Species-specific double-strand break repair and genome evolution in plants

Abstract

Even closely related eukaryotic species may differ drastically in genome size. While insertion of retroelements represents a major source of genome enlargement, the mechanism mediating species‐ specific deletions is fairly obscure. We analyzed the formation of deletions during double‐strand break (DSB) repair in Arabidopsis thaliana and tobacco, two dicotyledonous plant species differing >20‐fold in genome size. DSBs were induced by the rare cutting restriction endonuclease I‐ Sce I and deletions were identified by loss of function of a negative selectable marker gene containing an I‐ Sce I site. Whereas the partial use of micro‐homologies in junction formation was similar in both species, in tobacco 40% of the deletions were accompanied by insertions. No insertions could be detected in Arabidopsis , where larger deletions were more frequent, indicating a putative inverse correlation between genome size and the average length of deletions. Such a correlation has been postulated before by a theoretical study on the evolution of related insect genomes and our study now identifies a possible molecular cause for the phenomenon, indicating that species‐specific differences in DSB repair might indeed influence genome evolution.