Global ETD Search

1	The C-terminal DNA endonuclease region and biotechnology applications of a group II intron reverse transcriptase from Thermosynechoccus elongatus Smith, Whitney Gail 28 September 2011 (has links) Group II introns insert site-specifically into DNA target sites through a process termed retrohoming. They consist of a structured, catalytically active intron RNA and its encoded protein. The protein contains several domains, including a reverse transcriptase domain and a DNA endonuclease domain used for bottom-strand cleavage. Recently, the thermophile Thermosynechococcus elongatus BP-1 was found to contain eight functional group II intron-encoded proteins. The proteins are thermostable and active at temperatures up to 65°C. The intron-encoded protein, TeI4c displays the greatest reverse transcriptase activity of these eight proteins, as well as high fidelity and processivity; ideal qualities for a commercial reverse transcriptase. This work explores the possibility of using TeI4c for biotechnology applications, and specifically examines the C-terminal endonuclease domain of TeI4c and its effect on reverse transcription. Additionally, this work investigates the retrohoming activity of a TeI4c truncation that deletes the endonuclease domain. / text Group II introns Thermosynechoccus elongatus
2	DNA target site recognition by the Ll.LtrB group II intron RNP Whitt, Jacob Tinsley 07 November 2011 (has links) Mobile group II introns are retroelements that site-specifically insert into DNA target sequences. The group II intron mobility pathway is mediated by a ribonucleoprotein particle (RNP) composed of excised intron RNA and an intron-encoded protein (IEP). The intron lariat inserts at a specific DNA target sequence and is then reverse transcribed by the IEP. Both the intron RNA and IEP are required for DNA target site recognition. I have identified the contact sites within the IEP responsible for recognition of two key positions in the DNA target, T+5 and T-23. IEP recognition of T+5 in the 3'-exon is required for endonuclease cleavage of the bottom-strand of the DNA target site, which generates a primer used for initiation of reverse transcription of the intron. The T+5 base is contacted by G498 in the LtrA DNA-binding domain and nearby residues, particularly K499, potentially bolster this interaction. Recognition of T-23 in the distal 5'-exon is required for initial recognition of the DNA target site by the RNP. The T533 side-chain contacts the T-23 base and the L534 side-chain may also contribute to recognition through hydrophobic interactions with the C5 methyl group. A mutant, L534H, that switches target site specificity to T-23G has been characterized. In order for the RNP to make these and other contacts in the 5'- and 3'-exons simultaneously, the DNA must be bent. I have dissected the role of DNA bending in the intron mobility pathway and found that the DNA is bent at two progressively larger angles as the reaction proceeds. The predominant bend angle at earlier time points places the bottom-strand DNA cleavage site at the protein endonuclease active site. The predominant bend angle of later time points places the cleaved DNA site at the RT domain active site for initiation of reverse transcription of intron cDNA. Finally, in a practical application of group II intron mobility, I have used reprogrammed group II introns ("targetrons") to target two genes in Bacillus subtilis to demonstrate the suitability of targetron technology for gene targeting in the Gram-positive Bacillus genus. / text Group II introns Catalytic RNA DNA recognition
3	Group II intron mobility and its gene targeting applications in prokaryotes and eukaryotes Zhuang, Fanglei 23 October 2009 (has links) Mobile group II introns are retroelements that insert site-specifically into DNA target sites by a process called retrohoming. Retrohoming is mediated by a ribonucleoprotein particle (RNP) that contains both the intron RNA and the intronencoded protein (IEP). My dissertation focuses on two mobile group II introns: Lactococcus lactis Ll.LtrB and Escherichia coli EcI5, which belong to structural subclasses IIA and CL/IIB1, respectively. Previous studies showed that the Ll.LtrB IEP, denoted LtrA protein, is pole localized in E. coli. First, I found that active LtrA protein is associated with E. coli membrane fractions, suggesting that LtrA pole localization might reflect association with a membrane receptor. Second, I found that EcI5 is highly active in retrohoming in E. coli and obtained a comprehensive view of its DNA target site recognition by selection experiments. I found that EcI5 recognizes DNA target sequences by using both the IEP and base pairing of the intron RNA, with the IEP having different target specificity than for other mobile group II introns. A computer algorithm based on the empirically determined DNA recognition rules enabled retargeting of EcI5 to integrate at ten different sites in the chromosomal lacZ gene at frequencies up to 98% without selection. Finally, I developed methods for gene targeting in the frog Xenopus laevis by using Ll.LtrB RNPs for site-specific DNA modification in isolated sperm nuclei, followed by in vitro fertilization to generate genetically modified animals. The site-specific integrations were efficient enough to detect in fifty sperm nuclei for a multiple copy target site, the Tx1 transposon, and several hundred sperm nuclei for protein-encoding genes. Based on these results, I obtained transgenic tadpoles with sitespecific Tx1 integrations by simple screening. To facilitate screening for embryos with targeted integrations in protein-encoding genes, I constructed an intron carrying a GFPRAM (Retrotransposition-Activated Marker). By using this GFP-RAM with introns containing randomized sequences that base pair with the target DNA, I obtained tadpoles with intron integrations at different genomic locations, including protein-encoding genes. The methods for using group II introns for targeted sperm DNA modification in X. laevis may be applicable to other animals. / text Mobile group II introns Lactococcus lactis Escherichia coli Retrohoming
