Role of Notch and NF-kB in the regulation of transcription factors during in vitro differentiation of T cells from CD34+

In previous studies by this research group a higher expression of transcriptional targets and components via NF-kB, as well as high levels of NOTCH1, was identified in hematopoietic stem cells (HSC) CD34 + cells from umbilical cord blood (UCB) compared to CD34 + hematopoietic stem cells from bone marrow (BM). This group also found, by comparing the CD34 + cells with CD133 + (more primitive) that several transcription factors (TF) involved in the potential of hemangioblast, with self-renewal of hematopoietic stem cells and to differentiated lymphocytic; as Runx1 / AML1, GATA3, USF1, TAL1/SCL, HOXB4 and HOXA9 were more expressed in more primitive cells. The potential involvement of Notch signaling pathways and NF-kB in the regulation of FT has conceptual and practical importance in understanding the biology of HSC, and the processes involved in differentiation of these cells. With this in mind, this project aimed to study the role of NF-kB pathway and Notch signaling in the regulation of FT. For this, an experimental model in vitro differentiation of CD34 + hematopoietic stem cells into T lymphocytes, was used and the influence of pharmacological agonists and inhibitors of these pathways were evaluated by flow cytometry and real-time PCR. Our results highlight the role of Notch signaling in the transcriptional regulation of GATA3 and HOXB4 in hematopoietic stem cells CD34 + human, which was confirmed based on the expression of direct targets of Notch (HES1 and HEY1). We also note that the expression of transcripts HES1, GATA3 and HOXB4 protein synthesis is hampered by the HSC, since when we use the pre-treatment with the drug there CHX increased transcription thereof. We can also infer that the action of TNF- is positive about these transcripts, since when we use it for raising the level of expression of these transcripts, except the HES1. In relation to the HSC coculture with stromal cells of mice, we found that only the line-DL1 Op9 has the ability to promote T cell differentiation, and this was evidenced by the appearance of cells committed to the T lymphocyte lineage, through the presence of specific surface markers CD7 + and CD1a +. These results will help understand the molecular mechanisms of transcriptional regulation involved not only in the differentiation of T lymphocytes, but also in maintaining a more primitive state of HSC. This knowledge may contribute to the development or optimization of laboratory protocols aimed at the expansion of HSC or generation of T cells for therapeutic use. (AU)