Distribution of Unlinked Transpositions of a Ds Element from a T-DNA Locus on Tomato Chromosome 4

In maize, receptor sites for unlinked transpositions of Activator (Ac) elements are not distributed randomly. To test whether the same is true in tomato, the receptor sites for a Dissociation (Ds) element derived from Ac, were mapped for 26 transpositions unlinked to a donor T-DNA locus on chromosome 4. Four independent transposed Dss mapped to sites on chromosome 4 genetically unlinked to the donor T-DNA, consistent with a preference for transposition to unlinked sites on the same chromosome as opposed to sites on other chromosomes. There was little preference among the nondonor chromosomes, except perhaps for chromosome 2, which carried seven transposed Dss, but these could not be proven to be independent. However, these data, when combined with those from other studies in tomato examining the distribution of transposed Acs or Dss among nondonor chromosomes, suggest there may be absolute preferences for transposition irrespective of the chromosomal location of the donor site. If true, transposition to nondonor chromosomes in tomato would differ from that in maize, where the preference seems to be determined by the spatial arrangement of chromosomes in the interphase nucleus. The tomato lines carrying Ds elements at known locations are available for targeted transposon tagging experiments.     

Frequency and pattern of transposition of the maize transposable element Ds in transgenic rice plants

Two kinds of T-DNA constructs, I-RS/dAc-I-RS and Hm(R)Ds, carrying a non-autonomous transposable element of Ac of maize were introduced into rice plants by Agrobacterium-mediated gene transfer. Six transgenic rice plants identified as containing a single copy of the element were crossed with two transgenic rice plants carrying a gene for Ac transposase under the control of the cauliflower mosaic virus 35S promoter. In F2 progenies, excision of the element was detected by PCR analysis and re-integration of the element was investigated by Southern blot analysis. The frequency of the excision of the element was found to vary from 0 to 70% depending on the crossing combination. The frequency of the number of individual transposition events out of the total number of F2 plants with germinal excision was 44% in one crossing combination and 38% in the other. In the most efficient case, 10 plants with independent transposition were obtained out of the 49 F2 plants tested. Linkage analysis of the empty donor site and the transposed Ds-insertion site in F3 plants demonstrated that one of five Ds-insertion sites was not linked to the empty donor site. The transgenic rice obtained in this study can be used for functional genomics of rice.     

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.     

Transposition patterns of unlinked transposed Ds elements from two T-DNA loci on tomato chromosomes 7 and 8

We have previously reported that unlinked transposed Ds elements originating from chromosome 4 of tomato preferentially inserted in chromosome 2. This observation, together with data from other studies, suggested that there may be absolute preferences for transposition, irrespective of the chromosomal location of the donor site. The aim of the present work was to verify whether the distribution of transposed Ds elements on chromosome 2 was non-random and thus whether, unlike the case in maize, unlinked transpositions in tomato are not distributed randomly. To do this, unlinked acceptor sites of Ds elements originating from two donor T-DNA loci lying on chromosomes 7 and 8 were mapped. Receptor sites for tr Ds elements transposed from the 1601D locus on chromosome 8 exhibited a non-random distribution (P<0.01). Eleven out of 46 independent transpositions mapped to chromosome 2 and, as this was statistically significant (P<0.01), proves that receptor sites for this element are not randomly distribution on the chromosomes. In addition, deviation of the observed number from the expected number of tr Dss was close to being significant for chromosome 4 (P=0.05-0.1). In contrast, the distribution of unlinked receptor sites for tr Dss derived from the 1481J locus on chromosome 7 was random. Chi(2)tests were performed for each chromosome, and for chromosome 4 the difference between the observed and the expected number of tr Dss was very high but statistically non-significant (P=0.05-0.1). For chromosome 2 the difference was statistically negligible. Therefore, we conclude that chromosome 2 does not serve as a preferential receptor for the transposition of Ds elements independently of the location of the donor site.     

