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.     

Undescribed wheat gene for partial leaf rust and stripe rust resistance from Thatcher derivatives RL6058 and 90RN249 carryingLr34

Inheritance of partial leaf rust and stripe rust resistance of a Thatcher wheat 90RN2491, earlier reported to carry two doses of the gene pairLr34-Yr18 and the reference line RL6058 (6*Thatcher/PI58548) for theLr34-Yr18 gene pair was studied against predominant and highly virulent Indian races. Thatcher derivatives 90RN2491 and RL6058 were intercrossed as well as crossed with the leaf rust and stripe rust susceptible Indian cultivar WL711. The F₁, F₂ and F₃ generations from these crosses were assessed for rust severity against leaf rust race 77-5 and stripe rust race 46S119. The F₂ and F₃ generations from the crosses of RL6058 and 90RN2491 with WL711, segregated 15 resistant : 1 susceptible (F₂) and 7 homozygous resistant : 8 segregating : 1 homozygous susceptible (F₃) ratios, respectively, both for leaf rust and stripe rust severity. Therefore, partial resistance against each of the leaf rust and stripe rust races in both RL6058 and 90RN2491 is ascribed to two independently inherited dominant genes. One of the two genes for leaf rust and stripe rust resistance in 90RN2491 and RL6058 isLr34 and the linked geneYr18, respectively. The second leaf rust resistance gene in both the Thatcher lines segregated independently of stripe rust resistance. Therefore, it is notLr34 and it remains unidentified.     

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     

Recombination among genes at the L group in flax conferring resistance to rust

Summary Fourteen of the known genes conferring resistance to rust in flax occur in the L group, and recombinational analysis has been used to study their fine structure. Three important features were observed. (a) Similar to the findings of Shepherd and Mayo, only susceptible recombinants were detected among the testcross progeny of 11 of the 15 heterozygotes involving pairs of L genes. Some of these recombinants showed variation in the degree of their susceptibility and appeared to be unstable in nature. (b) A new class of recombinants exhibiting a modified type of resistance was recovered. They occurred rarely but consistently, with frequencies similar to that of susceptible recombinants. (c) Rare resistant plants occurred among the progeny of susceptible recombinants. In each case, the specificity of the resistant plant corresponded to only one of the parental types. The relative roles of seed contamination, mutation, recombination and the transposition of genetic elements are discussed to account for these features.     

Construction of an inducible transposon,INAc, to develop a gene tagging system in higher plants

An inducible transposable element, termed INAc (inducible Activator), was constructed for development of a gene tagging system in higher plants. The advantage of such an inducible element is that, unlike the native transposon, its excision can be induced at any time during plant development and the resulting mutants are stable after removal of the inducer. A fusion of the SA inducible promoter (PR-1a) with the Ac transposase gene was inserted together with a hygromycin resistance gene between ca. 400 bp sequences from each end of the maize Ac element, yielding INAc. The INAc element was introduced into tobacco and tomato plants. A high frequency of spontaneous transposition was apparent in primary transformed tomato calli but not in tobacco calli. Treatment of tobacco plants with salicylic acid induced transposition of INAc in both somatic and germinal tissue, with germinal transposition events being revealed by characterization of the progeny of transformed plants whose flowers were exposed to SA. The INAc element thus exhibits potential for development of an inducible transposon system suitable for gene isolation in heterologous plant species.     

Accumulation of genes for susceptibility to rust fungi for which barley is nearly a nonhost results in two barley lines with extreme multiple susceptibility

Nonhost resistance is the most common type of resistance in plants. Understanding the factors that make plants susceptible or resistant may help to achieve durably effective resistance in crop plants. Screening of 109 barley (Hordeum vulgare L.) accessions in the seedling stage indicated that barley is a complete nonhost to most of the heterologous rust fungi studied, while it showed an intermediate status with respect to Puccinia triticina, P. hordei-murini, P. hordei-secalini, P. graminis f. sp. lolii and P. coronata ff. spp. avenae and holci. Accessions that were susceptible to a heterologous rust in the seedling stage were much more or completely resistant at adult plant stage. Differential interaction between barley accessions and heterologous rust fungi was found, suggesting the existence of rust-species-specific resistance. In particular, many landrace accessions from Ethiopia and Asia, and naked-seeded accessions, tended to be susceptible to several heterologous rusts, suggesting that some resistance genes in barley are effective against more than one heterologous rust fungal species. Some barley accessions had race-specific resistance against P. hordei-murini. We accumulated genes for susceptibility to P. triticina and P. hordei-murini in two genotypes called SusPtrit and SusPmur, respectively. In the seedling stage, these accessions were as susceptible as the host species to the target rusts. They also showed unusual susceptibility to other heterologous rusts. These two lines are a valuable asset to further experimental work on the genetics of resistance to heterologous rust fungi.Electronic Supplementary Material Supplementary material is available in the online version of this article at http://dx.doi.org/10.1007/s00425-004-1319-1Abbreviations ff. spp Formae speciales - RIL Recombinant inbred line - DC Double cross - DC-S Progeny produced by selfing of double-cross plants     

