Tam3 produces a suppressible allele of the DAG locus of Antirrhinum majus similar to Mu-suppressible alleles of maize

Tam3 from Antirrhinum majus belongs to the Ac/Ds family of transposable elements. An allele of the DAG locus of Antirrhinum ( dag ::Tam3), which is required for chloroplast development and leaf palisade differentiation, has been generated by Tam3 insertion into the untranslated leader sequence of the gene. This allele gives rise to a cold-sensitive phenotype, where mutant tissue containing wild-type revertant somatic sectors is observed in the leaves of plants grown at 15°C, while leaves of plants grown at 25°C appear near wild-type. The temperature sensitivity of dag ::Tam3 results from expression of the DAG locus responding to the activity of the transposable element, the transposition of which is very sensitive to growing temperature. Genetic suppression of Tam3 transposition, using the STABILISER locus, also results in suppression of the dag mutant phenotype. dag ::Tam3 represents a Tam3-suppressible allele similar to those described for Mu transposons in maize. Suppression of the dag mutant phenotype in response to element inactivation appears to result from use of an alternative promoter at the 3' end of the Tam3 element. The production of suppressible alleles by an Ac-like element is discussed in relation to the mutagenic potential of plant transposons in producing complex genetic diversity.     

Molecular analysis of paramutant plants of Antirrhinum majus and the involvement of transposable elements

Paramutation is observed when the Antirrhinum majus lines 44 and 53 are crossed. These two lines both have insertions at the nivea locus, which encodes chalcone synthase (chs). The allele niv-53 carries the transposable element Tam1 in the promoter region of the chs gene; niv-44 carries the element Tam2 within the gene. The Tam1 element has previously been extensively characterised. Here the Tam2 element is further characterised, and the arrangement of the nivea locus in paramutant plants is analysed. The complete sequence of Tam2, and that of a partial cDNA complementary to it, have been determined. The cDNA is probably transcribed from a different copy of Tam2 from that present at the nivea locus, and does not encode a functional protein. Genomic Southerns of F1 plants from the 53/44 cross show that no major rearrangements are consistently associated with paramutation at the nivea locus of A. majus. The isolation from a paramutant plant arising from a 53/44 cross of an allele (niv-4432) resulting from the excision of Tam2 is reported. The excision of Tam2 resulted in a 32 bp deletion of chs gene sequences. Plants homozygous for the new niv-4432 allele have white flowers and are still paramutagenic, demonstrating that Tam2 need not be present at the nivea locus for paramutation to occur. Different interactions between Tam1 and Tam2 are discussed, and a possible model for paramutation is presented.     

Large-scale chromosomal restructuring is induced by the transposable element tam3 at the nivea locus of antirrhinum majus

The transposable element, Tam3, gives rise to large-scale (greater than 1 kb) chromosomal rearrangements at a low frequency, when it is inserted at the nivea locus of Antirrhinum majus. Although some deletions may result from imprecise excision of Tam3, rearrangements involving deletion, dispersion and inverted duplication of flanking sequences, where Tam3 remains in situ, have also been identified. These rearrangements have been mapped at the molecular level, and the behavior of Tam3 following rearrangement has been observed. It is clear that Tam3 has enormous potential to restructure chromosomes through successive rounds of large-scale rearrangements. The mechanisms by which such rearrangements might arise are discussed.     

Molecular Analysis of a Transposon-Induced Deletion of the Nivea Locus in Antirrhinum Majus

The transposable element Tam3 of Antirrhinum majus is capable of causing large-scale chromosomal restructuring. It induced a large deletion at the nivea locus, to produce the allele niv-:529. The deletion removed the entire nivea coding region while the element remains intact with the potential to induce further rearrangements. Genetic experiments showed that the endpoint of the deletion (called x) is closely linked to nivea. The DNA sequences of niv-:529, a genomic excision of Tam3 from niv-:529, and the original genomic position of x have been determined. These data suggest that the deletion could have resulted from an abortive transposition or through breakage and religation.     

