Příprava prasečích indukovaných pluripotentních kmenových buněk - model Huntingtonovy choroby. / Generation of porcine induced pluripotent stem cells - a model of Huntington disease.

Svobodová, Eliška

January 2013

Stable porcine ES cell lines have not been succesfully established yet. Ability to selfrenew or to differentiate has been limited in different porcine ES-like cell lines so far. PiPSCs represent an alternative to pESCs. PiPSCs can be generated by reprogramming of somatic cells by introduction of several transcription factors on viral vectors and were established by several groups. However, the majority of piPS cell lines depend on transgene expression because of incomplete reprogramming and weak activation of endogenous pluripotency genes. Transgene expression can infuence differentiation potential of piPSCs. Therefore, we have used integrative and reexcisable PiggyBac transposons to generate viral free piPSCs. At the same time, small molecules (low-molecular inhibitors) with potential to increase reprogramming efficiency and to activate endogenous pluripotency genes were used in the reprogramming media. This strategy has a potential for generation of naive piPSCs. Successful excision of transgenes would generate transgene-free piPSCs with uncompromised differentiation potential. Pig (Sus Scrofa) is at the same time an important animal model in preclinical stage research of the diseases. Somatic cells used for generation of piPSCs were isolated from pigs carrying mutated huntingtin. Integration of the...

Genome engineering and gene drive in the mosquito aedes aegypti

St John, Oliver Tudor Lockhart

January 2012

Genetic control strategies are a novel method for reducing populations of pest insects such as the yellow fever mosquito Aedes aegypti, a major vector of several important arboviral diseases. This thesis describes efforts to develop new tools to engineer the Ae. aegypti genome and to better understand existing tools, and furthermore to use these to engineer a gene drive system in Ae. aegypti. The piggyBac transposon was found to be extremely stable in the germline of Ae. aegypti, and transposons engineered into the germline could not be remobilized with either an endogenous or exogenous source of piggyBac transposase. Conversely, somatic remobilization of piggyBac transposons was found to be readily detectable in the presence of a source of active transposase, the first report of such remobilization in Ae. aegypti. Toward new tools for genome engineering, the site-specific integrase from the phage φC31 was successfully used to promote exchange between a transgene cassette inserted into the genome of Ae. aegypti and a cassette in a plasmid vector, in the first demonstration of recombinase mediated cassette exchange technology in a pest insect species. The integrases from phages φRV1 and Bxb1 were not found to be active in the germline of the mosquito. Finally, development of a gene drive system in Ae. aegypti using an RNAi-mediated killer-rescue mechanism was attempted. Tissue-specific expression of tTAV-regulated-toxic effectors genes, using the promoter regions of the blood meal induced genes Carboxypeptidase A-1, 30Kb and Vitellogenin A, was possible, but sex-specificity was not achieved. A blood meal inducible lethal phenotype was not possible using the chosen promoters, with expression of the effectors either leading to death in early development or to a sublethal phenotype. RNAi against tTAV fused to the Mnp fragment of the dengue virus’ genome was tissue specific, but was found to be highly effective in the fat body suggesting that the Vitellogenin A was the best candidate for the engineering of killer-rescue systems in the mosquito.

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