Transposon Ac/Ds-induced chromosomal rearrangements at the rice OsRLG5 locus

Previous studies have shown that pairs of closely-linked Ac/Ds transposable elements can induce various chromosomal rearrangements in plant genomes. To study chromosomal rearrangements in rice, we isolated a line (OsRLG5-161) that contains two inversely-oriented Ds insertions in OsRLG5 (Oryza sativa Receptor like kinase Gene 5). Among approximately 300 plants regenerated from OsRLG5-161 heterozygous seeds, 107 contained rearrangements including deletions, duplications and inversions of various sizes. Most rearrangements were induced by previously identified alternative transposition mechanism. Furthermore, we also detected a new class of rearrangements that contain juxtaposed inversions and deletions on the same chromosome. We propose that these novel alleles were generated by a previously unreported type of alternative transposition reactions involving the 5' and 3' termini of two inversely-oriented Ds elements located on the same chromatid. Finally, 11% of rearrangements contained inversions resulting from homologous recombination between the two inverted Ds elements in OsRLG5-161. The high frequency inheritance and great variety of rearrangements obtained suggests that the rice regeneration system results in a burst of transposition activity and a relaxation of the controls which normally limit the transposition competence of individual Ds termini. Together, these results demonstrate a greatly enlarged potential of the Ac/Ds system for plant chromosome engineering.     

Genome rearrangements in maize induced by alternative transposition of reversed ac/ds termini

Alternative transposition can induce genome rearrangements, including deletions, inverted duplications, inversions, and translocations. To investigate the types and frequency of the rearrangements elicited by a pair of reversed Ac/Ds termini, we isolated and analyzed 100 new mutant alleles derived from two parental alleles that both contain an intact Ac and a fractured Ac (fAc) structure at the maize p1 locus. Mutants were characterized by PCR and sequencing; the results show that nearly 90% (89/100) of the mutant alleles represent structural rearrangements including deletions, inversions, translocations, or rearrangement of the intertransposon sequence (ITS). Among 37 deletions obtained, 20 extend into the external flanking sequences, while 17 delete portions of the intertransposon sequence. Interestingly, one deletion allele that contains only a single nucleotide between the retained Ac and fAc termini is not competent for further alternative transposition events. We propose a new model for the formation of intertransposon deletions through insertion of reversed transposon termini into sister-chromatid sequences. These results document the types and frequencies of genome rearrangements induced by alternative transposition of reversed Ac/Ds termini in maize.     

Reversed end Ds element: a novel tool for chromosome engineering in Arabidopsis

The maize Ac/Ds transposable element (TE) transposes by a "cut and paste" mechanism. Previous studies in maize showed that when the TE ends are in reversed orientation with respect to each other, alternative transposition reactions can occur resulting in large scale genome rearrangements including deletions and inversions. To test whether similar genome rearrangements can also occur in other plants, we studied the efficacy of such alternative transposition-mediated genome rearrangements in Arabidopsis. Here we present our analysis of 33 independent chromosome rearrangements. Transposition at the reversed ends Ds element can cause deletions over 1 Mbp, and inversions up to 2.4 Mbp in size. We identified additional rearrangements including a reciprocal translocation and a putative ring chromosome. Some of the deletions and inversions are germinally transmitted.     

Genome rearrangements by nonlinear transposons in maize.

Transposable elements have long been considered as potential agents of large-scale genome reorganization by virtue of their ability to induce chromosomal rearrangements such as deletions, duplications, inversions, and reciprocal translocations. Previous researchers have shown that particular configurations of transposon termini can induce chromosome rearrangements at high frequencies. Here, we have analyzed chromosomal rearrangements derived from an unstable allele of the maize P1 (pericarp color) gene. The progenitor allele contains both a full-length Ac (Activator) transposable element and an Ac terminal fragment termed fAc (fractured Ac) inserted in the second intron of the P1-rr gene. Two rearranged alleles were derived from a classical maize ear twinned sector and were found to contain a large inverted duplication and a corresponding deficiency. The sequences at the junctions of the rearrangement breakpoints indicate that the duplication and deletion structures were produced by a single transposition event involving Ac and fAc termini located on sister chromatids. Because the transposition process we describe involves transposon ends located on different DNA molecules, it is termed nonlinear transposition (NLT). NLT can rapidly break and rejoin chromosomes and thus could have played an important role in generating structural heterogeneity during genome evolution.     