Immobilized copies with a nearly intact structure of the transposon Tam3 in Antirrhinum majus: implications for the cis-element related to the transposition

 In this study we have focused on two copies of the transposon Tam3 isolated from an Antirrhinum majus plant which has flower variegation due to the excision of Tam3 from the nivea locus. These two copies possess a high homology, over 95%, to an active Tam3 element found in the nivea ^{recurrence:Tam3} allele. Although somatic excision of the Tam3 copy from the nivea locus can be detected at 15°C by Southern blotting, neither of the two copies showed any sign of the excision. Both of the immobilized copies were also found in five varieties from different A. majus sources, all of which contain common fragments. The results suggest that the two copies have been fixed in the genomes of many A. majus varieties. Structural differences between these immobilized copies and the known active copy were mainly observed in the subterminal regions, including the terminal inverted repeats. The immobility of the two Tam3 copies might be due to mutations within the end regions of essential cis-elements in Tam3 transposition, as reported for Ac and En/Spm. Received: 30 June 1997 / Accepted: 5 August 1997     

Genome juggling by transposons: Tam3-induced rearrangements in Antirrhinum majus

Transposable elements are well known for their ability to generate large- and small-scale rearrangements of the sequences flanking their insertion sites. These include deletions, inversions, and duplications. Tam3, a transposon from the Snapdragon (Antirrhinum majus), is highly active in the generation of such rearrangements. We have analysed a number of Tam3-induced rearrangements at the nivea (niv) locus by Southern blotting, cloning, and sequence determination. The data obtained from these analyses have led to an understanding of the mechanisms by which these complex alleles were formed. We have shown that the primary rearrangements usually occur without excision of the element and therefore result from aberrant transposition attempts. Subsequent rearrangements may occur on excision of the element. Finally, we suggest how the analysis of such rearrangements may not only provide information about Tam3 transposition but also show how transposon-induced rearrangements may influence the structure and function of the genome as a whole.     

The transposable element Tam3 of Antirrhinum majus generates a novel type of sequence alterations upon excision

Summary The 3.5 kb transposable element, Tam3, has been shown to cause somatic and germinal instability at the nivea locus, which encodes chalcone synthase, of Antirrhinum majus. Molecular cloning and sequence analysis of the niv-98::Tam3 allele revealed that the termini of Tam3 consist of 12 bp perfect inverted repeats. Tam3 is integrated in the promoter region of the chalcone synthase gene and generates an 8 bp duplication of target sequences upon integration. DNA sequencing of a niv ⁺x revertant, niv-164, revealed a new type of sequence alteration upon excision: the duplications are displaced by ten nucleotides generated from adjacent sequences. Structural similarities of Tam3 and the maize elements Ac/Ds suggest that these elements belong to a common family.Dedicated to Professor Georg Melchers to celebrate his 50-year association with the journal     

De novo activation of the transposable element Tam2 of Antirrhinum majus

Summary The nivea locus of Antirrhinum majus encodes the enzyme chalcone synthase required for the synthesis of red anthocyanin pigment. The stable allele niv-44 contains an insertion in the nivea gene (Tam2) which has all the structural features of a transposable element. We have shown that this insertion can excise from the nivea locus when niv-44 is combined with another allele (niv-99) in a heterozygote. Activation of Tam2 excision is caused by a factor tightly linked to the niv-99 allele and may be due to complementation between Tam2 and a related element, Tam1. Factors which repress the excision of Tam2 and Tam1 are also described. Repression is not inherited in a simple mendelian way. Many stable mutations may be due to the insertion of transposable elements. Our data suggest that their stability may be due to the absence in the genome of activating factors and to the presence of repressors.     

Comparison of genetic behaviour of the transposable element Tam3 at two unlinked pigment loci in Antirrhinum majus

Summary In Antirrhinum majus the transposable element Tam3 has been described at two unlinked loci pallida and nivea, both of which are required for the production of anthocyanin pigment in flowers. In each case the element is inserted in the promoter region and gives a variegated phenotype. We show that the rate of Tam3 excision at both loci is greatly affected by temperature, being approximately 1000-fold higher at 15°C compared with 25°C. Tam3 is also controlled by an unlinked gene Stabiliser, which considerably reduces excision rate. We show that the high degree of sensitivity to temperature and Stabiliser is an intrinsic property of Tam3 which is not shared by an unrelated element, Tam1. The Tam3 insertion at nivea gives rise to a series of alleles which confer reduced pigmentation, novel spatial patterns and changed instability. These are probably a result of imprecise excision and rearrangements of the Tam3 element.     

