Retrotransposons, which proliferate by reverse transcription of RNA intermediates, comprise a major portion of plant genomes. Plants often change the genome size and organization during evolution by rapid proliferation and deletion of long terminal repeat (LTR) retrotransposons. Precise transposon sequences throughout the Arabidopsis thaliana genome and the trans-acting mutations affecting epigenetic states make it an ideal model organism with which to study transposon dynamics. Here we report the mobilization of various families of endogenous A. thaliana LTR retrotransposons identified through genetic and genomic approaches with high-resolution genomic tiling arrays and mutants in the chromatin-remodelling gene DDM1 (DECREASE IN DNA METHYLATION 1). Using multiple lines of self-pollinated ddm1 mutant, we detected an increase in copy number, and verified this for various retrotransposons in a gypsy family (ATGP3) and copia families (ATCOPIA13, ATCOPIA21, ATCOPIA93), and also for a DNA transposon of a Mutator family, VANDAL21. A burst of retrotransposition occurred stochastically and independently for each element, suggesting an additional autocatalytic process. Furthermore, comparison of the identified LTR retrotransposons in related Arabidopsis species revealed that a lineage-specific burst of retrotransposition of these elements did indeed occur in natural Arabidopsis populations. The recent burst of retrotransposition in natural population is targeted to centromeric repeats, which is presumably less harmful than insertion into genes. The ddm1-induced retrotransposon proliferations and genome rearrangements mimic the transposon-mediated genome dynamics during evolution and provide experimental systems with which to investigate the controlling molecular factors directly.
SUMMARYGene silencing through transcriptional repression can be induced by targeting double-stranded RNA (dsRNA) to a gene promoter. It has been reported that a transgene was silenced by targeting dsRNA to the promoter, and the silenced state was inherited to the progeny plant even after removal of the silencing inducer from cells. In contrast, no plant has been produced that harbors silenced endogenous gene after removal of promotertargeting dsRNA. Here, we show that heritable gene silencing can be induced by targeting dsRNA to the endogenous gene promoters in petunia and tomato plants, using the Cucumber mosaic virus (CMV)-based vector. We found that efficient silencing of endogenous genes depends on the function of the 2b protein encoded in the vector virus, which has the ability to facilitate epigenetic modifications through the transport of short interfering RNA to nucleus. Bisulfite sequencing analyses on the targeted promoter in the virus-infected and its progeny plants revealed that cytosine methylation was found not only at CG or CNG but also at CNN sites. The observed inheritance of asymmetric DNA methylation is quite unique, suggesting that plants have a mechanism to maintain even asymmetric methylation. This CMV-based gene silencing system provides a useful tool to artificially modify DNA methylation in plant genomes and elucidate the mechanism for epigenetic controls.
The plant genome evolves with rapid proliferation of LTR-type retrotransposons, which is associated with their clustered accumulation in gene-poor regions, such as centromeres. Despite their major role for plant genome evolution, no mobile LTR element with targeted integration into gene-poor regions has been identified in plants.Here, we report such targeted integrations de novo. We and others have previously shown that an ATCOPIA93 family retrotransposon in Arabidopsis thaliana is mobilized when the DNA methylation machinery is compromised. Although ATCOPIA93 family elements are low copy number in the wild-type A. thaliana genome, high-copynumber related elements are found in the wild-type Arabidopsis lyrata genome, and they show centromere-specific localization. To understand the mechanisms for the clustered accumulation of the A. lyrata elements directly, we introduced one of them, named Tal1 (Transposon of Arabidopsis lyrata 1), into A. thaliana by transformation. The introduced Tal1 was retrotransposed in A. thaliana, and most of the retrotransposed copies were found in centromeric repeats of A. thaliana, suggesting targeted integration. The targeted integration is especially surprising because the centromeric repeat sequences differ considerably between A. lyrata and A. thaliana. Our results revealed unexpectedly dynamic controls for evolution of the transposon-rich heterochromatic regions.[Keywords: centromere; tandem repeat; retrotransposon; evolution] Supplemental material is available for this article. Received November 22, 2011; revised version accepted February 21, 2012. Retrotransposons are major factors causing rapid evolution of plant genomes; comparison of genome structures in closely related plant species has revealed that the changes in plant genome size and organization are mainly caused by rapid proliferation and deletion of LTR retrotransposons (Hawkins et al. 2006;Vitte and Bennetzen 2006;Hu et al. 2011). Rapid proliferation of transposons would be a potential threat to the function of the host genome because each integration may directly disrupt a protein-coding region or indirectly perturb transcription of nearby genes. However, most of the LTR retrotransposons in plant genomes are accumulated in gene-poor regions, resulting in proliferation of these elements with less harmful effects to the host (SanMiguel et al. 1996(SanMiguel et al. , 1998Rabinowicz et al. 1999). This feature causes a differentiation of gene-rich regions and transposon-rich regions within plant genomes. The latter constitute heterochromatic domains, which play a significant role in large-scale chromosome organization and its behavior (Dawe and Hiatt 2004;Grewal and Jia 2007).How are the biased distributions of LTR retrotransposons generated? One possibility is through natural selection; if chromosomal domains with deleterious transposon insertions into genic regions are eliminated from natural populations, the transposons would be condensed in genepoor regions. An alternative mechanism for the biased distribution is...
A Ty1/Copia-like retrotransposon, ONSEN, is activated by heat stress in Arabidopsis thaliana, and its de novo integrations that were observed preferentially within genes implies its regulation of neighboring genes. Here we show that ONSEN related copies were found in most species of Brassicaceae, forming a cluster with each species in phylogenetic tree. Most copies were localized close to genes in Arabidopsis lyrata and Brassica rapa, suggesting conserved integration specificity of ONSEN family into genic or open chromatin. In addition, we found heat-induced transcriptional activation of ONSEN family in several species of Brassicaceae. These results suggest that ONSEN has conserved transcriptional activation promoted by environmental heat stress in some Brassicaceae species.
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