Resistance to gap repair of the transposon Tam3 in Antirrhinum majus: a role of the end regions

The extremely homogeneous organization of the transposon family Tam3 in Antirrhinum majus is in sharp contrast to the heterogeneity of the copies constituting many other transposon families. To address the issue of the Tam3 structural uniformity, we examined two possibilities: (1) recent invasion of Tam3 and (2) failure of gap repair, which is involved in conversion from autonomous forms to defective forms. The phylogenetic analysis of 17 Tam3 copies suggested that the invasion of Tam3 into the Antirrhinum genome occurred at least 5 mya, which is sufficiently long ago to have produced many aberrant copies by gap repair. Thus, we investigated gap repair events at the nivea(recurrens:Tam3) (niv(rec)::Tam3) allele, where Tam3 is actively excised. We show here that the gap repair of de novo somatic Tam3 excision was arrested immediately after initiation of the process. All of the identified gap repair products were short stretches, no longer than 150 bp from the ends. The Tam3 ends have hairpin structures with low free energies. We observed that the gap repair halted within the hairpin structure regions. Such small gap repair products appear to be distributed in the Antirrhinum genome, but are unlikely to be active. Our data strongly suggest that the structural homogeneity of Tam3 was caused by immunity to gap repair at the hairpins in both of the end regions. The frequency of extensive gap repair of de novo excision products in eukaryotic transposons was found to be correlated with the free energies of the secondary structures in the end regions. This fact suggests that the fates of transposon families might depend on the structures of their ends.     

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.     

Duplication of floral regulatory genes in the Lamiales

Duplication of some floral regulatory genes has occurred repeatedly in angiosperms, whereas others are thought to be single-copy in most lineages. We selected three genes that interact in a pathway regulating floral development conserved among higher tricolpates (LFY/FLO, UFO/FIM, and AP3/DEF) and screened for copy number among families of Lamiales that are closely related to the model species Antirrhinum majus. We show that two of three genes have duplicated at least twice in the Lamiales. Phylogenetic analyses of paralogs suggest that an ancient whole genome duplication shared among many families of Lamiales occurred after the ancestor of these families diverged from the lineage leading to Veronicaceae (including the single-copy species A. majus). Duplication is consistent with previous patterns among angiosperm lineages for AP3/DEF, but this is the first report of functional duplicate copies of LFY/FLO outside of tetraploid species. We propose Lamiales taxa will be good models for understanding mechanisms of duplicate gene preservation and how floral regulatory genes may contribute to morphological diversity.     

Position effect of the excision frequency of the Antirrhinum transposon Tam3: implications for the degree of position-dependent methylation in the ends of the element

We identified eight independent Tam3 copies residing in the same Antirrhinum majus genome. All the copies showed excision at 15 °C, but not at 25 °C. Under conditions promoting excision, each copy appeared to transpose in the leaves and flower lobes with a nearly constant frequency, whereas individual transposition abilities varied widely: the most active copy had an excision frequency more than 100-fold greater than that of the least active one. Despite the different transposition abilities, the structures of the eight Tam3 copies were almost identical. These results made it clear that the transpositional ability of Tam3 is regulated by chromosomal position, but they do not imply position-dependent transposase activity. The position effect of the Tam3 transposition was found to be correlated to the methylation state of the copy's end regions: DNA methylation in the Tam3 end regions tended to suppress the excision activity, and the degree of methylation was dependent on the chromosomal position. Our results also provide evidence of de novo methylation provoked by transposition of the endogenous element. We propose a mechanism of transpositional regulation of plant transposons that responds to the degree of methylation as determined by chromosomal position.     

Tam3 in Antirrhinum majus is exceptional transposon in resistant to alteration by abortive gap repair: identification of nested transposons

Most transposon families consist of heterogeneous copies with varying sizes. In contrast, the Tam3 copies in Antirrhinum majus are known to have exceptionally conserved structures of uniform size. Gap repair has been reported to be involved in the structural alteration of copies from several transposon families. In this study, we have asked whether or not gap repair has affected Tam3 copies. Five Tam3 copies carrying aberrant sequences were selected from 40 independent Tam3 clones and their sequences were analyzed. Two of the five copies contain insertions in the Tam3 sequence. These two insertions, designated Tam356 and Tam661, are typical transposon-like sequences, which have terminal inverted repeats and cause target site duplication. These nested transposons were obviously associated with transpositional events, and did not originate from the gap-repair process. The remaining three copies had lost large parts of the Tam3 sequence. We could not find any relationship between the deletions of Tam3 sequence in the three copies and gap repair. PCR analysis of a Tam3 excision site in the nivea ^{recurrence:Tam3} mutant also showed that most of the repair events after the Tam3 excision involved end-joining. In addition to the results obtained here, among the other clones isolated, we could not find any of the internally deleted copies that comprise a major part of other transposon families. All of these data suggest that some feature of the Tam3 structure suppresses the structural alterations that are otherwise generated during the gap repair process.     

