Abstract
The role of transposable elements in sculpting the genome is well appreciated but remains poorly understood. Some organisms, such as humans, do not have active transposons; however, transposable elements were presumably active in their ancestral genomes. Of specific interest is whether the DNA surrounding the sites of transposon excision become recombinogenic, thus bringing about homologous recombination. Previous studies in maize and Drosophila have provided conflicting evidence on whether transposon excision is correlated with homologous recombination. Here we take advantage of an atypical Dissociation (Ds) element, a maize transposon that can be mobilized by the Ac transposase gene in Arabidopsis thaliana, to address questions on the mechanism of Ds excision. This atypical Ds element contains an adjacent 598 base pairs (bp) inverted repeat; the element was allowed to excise by the introduction of an unlinked Ac transposase source through mating. Footprints at the excision site suggest a micro-homology mediated non-homologous end joining reminiscent of V(D)J recombination involving the formation of intra-helix 3′ to 5′ trans-esterification as an intermediate, a mechanism consistent with previous observations in maize, Antirrhinum and in certain insects. The proposed mechanism suggests that the broken chromosome at the excision site should not allow recombinational interaction with the homologous chromosome, and that the linked inverted repeat should also be mobilizable. To test the first prediction, we measured recombination of flanking chromosomal arms selected for the excision of Ds. In congruence with the model, Ds excision did not influence crossover recombination. Furthermore, evidence for correlated movement of the adjacent inverted repeat sequence is presented; its origin and movement suggest a novel mechanism for the evolution of repeated elements. Taken together these results suggest that the movement of transposable elements themselves may not directly influence linkage. Possibility remains, however, for novel repeated DNA sequences produced as a consequence of transposon movement to influence crossover in subsequent generations.
Highlights
Mobile genetic elements are important forces of evolution [1]
Here we examined transposition of an active Ds element artificially introduced into Arabidopsis thaliana
The Ds site from which excision was allowed has an atypical configuration at the 39 end: the 39 terminal inverted repeat (39 TIR) of the Ds end is situated adjacent to another inverted repeat of bp (Figure 1A)
Summary
Mobile genetic elements are important forces of evolution [1]. Ac/ Ds elements are DNA transposons that use a conservative ‘‘cutand-paste’’ mechanism involving double-stranded DNA breaks to move within the genome. Repair of broken chromosome ends at the donor (excision) site contributes to genetic alterations in adjoining sequences [2,3,4]. Footprints or DNA sequence rearrangements left at the donor site following transposition provide clues to the repair mechanisms [3,5,6]. Transposons are frequently involved in gene conversion [10] and stimulate crossover within repeated DNA [11], recent genome level analysis shows either no correlation [12] or negative correlation [13,14] between recombination rate and transposable element density along the chromosome. The question remains whether a pioneering transposable element in a chromosome free of prior copies of that transposon allows high frequency crossover during its movement
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