Abstract
Long interspersed element-1 (LINE-1 or L1) retrotransposition induces insertional mutations that can result in diseases. It was recently shown that the copy number of L1 and other retroelements is stable in induced pluripotent stem cells (iPSCs). However, by using an engineered reporter construct over-expressing L1, another study suggests that reprogramming activates L1 mobility in iPSCs. Given the potential of human iPSCs in therapeutic applications, it is important to clarify whether these cells harbor somatic insertions resulting from endogenous L1 retrotransposition. Here, we verified L1 expression during and after reprogramming as well as potential somatic insertions driven by the most active human endogenous L1 subfamily (L1Hs). Our results indicate that L1 over-expression is initiated during the reprogramming process and is subsequently sustained in isolated clones. To detect potential somatic insertions in iPSCs caused by L1Hs retotransposition, we used a novel sequencing strategy. As opposed to conventional sequencing direction, we sequenced from the 3′ end of L1Hs to the genomic DNA, thus enabling the direct detection of the polyA tail signature of retrotransposition for verification of true insertions. Deep coverage sequencing thus allowed us to detect seven potential somatic insertions with low read counts from two iPSC clones. Negative PCR amplification in parental cells, presence of a polyA tail and absence from seven L1 germline insertion databases highly suggested true somatic insertions in iPSCs. Furthermore, these insertions could not be detected in iPSCs by PCR, likely due to low abundance. We conclude that L1Hs retrotransposes at low levels in iPSCs and therefore warrants careful analyses for genotoxic effects.
Highlights
It is possible to reprogram fully differentiated somatic cells back to the embryonic state by forced expression of certain transcriptional factors such as OCT4, SOX2, C-MYC and KLF4
Our results indicate that L1 transcription is activated in induced pluripotent stem cells’ (iPSCs) and that LINE-1 human specific (L1Hs) retrotransposes in iPSCs at low levels, resulting in a low frequency of somatic insertions
We had previously derived several iPSC clones from human fetal fibroblasts (HFF) by forced expression of the cDNA of the four reprogramming factors OCT4, SOX2, C-MYC and KLF4 encoded by the FRh11 lentiviral vector [35]
Summary
It is possible to reprogram fully differentiated somatic cells back to the embryonic state by forced expression of certain transcriptional factors such as OCT4, SOX2, C-MYC and KLF4. These reprogrammed cells, termed ‘induced pluripotent stem cells’ (iPSCs), are capable of unlimited self-renewal and display full pluripotency [1,2,3,4]. There are concerns about aberrant genomic imprinting, lineage specific differentiation and the potential formation of teratomas and tumors in vivo [5,6,7,8] Another crucial aspect that has been studied is the genomic integrity of these cells. IPSCs can have abnormal karyotypes, chromosomal aberrations and mutated exomes [9,10,11]
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