Implications for the cis-requirements for Ds transposition based on the sequence of the wxB4 Ds element

Summary The nucleotide sequence of the 1494 by wxB4 Ds element is presented. A comparison with previously characterized Ds elements reveals several novel features. This element has less Ac terminal sequence than other Ac-like Ds elements. The left terminus contains 398 by of Ac sequence interrupted by a transposon-like DNA insertion, leaving only 317 by of contiguous Ac sequence. The right terminus has 259 by of Ac terminal sequence. The interior of the element contains sequences not found in other cloned members of the Ac/Ds family. We suggest that the role of this non-Ac DNA is to separate the Ac termini by a minimum distance and may be a cis requirement for Ds transposition in maize.Abbreviations Ac activator - Adh1 alcohol dehydrogenase 1 - Ds dissociation - RFLP restriction fragment length polymorphism - Spm suppressor mutator - Wx waxy     

A maize cryptic Ac-homologous sequence derived from an Activator transposable element does not transpose.

Summary Sequences sharing homology to the transposable element Activator (Ac) are prevalent in the maize genome. A cryptic Ac-like DNA, cAc-11, was isolated from the maize inbred line 4Co63 and sequenced. Cryptic Ac-11 has over 90% homology to known Ac sequences and contains an 11 by inverted terminal repeat flanked by an 8 by target site duplication, which are characteristics of Ac and Dissociation (Ds) transposable elements. Unlike the active Ac element, which encodes a transposase, the corresponding sequence in cAc-11 has no significant open reading frame. A 44 by tandem repeat was found at one end of cAc-11, which might be a result of aberrant transposition. The sequence data suggest that cAc-11 may represent a remnant of an Ac or a Ds element. Sequences homologous to cAc-11 can be detected in many maize inbred lines. In contrast to canonical Ac elements, cAc-11 DNA in the maize genome is hypermethylated and does not transpose even in the presence of an active Ac element.     

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     

Analysis of the chromosomal distribution of transposon-carrying T-DNAs in tomato using the inverse polymerase chain reaction

We are developing a system for isolating tomato genes by transposon mutagenesis. In maize and tobacco, the transposon Activator (Ac) transposes preferentially to genetically linked sites. To identify transposons linked to various target genes, we have determined the RFLP map locations of Ac- and Dissociation (Ds)-carrying T-DNAs in a number of transformants. T-DNA flanking sequences were isolated using the inverse polymerase chain reaction (IPCR) and located on the RFLP map of tomato. The authenticity of IPCR reaction products was tested by several criteria including nested primer amplification, DNA sequence analysis and PCR amplification of the corresponding insertion target sequences. We report the RFLP map locations of 37 transposon-carrying T-DNAs. We also report the map locations of nine transposed Ds elements. T-DNAs were identified on all chromosomes except chromosome 6. Our data revealed no apparent chromosomal preference for T-DNA integration events. Lines carrying transposons at known map locations have been established which should prove a useful resource for isolating tomato genes by transposon mutagenesis.     

Excision of the maize transposable element Ac in flax callus

The frequency and fidelity of Ac transposition, and that of its non-autonomous derivative Ds, were investigated in flax callus. Flax (Linum usitatissimum var. Antares) hypocotyls were transformed with Agrobacterium Ti plasmid vectors containing the Ac or Ds element inserted within the untranslated leader sequence of a chimaeric neomycin phosphotransferase II gene. Kanamycin resistant tissues were produced as a result of excision of Ac in around 35% of the total number of Ac-containing transformants. In contrast, no excision was observed from transformants containing the Ds element. Whilst Ac appears to have excised completely from T-DNAs, little evidence was found to infer reintegration of the Ac element into the genome.Abbreviations NPT-II/npt-II Neomycin phosphotransferase II - kb Kilobasepairs - bp basepairs - MSO Murashige and Skoog medium - NAA naphthalene acetic acid - BAP 6-benzylaminopurine     

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.     

Some features about transposition of the maize elementDissociation inNicotiana plumbaginifolia

We have recently shown that a plasmid-borneDissociation (Ds) element can excise from extrachromosomal plasmid DNA and integrate into a plant genome in the presence of theActivator (Ac) transposase.Ds andAc-carrying plasmids were used to co-transformNicotiana plumbaginifolia protoplasts. Transgenic plants were regenerated and analyzed. Here we describe further characterization of the system and discuss its efficiency in terms of DNA transformation and transposon tagging.     

Molecular evolution of human T-cell leukemia virus

Summary In light of previous data, which suggested thatAc-like sequences might have undergone a significant radiation in the recent past, I examined the copy number ofAc-like sequences in representatives of all theZea taxa, both maize and teosinte. The maize and teosinte samples contained approximately equal numbers ofAc-like sequences. FewAc-like sequences were in unmethylated regions of DNA. Unmethylated elements were distributed randomly among both maize and teosinte lines. The appearance in a line of a discrete band resulting from digestion with one methylation-sensitive restriction enzyme was correlated with the appearance of discrete bands with other methylation-sensitive bands. This suggests that individualAc-like elements are occasionally demethylated in many sites. No unmethylated element having restriction fragments of the lengths predicted from the publishedAc sequence was seen in the approximately 326 elements examined.     

