Cristina Menchón Najas
Embryonic stem cells (ESC) are derived from the inner cell mass (ICM) of the blastocyst and have the capacity for unlimited proliferation while retaining their potential to differentiate into a wide variety of cell types when cultured in vitro. These properties have made of human embryonic stem cells (hESC) an excellent model on which to study the conditions required for differentiation into specific cell lineages, and consequently the possibility of transplanting specific cell types into damaged tissues. The continued turn over of ESC while maintaining an undifferentiated state is dependent on unusual cell cycle properties. These unusual proliferative properties are responsible for the generation of tumours when these cells are injected into adult animals. Thus, the study of the unusual proliferative properties of hESC needs to be addressed if their potential is to be realized. To date, most studies of the cell cycle in hESC have been descriptive, lacking functional studies that reveal the mechanisms of how the cell cycle maintains pluripotency and self- renewal of hESC. In this thesis we sought to understand the mechanisms of cell cycle control of hESC. We asked the question if a single cell cycle gene could regulate the self-renewal or pluripotency properties of hESC using a gain and loss of gene function strategy. We have identified that the protein expression of the p27Kip1 cell cycle inhibitor was low in human pluripotent cells, but its expression increased during differentiation together with changes in the cell cycle structure of pluripotent cells. By adopting a gain and loss of function strategy we increased or reduced its expression in undifferentiating conditions to define its functional role in self-renewal and pluripotency of Hesc, using undifferentiation conditions, overexpression of p27Kip1 in hESC lead to a G1 phase arrest with an enlarged and flattened hESC morphology and consequently loss of self-renewal ability. Loss of p27Kip1 caused an increase of self-renewal while maintaining an undifferentiated phenotype. Moreover, we have shown that a change in the balance of p27Kip1 levels in undifferentiated hESC affects expression of the mesoderm markers: BRACHYURY and TWIST. We have found that expression changes of TWIST are associated with the presence of p27Kip1 protein in the TWIST1 gene promoter. The results presented in this thesis have interesting implications in stem cell biology. Firstly, these results define that the maintenance of p27Kip1 protein levels at a certain level is essential for self-renewal and pluripotency of hESC. Secondly, p27Kip1 is involved in the regulation of TWIST which is upregulated in several types of tumours and induces an epithelial-mesenchymal transition to facilitate tumor metastasis.
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