Molecular and functional characterization of Slide,anAc-like autonomous transposable element from tobacco

A new transposable element of tobacco, Slide, was isolated from thetl mutant line, which shows somatic instability, after its transposition into a locus encoding nitrate reductase (NR). The Slide-124 element is 3733 bp long and its coding sequences show similarities with conserved domains of the transposases ofAc, Tam3 andhobo. Excision from the NR locus is detectable in somatic leaf tissues and Slide mobility is triggered by in vitro tissue culture. Slide excision events create footprints similar to those left byAc and Tam3. Tobacco lines derived from thetl mutant line seem characterized by unmethylated copies of a few members of the highly repetitive Slide family. Slide mobility was monitored in transient expression assays. In wild-type tobacco protoplasts, the complete Slide element, as well as a defective copy, is able to excise. The complete Slide element, but not the defective version, is able to excise in protoplasts of the heterologous species lettuce (Lactuca sativa). These results show that Slide carries the functions required for its own mobility, and represents the first autonomousAc-like element characterized inSolanaceae species.     

Molecular and functional characterization of Slide, anAc-like autonomous transposable element from tobacco

A new transposable element of tobacco, Slide, was isolated from thetl mutant line, which shows somatic instability, after its transposition into a locus encoding nitrate reductase (NR). The Slide-124 element is 3733 bp long and its coding sequences show similarities with conserved domains of the transposases ofAc, Tam3 andhobo. Excision from the NR locus is detectable in somatic leaf tissues and Slide mobility is triggered by in vitro tissue culture. Slide excision events create footprints similar to those left byAc and Tam3. Tobacco lines derived from thetl mutant line seem characterized by unmethylated copies of a few members of the highly repetitive Slide family. Slide mobility was monitored in transient expression assays. In wild-type tobacco protoplasts, the complete Slide element, as well as a defective copy, is able to excise. The complete Slide element, but not the defective version, is able to excise in protoplasts of the heterologous species lettuce (Lactuca sativa). These results show that Slide carries the functions required for its own mobility, and represents the first autonomousAc-like element characterized inSolanaceae species.     

Phenotypic effects of short-range and aberrant transposition in Antirrhinum majus

We describe two novel ways in which changes in gene expression in Antirrhinum majus may arise as a consequence of the Tam3 transposition mechanism. One involves excision of Tam3 from the nivea gene promoter and insertion of two new Tam3 copies 3.4 kb and 2.1 kb away, on either side of the excision site. One of the new insertions is in the nivea coding region and completely blocks production of an active gene product. This allele probably arose by a symmetrical double transposition, following chromosome replication. The second case involves a small deletion at one end of Tam3 in the pallida gene, flanked by a sequence typical of a Tam3 excision footprint. This suggests that the end of Tam3 was cleaved at an early step in an attempted transposition and re-ligated back to its original flanking sequence. The alteration restores some expression to the pallida gene, suggesting that the ends of the intact Tam3 element contain components which can actively inhibit gene expression. The implications of these findings for the mechanism of Tam3 transposition and for the effects of Tam3 on host gene expression are discussed.     

The transposable element Tam1 of Antirrhinum majus is 17 kb long

Summary The nivea locus of Antirrhinum majus encodes chalcone synthase, a key enzyme in anthocyanin biosynthesis. Genetic instability is known to occur at this locus. In vitro cloning and characterization of genomic DNA fragments from the unstable nivea-recurrens allele T53 revealed that the instability of nivea-recurrens is due to the presence of a 17 kb DNA insert in the nivea locus. Somatic instability leading to the variegated phenotype, i.e. highly spotted flowers, is due to frequent excision of the 17 kb Tam1 element (Transposon antirrhinum majus) during development of the plant. Excision of Tam1 is not tissue specific, but occurs with similar frequencies in leaves and blossoms.     

