Excision and transposition of two Ds transposons from the bronze mutable 4 derivative 6856 allele of Zea mays L

Summary The regulatory mutation bronze mutable 4 Derivative 6856 (bz-m4 D6856) contains a complex 6.7 kb Dissociation (Ds) element tagged with a duplication of low copy bz 3 flanking sequences (Klein et al. 1988). This creates a unique opportunity to study the transposition of a single member of the repetitive family of Ds elements. Eighteen full purple revertants (Bz alleles) of bz-m4 were characterized enzymatically and by genomic mapping. For 17 of the Bz alleles, reversion to a wild-type phenotype was caused by excision of the 6.7 kb Ds transposon. Nine of these Bz alleles retained the transposon somewhere in their genome. In this study we show that like Ac (Schwartz 1989; Dooner and Belachew 1989), the 6.7 kb Ds element can transpose within a short physical distance, both proximal and distal to its original position. Additional bz sequences have been mapped immediately distal to the mutant locus in bz-m4 D6856; genetic evidence suggests these are flanked by two additional Ds elements. The remaining Bz revertant, Bz :107, arose from excision of a more complex 13 kb Ds element.     

Development of Ac and Ds transposon tagging lines for gene isolation in diploid potato

For the development of an efficient transposon tagging strategy it is important to generate populations of plants containing unique independent transposon insertions that will mutate genes of interest. To develop such a transposon system in diploid potato the behavior of the autonomous maize transposable element Ac and the mobile Ds element was studied. A GBSS (Waxy) excision assay developed for Ac was used to monitor excision in somatic starch-forming tissue like tubers and pollen. Excision of Ac results in production of amylose starch that stains blue with iodine. The frequency and patterns of blue staining starch granules on tuber slices enabled the identification of transformants with different Ac activity. After excision the GBSS complementation was usually not complete, probably due to the segment of DNA flanking Ac that is left behind in the GBSS gene. Molecular and phenotypic analyses of 40 primary transformants classified into 4 phenotypic classes revealed reproducible patterns. A very high percentage (32.5%) of the primary transformants clearly showed early excision in the first transformed cell as displayed both by the analysis of the GBSS excision marker gene as well as DNA blot analyses. Genotypes useful for tagging strategies were used for crosses and the frequency of independent germinal transpositions was assessed. In crosses to Ds genotypes, excision of Ds was revealed that correlated to the activity of the Ac genotype. A line displaying Ac amplification to multiple copies conferred a high frequency of independent Ds transpositions. The genotypes described here are useful in somatic insertion mutagenesis aimed at the isolation of tagged mutations in diploid potato.     

Double Ds elements are involved in specific chromosome breakage

Summary The structure of the unstable Ds-induced sh-m5933 allele of the maize sucrose synthase gene was analysed and a double Ds structure found in opposite orientation on both sides of a 30 kb insert interrupting the sucrose synthase gene. The double Ds structures bordering the insert are identical over a distance of approximately 3 kb. These double Ds structures and the DNA segments beyond them are in opposite orientation and identical over a distance of approx. 5.3 kb. A hypothesis for how such a symmetrical structure could be formed is proposed. When one complete Ds element was excised from one of the double Ds structures a half Ds element was left behind. This half Ds element was found in one revertant strain which displayed an altered pattern of chromosome breakage compared to revertant strains which had not undergone Ds excision. Nine new maize strains which showed a similarly altered chromosome breakage pattern were isolated. In all nine cases we observed an indistinguishable deletion in the genomic DNA. These excisions are likely to be the result of similar excision events to that described above. We conclude that double Ds structures are responsible for Ds-induced chromosome breakage.     

