Abstract
Long interspersed nuclear elements-1 (L1s) are a large family of retrotransposons. Retrotransposons are repetitive sequences that are capable of autonomous mobility via a copy-and-paste mechanism. In most copy events, only the L1 sequence is inserted, however, they can also mobilize the flanking non-repetitive region by a process known as 3′ transduction. L1 insertions can contribute to genome plasticity and cause potentially tumorigenic genomic instability. However, detecting the activity of a particular source L1 and identifying new insertions stemming from it is a challenging task with current methodological approaches. We developed a long-distance inverse PCR (LDI-PCR) based approach to monitor the mobility of active L1 elements based on their 3′ transduction activity. LDI-PCR requires no prior knowledge of the insertion target region. By applying LDI-PCR in conjunction with Nanopore sequencing (Oxford Nanopore Technologies) on one L1 reported to be particularly active in human cancer genomes, we detected 14 out of 15 3′ transductions previously identified by whole genome sequencing in two different colorectal tumour samples. In addition we discovered 25 novel highly subclonal insertions. Furthermore, the long sequencing reads produced by LDI-PCR/Nanopore sequencing enabled the identification of both the 5′ and 3′ junctions and revealed detailed insertion sequence information.
Highlights
Long interspersed nuclear elements (LINE)-1, known as L1 elements, are active mobile repeat elements in the human genome
We selected the L1 located in the first intron of TTC28 for long-distance inverse PCR (LDI-PCR) analysis, as it had been previously reported to be highly active in colorectal cancer[9]
The long-distance inverse (LDI)-PCR product corresponding to the source TTC28 L1 was observed in almost all the samples digested with PstI and SacI (Fig. 2) but only sporadically observed in NsiI digested samples
Summary
Long interspersed nuclear elements (LINE)-1, known as L1 elements, are active mobile repeat elements in the human genome. 3′ transduction occurs when the canonical 3′ polyadenylation signal of the source L1 is weak, causing the transcription machinery to skip it and to continue transcribing the non-repetitive region downstream in the 3′ flanking region until it reaches a stronger polyadenylation/termination signal. Some of this unique sequence is included in the RNA intermediate and subsequently incorporated into the new chromosomal location, thereby serving as a unique sequence tag that reveals the L1’s origin. That L1 insertions exhibiting 3′ transduction represent a quarter of the total L1 insertions emanating from any particular source[11]
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