Abstract
Transposable elements, once described by Barbara McClintock as controlling genetic units, not only occupy the largest part of our genome but are also a prominent moving force of genomic plasticity and innovation. They usually replicate and reintegrate into genomes silently, sometimes causing malfunctions or misregulations, but occasionally millions of years later, a few may evolve into new functional units. Retrotransposons make their way into the genome following reverse transcription of RNA molecules and chromosomal insertion. In therian mammals, long interspersed elements 1 (LINE1s) self-propagate but also coretropose many RNAs, including mRNAs and small RNAs that usually exhibit an oligo(A) tail. The revitalization of specific LINE1 elements in the mammalian lineage about 150 Ma parallels the rise of many other nonautonomous mobilized genomic elements. We previously identified and described hundreds of tRNA-derived retropseudogenes missing characteristic oligo(A) tails consequently termed tailless retropseudogenes. Additional analyses now revealed hundreds of thousands of tailless retropseudogenes derived from nearly all types of RNAs. We extracted 2,402 perfect tailless sequences (with discernible flanking target site duplications) originating from tRNAs, spliceosomal RNAs, 5S rRNAs, 7SK RNAs, mRNAs, and others. Interestingly, all are truncated at one or more defined positions that coincide with internal single-stranded regions. 5S ribosomal and U2 spliceosomal RNAs were analyzed in the context of mammalian phylogeny to discern the origin of the therian LINE1 retropositional system that evolved in our 150-Myr-old ancestor.
Highlights
Long interspersed element 1 (LINE1 or L1) autonomous retrotransposons evolved less than 450 Ma in the common ancestor of deuterostomes, a clade comprising Echinodermata and Chordata, and, over time, gave raise to more than 300 diverse element families and a plethora of subfamilies (Kordis et al 2006)
To detect different types of tailless retropseudogenes genome wide, we screened the human genome for all known small RNAs, ribosomal RNA genes, and some mRNA subsets, including LINEs, histone, monoexonic mRNA, and housekeeping genes, compiled in a user-defined library using the local version of RepeatMasker
Gray bars represent the relative numbers of truncated fragments ending at the corresponding nucleotide
Summary
Long interspersed element 1 (LINE1 or L1) autonomous retrotransposons evolved less than 450 Ma in the common ancestor of deuterostomes, a clade comprising Echinodermata and Chordata, and, over time, gave raise to more than 300 diverse element families and a plethora of subfamilies (Kordis et al 2006). In some cases, similar structures can favor coretroposition of “free-riders,” usually abundant cellular RNAs that are devoid of their own enzymatic equipment and in turn may evolve into highly repetitive short interspersed elements (SINEs) Such tight association of autonomous and specific nonautonomous elements that harbor, for example, LINE-like tails, is characteristic for many SINEs. For instance, Bov-tA SINEs of ruminants share identical RNA 30-termini with the associated autonomous BovB LINEs (Ohshima and Okada 2005). This single surviving LINE family, presumably due to lack of competition, became highly active and caused an explosive radiation of retrotransposons in placentals, with an especially high activity peak in primates and rodents
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