Frequency and distance of transposition of a modifiedDissociation element in transgenic tobacco

Effective transposon tagging with theAc/Ds system in heterologous plant species relies on the accomplishment of a potentially high transposon-induced mutation frequency. The primary parameters that determine the mutation frequency include the transposition frequency and the transposition distance. In addition, the development of a generally applicable transposon tagging strategy requires predictable transposition behaviour. We systematically analysedDs transposition frequencies andDs transposition distances in tobacco. An artificialDs element was engineered with reporter genes that allowed transposon excision and integration to be monitored visually. To analyse the variability ofDs transposition between different tobacco lines, eight single copy T-DNA transformants were selected. Fortrans-activation of theDs elements, differentAc lines were used carrying an unmodifiedAc ⁺ element, an immobilizedsAc element and a stableAc element under the control of a heterologous chalcone synthas (chsA) promoter. With allAc elements, eachDs line showed characteristic and heritable variegation patterns at the seedling level. SimilarDs line-specificity was observed for the frequency by whichDs transpositions were germinally transmitted, as well as for the distances of theDs transpositions. ThesAc element induced transposition ofDs late in plant development, resulting in low germinal transposition frequencies (0.37%) and high incidences of independent transposition (83%). The majority of theseDs elements (58%) transposed to genetically closed linked sites (10 cM).     

Use of the transposable element Ac/Ds in conjunction with Spm/dSpm for gene tagging allows extensive genome coverage with a limited number of starter lines: functional analysis of a four-element system in Arabidopsis thaliana

We have developed a novel four-element based gene tagging system in Arabidopsis to minimize the number of starter lines required to generate genome-wide insertions for saturation mutagenesis. In this system, the non-autonomous cassette, Ds(dSpm), comprises of both Ds and dSpm elements cloned one within the other along with appropriate selection markers to allow efficient monitoring of excision and re-integration of the transposons. Trans-activation of the outer borders (Ds) and selection against the negative selection marker (iaaH) linked to the cassette ensures unlinked spread of the Ds(dSpm) cassette from the initial site of integration of the T-DNA. This creates several launch pads within the genome from where the internal element (dSpm) can be subsequently mobilized to generate secondary insertions. In this study, starting from a single T-DNA integration we could spread the Ds(dSpm) cassette to 11 different locations over all the five chromosomes of Arabidopsis. The frequency of unlinked Ds transpositions in the F2 generation varied between 0.05 and 3.35%. Three of these lines were then deployed to trans-activate the internal dSpm element which led to the selection of 29 dSpm insertions. The study conclusively shows the feasibility of deploying Ds and the dSpm elements in a single construct for insertional mutagenesis.     

Development of an efficient two-element transposon tagging system in Arabidopsis thaliana

Summary Modified Ac and Ds elements, in combination with dominant markers (to facilitate monitoring of excision, reinsertion and segregation of the elements) were introduced into Arabidopsis thaliana ecotype Landsberg erecta. The frequencies of somatic and germinal transactivation of the Ds elements were monitored using a streptomycin resistance assay. Transactivation was significantly higher from a stable Ac (sAc) carrying a 537 by deletion of the CpG-rich 5 untranslated leader of the transposase mRNA than from a wild-type sAc. However, substitution of the central 1.77 kb of the transposase open reading frame (ORF) with a hygromycin resistance marker did not alter the excision frequency of a Ds element. -Glucuronidase (GUS) or iaaH markers were linked to the transposase source to allow the identification of plants in which the transposase source had segregated away from the transposed Ds element, eliminating the possibility of somatic or germinal re-activation. Segregation of the excision marker, Ds and sAc was monitored in the progeny of plants showing germinal excision of Ds. 29% of the plants inheriting the excision marker carried a transposed Ds element.     

The<Emphasis Type="Italic"> HY2</Emphasis> gene as an efficient marker for transposon excision in<Emphasis Type="Italic"> Arabidopsis</Emphasis>

Transposable elements can generate germinal and somatic mutations, and hence represent a powerful tool for the analysis of gene function. Transposons from maize have been adapted to mutagenise the genomes of diverse species. The efficiency of these systems partly relies on the ease with which germinal (i.e. germinally transmitted) or somatic excisions can be detected. Here we describe the use of HY2, a gene that codes for an enzyme involved in the biosynthesis of the phytochrome chromophore, to monitor the excision of a Ds gene-trap element in Arabidopsis thaliana. Taking advantage of the altered germination and de-etiolation behaviour of a Ds -tagged hy2 mutant, we have designed an efficient protocol for the recovery of germinal revertants, making HY2 the most precocious excision marker available, to the best of our knowledge. In addition, HY2 is also useful for generating visible sectors in photosynthetic tissues, thanks to the somatic instability of this mutable hy2 allele.Communicated by M.-A. Grandbastien     

Developing a transposon tagging system to isolate rust-resistance genes from flax