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).     

Evolution of Ac and Dsl elements in select grasses (Poaceae)

We present data on evolution of the Ac/Ds family of transposable elements in select grasses (Poaceae). An Ac-like element was cloned from a DNA library of the grass Pennisetum glaucum (pearl millet) and 2387 bp of it have been sequenced. When the pearl millet Ac-like sequence is aligned with the corresponding region of the maize Ac sequence, it is found that all sequences corresponding to intron II in maize Ac are absent in pearl millet Ac. Kimura's evolutionary distance between maize and pearl millet Ac sequences is estimated to be 0.429±0.020 nucleotide substitutions per site. This value is not significantly different from the average number of synonymous substitutions for coding regions of the Adh1 gene between maize and pearl millet, which is 0.395±0.051 nucleotide substitutions per site. If we can assume Ac and Adh1 divergence times are equivalent between maize and pearl millet, then the above calculations suggest Ac-like sequences have probably not been strongly constrained by natural selection. The level of DNA sequence divergence between maize and pearl millet Ac sequences, the estimated date when maize and pearl millet diverged (25–40 million years ago), coupled with their reproductive isolation/lack of current genetic exchange, all support the theory that Ac-like sequences have not been recently introduced into pearl millet from maize. Instead, Ac-like sequences were probably present in the progenitor of maize and pearl millet, and have thus existed in the grasses for at least 25 million years. Ac-like sequences may be widely distributed among the grasses. We also present the first 2 Dsl controlling element sequences from teosinte species: Zea luxurians and Zea perennis. A total of 10 Dsl elements had previously been sequenced from maize and a distant maize relative, Tripsacum. When a maximum likelihood network of genetic relationships is constructed for all 12 sequenced Dsl elements, the 2 teosinte Dsl elements are as distant from most maize Dsl elements and from each other, as the maize Dsl elements are from one another. Our new teosinte sequence data support the previous conclusion that Dsl elements have been accumulating mutations independently since maize and Tripsacum diverged. We present a scenario for the origin of Dsl elements.     

A genetic analysis of mutations recovered from tomato following Agrobacterium-mediated transformation with the maize transposahle elements Activator and Dissociation

Summary The maize autonomous transposable element, Activator (Ac), and the nonautonomous element Dissociation (Ds), were introduced into the tomato cultivars VF36 and VFNT Cherry by Agrobacterium-mediated transformation. Progeny families from 145 primary transformants were scored at the seedling stage for phenotypically variant individuals. When VF36 was transformed, 20% of families had progeny with aberrant phenotypes. The mutation frequency in VFNT Cherry transformants was lower; in this cultivar 7% of the transformants had progeny segregating for seedling mutations. The majority of the mutations showed monogenic inheritance in the R₁ population, suggesting that the mutations occurred early in the transformation/regeneration process. One mutation, however, was recovered at low frequency in the R₁, suggesting a late mutagenesis event. When tomato was transformed with either the Ac or Ds elements, no differences in mutation frequencies were observed. Since Ac is transpositionally active in tomato transformants while Ds is not, these numbers indicate that the mutation frequency inherent to the transformation process is higher than the mutational activity of Ac. These results demonstrate that efficient gene tagging using heterologous transposable elements will require screening for transposon-induced mutations in later generations.     

Transposition of a Ds element from a plasmid into the plant genome in Nicotiana plumbaginifolia protoplast-derived cells

Nicotiana plumbaginifolia haploid protoplasts were co-transformed with two plasmids, one with a NPT-II/Ds element and one with a gene encoding an amino-terminal truncated Ac transposase. It is shown that Ds can efficiently transpose from extrachromosomal DNA to N. plumbaginifolia chromosomes when the Ac transposase gene is present in trans. Ds has been shown to have transposed into the plant genome in a limited number of copies (1.9 copies per genome), for 21/32 transgenic lines tested. The flanking sequences present in the original plasmid are missing in these 21 plants. In only two of 21 plants was part of the transposase construct integrated. By segregation analysis of transgenic progeny, Ds was shown to be present in the heterozygous state in 10 lines even though haploid protoplasts had been originally transformed. This observation could indicate that integration occurred after or during DNA replication that leads to protoplast diploidization.     