Molecular analysis of rice plants harboring an Ac/Ds transposable element-mediated gene trapping system

In rice, limited efforts have been made to identify genes by the use of insertional mutagens, especially heterologous transposons such as the maize Ac/Ds. We constructed Ac and gene trap Ds vectors and introduced them into the rice genome by Agrobacterium-mediated transformation. In this report, rice plants that contained single and simple insertions of T-DNA were analysed in order to evaluate the gene-tagging efficiency. The 3' end of Ds was examined for putative splicing donor sites. As observed in maize, three splice donor sites were identified at the 3' end of the Ds in rice. Nearly 80% of Ds elements were excised from the original T-DNA sites, when Ac cDNA was expressed under a CaMV 35S promoter. Repetitive ratoon culturing was performed to induce new transpositions of Ds in new plants derived from cuttings. About 30% of the plants carried at least one Ds which underwent secondary transposition in the later cultures. Eight per cent of transposed Ds elements expressed GUS in various tissues of rice panicles. With cloned DNA adjacent to Ds, the genomic complexities of the insertion sites were examined by Southern hybridization. Half of the Ds insertion sites showed simple hybridization patterns which could be easily utilized to locate the Ds. Our data demonstrate that the Ac/Ds-mediated gene trap system could prove an excellent tool for the analysis of functions of genes in rice. We discuss genetic strategies that could be employed in a large scale mutagenesis using a heterologous Ac/Ds family in rice.     

Linked and Unlinked Transposition of a Genetically Marked Dissociation Element in Transgenic Tomato

We have introduced a genetically marked Dissociation transposable element (Ds(neo)) into tomato. In the presence of Ac transposase, Ds(neo) excised from an integrated T-DNA and reinserted at numerous new sites in the tomato genome. The marker genes of Ds(neo) (NPTII) and the T-DNA (HPT) facilitated identification of plants bearing transposon excisions and insertions. To explore the feasibility of gene tagging strategies in tomato using Ds(neo), we examined the genomic distribution of Ds(neo) receptor sites, relative to the location of the donor T-DNA locus. Restriction fragment length polymorphism mapping of transposed Ds(neo) elements was conducted in two tomato families, derived from independent primary transformants each bearing Ds(neo) within a T-DNA at a unique position in the genome. Transposition of Ds(neo) generated clusters of insertions that were positioned on several different tomato chromosomes. Ds(neo) insertions were often located on the same chromosome as the T-DNA donor site. However, no insertion showed tight linkage to the T-DNA. We consider the frequency and distance of Ds(neo) transposition observed in tomato to be well suited for transposon mutagenesis. Our study made use of a novel, stable allele of Ac (Ac3) that we discovered in transgenic tomato. We determined that the Ac3 element bears a deletion of the outermost 5 base pairs of the 5'-terminal inverted repeat. Though incapable of transposition itself, Ac3 retained the ability to mobilize Ds(neo). We conclude that a dual element system, composed of the stable Ac3 trans-activator in combination with Ds(neo), is an effective tool for transposon tagging experiments in tomato.     

Rapid, large-scale generation of Ds transposant lines and analysis of the Ds insertion sites in rice

Rapid, large-scale generation of a Ds transposant population was achieved using a regeneration procedure involving tissue culture of seed-derived calli carrying Ac and inactive Ds elements. In the F(2) progeny from genetic crosses between the same Ds and Ac starter lines, most of the crosses produced an independent germinal transposition frequency of 10-20%. Also, many Ds elements underwent immobilization even though Ac was expressed. By comparison, in a callus-derived regenerated population, over 70% of plants carried independent Ds insertions, indicating transposition early in callus formation. In the remaining population, the majority of plants carried only Ac. Most of the new Ds insertions were stably transmitted to a subsequent generation. An exceptionally high proportion of independent transposants in the regenerated population means that selection markers for transposed Ds and continual monitoring of Ac/Ds activities may not necessarily be required. By analyzing 1297 Ds-flanking DNA sequences, a genetic map of 1072 Ds insertion sites was developed. The map showed that Ds elements were transposed onto all of the rice chromosomes, with preference not only near donor sites (36%) but also on certain physically unlinked arms. Populations from both genetic crossing and tissue culture showed the same distribution patterns of Ds insertion sites. The information of these mapped Ds insertion sites was deposited in GenBank. Among them, 55% of Ds elements were on predicted open-reading frame (ORF) regions. Thus, we propose an optimal strategy for the rapid generation of a large population of Ds transposants in rice.     

