Adjacent Sequences Influence DNA Repair Accompanying Transposon Excision in Maize

Mobile elements transposing via DNA intermediates often leave small rearrangements, or ``transposon footprints,' at sites where they excise. Each excision event leaves its own footprint and, at any given site, these vary in size and sequence. Footprint formation involves DNA repair of sequences flanking the element. We have analyzed the footprints formed by a 2-kb Ds element excising from six different sites in exons of the maize waxy (Wx) gene. We find that groups of footprints left at individual sites are surprisingly nonrandom; different excision products predominate consistently at each site. Less frequent footprints left by each insertion appear related to the predominant type. The data suggest that flanking sequences affect the DNA repair processes associated with element excision. Two models have been proposed to explain footprint formation, one featuring a 5' exonuclease and the other featuring hairpin loop formation and an endonuclease. Our data have interesting implications for both these models. Evidence is also presented to support the presence of a separate excision mechanism that can remove Ac/Ds elements without leaving any footprint and that operates in parallel with the footprint-forming mechanism.     

Origination of Ds elements from Ac elements in maize: evidence for rare repair synthesis at the site of Ac excision.

Although it has been known for some time that the maize transposon Ac can mutate to Ds by undergoing internal deletions, the mechanism by which these mutations arise has remained conjectural. To gain further insight into this mechanism in maize we have studied a series of Ds elements that originated de novo from Ac elements at known locations in the genome. We present evidence that new, internally deleted Ds elements can arise at the Ac donor site when Ac transposes to another site in the genome. However, internal deletions are rare relative to Ac excision footprints, the predominant products of Ac transposition. We have characterized the deletion junctions in five new Ds elements. Short direct repeats of variable length occur adjacent to the deletion junction in three of the five Ds derivatives. In the remaining two, extra sequences or filler DNA is inserted at the junction. The filler DNAs are identical to sequences found close to the junction in the Ac DNA, where they are flanked by the same sequences that flank the filler DNA in the deletion. These findings are explained most simply by a mechanism involving error-prone DNA replication as an occasional alternative to end-joining in the repair of Ac-generated double-strand breaks.     

Transposon excision from an atypical site: a mechanism of evolution of novel transposable elements

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.     

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.     

水稻基因组上一个Ds切离及其双位点插入行为的分子鉴定

玉米转座元件Ac/Ds是hAT转座子家族的成员, 导入水稻基因组后具有转座活性, 尽管转座机制还不完全清楚, 但它们通常经保守的非复制型“剪切-粘贴”过程转座。研究表明, 在Ac编码的转座酶作用下, Ds从原位点切离后常优先重新插入到连锁位点。文章利用TAIL-PCR技术从水稻一个Ds插入突变体及其回复突变体中分离Ds侧翼序列, 结合生物信息学分析方法, 对Ds在突变体上插入位点、回复突变体内切离足迹和重新插入位点进行了分子鉴定。结果显示, 突变体中Ds从3号染色体切离后, 在原插入位点残留了8 bp足迹序列(CATCATGA), 引起Ds标记基因外显子和内含子数目增加, 从而影响基因结构。切离后的Ds重新插入回复突变体第2和第6号染色体上, 分别编码烟草胺氨基转移酶和衰老相关蛋白的2个基因的编码区。因此, 典型的“剪切-粘贴”机制不能完全解释Ds的转座行为, Ds转座存在“剪切-复制-粘贴”的特点。     

Abortive gap repair: underlying mechanism for Ds element formation.

The mechanism by which the maize autonomous Ac transposable element gives rise to nonautonomous Ds elements is largely unknown. Sequence analysis of native maize Ds elements indicates a complex chimeric structure formed through deletions of Ac sequences with or without insertions of Ac-unrelated sequence blocks. These blocks are often flanked by short stretches of reshuffled and duplicated Ac sequences. To better understand the mechanism leading to Ds formation, we designed an assay for detecting alterations in Ac using transgenic tobacco plants carrying a single copy of Ac. We found frequent de novo alterations in Ac which were excision rather than sequence dependent, occurring within Ac but not within an almost identical Ds element and not within a stable transposase-producing gene. The de novo DNA rearrangements consisted of internal deletions with breakpoints usually occurring at short repeats and, in some cases, of duplication of Ac sequences or insertion of Ac-unrelated fragments. The ancient maize Ds elements and the young Ds elements in transgenic tobacco showed similar rearrangements, suggesting that Ac-Ds elements evolve rapidly, more so than stable genes, through deletions, duplications, and reshuffling of their own sequences and through capturing of unrelated sequences. The data presented here suggest that abortive Ac-induced gap repair, through the synthesis-dependent strand-annealing pathway, is the underlying mechanism for Ds element formation.     

