulate CCR5 as a gene therapy approach, we targeted seven unique sites within the CCR5 mRNA by a multimeric hammerhead ribozyme, Rz1-7. Hammerhead ribozyme is a small RNA that cleaves a target RNA upon binding to it. Expressing the Rz1-7 from HIV-1- and MSCV-based vectors in otherwise susceptible cells inhibited replication of a CCR5-tropic strain of HIV-1 by 99-100%. The Rz1-7 will be tested for inhibition of HIV-1 replication in the CD4+ T-lymphoid and myeloid progeny of transduced human CD34+ hematopoietic progenitor stem cells. It may be preferable to interfere HIV-1 life cycle at the DNA level since a one-time inactivation might suffice to confer a complete and permanent inhibition of virus replication in the gene modified cells and their progeny. This is what other strategies that target the HIV-1 RNA/protein can hardly offer. For this purpose, group II introns, which are able to splice out and get incorporated into a specific DNA sequence, can be designed/modified to gain novel DNA targeting specificities. As a novel approach, we have examined whether insertion of a modified intron into an infectious HIV-1 clone at two sites within the integrase domain of HIV-1 pol gene could inhibit virus replication. Intron insertion into the HIV-1 clone was induced and mammalian cells were transfected with intron-inserted HIV-1 clones. Although similar amounts of HIV-1 RNA, protein, and progeny virus were produced from the clones as from wild-type HIV-1 provirus DNA, in the absence of a functional integrase, the HIV-1 reverse-transcribed DNA failed to integrate and virus replication was aborted. These results demonstrate that modified group II introns can confer complete inhibition of virus replication at the level of second round of infection. We are now developing vectors to assess whether intron insertion can take place in mammalian cells. HIV-1 gene therapy Interfering RNA CCR5 co-receptor Integrase Hammerhead ribozyme Group II intron 0307
5	RNA and DNA Inactivation Strategies to Prevent or Inhibit HIV-1 Replication via Gene Therapy Nazari, Reza 20 January 2009 (has links) AIDS is caused by a lentivirus, HIV-1. In addition to antiretroviral drugs that are currently in use for HIV/AIDS therapy, a number of gene therapy strategies have been designed as alternative therapies. Most of these therapies target HIV RNA/proteins, which are subject to high rate of mutation, resulting in escape mutants. Viral entry is mediated by CCR5 co-receptor in most routes of transmission. To downregulate CCR5 as a gene therapy approach, we targeted seven unique sites within the CCR5 mRNA by a multimeric hammerhead ribozyme, Rz1-7. Hammerhead ribozyme is a small RNA that cleaves a target RNA upon binding to it. Expressing the Rz1-7 from HIV-1- and MSCV-based vectors in otherwise susceptible cells inhibited replication of a CCR5-tropic strain of HIV-1 by 99-100%. The Rz1-7 will be tested for inhibition of HIV-1 replication in the CD4+ T-lymphoid and myeloid progeny of transduced human CD34+ hematopoietic progenitor stem cells. It may be preferable to interfere HIV-1 life cycle at the DNA level since a one-time inactivation might suffice to confer a complete and permanent inhibition of virus replication in the gene modified cells and their progeny. This is what other strategies that target the HIV-1 RNA/protein can hardly offer. For this purpose, group II introns, which are able to splice out and get incorporated into a specific DNA sequence, can be designed/modified to gain novel DNA targeting specificities. As a novel approach, we have examined whether insertion of a modified intron into an infectious HIV-1 clone at two sites within the integrase domain of HIV-1 pol gene could inhibit virus replication. Intron insertion into the HIV-1 clone was induced and mammalian cells were transfected with intron-inserted HIV-1 clones. Although similar amounts of HIV-1 RNA, protein, and progeny virus were produced from the clones as from wild-type HIV-1 provirus DNA, in the absence of a functional integrase, the HIV-1 reverse-transcribed DNA failed to integrate and virus replication was aborted. These results demonstrate that modified group II introns can confer complete inhibition of virus replication at the level of second round of infection. We are now developing vectors to assess whether intron insertion can take place in mammalian cells. HIV-1 gene therapy Interfering RNA CCR5 co-receptor Integrase Hammerhead ribozyme Group II intron 0307
6	Characterization of the Group II Intron Gs. Int1 from the Thermophilic Bacterium <em>Geobacillus stearothermophilus</em>. Sun, Huijing 14 August 2007 (has links) (PDF) Group II Introns are small segments of DNA that reside in the chromosome of bacteria or the organelles of primitive eukaryotes. These elements have some very interesting properties. First, they are retrotransposons that can move from one location to a new location in DNA via a reverse transcription mechanism. Second, they form a large ribozyme that mediates self-splicing of the intron from pre-mRNA. A Group II Intron type protein with similarity to reverse transcriptase was discovered in the thermophilic bacterium Geobacillus stearothermophilus strain 10 (Vellore et al., 2004, Appl. Environ. Microbiol. 70: 7140-7147). Numerous copies of the intron, designated Gs. Int1, are present in the chromosome of strain 10 but absent from a related strain ATCC 12980. Experiments to detect the in vivo splicing of intron Gs.Int1 from G. stearothermophilus cells did not work. Plasmids to that will over-express the Gs. Int1 intron to detest splicing in vivo in Escherichia coli have been constructed. Group II Intron Geobacillus stearothermophilus Thermophilic bacterium Genetics and Genomics Life Sciences Molecular Genetics
