Lipids profile changes associated to pluripotency regulatory mechanisms during mesenchymal cells reprogramming to Human Induced Pluripotent Stem cells (iPS)

The generation of induced pluripotent stem cells (iPS) from adult somatic cells has shown that mammalian cells can be reprogrammed to a pluripotent state by the insertion of embryonic transcription factors. This finding has raised questions about the fundamental mechanisms through which these transcription factors epigenetically influence cells, their potential of differentiation after reprogramming and normal development. Lipid and lipoprotein components affect numerous aspects of cell behavior during its maintenance and differentiation, which can directly affect main factors in cell reprogramming processes, maintenance of pluripotency and epigenetic profile of the cells. Thus, this thesis proposed to study, with different approaches, the lipid composition of iPS cells, embryonic stem cells (H1) and fibroblast cells (BJ). Three induced pluripotent cell lines were produced in the human model. They were characterized regarding their pluripotency and used along with H1 and BJ cell lines, as models for the proposed lipid composition study. A total of 44 species of lipid from the classes PC, PE, PI, PS and SM have been identified, studied and discussed regarding cellular reprogramming and maintenance of pluripotency. A different phospholipid composition pattern was observed between pluripotent and non-pluripotent cells, and it is speculated that the presence of these species appears to have a major involvement on the maintenance of pluripotency. This array showed, by the principal component analysis, that during the reprogramming process changes in the lipid composition occur, so that pluripotency takes place during reprogramming, highlighting lipid changes particular of the pluripotency state, suggesting a connection between these changes in lipid composition and the metabolic changes of cell reprogramming. The study of the quantitation of phospholipids from pluripotent and non-pluripotent cell lines indicated a phospholipid difference between these cell lines when considering the observed classes and quantified phospholipid. It was eminent that iPS lines and H1 are similar and differ from non-pluripotent cells. It is clear that these lipid molecules are not individually capable of modulating processes such as cell reprogramming, however, it is extremely important to understand them within cellular reprogramming and maintenance of pluripotency. Our data suggests that the lipid composition of pluripotent cells has important role in the development and evolution of cellular reprogramming process and the understanding the maintenance of pluripotency (AU)