Microhomology-dependent end joining and repair of transposon-induced DNA hairpins by host factors in Saccharomyces cerevisiae

The maize, cut-and-paste transposon Ac/Ds is mobile in Saccharomyces cerevisiae, and DNA sequences of repair products provide strong genetic evidence that hairpin intermediates form in host DNA during this transposition, similar to those formed for V(D)J coding joints in vertebrates. Both DNA strands must be broken for Ac/Ds to excise, suggesting that double-strand break (DSB) repair pathways should be involved in repair of excision sites. In the absence of homologous template, as expected, Ac excisions are repaired by nonhomologous end joining (NHEJ) that can involve microhomologies close to the broken ends. However, unlike repair of endonuclease-induced DSBs, repair of Ac excisions in the presence of homologous template occurs by gene conversion only about half the time, the remainder being NHEJ events. Analysis of transposition in mutant yeast suggests roles for the Mre11/Rad50 complex, SAE2, NEJ1, and the Ku complex in repair of excision sites. Separation-of-function alleles of MRE11 suggest that its endonuclease function is more important in this repair than either its exonuclease or Rad50-binding properties. In addition, the interstrand cross-link repair gene PSO2 plays a role in end joining hairpin ends that is not seen in repair of linearized plasmids and may be involved in positioning transposase cleavage at the transposon ends.     

Ac／Ds转座系统在水稻转化群体中的转座活性及转座子插入位点旁侧序列的分析

利用本实验室构建的转Ac(Ac TPase)及Ds(Dissociation)的水稻(Oryza sativa L.)转化群体,配置了Ae×Ds的杂交组合354个。检测了转基因植株的T-DNA插入位点右侧旁邻序列,研究了Ac/Ds转座系统在水稻转化群体中的转座活性。结果表明,有些转化植株T-DNA插入位点相同或相距很近,插入位点互不相同的占65.4％。检测到T-DNA可插入到编码蛋白的基因中。在Ac×Ds的F2代中,Ds因子的转座频率为22.7％。对Ac×Ds杂交子代中Ds因子旁侧序列的分析,进一步表明了Ds因子在水稻基因组中的转座活性,除了从原插入位点解离并转座到新的位点之外,还有复制——转座和小完全切离等现象。获得的旁侧序列中,有些序列与GenBank中的数据没有同源性,目前有2个DNA片段在GenBank登录。探讨了构建转座子水稻突变体库进行水稻功能基因组学研究的策略。     

Ac/Ds转座系统在水稻转化群体中的转座活性及转座子插入位点旁侧序列的分析

利用本实验室构建的转Ac(AcTPase)及Ds(Dissociation)的水稻(Oryza sativa L.)转化群体,配置了Ac×Ds的杂交组合354个.检测了转基因植株的T-DNA插入位点右侧旁邻序列,研究了Ac/Ds转座系统在水稻转化群体中的转座活性.结果表明,有些转化植株T-DNA插入位点相同或相距很近,插入位点互不相同的占65.4%.检测到T-DNA可插入到编码蛋白的基因中.在Ac×Ds的F2代中,Ds因子的转座频率为22.7%.对Ac×Ds杂交子代中Ds因子旁侧序列的分析,进一步表明了Ds因子在水稻基因组中的转座活性,除了从原插入位点解离并转座到新的位点之外,还有复制--转座和不完全切离等现象.获得的旁侧序列中,有些序列与GenBank中的数据没有同源性,目前有2个DNA片段在GenBank登录.探讨了构建转座子水稻突变体库进行水稻功能基因组学研究的策略.     

Transposition Pattern of the Maize Element Ds in Arabidopsis Thaliana

As part of establishing an efficient transposon tagging system in Arabidopsis using the maize elements Ac and Ds, we have analyzed the inheritance and pattern of Ds transposition in four independent Arabidopsis transformants. A low proportion (33%) of plants inheriting the marker used to monitor excision contained a transposed Ds. Selection for the transposed Ds increased this to at least 49%. Overall, 68% of Ds transpositions inherited with the excision marker were to genetically linked sites; however, the distribution of transposed elements varied around the different donor sites. Mapping of transposed Ds elements that were genetically unlinked to the donor site showed that a proportion (3 of 11 tested) integrated into sites which were still physically linked.     

State II dissociation element formation following activator excision in maize

Active Activator (Ac) elements undergo mutations to become nonautonomous Dissociation (Ds) elements at a low frequency. To understand the mechanism of Ds formation, we have developed high-throughput genetic and molecular screens to identify these rare Ds derivatives generated from any Ac insertion in the maize genome. Using these methods we have identified 15 new Ds elements derived from Ac insertions at eight different loci. Approximately half of the Ds elements contain filler DNA inserted at the deletion junction that is derived from sequences within or adjacent to Ac. In contrast to previous reports, several of these Ds elements lack direct repeats flanking the deletion junctions and filler DNA in the donor Ac. To accommodate our findings and those of others, we propose a model of slip mispairing during error-prone repair synthesis to explain the formation of state II Ds elements in maize. We discuss the use of these lines and molecular techniques developed here to capture somatic Ds transposition events in two-component Ac/Ds tagging programs in maize.     