4	Toward group II intron-based genome targeting in eukaryotic cells Vernon, Jamie Lee 02 June 2010 (has links) Mobile group II introns consist of a self-splicing RNA molecule and an intron-encoded protein with reverse transcriptase activity that function together in an RNP and catalyze the insertion of the intron into specific DNA target sites by a process known as retrohoming. The mechanism of insertion requires the intron RNA to bind and reverse splice into one strand of the DNA target site, while the intron-associated protein cleaves the opposite DNA strand and reverse transcribes the intron RNA. DNA target site recognition and binding are dependent upon base pairing between the intron RNA and the target DNA molecule. By modifying the recognition sequences in the intron RNA, group II introns can be engineered to insert into virtually any desired target DNA. Based on this technology, a novel class of commercially available group II intron-based gene targeting vectors, called targetrons, has been developed. Targetrons have been used successfully for gene targeting in a broad range of bacteria. Previously, our laboratory demonstrated that group II introns retain controllable retrohoming activity in mammalian cells, albeit with very low targeting efficiency. However, the gene targeting capability of group II introns is not limited to direct insertion of the intron. Group II introns can also create double-strand breaks that stimulate homologous recombination. By virtue of these attributes, mobile group II introns offer great promise for applications in genetic engineering, functional genomics and gene therapy. Here I present the results of experiments in which I tested group II introns for gene targeting activities in eukaryotic cells. First, I demonstrated that group II introns injected into zebrafish (Danio rerio) embryos retain in vivo plasmid targeting activity that is enhanced by the addition of magnesium chloride and deoxynucleotides. I also verified that similar in vivo targeting activity is retained in Drosophila melanogaster embryos. Further, I describe repeated experiments in zebrafish embryos designed to target the zebrafish genome with inconclusive results. Group II introns were also delivered to cultured human cells for genome targeting. Here I present promising evidence for the ability of group II introns to stimulate homologous recombination between an exogenously introduced donor DNA molecule and the chromosome. The donor DNA was delivered either as a linearized double-stranded plasmid by electroporation or as a single stranded genome of a recombinant adeno-associated virus (AAV). In both cases, cells receiving both the group II intron RNP and the donor DNA showed more efficient integration of the donor DNA than introduction of the donor DNA alone. The studies presented here provide insight into the potential of using group II introns for future applications in gene targeting in eukaryotes. / text Gene targeting Genome targeting Group II introns Eukaryotic cells
5	Group II intron thermophilic reverse transcriptases Voina, Natasha J. January 2011 (has links) A reverse transcription reaction allows the production of complementary DNA (cDNA) using an RNA template and relies on polymerases displaying reverse transcriptase (RT) activity. This process, with major applications in both research and in medical diagnostics, is often limited by the nature of the RTs available. RNA secondary structure can prove problematic where mesophilic retroviral RTs are used while the alternative approach, using thermophilic DNA polymerases with RT activity, often results in error-prone cDNA production. <br /> This project recognised the need to study other possible sources of thermophilic RTs and outlines the study of four previously uncharacterised Group II Intronencoded proteins (IEP), with RT domains, from thermophilic bacteria. While cloning of the IEP genes and their expression on a small scale proved successful, difficulties were encountered when attempting purification. Despite a lack of overall purity, samples containing IEPs from Thermosinus carboxydivorans and Petrotoga mobilis were shown to have RT activity but characterisation of these IEPs was not carried out. However, an IEP from Bacillus caldovelox proved to be an excellent candidate for characterisation as successful purification was achieved. Enzyme engineering was also performed, fusing a Sac7d domain onto the C-terminus of this protein. These enzymes were shown to have optimum RT activity at 54ºC with activity still being displayed at 76ºC. Other studies on these enzymes showed that, unlike the retroviral RTs, the IEPs displayed no DNA-dependent DNA polymerase activity. The Sac7d fusion protein was also studied in terms of possible enhancements to the RT activity of an IEP. However, preliminary studies showed that, although this domain did not prove to be detrimental to the enzyme, it had little effect on improving the processivity of the RTs. <br /> Although this class of RT looks promising in terms of use as an alternative thermophilic RT, the IEPs studied in this report did incur major limitations during cDNA synthesis, which included lower than expected optimum reaction temperatures, very low fidelity and an inability to synthesise cDNA using complex RNA templates. 572.7
