Abstract
Mobile elements are responsible for half of the human genome. Among the elements, L1 and Alu are most ubiquitous. They use L1 enzymatic machinery to move in their host genomes. A significant amount of research has been conducted about these two elements. The results showed that these two elements have played important roles in generating genomic variations between human and chimpanzee lineages and even within a species, through various mechanisms. SVA elements are a third type of mobile element which uses the L1 enzymatic machinery to propagate in the human genome but has not been studied much relative to the other elements. Here, we attempt the first identification of the human genomic deletions caused by SVA elements, through the comparison of human and chimpanzee genome sequences. We identified 13 SVA recombination-associated deletions (SRADs) and 13 SVA insertion-mediated deletions (SIMDs) in the human genome and characterized them, focusing on deletion size and the mechanisms causing the events. The results showed that the SRADs and SIMDs have deleted 15,752 and 30,785 bp, respectively, in the human genome since the divergence of human and chimpanzee and that SRADs were caused by two different mechanisms, nonhomologous end joining and nonallelic homologous recombination.
Highlights
Human diverged from chimpanzee, its most closely related species, ∼six million years ago [1, 2]
We further examined the remaining 1,402 SVA elements, which are shared between human and chimpanzee genomes, to determine whether the elements were associated with deletions in the human genome
We identified 13 SVA recombination-associated deletions (SRADs) in the human genome by comparing the human and chimpanzee sequences for each locus
Summary
Human diverged from chimpanzee, its most closely related species, ∼six million years ago [1, 2]. Species-specific insertion of mobile elements and subsequent genomic rearrangements are major factors causing the INDELs between human and chimpanzee genomes [3,4,5,6,7,8,9]. The commonality of the three elements is that they use L1 enzymatic machinery to retrotranspose in their host genomes. They mobilize via a “copy and paste” mechanism; they transcribe their RNA intermediates, and the RNA intermediates integrate into new genomic regions in a process known as retrotransposition. The mechanism for this process is called target-primed reverse transcription (TPRT) [15, 16]
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