Transposition of reversed Ac element ends generates novel chimeric genes in maize

The maize Activator/Dissociation (Ac/Ds) elements are members of the hAT (hobo, Ac, and Tam3) superfamily of type II (DNA) transposons that transpose through a “cut-and-paste” mechanism. Previously, we reported that a pair of Ac ends in reversed orientation is capable of undergoing alternative transposition reactions that can generate large-scale chromosomal rearrangements, including deletions and inversions. We show here that rearrangements induced by reversed Ac ends transposition can join the coding and regulatory sequences of two linked paralogous genes to generate a series of chimeric genes, some of which are functional. To our knowledge, this is the first report demonstrating that alternative transposition reactions can recombine gene segments, leading to the creation of new genes.     

Macrotransposition and other complex chromosomal restructuring in maize by closely linked transposons in direct orientation

Several observations indicate that compatible ends of separate, yet closely linked, transposable elements (TEs) can interact in alternative transposition reactions. First, pairs of TEs cause chromosome breaks with frequencies inversely related to the intertransposon distance. Second, some combinations of two TEs produce complex rearrangements that often include DNA adjacent to one or both elements. In pairs of TEs in direct orientation, alternative reactions involving the external ends of the two TEs should lead to the transposition of a macrotransposon consisting of both elements plus the intervening chromosomal segment. Such macrotransposons have been hypothesized previously based on deletions, but no macrotransposon insertions have been recovered. To detect macrotransposition, we have analyzed heritable chromosomal rearrangements produced by a chromosome-breaking pair of Ac and Ds elements situated 6.5 kb apart in direct orientation in a part of the maize (Zea mays) genome dispensable for viability. Here, we show that the postulated macrotransposon can excise and reinsert elsewhere in the genome. In addition, this transposon pair produces other complex rearrangements, including deletions, inversions, and reshuffling of the intertransposon segment. Thus, closely linked TE pairs, a common transposition outcome in some superfamilies, are adept at restructuring chromosomes and may have been instrumental in reshaping plant genomes.     

Intra-chromosomal rearrangements generated by Cre-lox site-specific recombination.

Chromosomal rearrangements are useful genetic and breeding tools but are often difficult to detect and characterize. To more easily identify and define chromosome deletions and inversions, we have used the bacteriophage P1 Cre-lox site-specific recombination system to generate these events in plants. This involves three steps: (i) the introduction of two lox sites into one locus in a plant genome, including one site within a modified Ds transposon; (ii) Ac transposase-mediated transposition of the Ds-lox element to a new locus on the same chromosome; (iii) Cre-mediated site-specific recombination between the two lox sites that bracket a chromosome segment. We report the production of a deletion and three inversion events in tobacco. The utility of chromosomal segments bracketed by lox sites for targeted manipulation and cloning is discussed.     

Fusion of reverse-oriented Ds termini following abortive transposition in Arabidopsis: implications for the mechanism of Ac/Ds transposition

We studied the products of alternative transposition reactions that utilize reverse-oriented Ds termini as substrates. In this configuration, Ds transposition can generate genome rearrangements including deletions, inversions, and reciprocal translocations. In approximately half of the transposition products recovered in Arabidopsis, the termini of the reversed ends Ds element were ligated together. The sequences at these fused-end junctions suggest that the excised transposon termini form covalently closed hairpin structures. These results shed new light on the mechanism of Ac/Ds transposition.     

Alternative Transposition Generates New Chimeric Genes and Segmental Duplications at the Maize p1 Locus

The maize Ac/Ds transposon family was the first transposable element system identified and characterized by Barbara McClintock. Ac/Ds transposons belong to the hAT family of class II DNA transposons. We and others have shown that Ac/Ds elements can undergo a process of alternative transposition in which the Ac/Ds transposase acts on the termini of two separate, nearby transposons. Because these termini are present in different elements, alternative transposition can generate a variety of genome alterations such as inversions, duplications, deletions, and translocations. Moreover, Ac/Ds elements transpose preferentially into genic regions, suggesting that structural changes arising from alternative transposition may potentially generate chimeric genes at the rearrangement breakpoints. Here we identified and characterized 11 independent cases of gene fusion induced by Ac alternative transposition. In each case, a functional chimeric gene was created by fusion of two linked, paralogous genes; moreover, each event was associated with duplication of the ∼70-kb segment located between the two paralogs. An extant gene in the maize B73 genome that contains an internal duplication apparently generated by an alternative transposition event was also identified. Our study demonstrates that alternative transposition-induced duplications may be a source for spontaneous creation of diverse genome structures and novel genes in maize.     