Interaction between the Tam1 and Tam2 transposable elements of Antirrhinum majus

Summary Two stable derivatives of the highly unstable niv-53::Tam1 allele of Antirrhinum majus were analysed. In both derivatives the Tam1 element is integrated at the same site and in the same orientation as in the parental niv-53::Tam1 allele. In both cases the Tam1 element was found to carry a 5 bp deletion (CACTA) in one of its termini. This explains the excision deficiency of these two alleles of Tam1, niv-53::Tam1-46 and niv-53::Tam1-49. Niv-44::Tam2, another stable nivea mutation, carries the 5 kb element Tam2, which is not a derivative of Tam1 but possesses identical terminal inverted repeats. When the stable lines 46 and 49 were corssed with line 44, suprisingly, a high number of the flowers in the F₁ displayed a variegated phenotype. Sequence analysis of two germinal revertants isolated from the heterozygote niv-53::Tam1-46/niv-44::Tam2 shows excision of the Tam2 element. This indicates that Tam2 is a defective element, which can be complemented by an active Tam1 element. However, the variegated F₁ phenotype observed is not inherited monofactorially. Variegation is seen only at particular times of development of the F₁ plants. These phenomena seem to involve both the Tam1 and Tam2 transposable elements.     

Activity of the transposon Tam3 in Antirrhinum and tobacco: possible role of DNA methylation.

The transposon Tam3 from Antirrhinum majus can transpose in a heterologous host (Nicotiana tabacum); thus the element is autonomous, probably encoding the specific information required for its own transposition. In transgenic tobacco Tam3 rapidly becomes methylated at its ends whilst adjacent flanking sequences remain hypomethylated. This methylation may account for our failure to detect Tam3 transposition in the progeny of transgenic tobacco. Treatment with the inhibitor of cytosine methylation, 5 aza-cytosine appeared to induce transposon related activity at a low level. In Antirrhinum methylation also appears to be associated with inactivation of Tam3 copies.     

The 17-kb Tam1 element of Antirrhinum majus induces a 3-bp duplication upon integration into the chalcone synthase gene

The DNA sequence of the termini and the flanking regions of the 17-kb transposable element Tam1 was determined. Tam1 is integrated in the chalcone synthase gene of the niv-53 mutant of Antirrhinum majus. The element has a 13-bp perfect inverted repeat at its termini and appears to induce a 3-bp duplication of the target site upon integration. The DNA sequence of a niv⁺ revertant was analyzed and found to differ from the wild-type sequence by an additional 2 bp that seem to derive from the target site duplication. Stretches of homologous sequences have been found between the ends of Tam1, within each terminus of the element, and between the termini and target site sequences. Structural similarities between the ends of Tam1 and the Spm-18 element of Zea mays reflect a possible horizontal spread of a common progenitor.     

Evidence forTAM3 activity in transgenicArabidopsis thaliana

Summary TheAntirrhinum majus Tam3 element was introduced intoArabidopsis thaliana protoplasts and plants in order to assess the influence of anin vitro culture phase such as protoplasts and callus culture on the mobility of this transposable element in this plant species. The constructs used contained theTam3 element inserted in between the CaMV 35S promoter and thegus- orhpt-coding region, allowing a direct selection of excision candidates. From the different approaches used, only a long-term callus culture allowed us to detectTam3 activity. NoTam3 activity could be detected in protoplasts or protoplast-derived microcolonies. Our data are compared with those previously reported forTam3 in tobacco and petunia.     

Temperature controls nuclear import of Tam3 transposase in Antirrhinum

It has been proposed that environmental stimuli can activate transposable elements (TEs), whereas few substantial mechanisms have been shown so far. The class-II element Tam3 from Antirrhinum majus exhibits a unique property of low-temperature-dependent transposition (LTDT). LTDT has proved invaluable in developing the gene isolation technologies that have underpinned much of modern plant developmental biology. Here, we reveal that LTDT involves differential subcellular localization of the Tam3 transposase (TPase) in cells grown at low (15°C) and high (25°C) temperatures. The mechanism is associated with the nuclear import of Tam3 TPase in Antirrhinum cells. At high temperature, the nuclear import of Tam3 TPase is severely restricted in Antirrhinum cells, whereas at low temperature, the nuclear localization of Tam3 TPase is observed in about 20% of the cells. However, in tobacco BY-2 and Allium cepa (onion) cells, Tam3 TPase is transported into most nuclei. In addition to three nuclear localization signals (NLSs), the Tam3 TPase is equipped with a nuclear localization inhibitory domain (NLID), which functions to abolish nuclear import of the TPase at high temperature in Antirrhinum. NLID in Tam3 TPase is considered to interact with Antirrhinum-specific factor(s). The host-specific regulation of the nuclear localization of transposase represents a new repertoire controlling class-II TEs.