Recurrent LINE 1 exonization drives transcriptome remodelling in NSCLC

The only autonomously active transposable elements in the human genome are Long interspersed nuclear element-1 (LINE-1) elements. These elements are known to play an important role in changing the transcriptome. LINE-1 sequences affect gene regulation during post-transcription processing, along with their established role in retrotransposition. Exonization is one mechanism where the LINE-1 integrated genome undergoes alternative splicing to produce new isoforms of transcripts. Our work mainly highlights the effect of LINE-1 associated exonization, focusing on the formation of isoforms of transcripts. Using Non-small cell lung cancer (NSCLC) as a model, we conducted a detailed transcriptome study that combines splice junction profiling with gene expression data. Our results show that LINE-1 sequences are often included as exons in host transcripts, leading to the formation of new exons and their various isoforms. The events are validated by solid splice junction evidence that proves the reliability and reproducibility. In particular, it was observed that repetitive analyses revealed certain LINE-1 exonization events that were consistent. The finding indicates that LINE-1 act as recurrent sources of splice ready sequences. Though exonizations do not necessarily affect the total expression levels of genes, our study reveals that they certainly contribute to transcript diversity. The diversity of isoforms generated potentially contributes to the effects of gene function. This study is limited to NSCLC, but it is likely that the exonizations events play a crucial role in the altering RNA diversity in cancers. Therefore the study elucidates new insights into how transposable elements modify gene structure and function during cancer development.