Summary A line of flax, homozygous for four genes controlling resistance to flax rust, was transformed with T-DNA vectors carrying the maize transposable elements Ac and Ds to assess whether transposition frequency would be high enough to allow transposon tagging of the resistance genes. Transposition was much less frequent in flax than in Solanaceous hosts such as tobacco, tomato and potato. Transposition frequency in callus tissue, but not in plants, was increased by modifications to the transposase gene of Ac. Transactivation of the excision of a Ds element was achieved by expressing a cDNA copy of the Ac transposase gene from the Agrobacterium T-DNA 2 promoter. Progeny of three plants transformed with Ac and 15 plants transformed with Ds and the transposase gene, were examined for transposition occurring in the absence of selection. Transposition was observed in the descendants of only one plant which contained at least nine copies of Ac. Newly transposed Ac elements were observed in 25–30% of the progeny of some members of this family and one active Ac element was located 28.8 (SE=6.3) map units from the L ⁶ rust-resistance gene. This family will be potentially useful in our resistance gene tagging program.     

Selection of independent Ds transposon insertions in somatic tissue of potato by protoplast regeneration

Potato is an autotetraploid crop plant that is not very amenable to the deployment of transposon tagging for gene cloning and gene identification. After diploidisation it is possible to get potato genotypes that grow well, but they are self-incompatible. This prevents the production of selfed progeny that are normally used in gene tagging approaches to select for parental lines with the target gene to be tagged in a homozygous stage. We describe here an alternative selection method for directed transposon tagging for a gene of interest in a heterozygous background. Diploid potato plants with a Ds transposon linked to the desired gene of interest (the Phytophthora infestans R1 resistance locus) in a heterozygous stage were used for the development of this directed transposon tagging strategy. After crossing to a diploid Ac transposon-containing genotype, 22 ’interesting’ seedlings (R1Ds/r–; Ac/–) were selected that showed active Ds transposition as displayed by DNA blot hybridisation, empty donor site PCR and sequencing. Protoplast isolation and the use of the hygromycin gene as a cell-specific selection marker of Ds excision enabled the direct selection of Ds excision sectors in these highly chimaeric seedlings. This somatic selection of Ds transpositions and the regeneration through protoplasts resulted in the development of a large population of almost 2000 hygromycin-resistant plants. Southern blot analysis confirmed the insertion of Ds at independent positions in the genome. Every selected plant displayed independent Ds excisions and re-insertions due to the expression of the Ac transposase throughout development. This population, which is developed from seedlings with the desired R1 gene in a heterozygous stage, is directly useful for searching for transposon-tagged R1 mutants. In general, this approach for selecting for somatic transpositions is particularly suitable for the molecular isolation of genes in a heterozygous crop like potato. Received: 29 November 1999 / Accepted: 30 December 1999     

Identification and Ds‐tagged isolation of a new gene at the Cf‐4 locus of tomato involved in disease resistance to Cladosporium fulvum race 5

Leaf mould disease in tomato is caused by the biotrophic fungus Cladosporium fulvum. An Ac/Ds targeted transposon tagging strategy was used to isolate the gene conferring resistance to race 5 of C. fulvum, a strain expressing the avirulence gene Avr4. An infection assay of 2-week-old seedlings yielded five susceptible mutants, of which two had a Ds element integrated in the same gene at different positions. This gene, member of a gene family, showed high sequence homology to the C. fulvum resistance genes Cf-9 and Cf-2. The gene is predicted to encode an extracellular transmembrane protein containing a divided domain of 25 leucine-rich repeats. Three mutants exhibited a genomic deletion covering most of the Lycopersicon hirsutum introgressed segment, including the Cf-4 locus. Southern blot analysis revealed that this deletion includes the tagged gene and five homologous sequences. To test whether the tagged gene confers resistance to C. fulvum via Avr4 recognition, the Avr4 gene was expressed in planta. Surprisingly, expression of the Avr4 gene still triggered a specific necrotic response in the transposon-tagged plants, indicating that the tagged resistance gene is not, or is not the only gene, involved in Avr4 recognition. Mutants harbouring the genomic deletion did not show this Avr4-specific response. The deleted segment apparently contains, in addition to the tagged gene, one or more other genes, which play a role in the Avr4 responses. The tagged gene is present at the Cf-4 locus, but it does not necessarily recognize Avr4 and is therefore designated Cf-4A.     