A curious case of resistance to a new encounter pathogen: myrtle rust in Australia

Resistance genes (R genes) in plants mediate a highly specific response to microbial pathogens, often culminating in localized cell death. Such resistance is generally pathogen race specific and believed to be the result of evolutionary selection pressure. Where a host and pathogen do not share an evolutionary history, specific resistance is expected to be absent or rare. Puccinia psidii, the causal agent of myrtle rust, was recently introduced to Australia, a continent rich in myrtaceous taxa. Responses within species to this new pathogen range from full susceptibility to resistance. Using the myrtle rust case study, we examine models to account for the presence of resistance to new encounter pathogens, such as the retention of ancient R genes through prolonged ‘trench warfare’, pairing of resistance gene products and the guarding of host integrity.     

A heat-shock promoter fusion to the Ac transposase gene drives inducible transposition of a Ds element during Arabidopsis embryo development

A heat-shock promoter fusion to the Ac transposase gene (hs::TPase) was constructed and introduced into Arabidopsis. In five transformants containing the fusion the abundance of transposase mRNA increased approximately 120-fold on exposure to high temperatures. Hybrid plants containing hs::TPase and a Ds element inserted in a streptomycin resistance gene (Ds::SPT) were made and these plants were self-fertilized either after heat shocking at different stages in development or without exposure to high temperature. The progeny of these plants were sown on streptomycin-containing medium and the frequency with which variegated or streptomycin-resistant (strep^R) seedlings occurred was used as an indication of the frequency of Ds excision. Very few of the progeny of plants not exposed to heat shock or of those heat shocked only during vegetative development were variegated or strep^R. However, plants that were heat shocked after the appearance of flower buds and during seed development produced high frequencies (approaching 100%) of variegated, but very few strep^R, progeny. Furthermore, when variegated seedlings were grown to maturity and self-fertilized without further exposure to heat shock then strep^R seedlings often occurred at high frequency among their progeny. Southern analysis indicated that the majority of these strep^R plants contained a transposed Ds at a new location. These data indicate that in response to heat shock Ds excision frequently occurs in embryonic cells which ultimately give rise to the gametes, as well as in cells of the developing cotyledons. The importance of an inducible transposon system for transposon tagging is discussed.     

Analysis of leaf and stripe rust severities reveals pathotype changes and multiple minor QTLs associated with resistance in an Avocet?×?Pastor wheat population

Leaf rust and stripe rust are important diseases of wheat world-wide and deployment of cultivars with genetic resistance is an effective and environmentally sound control method. The use of minor, additive genes conferring adult plant resistance (APR) has been shown to provide resistance that is durable. The wheat cultivar ‘Pastor’ originated from the CIMMYT breeding program that focuses on minor gene-based APR to both diseases by selecting and advancing generations alternately under leaf rust and stripe rust pressures. As a consequence, Pastor has good resistance to both rusts and was used as the resistant parent to develop a mapping population by crossing with the susceptible ‘Avocet’. All 148 F₅ recombinant inbred lines were evaluated under artificially inoculated epidemic environments for leaf rust (3 environments) and stripe rust (4 environments, 2 of which represent two evaluation dates in final year due to the late build-up of a new race virulent to Yr31) in Mexico. Map construction and QTL analysis were completed with 223 polymorphic markers on 84 randomly selected lines in the population. Pastor contributed Yr31, a moderately effective race-specific gene for stripe rust resistance, which was overcome during this study, and this was clearly shown in the statistical analysis. Linked or pleiotropic chromosomal regions contributing to resistance against both pathogens included Lr46/Yr29 on 1BL, the Yr31 region on 2BS, and additional minor genes on 5A, 6B and 7BL. Other minor genes for leaf rust resistance were located on 1B, 2A and 2D and for stripe rust on 1AL, 1B, 3A, 3B, 4D, 6A, 7AS and 7AL. The 1AL, 1BS and 7AL QTLs are in regions that were not identified previously as having QTLs for stripe rust resistance. The development of uniform and severe epidemics facilitated excellent phenotyping, and when combined with multi-environment analysis, resulted in the relatively large number of QTLs identified in this study.     