7	Molecular epidemiology of streptococcus agalactiae : mobile elements as genetic markers. Luan, Shi-Lu January 2006 (has links) <p>Streptococcus agalactiae, also designated group B streptococcus (GBS), is a Gram-positive coccus, and it is an important pathogen that causes invasive disease in neonates, pregnant adults, and non-pregnant adults with predisposing conditions. The group II intron GBSi1 is one of the major mobile genetic elements identified in S. agalactiae. The aim of this thesis was to characterize the GBSi1 distribution pattern, the population structure, and the influence of serotype- and clone-specific properties on the invasive capacity among clinical invasive and non-invasive isolates of S. agalactiae.</p><p>Two additional copies of GBSi1 were identified at sites different from the primarily identified scpB-lmb locus. The distribution of GBSi1 was uneven among different serotypes. Three intron copies were only found in isolates of serotype III, and these targeted all the three identified gene loci. In contrast, a single copy of GBSi1 was found in isolates of serotype II and V and only located at the scpB-lmb locus. Furthermore, at the 5′ flanking region of the scpB-lmb gene locus, a novel 2.1 kb DNA fragment with plasmid features was identified only in intron carrying isolates. This may suggest that GBSi1 once was brought into the S. agalactiae genome by an integrated plasmid.</p><p>Multilocus sequence typing was used to characterize totally 314 invasive and non-invasive S. agalactiae isolates collected in Northern and Western Sweden from the years 1988 to 2004. Five major genetic lineages (clonal complexes) were identified among both invasive and non-invasive isolates, including serotype Ia, Ib, and II to V, indicating a clonal population structure of S. agalactiae isolates. A number of genetically highly related isolates were found to express different capsular types, suggesting that capsule switching occurs rather frequently between isolates. Furthermore, non-invasive isolates belonging to the same clonal complexes displayed more heterogeneity in capsule expression as well as in the distribution patterns of mobile genetic elements than invasive isolates. This indicates that less variability is allowed in a highly selective environment such as the blood. All major clonal complexes and serotypes caused invasive disease, although their ability to do so varied greatly. CC17 was significantly associated with neonatal invasive disease; whereas CC19 was equally common among isolates from adult and neonatal disease, despite that both CC17 and CC19 expressed capsular type III. This striking difference seen between CC17 and CC19 suggests that clonal complex associated properties, in addition to capsular type, play important roles in the virulence of S. agalactiae. CC1, a new emerging clone since early 1990s, has caused substantial amount of disease among adults. In addition, mutually exclusive distribution of mobile elements GBSi1 and IS1548 was seen, and they were shown to constitute genetic markers for serotype III CC17 and CC19 isolates, respectively.</p> Streptococcus agalactiae group II intron (GBSi1) multilocus sequence typing capsular serotype population structure Clinical bacteriology Klinisk bakteriologi
8	Molecular epidemiology of streptococcus agalactiae : mobile elements as genetic markers. Luan, Shi-Lu January 2006 (has links) Streptococcus agalactiae, also designated group B streptococcus (GBS), is a Gram-positive coccus, and it is an important pathogen that causes invasive disease in neonates, pregnant adults, and non-pregnant adults with predisposing conditions. The group II intron GBSi1 is one of the major mobile genetic elements identified in S. agalactiae. The aim of this thesis was to characterize the GBSi1 distribution pattern, the population structure, and the influence of serotype- and clone-specific properties on the invasive capacity among clinical invasive and non-invasive isolates of S. agalactiae. Two additional copies of GBSi1 were identified at sites different from the primarily identified scpB-lmb locus. The distribution of GBSi1 was uneven among different serotypes. Three intron copies were only found in isolates of serotype III, and these targeted all the three identified gene loci. In contrast, a single copy of GBSi1 was found in isolates of serotype II and V and only located at the scpB-lmb locus. Furthermore, at the 5′ flanking region of the scpB-lmb gene locus, a novel 2.1 kb DNA fragment with plasmid features was identified only in intron carrying isolates. This may suggest that GBSi1 once was brought into the S. agalactiae genome by an integrated plasmid. Multilocus sequence typing was used to characterize totally 314 invasive and non-invasive S. agalactiae isolates collected in Northern and Western Sweden from the years 1988 to 