Cloning of the Bz2 locus of Zea mays using the transposable element Ds as a gene tag

Summary The Bz2 locus of Zea mays has been cloned, utilizing the presence of the transposable element Dissociation (Ds) at the locus as a gene tag. The Ds element inserted in the bz2-m allele was identified among many members of the Ac/Ds family in a Southern blot analysis of a population segregating for bz2-m and Bz2. After cloning a DNA fragment from the bz2-m allele, sequences flanking the Ds insertion were shown to be Bz2-specific and were used to isolate a homologous fragment from a wild-type Bz2 line. The Ds insertion in the bz2-m allele was found to be a Ds2 element identical to the Ds insertion in adh1-2F11.     

Mapping Ds insertions in barley using a sequence-based approach

A transposon tagging system, based upon maize Ac/Ds elements, was developed in barley (Hordeum vulgare subsp. vulgare). The long-term objective of this project is to identify a set of lines with Ds insertions dispersed throughout the genome as a comprehensive tool for gene discovery and reverse genetics. AcTPase and Ds-bar elements were introduced into immature embryos of Golden Promise by biolistic transformation. Subsequent transposition and segregation of Ds away from AcTPase and the original site of integration resulted in new lines, each containing a stabilized Ds element in a new location. The sequence of the genomic DNA flanking the Ds elements was obtained by inverse PCR and TAIL-PCR. Using a sequence-based mapping strategy, we determined the genome locations of the Ds insertions in 19 independent lines using primarily restriction digest-based assays of PCR-amplified single nucleotide polymorphisms and PCR-based assays of insertions or deletions.The proncipal strategy was to identify and map sequence polymorphisms in the regions corresponding to the flanking DNA using the Oregon Wolfe Barley mapping population. The mapping results obtained by the sequence-based approach were confirmed by RFLP analyses in four of the lines. In addition, cloned DNA sequences corresponding to the flanking DNA were used to assign map locations to Morex-derived genomic BAC library inserts, thus integrating genetic and physical maps of barley. BLAST search results indicate that the majority of the transposed Ds elements are found within predicted or known coding sequences. Transposon tagging in barley using Ac/Ds thus promises to provide a useful tool for studies on the functional genomics of the Triticeae.Electronic Supplementary Material Supplementary material is available in the online version of this article at Communicated by M.-A. GrandbastienThe first three authors contributed equally to this work     

Chromosome labeling with transposable elements in maize

Transposable elements randomly insert into a targeted locus at a frequency of 10^-6 to 10^-5. The En element has been shown in previous studies to transpose more frequently into closely linked sites. Thus, it is appropriate to place an En element onto each of the 20 chromosome arms in maize to maximize tagging efficiency. This is called chromosome labeling for tagging purposes with transposons. After a chromosome arm has been labeled with a transposon, genes residing in that arm will have a greater chance to be tagged by the transposon. To date, all of the maize chromosome arms have been labeled with at least one of five Encontaining alleles. The elements were linked to the arms using reciprocal translocations. The usage of these arm-labeled lines is discussed in the context of gene tagging.Journal Paper No. 15224 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa; Project No. 3176     

<Emphasis Type="Italic">Ds</Emphasis> insertion mutagenesis as an efficient tool to produce diverse variations for rice breeding

The availability of diversified germplasm resources is the most important for developing improved rice varieties with higher seed yield or tolerance to various biotic or abiotic stresses. Here we report an efficient tool to create increased variations in rice by maize Ac/Ds transposon (a gene trap system) insertion mutagenesis. We have generated around 20,000 Ds insertion rice lines of which majority are homozygous for Ds element. We subjected these lines to phenotypic and abiotic stress screens and evaluated these lines with respect to their seed yields and other agronomic traits as well as their tolerance to drought, salinity and cold. Based on this evaluation, we observed that random Ds insertions into rice genome have led to diverse variations including a range of morphological and conditional phenotypes. Such differences in phenotype among these lines were accompanied by differential gene expression revealed by GUS histochemical staining of gene trapped lines. Among the various phenotypes identified, some Ds lines showed significantly higher grain yield compared to wild-type plants under normal growth conditions indicating that rice could be improved in grain yield by disrupting certain endogenous genes. In addition, several 1,000s of Ds lines were subjected to abiotic stresses to identify conditional mutants. Subsequent to these screens, over 800 lines responsive to drought, salinity or cold stress were obtained, suggesting that rice has the genetic potential to survive under abiotic stresses when appropriate endogenous genes were suppressed. The mutant lines that have higher seed yielding potential or display higher tolerance to abiotic stresses may be used for rice breeding by conventional backcrossing combining with molecular marker-assisted selection. In addition, by exploiting the behavior of Ds to leave footprints upon remobilization, we have shown an alternative strategy to develop new rice varieties without foreign DNA sequences in their genome. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Transgenic tomato lines containing Ds elements at defined genomic positions as tools for targeted transposon tagging