Tam3 in Antirrhinum majus is exceptional transposon in resistant to alteration by abortive gap repair: identification of nested transposons

Most transposon families consist of heterogeneous copies with varying sizes. In contrast, the Tam3 copies in Antirrhinum majus are known to have exceptionally conserved structures of uniform size. Gap repair has been reported to be involved in the structural alteration of copies from several transposon families. In this study, we have asked whether or not gap repair has affected Tam3 copies. Five Tam3 copies carrying aberrant sequences were selected from 40 independent Tam3 clones and their sequences were analyzed. Two of the five copies contain insertions in the Tam3 sequence. These two insertions, designated Tam356 and Tam661, are typical transposon-like sequences, which have terminal inverted repeats and cause target site duplication. These nested transposons were obviously associated with transpositional events, and did not originate from the gap-repair process. The remaining three copies had lost large parts of the Tam3 sequence. We could not find any relationship between the deletions of Tam3 sequence in the three copies and gap repair. PCR analysis of a Tam3 excision site in the nivea ^{recurrence:Tam3} mutant also showed that most of the repair events after the Tam3 excision involved end-joining. In addition to the results obtained here, among the other clones isolated, we could not find any of the internally deleted copies that comprise a major part of other transposon families. All of these data suggest that some feature of the Tam3 structure suppresses the structural alterations that are otherwise generated during the gap repair process. Received: 22 April 1998 / Accepted: 15 June 1998     

Transposable elements generate novel spatial patterns of gene expression in Antirrhinum majus

The pallida gene of A. majus encodes a product required for the synthesis of red flower pigment. We have shown that the unstable pallida(recurrens) mutation is due to the insertion of the Tam3 transposable element near the promoter of the gene. Imprecise excision of Tam3 alters pallida gene expression and generates new spatial patterns or different intensities of flower pigmentation. Distinct spatial patterns may also result from rearrangements induced by Tam3 that alter the relative position of the pallida gene. Changes in Tam3 structure or position result in new unstable phenotypes. These findings suggest that genes may be rendered genetically hypervariable as a consequence of transposable element insertion and excision.     

Hypervariability in Gene Copy Number for the Glucose Transporter Genes in Trypanosomes

The copy number of the gene encoding the carrier protein responsible for the uptake of glucose in bloodstream form Trypanosoma brucei (THT1) was investigated in the genome of 55 different members of the subgenus Trypanozoon. The gene is present in multiple copies in tandem arrays on two homologous chromosomes in these organisms, and copy number varies both intra- and interspecifically. Variability is also apparent in the number of genes encoding a second hexose transporter (THT2) which is the only isoform expressed in procyclic organisms. Multiple copies of THT2 are conserved in representatives of the non-tsetse transmitted species, Trypanosoma evansi and Trypanosoma equiperdum.     

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.     

DNA methylation is not necessary for the inactivation of the Tam3 transposon at non-permissive temperature in Antirrhinum

It has been proposed that DNA methylation plays an important role in the inactivation of transposons. This view stems from a comparison of the degree of methylation of transposons in the active and inactive state. However, direct evidence for the degree of methylation required for the suppression of transposition has not been reported. Transposon Tam3 in Antirrhinum majus undergoes somatic reversal of its transposition activity, which is tightly controlled by temperature: low temperature around 15 degrees C permits transposition, high temperatures around 25 degrees C strongly inhibits it. Our previous study had shown that the methylation state of the Tam3 end regions is negatively correlated with the Tam3 transposition frequency. The results of the present study reveal that the inactive state of Tam3 copies at high temperature is unlikely to be directly coupled to the methylation state. Treatment with methylation inhibitors (5-azacytidine or 5-azacytidine+ethionine) does not affect Tam3 excision frequency in calli derived from Antirrhinum hypocotyls. The results suggest that methylation is not essential for the suppression of Tam3 transposition at high temperature, but rather that some other mechanism(s) involved in the control of Tam3 transposition may be obscured by methylation.     

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     

Dgp1 and Dfp1 are closely related plasmids in the Dictyostelium Ddp2 plasmid family

Dictyostelium plasmids Dgp1 and Dfp1, two members of the Ddp2 plasmid family, are 86% identical in nucleotide sequence. These small (4481 and 5015 bp), high copy number, nuclear plasmids carry both a gene homologous to the Ddp2 rep gene and a long 0.47- to 0. 48-kb inverted repeat region. Their Rep proteins are 82.8% identical in amino acid sequence and carry all 10 of the conserved peptide sequence motifs found in the Ddp2 family Rep proteins. Unlike other members of this family, Dgp1 carries two copies and Dfp1 carries four copies of a 162- to 166-bp direct repeat element. Both the direct and inverted repeat elements, as well as the promoter of the rep gene, are highly conserved (81 to 90% identical) between Dgp1 and Dfp1. In contrast, these regions are not highly conserved and the Rep proteins are only about 40% identical among the other known members of the plasmid family.     