2004. Five major genetic lineages (clonal complexes) were identified among both invasive and non-invasive isolates, including serotype Ia, Ib, and II to V, indicating a clonal population structure of S. agalactiae isolates. A number of genetically highly related isolates were found to express different capsular types, suggesting that capsule switching occurs rather frequently between isolates. Furthermore, non-invasive isolates belonging to the same clonal complexes displayed more heterogeneity in capsule expression as well as in the distribution patterns of mobile genetic elements than invasive isolates. This indicates that less variability is allowed in a highly selective environment such as the blood. All major clonal complexes and serotypes caused invasive disease, although their ability to do so varied greatly. CC17 was significantly associated with neonatal invasive disease; whereas CC19 was equally common among isolates from adult and neonatal disease, despite that both CC17 and CC19 expressed capsular type III. This striking difference seen between CC17 and CC19 suggests that clonal complex associated properties, in addition to capsular type, play important roles in the virulence of S. agalactiae. CC1, a new emerging clone since early 1990s, has caused substantial amount of disease among adults. In addition, mutually exclusive distribution of mobile elements GBSi1 and IS1548 was seen, and they were shown to constitute genetic markers for serotype III CC17 and CC19 isolates, respectively. Streptococcus agalactiae group II intron (GBSi1) multilocus sequence typing capsular serotype population structure Clinical bacteriology Klinisk bakteriologi
9	A survey of blue-stain fungi in Northwestern Ontario and characterization of mobile introns in ribosomal DNA Rudski, Shelly Marie 02 September 2011 (has links) This work presents a survey of blue-stain fungi found in Northwestern Ontario, characterization of a homing endonuclease gene within Grosmannia piceiperda and finally an examination of the introns and homing endonuclease genes found in the large ribosomal subunit gene in species of Ceratocystis; using molecular techniques and phylogenetic analysis, we studied the molecular evolution of these mobile genetic elements. The blue-stain fungi of Northwestern Ontario were identified based on phylogenic analysis of rDNA internal transcribed spacer region sequences. This data was supplemented with morphological characteristics of the fungal cultures. The second project was an examination of a LAGLIDADG homing endonuclease and its IC2 group I intron. This intron is uniquely positioned within the group I intron-encoded rps3 gene of the large subunit ribosomal RNA gene. The final chapter is an investigation of the large subunit ribosomal RNA gene in species of Ceratocystis. The 3’ segment of this gene contains several novel introns and homing endonuclease genes. There is also much diversity between strains despite their close relation on the rDNA internal transcribed spacer region phylogenetic tree. Further, our data also suggest that the single motif LAGLIDADG homing endonuclease of the rDNA mL1923 intron is likely to be an ancestor to other homing endonucleases in the area. The results of these studies demonstrate the role that these elements play in the genetic diversity observed in the blue-stain fungi. group I intron group II intron homing endonuclease gene LAGLIDADG GIY-YIG ophiostomatoid fungi blue-stain fungi
10	A survey of blue-stain fungi in Northwestern Ontario and characterization of mobile introns in ribosomal DNA Rudski, Shelly Marie 02 September 2011 (has links) This work presents a survey of blue-stain fungi found in Northwestern Ontario, characterization of a homing endonuclease gene within Grosmannia piceiperda and finally an examination of the introns and homing endonuclease genes found in the large ribosomal subunit gene in species of Ceratocystis; using molecular techniques and phylogenetic analysis, we studied the molecular evolution of these mobile genetic elements. The blue-stain fungi of Northwestern Ontario were identified based on phylogenic analysis of rDNA internal transcribed spacer region sequences. This data was supplemented with morphological characteristics of the fungal cultures. The second project was an examination of a LAGLIDADG homing endonuclease and its IC2 group I intron. This intron is uniquely positioned within the group I intron-encoded rps3 gene of the large subunit ribosomal RNA gene. The final chapter is an investigation of the large subunit ribosomal RNA gene in species of Ceratocystis. The 3’ segment of this gene contains several novel introns and homing endonuclease genes. There is also much diversity between strains despite their close relation on the rDNA internal transcribed spacer region phylogenetic tree. Further, our data also suggest that the single motif LAGLIDADG homing endonuclease of the rDNA mL1923 intron is likely to be an ancestor to other homing endonucleases in the area. The results of these studies demonstrate the role that these elements play in the genetic diversity observed in the blue-stain fungi. group I intron group II intron homing endonuclease gene LAGLIDADG GIY-YIG ophiostomatoid fungi blue-stain fungi

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