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

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

Functional conservation and RNA binding of the pre-mRNA splicing factor U2AF65 /

Henscheid, Kristy L.,

January 2007

Thesis (Ph. D.)--University of Oregon, 2007. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 129-141). Also available for download via the World Wide Web; free to University of Oregon users.

The [beta]-tubulin gene as a means to discriminate species and verify evolutionary patterns of arbuscular mycorrhizal fungi

Msiska, Zola.

January 1900

Thesis (Ph. D.)--West Virginia University, 2008. / Title from document title page. Document formatted into pages; contains ix, 138 p. : ill. (some col.). Includes abstract. Includes bibliographical references (p. 105-119).

Using nucleic acids to repair [beta] -globin gene mutations

Kierlin-Duncan, Monique Natasha,

January 2007

Thesis (Ph. D.)--Duke University, 2007.

Identification of nucleus-encoded factors required for group II intron splicing in chloroplasts /

Jenkins, Bethany Diane,

January 2000

Thesis (Ph. D.)--University of Oregon, 2000. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 110-117). Also available for download via the World Wide Web; free to University of Oregon users. Address: http://wwwlib.umi.com/cr/uoregon/fullcit?p9963446.

Splicing signals in Caenorhabditis elegans : candidate exonic splicing enhancer motifs /

Robinson, Robert Maxwell.

January 2005

Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (p. 233-246).

A Different Perspective on the Phylogenetic Relationships of the Moxostomatini (Cypriniformes: Catostomidae) Based on Cytochrome-b and Growth Hormone Intron Sequences

Clements, Mark D., Bart, Henry L., Hurley, David L.

01 April 2012

We have examined phylogenetic relationships of suckers of tribe Moxostomatini (Cypriniformes, Catostomidae) using cytochrome-b and Growth Hormone gene intron sequences. Phylogenies were significantly different from recent estimates of relationships based primarily on morphology (Smith, 1992) and cytochrome-b sequences (Harris et al., 2002). Overall, there was little support for many basal nodes in the phylogeny, however it was clear that Scartomyzon and Moxostoma were not monophyletic, despite morphological evidence provided Robins and Raney (1956, 1957), Jenkins (1970), and Smith (1992). Growth Hormone sequences provided good support for a monophyletic Western Scartomyzon lineage and thus suggested a single ancestral invasion of Scartomyzon-like fishes into drainages of Texas and Mexico. Phylogenetic relationships of Western Scartomyzon are structured geographically and do not conform well to current taxonomy.

Cytochrome-b

evolution

growth hormone

incongruence

introns

phylogenetics

Pharmaceutical Sciences

Exploring the evolution of group II introns using LI.LtrB from Lactococcus lactis as a model system

Belhocine, Z. Kamila.

January 2007

No description available.

Bacterial Proteins -- physiology.

Lactococcus lactis -- genetics.

Trans-Splicing.

Introns.

Characterization of Group I Introns in the Ribosomal RNA Internal Transcribed Spacers of Eight Orders of Sharks

Patil, Veena P.

17 November 2011

No description available.

Molecular Biology

Group I introns

Ribosomal RNA

Internal transcribed spacers

História evolutiva de exon shuffling em eucariotos / Evolutionary history of exon shuffling in eukaryotes

França, Gustavo Starvaggi

11 February 2010

Exon shuffling foi primeiramente proposto por Walter Gilbert em 1978 como um mecanismo em que exons de diferentes genes podem ser combinados, levando à formação de novos genes. O mecanismo de exon shuffling é favorecido por recombinações intrônicas e está correlacionado com a simetria de exons. Evidências deste mecanismo provém de análises de combinações de fases de introns, correlações entre bordas de exons e de domínios protéicos e da recorrência de domínios em diversas proteínas. Dessa forma, a evolução de proteínas formadas por exon shuffling pode ser inferida considerando a organização exon-intron dos genes, o padrão de combinações de fases de introns e a organização de domínios nas proteínas. Neste sentido, regiões protéicas que possivelmente foram originadas por eventos de exon shuffling foram identificadas através de análises em larga escala em diferentes espécies eucarióticas. A estratégia foi baseada no alinhamento entre todas as proteínas anotadas de uma determinada espécie e a verificação da presença de introns e suas respectivas fases em torno das regiões alinhadas. Nós verificamos que eventos de exon shuffling em eucariotos antigos, de origem anterior aos Metazoa, são predominantemente simétricos 0-0, enquanto nos metazoários a predominância é de unidades simétricas 1-1. Esses dados confirmam idéias anteriores de que a transição para a multicelularidade animal foi marcada pelo embaralhamento extensivo de exons e domínios 1-1. O metazoário basal Trichoplax adhaerens pode ser considerado um representante desta transição, evidenciada pelas freqüências balanceadas de regiões simétricas 0-0 e 1-1. O sinal de flanqueamento por introns em torno das bordas de domínios protéicos confirmou os resultados obtidos através dos alinhamentos, com a prevalência de domínios 0-0 em não metazoários e 1-1 em metazaoários. Um agrupamento hierárquico de domínios flanqueados por introns foi construído, permitindo identificar domínios ou grupos de domínios com evidência de expansões em períodos específicos, como nos vertebrados. Por fim, os genes envolvidos em eventos de exon shuffling foram analisados quanto ao enriquecimento em termos do Gene Ontology. Os resultados indicaram que este mecanismo contribuiu significativamente para a formação de genes relacionados com uma grande diversidade de termos, alguns dos quais envolvidos diretamente com características de metazoários e vertebrados, tais como matriz extracelular, adesão, coagulação sangüínea, processos do sistema imune e sistema nervoso / Exon shuffling was first proposed by Walter Gilbert in 1979 as a mechanism in which exons from different genes could be combined to lead the creation of new genes. The mechanism of exon shuffling is favored by intronic recombinations and it is correlated with symmetry of exons. Evidence of this mechanism come from analyses of intron phase combinations, correlations between the borders of exons and domains and domain recurrence in several proteins. Taking this into account, the evolution of proteins formed by exon shuffling can be inferred regarding the exonintron organization of the genes, the pattern of intron phase combinations and the protein domain organization. In this sense, protein regions that were probably arose by exon shuffling events were identified through a large scale analysis in several eukaryotic species. The strategy was based on alignments between all annotated proteins from a given species. Then, the aligned regions were verified in respect with intron phase combinations surrounding them. We have found that exon shuffling events in early eukaryotes are preferentially symmetric of phase 0, while in metazoans, the preference is for 1-1 symmetric units. These data confirms previous ideas that the transition to animal multicellularity was marked by extensive 1-1 exon shuffling. The basal metazoan Trichoplax adhaerens is a representative of this transition, evidenced by the balanced frequencies of 0-0 and 1-1 symmetric regions. The signal of intron flanking around the borders of protein domains corroborated previous analyses, showing that non metazoans have higher frequencies of 0-0 domains and metazoans have higher frequencies of 1-1 domains. A hierarchical clustering of domains flanked by introns was built, allowing us to identify domains or groups of domains with evidence of expansions during specific periods, such as in vertebrates. Finally, genes involved in exon shuffling events were analyzed regarding the Gene Ontology enriched terms. The results indicated that this mechanism significantly contributed to the creation of genes related with a large diversity of terms, some of them are directly involved with features of metazoans and vertebrates, such as extracellular matrix, cell adhesion, blood coagulation and immune and nervous system processes

Domains

Domínios

Evolução

Evolution

Exon shuffling

Exon shuffling

Extracellular matrix

Genoma

Genome

Introns

Introns

Matriz extracelular

Metazoans

Metazoários