6	Group II intron and gene targeting reactions in Drosophila melanogaster White, Travis Brandon 10 January 2013 (has links) Mobile group II introns are retroelements that insert site-specifically into double-stranded DNA sites by a process called retrohoming. Retrohoming activity rests in a ribonucleoprotein (RNP) complex that contains an intron-encoded protein (IEP) and the excised intron RNA. The intron RNA uses its ribozyme activity to reverse splice into the top strand of the DNA target site, while the IEP cleaves the bottom DNA strand and reverse transcribes the inserted intron. My dissertation focuses on the Lactococcus lactis Ll.LtrB group II intron and its IEP, denoted LtrA. First, I investigated the ability of microinjected Ll.LtrB RNPs to retrohome into plasmid target sites in Drosophila melanogaster precellular blastoderm stage embryos. I found that injection of extra Mg2+ into the embryo was crucial for efficient retrohoming. Next, I compared retrohoming of linear and lariat forms of the intron RNP. Unlike lariat RNPs, retrohoming products of linear intron RNPs displayed heterogeneity at the 5’-intron insertion junction, including 5’-exon resection, intron truncation, and/or repair at regions of microhomology. To investigate whether these junctions result from cDNA ligation by non-homologous end-joining (NHEJ), I analyzed retrohoming of linear and lariat intron RNPs in D. melanogaster embryos with null mutations in the NHEJ genes lig4 and ku70, as well as the DNA repair polymerase polQ. I found that null mutations in each gene decreased retrohoming of linear compared to lariat intron RNPs. To determine whether novel activities of the LtrA protein contributed to the linear intron retrohoming 5’ junctions, I assayed the polymerase, non-templated nucleotide addition and template-switching activities of LtrA on oligonucleotide substrates mimicking the 5’-intron insertion junction in vitro. Although LtrA efficiently template switched to 5’-exon DNA substrates, the junctions produced differed from those observed in vivo, indicating that template switching is not a significant alternative to NHEJ in vivo. Finally, I designed and constructed retargeted Ll.LtrB RNPs to site-specifically insert into endogenous chromosomal DNA sites in D. melanogaster. I obtained intron integration efficiencies into chromosomal targets up to 0.4% in embryos and 0.021% in adult flies. These studies expand the utility of group II intron RNPs as gene targeting tools in model eukaryotic organisms. / text Catalytic RNA Group II introns Reverse transcriptases Gene targeting Drosophila
7	DNA target site recognition and toward gene targeting in mammalian cells by the Ll.LtrB group II intron RNP Hanson, Joseph Haskell 06 November 2013 (has links) Mobile group II introns insert site-specifically into DNA target sites through a mechanism ("retrohoming") that involves reverse splicing of the intron RNA into the DNA and its subsequent reverse transcription by an intron-encoded protein (IEP) that is associated with the RNA in a ribonucleoprotein (RNP) complex. Characterization of this RNP complex and its retrohoming activities have enabled the development of programmable mobile group II intron gene targeting vectors routinely used in prokaryotic organisms. Building upon recent research by our lab to develop gene targeting in Xenopus laevis and Drosophila melanogaster using the group II intron Ll.LtrB from Lactococcus lactis, I describe work to extend this system to mammalian cells. I demonstrate that group II intron RNPs can be delivered to mammalian cells efficiently and produced in vivo via a CMV/T7 hybrid expression system. Using a robust single-strand annealing assay to detect homologous recombination induced by double-strand breaks (DSBs), I found that group II intron-mediated DSBs are efficiently repaired by mammalian cells. Despite varied approaches, I failed to detect endogenous group II intron-mediated gene targeting in human and mouse cells in culture. Gene expression microarray analysis and in vivo imaging of RNP molecules indicated that group II intron RNPs are sequestered away from the genome and induce host innate immune responses. I also investigated how the C-terminal DNA-binding domain of the Ll.LtrB IEP contributes to DNA target site recognition. Building upon previous mass spectrophotometric analysis of site-specific UV-crosslinking, I used genetic and biochemical analyses to identify potential protein contacts for key target site residues T-23 and T+5. Genetic selection of mutants in a region contacting T+5 led to identification of LtrA variants with increased retrohoming efficiency. My results provide evidence that the DNA-binding domain of a group II intron reverse transcriptase functions in DNA target site recognition and suggest new methods for changing its DNA target specificity and targeting efficiency. / text Genetics Biochemistry Group II introns Gene targeting RNA biology