Characterization of an unusual <Emphasis Type="Italic">Ds</Emphasis> transposable element in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>: Insertion of an abortive circular transposition intermediate

The maize Ac/Dstransposable elements, which belong to the hAT transposon superfamily, are widely used as insertional mutagens in numerous plant species. Molecular studies suggest that Ac/Ds elements transpose in a conservative non-replicative fashion; however the molecular mechanism of transposition remains unclear. We describe here the identification of an unusual Ds element, Ds-mmd1, in a transgenic Arabidopsis line. Ds-mmd1 is rearranged relative to the original Ds element, such that the original 5 and 3 ends are internal and previously internal sequences are the new 5 and 3 termini of Ds-mmd1. Short duplications of plant genomic DNA and Ds sequences are present at the Ds-mmd1 junctions, suggesting that a circular Dsmolecule was part of the events that created the Ds-mmd1 element. In addition, a revertant analysis on mmd1 plants demonstrated that Ds-mmd1 can be eliminated from the genome in an Ac-dependent process.     

Molecular evolutionary characterization of an Activator (Ac)-like transposable element sequence from pearl millet (Pennisetum glaucum) (Poaceae)

We present data on the evolution of the Ac/Ds family of transposable elements in select grasses (Poaceae). A defective Ac-like element was cloned from a DNA library of the grass Pennisetum glaucum (pearl millet) and its entire 4531 bp sequence has been determined. When the pearl millet Ac-like sequence is aligned with the maize Ac sequence, it is found that there is approximately 70% DNA similarity in the central region spanning most of maize Ac exon II and all of exon III. In addition, there are two smaller regions of similarity at the Ac terminii. Besides these three major structural similarities, Pennisetum Ac has two large regions, one 5 and one 3, that show little similarity to Zea Ac. Furthermore, most of the sequences corresponding to intron II in maize Ac are absent in pearl millet Ac. Kimura's evolutionary distance between the central region of maize and pearl millet Ac sequences is estimated to be 0.429±0.020 nucleotide substitutions per site. This value is not significantly different from the average number of synonymous substitutions for coding regions of the Adh1 gene between maize and pearl millet, which is 0.395±0.051 nucleotide substitutions per site. If we assume Ac and Adh1 divergence times are equivalent between maize and pearl millet, then the above calculations suggest Ac-like sequences have probably not been strongly constrained by natural selection. Conserved DNA and amino acid sequence motifs are also examined. The level of DNA sequence divergence between maize and pearl millet Ac sequences, the estimated date when maize and pearl millet diverged (25–40 million years ago), coupled with their reproductive isolation/lack of current genetic exchange, all support the theory that Ac-like sequences have not been recently introduced into pearl millet from maize. Instead, Ac-like sequences were probably present in the progenitor of maize and pearl millet and have thus existed in the grasses for at least 25 million years.     

Transposition of the maize Ds element from a viral vector to the rice genome

The geminivirus miscanthus streak virus (MiSV) was used as a gene vector to study the transposition of the maize Ds element in rice protoplasts. Efficient excision of the Ds from the MISV vector was observed only when the MiSV vector was allowed to replicate and the plasmid expressing the transposase gene encoded by Ac was co-transfected. Under the same condition, the Ds carrying a hygromycin phosphotransferase gene (Ds::HPT) was also efficiently excised. Hygromycin-resistant calli were obtained by culturing these transfected protoplasts in order to examine the transposition of the excised Ds::HPT into the rice genome. In five out of 16 calli examined, the Ds::HPT, but not the vector sequence, was integrated into the rice genome and 8 bp target site duplication typical of Ac/Ds transposition was generated. These results show that the Ds::HPT inserted in the MISV vector transposed directly into the rice genome. This demonstrates the direct transposition of a cloned plant transposable element into the plant genome. Implications of these finding are discussed.     

The binding motifs for Ac transposase are absolutely required for excision of Ds1 in maize

A reverse genetic system for studying excision of the transposable elementDs1 in maize plants has been established previously. In this system, theDs1 element, as part of the genome of maize streak virus (MSV), is introduced into maize plants via agroinfection. In the presence of theAc element, excision ofDs1 from the MSV genome results in the appearance of viral symptoms on the maize plants. Here, we used this system to study DNA sequences requiredin cis for excision ofDs1. TheDs1 element contains theAc transposase binding motif AAACGG in only one of its subterminal regions (defined here as the 5′ subterminal region). We showed that mutation of these motifs abolished completely the excision capacity ofDs1. This is the first direct demonstration that the transposase binding motifs are essential for excision. Mutagenesis with oligonucleotide insertions in the other (3′) subterminal region resulted in elements with either a reduced or an increased excision efficiency, indicating that this subterminal region also has an important function.     

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.     

Ac transposition in transgenic tomato plants

Summary As an initial step towards developing a transposon mutagenesis system in tomato, the maize transposable element Ac was transformed into tomato plants via Agrobacterium tumefaciens. Southern analysis of leaf tissue indicated that in nine out of eleven transgenic plants, Ac excised from the T-DNA and reintegrated into new chromosomal locations. The comparison of Ac banding pattern in different leaves of the same primary transformant provided evidnece for transposition during later stages of transgenic plant development. There was no evidence of Ds mobilization in tomato transformants.