A versatile reporter system for CRISPR-mediated chromosomal rearrangements

Although chromosomal deletions and inversions are important in cancer, conventional methods for detecting DNA rearrangements require laborious indirect assays. Here we develop fluorescent reporters to rapidly quantify CRISPR/Cas9-mediated deletions and inversions. We find that inversion depends on the non-homologous end-joining enzyme LIG4. We also engineer deletions and inversions for a 50 kb Pten genomic region in mouse liver. We discover diverse yet sequence-specific indels at the rearrangement fusion sites. Moreover, we detect Cas9 cleavage at the fourth nucleotide on the non-complementary strand, leading to staggered instead of blunt DNA breaks. These reporters allow mechanisms of chromosomal rearrangements to be investigated.

Electronic supplementary material

The online version of this article (doi:10.1186/s13059-015-0680-7) contains supplementary material, which is available to authorized users.     

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.     

A segmental deletion series generated by sister-chromatid transposition of Ac transposable elements in maize

Certain configurations of maize Ac/Ds transposon termini can undergo alternative transposition reactions leading to chromosome breakage and various types of stable chromosome rearrangements. Here, we show that a particular allele of the maize p1 gene containing an intact Ac element and a nearby terminally deleted Ac element (fAc) can undergo sister-chromatid transposition (SCT) reactions that generate large flanking deletions. Among 35 deletions characterized, all begin at the Ac termini in the p1 gene and extend to various flanking sites proximal to p1. The deletions range in size from the smallest of 12,567 bp to the largest of >4.6 cM; >80% of the deletions removed the p2 gene, a paralog of p1 located ~60 kb from p1 in the p1-vv allele and its derivatives. Sequencing of representative cases shows that the deletions have precise junctions between the transposon termini and the flanking genomic sequences. These results show that SCT events can efficiently generate interstitial deletions that are useful for in vivo dissection of local genome regions and for the rapid correlation of genetic and physical maps. Finally, we discuss evidence suggesting that deletions induced by alternative transposition reactions can occur at other genomic loci, indicating that this mechanism may have had a significant impact on genome evolution.     

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.     

Resources for targeted insertional and deletional mutagenesis in Arabidopsis

The maize transposons Activator (Ac) and Dissociation (Ds) are active in many monocots and dicots, including Arabidopsis. We describe a new Ac-derived transposon construct, designated the Ds-loxP T-DNA, which can be used for both insertional and deletional mutagenesis. There are loxP sites in both orientations on both the transposon and the donor site T-DNA and an arrangement of marker genes that permits selection of transposition events, as well as deletions and inversions extending from the donor site to a transposon reinserted on either side of it. We show that Cre-mediated deletions and inversions occur at a high frequency. The tendency of Ac-Ds transposons to reinsert near the donor site can be used to target both insertional and deletional mutagenesis, but efficient exploitation of this property requires a library of mapped marked donor sites distributed in the genome. We have created a population of independent Ds T-DNA transformants and we have mapped an initial set of 75 Ds T-DNA integration sites. We assessed the potential efficiency of targeted mutagenesis by detecting Ds reinsertion events at several loci over a 400 kb interval from each of two donor sites with different Ds T-DNA constructs. The distribution of reinsertion sites is similar around the two tested loci, with roughly 10, 4, and ca. 1% of reinsertions detected within 1-2 kb of sites 10, 100, and 200-400 kb from the donor site, respectively. To facilitate the use of this targeted mutagenesis system. we have constructed a searchable database of the mapped Ds T-DNA integration sites.     