We have introduced a genetically marked Dissociation transposable element (Ds ^HPT ) into tomato (Lycopersicon esculentum) by Agrobacterium tumefaciens-mediated transformation. Probes for the flanking regions of the T-DNA and transposed Ds ^HPT elements were obtained with the inverse polymerase chain reaction (IPCR) technique and used in RFLP linkage analyses. The RFLP map location of 11 T-DNAs carrying Ds ^HPT was determined. The T-DNAs are distributed on 7 of the 12 tomato chromosomes. To explore the feasibility of gene tagging strategies in tomato using Ds ^HPT , we examined the genomic distribution of Ds ^HPT receptor sites relative to the location of two different, but very closely linked, T-DNA insertion sites. After crosses with plants expressing Ac transposase, the hygromycin phosphotransferase (HPT) marker on the Ds element and the excision markers -glucuronidase (GUS) and Basta resistance (BAR) facilitated the identification of plants bearing germinally transposed Ds ^HPT elements. RFLP mapping of 21 transposed Ds ^HPT elements originating from the two different T-DNA insertions revealed distinct patterns of reintegration sites.     

Molecular cloning of the o2-m5 allele of Zea mays using transposon marking

Summary The deposition of zein protein in maize endosperm is under the control of several regulatory loci. The isolation of DNA sequences corresponding to Opaque-2 (O2), one of such loci, is described in this paper. The mutable allele, o2-m5 was first induced moving the Ac transposable element present at the wx-m7 allele to the O2 locus. Genetic data suggest that a functional Ac element is responsible for the observed somatic mutability of o2-m5. The isolation of genomic clones containing flanking sequences corresponding to the O2 gene was possible by screening an o2-m5 genomic libary with a probe corresponding to internal Ac sequences usually absent in the defective element Ds. Out of 27 clones isolated with homology to the central part of Ac element, only clones 6IP and 21IP generated a 2.5 kb internal fragment size of an active Ac element when digested with PvuII restriction enzyme. A sequence representing a XhoI fragment of 0.9 kb lying, in the 6IP clone, adjacent to the Ac elements, was subcloned and utilized to prove that it corresponded to a part of the O2 gene. To obtain this information we made use of: (1) DNAs from several reversions originating from the unstable (o2mk-(r) allele, which, when digested with SstI, showed a correct 3.4 kb fragment typical of non-inserted alleles of the O2 locus; and (2) recessive alleles of the O2 locus which were devoid of a 2.0 kb mRNA, present on the contrary in the wild type and in other zein regulating mutants different from O2.This paper is dedicated to the memory of R. Marotta, who actively participated in the realization of this work     

Regional mutagenesis using Dissociation in maize

We describe genetic screens, molecular methods and web resources newly available to utilize Dissociation (Ds) as an insertional mutagen in maize. Over 1700 Ds elements have been distributed throughout the maize genome to serve as donor elements for local or regional mutagenesis. Two genetic screens are described to identify Ds insertions in genes-of-interest (goi). In scheme I, Ds is used to generate insertion alleles when a recessive reference allele is available. A Ds insertion will enable the cloning of the target gene and can be used to create an allelic series. In scheme II, Ds insertions in a goi are identified using a PCR-based screen to identify the rare insertion alleles among a population of testcross progeny. We detail an inverse PCR protocol to rapidly amplify sequences flanking Ds insertion alleles and describe a high-throughput 96-well plate-based DNA extraction method for the recovery of high-quality genomic DNA from seedling tissues. We also describe several web-based tools for browsing, searching and accessing the genetic materials described. The development of these Ds insertion lines promises to greatly accelerate functional genomics studies in maize.     

