Regulation of Activator/Dissociation Transposition by Replication and DNA Methylation

In maize the transposable elements Activator/Dissociation (Ac/Ds) transpose shortly after replication from one of the two resulting chromatids (“chromatid selectivity”). A model has been suggested that explains this phenomenon as a consequence of different affinity for Ac transposase binding to holo-, hemi-, and unmethylated transposon ends. Here we demonstrate that in petunia cells a holomethylated Ds is unable to excise from a nonreplicating vector and that replication restores excision. A Ds element hemi-methylated on one DNA strand transposes in the absence of replication, whereas hemi-methylation of the complementary strand causes a >6.3-fold inhibition of Ds excision. Consistently in the active hemi-methylated state, the Ds ends have a high binding affinity for the transposase, whereas binding to inactive ends is strongly reduced. These results provide strong evidence for the above-mentioned model. Moreover, in the absence of DNA methylation, replication enhances Ds transposition in petunia protoplasts >8-fold and promotes formation of a predominant excision footprint. Accordingly, replication also has a methylation-independent regulatory effect on transposition.

Variations in the maize Ac transposase transcript level and the Ds excision frequency in transgenic wheat callus lines

To investigate the excision of a maize transposable element in wheat cells, plasmid DNAs containing a Dissociation (Ds) element located between a rice actin 1 gene promoter and a beta-glucuronidase (GUS) gene (gus) were introduced into wheat callus lines by microprojectile bombardment, and transient GUS expression was assayed. The gus-expressing cells after Ds excision were detected only when the Activator (Ac) transposase gene was co-transformed. To further examine a relationship between the amount of Ac mRNA and the Ds excision frequency, the Ds-containing plasmids were introduced into 15 independent transgenic callus lines transformed with the Ac transposase gene. Ten lines expressed the Ac transposase gene under the control of either the cauliflower mosaic virus 35S promoter or the Ac native promoter. The gus gene expression that indicated the Ds excision was observed only in the transgenic callus lines stably expressing the Ac transposase gene. The number of blue spots reflecting the frequency of Ds excision was variable among them. Northern-blot analysis also showed a large variability in the amount of Ac transposase transcripts among the lines. It was however noted that the excision frequency was decreased at a high level of the Ac transposase transcripts, supporting the hypothesis that Ds excision is inhibited above a certain level of the Ac transposase as observed in maize and transgenic tobacco.Key words: transposon, Ds excision, Ac transposase transcript level, transgenic callus, wheat.

Circularized Ac/Ds Transposons: Formation, Structure and Fate

The maize Ac/Ds transposable elements are thought to transpose via a cut-and-paste mechanism, but the intermediates formed during transposition are still unknown. In this work we present evidence that circular Ac molecules are formed in plants containing actively transposing elements. In these circles, transposon ends are joined head-to-head. The sequence at the ends' junction is variable, containing small deletions or insertions. Circles containing deleted Ac ends are probably unable to successfully reintegrate. To test the ability of circles with intact transposon ends to integrate into the genome, an artificial Ds circle was constructed by cloning the joined ends of Ac into a plasmid carrying a plant selectable marker. When such a circular Ds was introduced into tobacco protoplasts in the presence of Ac-transposase, no efficient transposase-mediated integration was observed. Although a circular transposition intermediate cannot be ruled out, the findings of circles with deleted transposon ends and the absence of transposase-mediated integration of the circular Ds suggest that some of the joined-ends-carrying elements are not transposition intermediates, but rather abortive excision products. The formation of Ac circles might account for the previously described phenomenon of Ac-loss. The origin of Ac circles and the implications for models of Ac transposition are discussed.

Hygromycin-resistant calli generated by activation and excision of maize Ac/Ds transposable elements in diploid and hexaploid wheat cultured cell lines

To investigate the activation and transposition of maize transposable elements in wheat cultured cells, plasmid DNAs containing the maize Ac/Ds elements located between the CaMV 35S promoter and a hygromycin B resistance gene (hph) were introduced into two wheat (Triticum aestivum and Triticum monococcum) cultured cell lines by microprojectile bombardment. In the first experiment, hph was activated by excision of the Ac element, which encodes transposase, in the two wheat cell lines. In the second experiment, the Ds element was excised by a stabilized Ac element, lacking inverted repeats of the Ac element and located on another plasmid, and therefore leading to activation of hph. After selection of bombarded cells by hygromycin B, many resistant calli were recovered in both wheat cell lines. The integration of hph and the Ac transposase gene was confirmed by PCR and genomic Southern analysis. The stable expression of hph and the transposase gene was also assessed by Northern blot and reverse transcriptase PCR analysis, respectively. Moreover, characteristic sequence alterations were found at Ac/Ds excision sites. These findings indicate that the maize Ac/Ds transposable elements are activated and excised by expression of the Ac transposase gene in both diploid and hexaploid wheat cells. Key words : transposable elements, excision site, transgenic wheat callus, particle bombardment, Ac/Ds.