Lr68: a new gene conferring slow rusting resistance to leaf rust in wheat

The common wheat cultivar Parula possesses a high level of slow rusting, adult plant resistance (APR) to all three rust diseases of wheat. Previous mapping studies using an Avocet-YrA/Parula recombinant inbred line (RIL) population showed that APR to leaf rust (Puccinia triticina) in Parula is governed by at least three independent slow rusting resistance genes: Lr34 on 7DS, Lr46 on 1BL, and a previously unknown gene on 7BL. The use of field rust reaction and flanking markers identified two F₆ RILs, Arula1 and Arula2, from the above population that lacked Lr34 and Lr46 but carried the leaf rust resistance gene in 7BL, hereby designated Lr68. Arula1 and Arula2 were crossed with Apav, a highly susceptible line from the cross Avocet-YrA/Pavon 76, and 396 F₄-derived F₅ RILs were developed for mapping Lr68. The RILs were phenotyped for leaf rust resistance for over 2 years in Ciudad Obregon, Mexico, with a mixture of P. triticina races MBJ/SP and MCJ/SP. Close genetic linkages with several DNA markers on 7BL were established using 367 RILs; Psy1-1 and gwm146 flanked Lr68 and were estimated at 0.5 and 0.6 cM, respectively. The relationship between Lr68 and the race-specific seedling resistance gene Lr14b, located in the same region and present in Parula, Arula1 and Arula2, was investigated by evaluating the RILs with Lr14b-avirulent P. triticina race TCT/QB in the greenhouse. Although Lr14b and Lr68 homozygous recombinants in repulsion were not identified in RILs, γ-irradiation-induced deletion stocks that lacked Lr68 but possessed Lr14b showed that Lr68 and Lr14b are different loci. Flanking DNA markers that are tightly linked to Lr68 in a wide array of genotypes can be utilized for selection of APR to leaf rust.     

Enhanced frequency of transposition of the maize transposable elementActivator following excision from T-DNA inPetunia hybrida

Many of the systems currently employed for heterologous transposon tagging in plants rely on an excision assay to monitor transposon activity. We have used the streptomycin phosphotransferase (SPT) reporter system to assayAc activity inPetunia hybrida. In other species, such as tobacco orArabidopsis, excision ofAc from the SPT gene in sporogenous tissue gives rise to streptomycin-resistant seedlings in the following generation. The frequency of fully streptomycin-resistant seedlings in petunia was low (0.4%) but molecular analysis of these indicated that the actual excision frequency may be as low as 0.05%. This indicates that the SPT assay is not a reliable selection criterion for germinal excision in petunia. Extensive molecular screening for reinsertion ofAc was consistent with a low primary transposition frequency (0%–0.6%). In contrast to these findings, the progeny of confirmed germinal transpositions for three independent transformants showed frequent transposition to new sites (9.5%–17.0%). This suggests a high frequency of secondary transposition compared with primary transposition from the T-DNA. Segregation analysis indicates that the high transposition activity is closely associated with transposed copies ofAc. No evidence was found for an altered methylation state forAc following transposition. The implications of these results for heterologous transposon tagging in petunia are discussed in the context of the reliability of excision reporter systems in general.     

Pyramiding of alleles with different rust resistance specificities in <Emphasis Type="Italic">Linum usitatissimum</Emphasis> L.

Transgenic flax plants expressing flax rust resistance specificities conferred by L ² and L ¹⁰ alleles of L locus were produced through Agrobacterium tumefaciens-mediated transformation of hypocotyl segments or anther culture derived-calli. Transgenic plants were characterized by PCR amplification and Southern hybridization. Homozygous transgenic lines containing a single locus of effective transgene were isolated by consecutive progeny analyses of transgenic plants. In addition, homozygous lines were directly obtained from transformation of haploid cells followed by spontaneous or artificial chromosome doubling when anther culture derived-calli were used as the explants. All transgenic plants containing L ² transgene expressed L ² flax rust resistance specificity and had unambiguous infection type (IT) “0” (immune) reactions to flax rust race 22, which is virulent to endogenous L ⁶ and K ¹ genes present in the untransformed Linola™1084. Transgenic plants containing L ¹⁰ transgene exhibited various levels of resistance to flax rust race 191. Five plants had IT “fleck” (immune) reactions, similar to the reactions with the L ¹⁰ rust differential line, Bolley Golden Selection. The enhanced resistance to rust race 191 in these transgenic plants was attributed to the expression of L ¹⁰ rust resistance specificity. Further evaluation of the transgenic plants containing L ² or L ¹⁰ transgene to flax rust race 258 and race 247 respectively showed that the endogenous rust resistance specificities were not modified. The implication of this study in producing transgenic flax plants with multiple resistance specificities and for crop improvement using molecular breeding strategy is discussed.     