Mapped Ds/T-DNA launch pads for functional genomics in barley

A system for targeted gene tagging and local saturation mutagenesis based on maize transposable elements (Ac/Ds) was developed in barley (Hordeum vulgare L.). We generated large numbers of transgenic barley lines carrying a single copy of the non-autonomous maize Ds element at defined positions in the genome. Independent Ds lines were either generated by activating Ds elements in existing single-copy lines after crossing with AcTPase-expressing plants or by Agrobacterium-mediated transformation. Genomic DNA flanking Ds and T-DNA insertion sites from over 200 independent lines was isolated and sequenced, and was used for a sequence based mapping strategy in a barley reference population. More than 100 independent Ds insertion sites were mapped and can be used as launch pads for future targeted tagging of genes in the vicinity of the insertion sites. Sequence analysis of Ds and T-DNA flanking regions revealed a sevenfold preference of both mutagens for insertion into non-redundant, gene-containing regions of the barley genome. However, whilst transposed Ds elements preferentially inserted adjacent to regions with a high number of predicted and experimentally validated matrix attachment regions (nuclear MARs), this was not the case for T-DNA integration sites. These findings and an observed high transposition frequency from mapped launch pads demonstrate the future potential of gene tagging for functional genomics and gene discovery in barley.     

Ac Transposition from a T-DNA Can Generate Linked and Unlinked Clusters of Insertions in the Tomato Genome

We have investigated the distribution of transposed Acs in the tomato genome. Our approach has been to clone the regions flanking the T-DNAs and transposed Acs from two transgenic lines of tomato and place these sequences on the tomato restriction fragment length polymorphism (RFLP) map. The distribution of transposed Acs around the T-DNA and at locations unlinked to the T-DNA indicates that Ac transposes to linked and unlinked sites in tomato as it does in maize. The structure and terminal sequence of these cloned elements shows that Ac remains intact after transposition. We discuss these results and their bearing on gene tagging strategies using Ac and Ds.     

Sexual transmission of transposed activator elements in transgenic tomatoes

The transmission of transposed Ac elements in progeny derived by self-pollination of ten transformed tomato plants has been examined by Southern hybridization analysis. We show that six of these primary transformants have transmitted a transposed Ac to at least one progeny. One of the families was segregating for at least two different insertion events. In five of ten families, progeny were detected that contained a transposed Ac but no donor T-DNA sequences, indicating that a recombination event occurred between the original and new Ac insertion site. Somatic transposition of Ac as late as the R2 generation is evidenced. One family contained an empty donor site fragment but Ac was not detected in either the parent or progeny, indicating Ac was lost in this population early in regeneration. While four of ten families were segregating for aberrant phenotypes, there was no evidence that the mutated gene was linked to a transposed Ac.     

Independent transposition of multiple Ac elements in the same transgenic tomato cell

To effectively use transposable elements for the genetic manipulation of plant species lacking well characterized endogenous elements, it is important to evaluate the behavior of known transposable elements following their introduction into heterologous host species. One critical parameter concerns the timing of transposition in relation to the development of the transgenic host since this will affect the frequency with which transposition events are captured in the gametes. In order to examine whether different elements in the same cell are differentially active during development, we used Southern hybridizations to assess the activity of Activator (Ac) elements in progeny plants derived from a tomato transformant carrying five Ac'x at two loci. All of the elements at one locus transposed in the primary transformant at a developmental stage resulting in the transmission of newly transposed elements to the next generation. In contrast, one or more of the Ac's at the second locus were not active at this stage and were transmitted to the next generation at the original donor T-DNA insertion site. These elements were, however, transpositionally active in somatic tissue. These results demonstrated that individual transposable elements in the same transformed cell can be differentially activated during development.     