Large-scale systematic study on stability of the Ds element and timing of transposition in rice

Activator/Dissociation (Ac/Ds) transposon mutagenesis is a widely used tool for gene identification; however, several reports on silencing of the Ac/Ds element in starter lines and in stable transposants question the applicability of such an approach in later generations. We have performed a systematic analysis on various aspects of the silencing phenomenon in rice (Oryza sativa ssp. japonica cv. Nipponbare). High somatic and germinal transposition frequencies observed in earlier generations were maintained as late as T4 and T5 generations; thus the propagation of parental lines did not induce transposon silencing. Moreover, the stably transposed Ds element was active even at the F5 generation, since Ac could remobilize the Ds element as indicated by the footprint analysis of several revertants. Expression of the bar gene was monitored from F3 to F6 generations in >1,000 lines. Strikingly, substantial transgene silencing was not observed in any of the generations tested. We analyzed the timing of transposition during rice development and provide evidence that Ds is transposed late after tiller formation. The possibility, that the independent events could be the result of secondary transposition, was ruled out by analyzing potential footprints by reciprocal PCR. Our study validates the Ac/Ds system as a tool for large-scale mutagenesis in rice, since the Ds elements were active in the starter and insertion lines even in the later generations. We propose that harvesting rice seeds using their panicles is an alternative way to increase the number of independent transposants due to post-tillering transposition.     

Discovery of human inversion polymorphisms by comparative analysis of human and chimpanzee DNA sequence assemblies

With a draft genome-sequence assembly for the chimpanzee available, it is now possible to perform genome-wide analyses to identify, at a submicroscopic level, structural rearrangements that have occurred between chimpanzees and humans. The goal of this study was to investigate chromosomal regions that are inverted between the chimpanzee and human genomes. Using the net alignments for the builds of the human and chimpanzee genome assemblies, we identified a total of 1,576 putative regions of inverted orientation, covering more than 154 mega-bases of DNA. The DNA segments are distributed throughout the genome and range from 23 base pairs to 62 mega-bases in length. For the 66 inversions more than 25 kilobases (kb) in length, 75% were flanked on one or both sides by (often unrelated) segmental duplications. Using PCR and fluorescence in situ hybridization we experimentally validated 23 of 27 (85%) semi-randomly chosen regions; the largest novel inversion confirmed was 4.3 mega-bases at human Chromosome 7p14. Gorilla was used as an out-group to assign ancestral status to the variants. All experimentally validated inversion regions were then assayed against a panel of human samples and three of the 23 (13%) regions were found to be polymorphic in the human genome. These polymorphic inversions include 730 kb (at 7p22), 13 kb (at 7q11), and 1 kb (at 16q24) fragments with a 5%, 30%, and 48% minor allele frequency, respectively. Our results suggest that inversions are an important source of variation in primate genome evolution. The finding of at least three novel inversion polymorphisms in humans indicates this type of structural variation may be a more common feature of our genome than previously realized.     

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.     

Pattern of somatic transposition in a high copy Ac tomato line

A transgenic tomato line containing between eight and ten copies per genome of an exceptionally active maize transposable element Ac has previously been described. Southern analyses indicated that these elements are somatically active in these plants. In order to characterize further the pattern of somatic transposition in this line, 24 independent Ac insertion events from a single plant were cloned. In 21 cases, Ac inserted into single copy genomic DNA while in three cases Ac inserted into sequences present at two to four copies per genome; none of the insertions occurred into more highly repetitive DNA. The chromosomal locations of 20 insertion sites were determined by RFLP mapping and a pattern of small dispersed clusters emerged. Thirteen of the 20 insertion sites were linked to at least one other insertion site but these were distributed over nine of the 12 tomato chromosomes. Only one Ac insertion was linked to the T-DNA locus. The structural integrity of these Ac elements was examined and no evidence of deletions or other rearrangements suggestive of Ds elements was found. The implications of these findings with respect to the use of Ac as a transposon tag in heterologous species are discussed.     

Transposition of reversed Ac element ends generates chromosome rearrangements in maize

In classical "cut-and-paste" transposition, transposons are excised from donor sites and inserted at new locations. We have identified an alternative pathway in which transposition involves the 5' end of an intact Ac element and the 3' end of a nearby terminally deleted fAc (fractured Ac). The Ac and fAc elements are inserted at the maize p1 locus on chromosome 1s in the same orientation; the adjacent ends of the separate elements are thus in reversed orientation with respect to each other and are separated by a distance of approximately 13 kb. Transposition involving the two ends in reversed orientation generates inversions, deletions, and a novel type of local rearrangement. The rearrangement breakpoints are bounded by the characteristic footprint or target site duplications typical of Ac transposition reactions. These results demonstrate a new intramolecular transposition mechanism by which transposons can greatly impact genome evolution.