Molecular mapping of the rust resistance gene <Emphasis Type="Italic">R</Emphasis><Subscript><Emphasis Type="Italic">4</Emphasis></Subscript> to a large NBS-LRR cluster on linkage group 13 of sunflower

Rust is a serious fungal disease in the sunflower growing areas worldwide with increasing importance in North America in recent years. Several genes conferring resistance to rust have been identified in sunflower, but few of them have been genetically mapped and linked to molecular markers. The rust resistance gene R ₄ in the germplasm line HA-R3 was derived from an Argentinean open-pollinated variety and is still one of most effective genes. The objectives of this study were to determine the chromosome location of the R ₄ gene and the allelic relationship of R ₄ with the R _adv rust resistance gene. A total of 63 DNA markers previously mapped to linkage group (LG) 13 were used to screen for polymorphisms between two parental lines HA 89 and HA-R3. A genetic map of LG 13 was constructed with 21 markers, resulting in a total map length of 93.8 cM and an average distance of 4.5 cM between markers. Two markers, ZVG61 and ORS581, flanked the R ₄ gene at 2.1 and 0.8 cM, respectively, and were located on the lower end of LG 13 within a large NBS-LRR cluster identified previously. The PCR pattern generated by primer pair ZVG61 was unique in the HA-R3 line, compared to lines HA-R1, HA-R4, and HA-R5, which carry other R ₄ alleles. A SCAR marker linked to the rust resistance gene R _adv mapped to LG 13 at 13.9 cM from the R ₄ locus, indicating that R _adv is not an allele of the R ₄ locus. The markers tightly linked to the R ₄ gene will facilitate gene pyramiding for rust resistance breeding of sunflower.     

Combining transgenic and natural resistance to obtain broad resistance to tospovirus infection in tomato (Lycopersicon esculentum mill)

This study was undertaken to develop tomato plants with broad resistanceto tospoviruses which are a major limiting factor to tomato productionworldwide. A nontransgenic tomato line Stevens-Rodale (S-R), six transgenictomato lines expressing the nucleocapsid (N) protein gene of the lettuceisolate of tomato spotted wilt virus (TSWV-BL), and progeny of the crosses between S-Rand three of the transgenic lines homozygous for the N gene were evaluated fortheir resistance to tospovirus infection in greenhouse inoculation tests. S-Rhas the Sw-5 gene that confers resistance to several TSWVisolates. The six transgenic lines showed high levels of resistance wheninoculated with either TSWV-BL or a tomato isolate from Hawaii (TSWV-H).However, these same plants were highly susceptible to the Brazilian isolate ofgroundnut ringspot virus (GRSV-BR). Plants with the Sw-5gene were resistant to TSWV-BL and GRSV-BR, but were susceptible to TSWV-H.When inoculated with any of the three viruses, the F₁ progeny of thecrosses exhibited a susceptible, tolerant, or resistant phenotype with a higherproportion of the plants being either tolerant or resistant. When F₂progeny from F₁ resistant plants of each cross were inoculated withany of the three viruses, a higher proportion of tolerant and resistant plantswas observed compared to the F₁ progeny. Our results show thepotential to obtain broad resistance to tospoviruses by combining transgenicand natural resistance in a single plant.     

Genetics of adult plant stripe rust resistance in CSP44, a selection from Australian wheat

Wheat line CSP44, a selection from an Australian bread wheat cultivar Condor, has shown resistance to stripe rust in India since the last twenty years. Seedlings and adult plants of CSP44 showed susceptible infection types against stripe rust race 46S119 but displayed average terminal disease severity of 2.67 on adult plants against this race as compared to 70.33 of susceptible Indian cultivar, WL711. This suggests the presence of nonhypersensitive adult plant stripe rust resistance in the line CSP44. The evaluation of F₁, F₂ and F₃ generations and F₆ SSD families from the cross of CSP44 with susceptible wheat cultivar WL711 for stripe rust severity indicated that the resistance in CSP44 is based on two genes showing additive effect. One of these two genes isYr18 and the second gene is not yet described.     