Variable Patterns of Transposition of the Maize Element Activator in Tobacco

The strategy to be followed in a transposon tagging experiment will be determined largely by the transposition pattern of the transposon in question. With a view to utilizing the maize element Activator (Ac) as a transposon tag in heterologous systems, we investigated the pattern of Ac transposition from six different loci in transgenic tobacco. We isolated germinal revertants from plants carrying mutable alleles of the antibiotic-resistant gene streptomycin phosphotransferase (SPT) and mapped the location of the transposed Ac (trAc) elements relative to the donor SPT gene. A comparison of the distributions of trAcs among the six loci revealed that, although the receptor sites for trAcs tend to be linked to the donor locus, the pattern of Ac transposition in tobacco displays surprising locus-to-locus variation. Some trAc distributions showed the same tight clustering around the donor locus previously seen in maize, whereas others were more dispersed. The possible meaning of these findings and their implication for transposon tagging in heterologous systems are discussed.     

Gametophyte-specific transposition of the maize Ds element in transgenic tobacco

To assess the potential advantages of a transposon-tagging system based on gametophyte-specific transposition a fusion between the anther-specific Arabidopsis thaliana apg promoter and the maize Ac transposase gene was constructed and introduced into tobacco. The ability of this transposase source to activate Ds transposition in a developmentally controlled manner was monitored by crossing to plants harbouring the cell autonomous excision marker gene construct, Ds —SPT. A number of fully green, streptomycin-resistant seedlings resulting from germinal transposition events were observed in the progeny of apg -TPase x Ds —SPT F1 plants. Streptomycin-resistant sectors were not observed in either F₁ seedlings or F₂ progeny, indicating a complete lack of somatic excision. Further crosses of apg —TPase sources to plants containing Ds—bar herbicide selection excision marker constructs gave reproducible gametophytic excision frequencies of up to 0.3%. Sequencing of Ds excision sites from F₂ seedlings derived from single F₁ plants revealed various sequence alterations in the original Ds insertion 'footprint' indicative of independent Ds excision events. Independent re-insertion was confirmed by Southern analysis of F₂ siblings. It is concluded that apg -controlled Ac transposase expression activates male gametophyte-specific Ds transposition.     

Characterization and mapping of Ds—GUS-T-DNA lines for targeted insertional mutagenesis

The transposition patterns of the Ds —GUS transposon T-DNA in 23 independent single-copy lines have been characterized and the map positions of 10 of them on three of the five Arabidopsis chromosomes are reported. Using overexpressed Activator ( Ac ) elements as a transposase source, it was found that the primary determinant of transposition frequency is the insertion site of the Ac -T-DNA. Neither the structure of the transposon T-DNA nor, in most cases, its insertion site have a significant effect on transposition frequency. Both the frequency and timing of transposition are influenced by the parent through which the transposon and transposase T-DNAs are transmitted. Overall, nearly 75% of plants in which excision has occurred bear a reinserted element and very short-range transpositions predominate, underlining the advantage of using mapped transposons for insertional mutagenesis.     

Ac-immobilized, a stable source of Activator transposase that mediates sporophytic and gametophytic excision of Dissociation elements in maize

We have identified and characterized a novel Activator (Ac) element that is incapable of excision yet contributes to the canonical negative dosage effect of Ac. Cloning and sequence analysis of this immobilized Ac (Ac-im) revealed that it is identical to Ac with the exception of a 10-bp deletion of sequences at the left end of the element. In screens of approximately 6800 seeds, no germinal transpositions of Ac-im were detected. Importantly, Ac-im catalyzes germinal excisions of a Ds element resident at the r1 locus resulting in the recovery of independent transposed Ds insertions in approximately 4.5% of progeny kernels. Many of these transposition events occur during gametophytic development. Furthermore, we demonstrate that Ac-im transactivates multiple Ds insertions in somatic tissues including those in reporter alleles at bronze1, anthocyaninless1, and anthocyaninless2. We propose a model for the generation of Ac-im as an aberrant transposition event that failed to generate an 8-bp target site duplication and resulted in the deletion of Ac end sequences. We also discuss the utility of Ac-im in two-component Ac/Ds gene-tagging programs in maize.