High-frequency Ds remobilization over multiple generations in barley facilitates gene tagging in large genome cereals

Transposable elements have certain advantages over other approaches for identifying and determining gene function in large genome cereals. Different strategies have been used to exploit the maize Activator/dissociation (Ac/Ds) transposon system for functional genomics in heterologous species. Either large numbers of independent Ds insertion lines or transposants (TNPs) are generated and screened phenotypically, or smaller numbers of TNPs are produced, Ds locations mapped and remobilized for localized gene targeting. It is imperative to characterize key features of the system in order to utilize the latter strategy, which is more feasible in large genome cereals like barley and wheat. In barley, we generated greater than 100 single-copy Ds TNPs and determined remobilization frequencies of primary, secondary, and tertiary TNPs with intact terminal inverted repeats (TIRs); frequencies ranged from 11.8 to 17.1%. In 16% of TNPs that had damaged TIRs no transposition was detected among progeny of crosses using those TNPs as parental lines. In half of the greater than 100 TNP lines, the nature of flanking sequences and status of the 11 bp TIRs and 8-bp direct repeats were determined. BLAST searches using a gene prediction program revealed that 86% of TNP flanking sequences matched either known or putative genes, indicating preferential Ds insertion into genic regions, critical in large genome species. Observed remobilization frequencies of primary, secondary, tertiary, and quaternary TNPs, coupled with the tendency for localized Ds transposition, validates a saturation mutagenesis approach using Ds to tag and characterize genes linked to Ds in large genome cereals like barley and wheat.     

Ds transposition mediated by transient transposase expression in Heiracium aurantiacum

The feasibility of using transient transposase expression to mobilize Ds elements for gene tagging in Hieracium aurantiacum was evaluated. A T-DNA construct carrying the Ac transposase gene and either a visible marker gene (uidA) or the conditionally-lethal marker gene (codA) was transferred to H. aurantiacum leaf discs (previously transformed with a Ds element) by co-cultivation with Agrobacterium tumefaciens. Shoots were regenerated directly from the co-cultivated leaf discs under selection for antibiotic resistance resulting from Ds excision. Most regenerants carried unique transposition events. Of 84 regenerated plants, twenty one (25%) did not express the marker gene and the DNA coding sequence of the transposase could not be detected in seven (8.3%). Potential advantages of this method over conventional gene-tagging methods are: rapid recovery of individual transposition events; regenerated plants are isogenic; and the transient nature of transposase expression should facilitate the stabilisation of the transposed element.     

Trans-activation and stable integration of the maize transposable element Ds cotransfected with the Ac transposase gene in transgenic rice plants

To develop an efficient gene tagging system in rice, a plasmid was constructed carrying a non-autonomous maize Ds element in the untranslated leader sequence of a hygromycin B resistance gene fused with the 35S promoter of cauliflower mosaic virus. This plasmid was cotransfected by electroporation into rice protoplasts together with a plasmid containing the maize Ac transposase gene transcribed from the 35S promoter. Five lines of evidence obtained from the analyses of hygromycin B-resistant calli, regenerated plants and their progeny showed that the introduced Ds was trans-activated by the Ac transposase gene in rice. (1) Cotransfection of the two plasmids is necessary for generation of hygromycin B resistant transformants. (2) Ds excision sites are detected by Southern blot hybridization. (3) Characteristic sequence alterations are found at Ds excision sites. (4) Newly integrated Ds is detected in the rice genome. (5) Generation of 8 by target duplications is observed at the Ds integration sites on the rice chromosomes. Our results also show that Ds can be trans-activated by the transiently expressed Ac transposase at early stages of protoplast culture and integrated stably into the rice genome, while the cotransfected Ac transposase gene is not integrated. Segregation data from such a transgenic rice plant carrying no Ac transposase gene showed that four Ds copies were stably integrated into three different chromosomes, one of which also contained the functional hph gene restored by Ds excision. The results indicate that a dispersed distribution of Ds throughout genomes not bearing the active Ac transposase gene can be achieved by simultaneous transfection with Ds and the Ac transposase gene.