A role for host-parasite interactions in the horizontal transfer of transposons across phyla.

Horizontal transfer (HT), or the passage of genetic material between non-mating species, is increasingly recognized as an important force in the evolution of eukaryotic genomes. Transposons, with their inherent ability to mobilize and amplify within genomes, may be especially prone to HT. However, the means by which transposons can spread across widely diverged species remain elusive.

Horizontal SPINning of transposons.

The term 'horizontal transfer (HT)' refers to the transfer of genetic material between two reproductively isolated organisms. HT is thought to occur rarely in eukaryotes compared to vertical inheritance, the transmission of DNA from parent to offspring. In a recent study we have provided evidence that a family of DNA transposons, called SPACE INVADERS or SPIN, independently invaded horizontally the genome of seven distantly related tetrapod species and subsequently amplified to high copy number in each of them.

Repair-mediated duplication by capture of proximal chromosomal DNA has shaped vertebrate genome evolution.

DNA double-strand breaks (DSBs) are a common form of cellular damage that can lead to cell death if not repaired promptly. Experimental systems have shown that DSB repair in eukaryotic cells is often imperfect and may result in the insertion of extra chromosomal DNA or the duplication of existing DNA at the breakpoint. These events are thought to be a source of genomic instability and human diseases, but it is unclear whether they have contributed significantly to genome evolution.

Repeated horizontal transfer of a DNA transposon in mammals and other tetrapods.

Horizontal transfer (HT) is central to the evolution of prokaryotic species. Selfish and mobile genetic elements, such as phages, plasmids, and transposons, are the primary vehicles for HT among prokaryotes. In multicellular eukaryotes, the prevalence and evolutionary significance of HT remain unclear.

Target site analysis of RTE1_LA and its AfroSINE partner in the elephant genome.

SINEs retrotranspose using their partner LINE's enzymatic machinery. It has recently been proposed that AfroSINEs ending with GGTTT 3' tandem repeats were mobilized by RTE elements ending with CAA 3' tandem repeats in the Afrotherian genome. Using sequences from the elephant genome, we show that AfroSINEs derive from RTE ending with GGTTT-like 3' tandem repeats, a subgroup of RTE1_LA that only reached low copy number, and confirm that they were most likely mobilized by RTE ending with CAA(n) tandem repeats (RTE1_LA-CAA(n)).

The evolutionary history of human DNA transposons: evidence for intense activity in the primate lineage.

Class 2, or DNA transposons, make up approximately 3% of the human genome, yet the evolutionary history of these elements has been largely overlooked and remains poorly understood. Here we carried out the first comprehensive analysis of the activity of human DNA transposons over the course of primate evolution using three independent computational methods. First, we conducted an exhaustive search for human DNA transposons nested within L1 and Alu elements known to be primate specific.