Molecular evidence that chromosome breakage by Ds elements is caused by aberrant transposition.

The transposable Dissociation (Ds) element of maize was first discovered as a site of high-frequency chromosome breakage. Because both Ds-mediated breakage and transposition require the presence of the Activator (Ac) element, it has been suggested that chromosome breakage may be the outcome of an aberrant transposition event. This idea is consistent with the finding that only complex structures containing multiple Ds or Ac and Ds elements have been correlated with chromosome breakage. In this report, we describe two chromosome-breaking maize alleles that contain pairs of closely linked but separate Ds elements inserted at the Waxy locus. A polymerase chain reaction assay was utilized to isolate intermediates in the breakage process. The DNA sequence of these intermediates reveals deletions and base pair changes consistent with transposon footprints that may represent the junctions between fused sister chromatids. These results provide direct molecular evidence that chromosome breakage is the result of aberrant transposition events.     

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.     

Heterologous transposon tagging of the DRL1 locus in Arabidopsis.

The development of heterologous transposon tagging systems has been an important objective for many laboratories. Here, we demonstrate the use of a Dissociation (Ds) derivative of the maize transposable element Activator (Ac) to tag the DRL1 locus of Arabidopsis. The drl1 mutant shows highly abnormal development with stunted roots, few root hairs, lanceolate leaves, and a highly enlarged, disorganized shoot apex that does not produce an inflorescence. The mutation was shown to be tightly linked to a transposed Ds, and somatic instability was observed in the presence of the transposase source. Some plants showing somatic reversion flowered and produced large numbers of wild-type progeny. These revertant progeny always inherited a DRL1 allele from which Ds had excised. Analysis of the changes in DNA sequence induced by the insertion and excision of the Ds element showed that they were typical of those induced by Ac and Ds in maize.     

Analysis of extrachromosomal Ac/Ds transposable elements

The mechanism of transposition of the maize Ac/Ds elements is not well understood. The true transposition intermediates are not known and it has not been possible to distinguish between excision models involving 8-bp staggered cuts or 1-bp staggered cuts followed by hairpin formation. In this work, we have analyzed extrachromosomal excision products to gain insight into the excision mechanism. Plasmid rescue was used to demonstrate that Ds excision is associated with the formation of circular molecules. In addition, we present evidence for the formation of linear extrachromosomal species during Ds excision. Sequences found at the termini of circular and linear elements showed a broad range of nucleotide additions or deletions, suggesting that these species are not true intermediates. Additional nucleotides adjacent to the termini in extrachromosomal elements were compared to the sequence of the original donor site. This analysis showed that: (1) the first nucleotide adjacent to the transposon end was significantly more similar to the first nucleotide flanking the element in the donor site than to a random sequence and (2) the second and farther nucleotides did not resemble the donor site. The implications of these findings for excision models are discussed.     

Assignment of 44 Ds Insertions to the Linkage Map of Arabidopsis

Transposon tagging is a useful tool for biological studies. Transposon insertions have been used to obtain new mutants which are extremely helpful in understanding gene function. These insertions immediately provide a means to isolate the corresponding genes. Transposon tagging has also been used to clone genes previously defined by point mutations. In addition, transposon insertions into cloned genes that lack mutations can be generated to facilitate functional analysis. The maize Ac/Ds transposon elements are known to transpose to local sites with high frequencies and have been shown to function in several dicots. To generate a collection of Ds elements for the purpose of targeted insertional mutagenesis of mapped genes in Arabidopsis, we have mapped 44 Ds insertions by simple sequence length polymorphism (SSLP). Because the Arabidopsis genome project is advancing rapidly, many genes will be discovered whose functions are unknown. The mapped 44 Ds insertions will be a useful resource for post-genome analysis of gene functions in Arabidopsis.     

The Maize Transposable Element Ac Induces Recombination between the Donor Site and an Homologous Ectopic Sequence

The prominent repair mechanism of DNA double-strand breaks formed upon excision of the maize Ac transposable element is via nonhomologous end joining. In this work we have studied the role of homologous recombination as an additional repair pathway. To this end, we developed an assay whereby β-Glucuronidase (GUS) activity is restored upon recombination between two homologous ectopic (nonallelic) sequences in transgenic tobacco plants. One of the recombination partners carried a deletion at the 5' end of GUS and an Ac or a Ds element inserted at the deletion site. The other partner carried an intact 5' end of the GUS open reading frame and had a deletion at the 3' end of the gene. Based on GUS reactivation data, we found that the excision of Ac induced recombination between ectopic sequences by at least two orders of magnitude. Recombination events, visualized by blue staining, were detected in seedlings, in pollen and in protoplasts. DNA fragments corresponding to recombination events were recovered exclusively in crosses with Ac-carrying plants, providing physical evidence for Ac-induced ectopic recombination. The occurrence of ectopic recombination following double-strand breaks is a potentially important factor in plant genome evolution.