Generation of human induced pluripotent stem (iPS) cell using lentiviral vector and determination of the lentiviral integration profile

The induced pluripotent stem (iPS) cells came with the promise of circumvent some of the limitations in the use of embryonic stem cells, like ethical issues, biological safety, immune compatibility and availability. This cells can be generated from somatic cells of normal individuals or from patients with some genetic disease, making then an important tool for drug screening, construction of disease models and toxicological trials. Great advances have happened in reprogramming differentiated cells through the forced exogenous expression of transcription factors (TF), mostly by lentiviral vectors (LV), which provide an efficient reprogramming. However, the lentiviral insertion in the human genome and its influence in reprogramming is not well known. In this work, we evaluate the insertion profile of LV used to generate human iPS cells. The iPS cells were generated, by our group, from human fibroblasts transduced by LV containing 3 TF [SOX2, TCL-1A and C-MYC (TSM reprogrammed cell)], and from mesenchymal cells derived from human adipose tissue transduced by a polycistronic LV containing 4 TF [OCT4, SOX2, KLF4 and C-MYC (iPS 4TF)]. Five isolated colonies of each iPS cell were mapped and analyzed for the insertion sites through LM-PCR technique. The digested genomic DNA was amplified with a primer for the viral LTR e another for a synthetic linker. The products were cloned, sequenced and analyzed in database to identify similarities with the human genome, among other analyzes. In TSM cell, 176 sequences, derived from the LM-PCR technique, presented identity with the human genome, and about 50% of those occurred in genic regions with 94% in introns. In iPS 4TF, 251 sequences showed identity, with about 45% reaching genes, 92% of these in introns. The insertions were distributed on all chromosomes, with preference for the 16, 17 and 20 for the TSM cell, and for the 11, 15 and 17 for the iPS 4TF. We analyzed the distance of the insertion from de transcription start site, and insertions near CpG islands, which, overall, correspond to regulatory regions. The highest proportion of insertion occurred starting ±30Kb distance from these sites. The fragile sites and the repetitive regions of the genome were also reached, but with low frequency. The results showed a preference of lentiviral insertion for genic regions in iPS, indicating the potential participation of proteins like LEDGF/p75 in integration in the cells of this work. This work shows that the integration site may contribute to the reprogramming, and, despite possible negative effects of integration, these iPS cells are still an important tool for in vitro studies. Identify factors that influence the selection of insertion site is important for determination of \"safe\" chromosomal regions for the integration, increasing the safe in clinical use. (AU)