Transposition of the maize autonomous element Activator in transgenic Nicotiana plumbaginifolia plants

The maize autonomous transposable element Ac was introduced into haploid Nicotiana plumbaginifolia via Agrobacterium tumefaciens transformation of leaf disks. All the regenerated transformants (R0) were diploid and either homozygous or heterozygous for the hygromycin resistance gene used to select primary transformants. The Ac excision frequency was determined using the phenotypic assay of restoration of neomycin phosphotransferase activity and expression of kanamycin resistance among progeny seedlings. Some of the R0 plants segregated kanamycin-resistant seedlings in selfed progeny at a high frequency (34 to 100%) and contained one or more transposed Ac elements. In the primary transformants Ac transposition probably occurred during plant regeneration or early development. Other R0 transformants segregated kanamycin-resistant plants at a low frequency ( 4%). Two transformants of this latter class, containing a unique unexcised Ac element, were chosen for further study in the expectation that their kanamycin resistant progeny would result from independent germinal transposition events. Southern blot analysis of 32 kanamycin-resistant plants (R1 or R2), selected after respectively one or two selfings of these primary transformants, showed that 27 had a transposed Ac at a new location and 5 did not have any Ac element. Transposed Ac copy number varied from one to six and almost all transposition events were independent. Southern analysis of the R2 and R3 progeny of these kanamycin-resistant plants showed that Ac continued to transpose during four generations, and its activity increased with its copy number. The frequency of Ac transposition, from different loci, remained low ( 7%) from R0 to R3 generations when only one Ac copy was present. The strategy of choosing R0 plants that undergo a low frequency of germinal excision will provide a means to avoid screening non-independent transpositions and increase the efficiency of transposon tagging.     

Peroxidase Activity in Soybeans Following Inoculation with Phytophthora sojae

The effects of race-specific resistance as conditioned by Rps genes (rps, Rps1-k, Rps2, Rps3, Rps6) in two genetic backgrounds (Williams & Harosoy) on accumulation of soluble peroxidases were determined by a soybean peroxidase capture assay (SPCA) after inoculation with P. sojae races 2, 7, or 25. Peroxidase activity increased in all isolines during the 72 h after inoculation, but reactions varied depending on time after inoculation, genetic background, Rps gene and P. sojae race. Peroxidase activity was higher in race-specific resistant than in susceptible reactions at 72 h. after inoculation, except for plants with the Rps2 gene which confers a unique form of root resistance in addition to the whole plant race-specific resistance. Williams isolines had larger increases in peroxidase activity than Harosoy isolines when data were averaged across Rps genes, and was most evident when plants were inoculated with race 2. When soybeans were inoculated with race 7 Rps1-k resistant plants had the highest increase in peroxidase activity, but Rps2 susceptible plants had a significantly higher peroxidase activity than plants with rps, Rps3, and Rps6 that were also susceptible. Results from inoculations with race 25 were somewhat different, Rps2 resistant plants had the highest increase in peroxidase activity; however, plants with the Rps3 or Rps6 gene that were also resistant did not have a significantly higher peroxidase activity than susceptible plants with the rps or Rps1-k gene.     

Cloning and characterization of the durable tomato mosaic virus resistance gene Tm-22 from Lycopersicon esculentum

In tomato, infections by tomato mosaic virus are controlled by durable Tm-2² resistance. In order to gain insight into the processes underlying disease resistance and its durability, we cloned and analysed the Tm-2² resistance gene and the susceptible allele, tm-2. The Tm-2² gene was isolated by transposon tagging using a screen in which plants with a destroyed Tm-2² gene survive. The Tm-2² locus consists of a single gene that encodes an 861 amino acid polypeptide, which belongs to the CC-NBS-LRR class of resistance proteins. The putative tm-2 allele was cloned from susceptible tomato lines via PCR with primers based on the Tm-2² sequence. Interestingly, the tm-2 gene has an open reading frame that is comparable to the Tm-2² allele. Between the tm-2 and the Tm-2² polypeptide 38 amino acid differences are present of which 26 are located in the second half of the LRR-domain. Susceptible tomato plants, which were transformed with the Tm-2² gene, displayed resistance against ToMV infection. In addition, virus specificity, displayed by the Tm-2² resistance was conserved in these transgenic lines. To explain the durability of this resistance, it is proposed that the Tm-2²-encoded resistance is aimed at the Achilles' heel of the virus.     

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).