A novel transposon-like repeat interrupted by an LTR element occurs in a cluster of B1 repeats in the mouse c-mos locus.

The mouse genomic locus containing the oncogene c-mos was analyzed for repetitive DNA sequences. We found a single B1 repeat 10 kb upstream and three B1 repeats 0.6 kb, 2.7 kb, and 5.4 kb, respectively, downstream from c-mos. The B1 repeat closest to c-mos contains an internal 7-bp duplication and a 18-bp insertion. Localized between the last two B1 repeats is a copy of a novel mouse repeat. Sequence comparison of three copies of this novel repeat family shows that they a) contain a conserved BglII site, b) are approximately 420 bp long, c) possess internal 50-bp polypurine tracts, and d) have structural characteristics of transposable elements. They are present in about 1500 copies per haploid genome in the mouse, but are not detectable in DNA of other mammals. The BglII repeat downstream from c-mos is interrupted by a single 632-bp LTR element. We estimate that approximately 1200 copies of this element are present per haploid genome in BALB/c mice. It shares sequence homology in the R-U5 region with an LTR element found in 129/J mice.     

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.     

Population Genetics of an Expanding Family of Mobile Genetic Elements

A model of an expanding family of dispersed repetitive DNA was studied. Based on the previous result of the model of duplicative transposition, an approximate solution to give allelism and identify coefficients as functions of time was obtained, and theoretical predictions were verified by Monte Carlo experiments. The results show that, even if the copy number per genome increases very rapidly, allelism and identity coefficients may take a long time to reach equilibrium. The changes of allelism and allelic identity are similar to that of homozygosity at an ordinary single locus, whereas that of nonallelic identity can be much slower, particularly when the copy number per genome is large. Thus, many existing families of highly repetitive sequences may represent nonequilibrium states for nonallelic identity. The present model may be extended to include other evolutionary forces such as gene conversion or the recurrent insertion from normal gene copies.     

Comparative analysis of a translocated copy of the trnK intron in carnivorous family Nepenthaceae

During phylogenetic analysis of the Nepenthaceae cpDNA trnK intron, it became apparent that a second non-functional copy of the locus was present in most of the investigated taxa. The translocation event was older than the radiation of all recent Nepenthaceae, and the translocated pseudogenized copy was conserved in nearly all members of the plant family. Using single chloroplast PCR and inverse PCR, we could exclude a plastom location for the second copy. Although translocation into the nucleus is possible, mitochondrial localization seems more likely based on these data. In total, the translocated sequence contained at least 3525 base pairs (bp) that were homologous to the Spinacia oleracea chloroplast genome. Comparative phylogenetic analysis of the non-functional copy revealed a high amount of homoplasies compared to topologies from the cpDNA trnK intron phylogenetic reconstruction. Therefore, this copy proved to be insufficient for phylogenetic reconstruction of the family. Since two different paralogs of the non-functional copy were found in one species, it is feasible that different paralogs were conserved in different groups and that paralogous sequences were included in the data matrix. These data demonstrate that phylogenetic analyses of pseudogenized copies of phylogenetically relevant loci should be performed with great caution. In addition, pseudogenized copies can exist in nearly every member of a plant family, and can be PCR-amplified at levels comparable to the specific copy. In this case, the inclusion of such copies can easily remain unnoticed, thus leading to faulty hypotheses.     

Determination of the copy number of the nuclear rDNA and beta-tubulin genes of Pneumocystis carinii f. sp. hominis using PCR multicompetitors

Multiple copies of a gene may lead to difficulty in the interpretation of typing results because polymorphism of the copies may wrongly lead to the conclusion that different types are present in a specimen. To determine the copy number per genome of the nuclear rDNA and beta-tubulin genes analyzed for the typing of Pneumocystis carinii f. sp. hominis, we developed a strategy based on the use of the same multicompetitor molecule in two different quantitative-competitive PCRs, one for the gene under study and the other for a reference single copy gene, allowing direct comparison of the results of both PCRs. Control experiments showed that the strategy was sensitive enough to detect duplication of a gene. The copy number of the nuclear rDNA operon was determined by amplification of the intron of the 26S rDNA gene and that of the beta-tubulin by amplification of the region surrounding the intron no. 6. The method was first tested on P. c. carinii, the special form commonly infecting rats. Pneumocystis c. carinii was found to contain a single copy of the rDNA operon. The method was then applied to P. c. hominis. The results confirmed that P. c. hominis genome contains a single copy of the nuclear rDNA and beta-tubulin genes.