8	Functions of organelle-specific nucleic acid binding protein families in chloroplast gene expression Prikryl, Jana, 1976- 12 1900 (has links) xii, 83 p. : ill. A print copy of this thesis is available through the UO Libraries. Search the library catalog for the location and call number. / My dissertation research has centered on understanding how nuclear encoded proteins affect chloroplast gene expression in higher plants. I investigated the functions of three proteins that belong to families whose members function solely or primarily in mitochondrial and chloroplast gene expression; the Whirly family (ZmWHY1) and the pentatricopeptide repeat (PPR) family (ZmPPR5 and ZmPPR10). The Whirly family is a plant specific protein family whose members have been described as nuclear DNA-binding proteins involved in transcription and telomere maintenance. I have shown that ZmWHY1 is localized to the chloroplast where it binds nonspecifically to DNA and also binds specifically to the atpF group II intron RNA. Why1 mutants show reduced atpF intron splicing suggesting that WHY1 is directly involved in atpF RNA maturation. Why1 mutants also have aberrant 23S rRNA metabolism resulting in a lack of plastid ribosomes. The PPR protein family is found in all eukaryotes but is greatly expanded in land plants. Most PPR proteins are predicted to localize to the mitochondria or chloroplasts where they are involved in many RNA-related processes including splicing, cleavage, editing, stabilization and translational control. Our results with PPR5 and PPR10 suggest that most of these activities may result directly from the unusually long RNA binding surface predicted for PPR proteins, which we have shown imparts two biochemical properties: site-specific protection of RNA from other proteins and site-specific RNA unfolding activity. I narrowed down the binding site for PPR5 and PPR10 to ∼45 nt and 19 nt, respectively. I showed that PPR5 contributes to the splicing of its group II intron ligand by restructuring sequences that are important for splicing. I used in vitro assays with purified PPR10 to confirm that PPR10 can block exonucleolytic RNA decay from both the 5' and 3' directions, as predicted by prior in vivo data. I also present evidence that PPR10 promotes translation by restructuring its RNA ligand to allow access to the ribosome. These findings illustrate how the unusually long RNA interaction surface predicted for PPR proteins can have diverse effects on RNA metabolism. This dissertation includes both previously published and unpublished co-authored material. / Committee in charge: Eric Selker, Chairperson, Biology; Alice Barkan, Advisor, Biology; Victoria Herman, Member, Biology; Karen Guillemin, Member, Biology; J. Andrew Berglund, Outside Member, Chemistry Nucleic acid binding protein Chloroplast Gene expression Pentotricopeptide repats Group II introns Molecular biology Plant biology Biochemistry
9	Biochemical characterization of homing endonucleases encoded by fungal mitochondrial genomes Guha, Tuhin 23 May 2014 (has links) The small ribosomal subunit gene of the Chaetomium thermophilum DSM 1495 is invaded by a nested intron at position mS1247, which is composed of a group I intron encoding a LAGLIDADG open reading frame interrupted by an internal group II intron. The first objective was to examine if splicing of the internal intron could reconstitute the coding regions and facilitate the expression of an active homing endonuclease. Using in vitro transcription assays, the group II intron was shown to self-splice only under high salt concentration. Both in vitro endonuclease and cleavage mapping assays suggested that the nested intron encodes an active homing endonuclease which cleaves near the intron insertion site. This composite arrangement hinted that the group II intron could be regulatory with regards to the expression of the homing endonuclease. Constructs were generated where the codon-optimized open reading frame was interrupted with group IIA1 or IIB introns. The concentration of the magnesium in the media sufficient for splicing was determined by the Reverse Transcriptase-Polymerase Chain Reaction analyses from the bacterial cells grown under various magnesium concentrations. Further, the in vivo endonuclease assay showed that magnesium chloride stimulated the expression of a functional protein but the addition of cobalt chloride to the growth media antagonized the expression. This study showed that the homing endonuclease expression in Escherichia coli can be regulated by manipulating the splicing efficiency of the group II introns which may have implications in genome engineering as potential ‘on/off switch’ for temporal regulation of homing endonuclease expression . Another objective was to characterize native homing endonucleases, cytb.i3ORF and I-OmiI encoded within fungal mitochondrial DNAs, which were difficult to express and purify. For these, an alternative approach was used where two compatible plasmids, HEase.pET28b (+)-kanamycin and substrate.pUC57-chloramphenicol, based on the antibiotic markers were maintained in Escherichia coli BL21 (DE3). The in vivo endonuclease assays demonstrated that these homing endonucleases were able to cleave the substrate plasmids when expressed, leading to the loss of the antibiotic markers and thereby providing an indirect approach to screen for potential active homing endonucleases before one invests effort into optimizing protein overexpression and purification strategies. / October 2016 Homing endonucleases Small ribosomal subunit gene Nested intron Twintron Ribozyme based molecular switch Group I introns Group II introns Bioprospecting Native homing endonuclease Temporal regulation Fungal mitochondrial DNA Magnesium induction Cobalt antagonization DNA cutting enzymes LAGLIDADG homing endonuclease Splicing Genome engineering

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