Novel Transposable Elements in Solanaceae: Evolutionary Relationships among Tnt1-related Sequences in Wild Petunia Species

Transposable elements (TEs) are widespread in eukaryotic genomes. The diversity and abundance of TEs are highly variable among species and may correspond to particular relationships between a species and the elements in its genome. There are often many TE families within a single genome; thus, the amplification of one TE family may influence the amplification of other families. LTR retrotransposons (LTR-RTs) are extremely abundant in flowering plants, and Tnt1 is one of the most well known. First characterized in tobacco, Tnt1-related sequences have since been reported in other genera of Solanaceae. In this study, we investigated the profile of Tnt1-related sequences among the species of three Solanaceae genera through genomic amplification and the cloning of partial sequences. The analysis of these sequences revealed high levels of diversity and showed that the sequences are not as closely related to Tnt1 as had been previously hypothesized. The classification of the sequences yielded ten possible families of LTR-RTs, which are, in addition to Tnt1, all members of the Tork clade within the Copia superfamily. However, the sequences did not follow the phylogeny of the species and were not homogeneously distributed. One family includes only sequences of taxa that inhabit dry areas. These findings were consistent with previous suggestions of an early association of Tnt1-related elements with the evolution of several Solanaceae species.     

The distribution of copia-type retrotransposons and the evolutionary history of tomato and related wild species

Retrotransposons are mobile genetic elements that amplify throughout the genome and may be important contributors of genetic diversity. Their distribution is influenced by element behaviour and host-driven controls. We analysed the distribution of three copia-type retrotransposons, ToRTL1, T135 and Tnt1 using sequence-specific amplification polymorphism in self-compatible (SC) and incompatible (SI) species of Solanum subsection Lycopersicon, and genetically mapped polymorphic insertions in S. lycopersicum (tomato). The majority of polymorphic insertions (61%) are located in centromeric regions of the tomato genome. A significant positive relationship was detected between insertion polymorphisms and mating system, independent of selection as most insertions were found to be neutral. As insertion patterns successfully inferred interspecific relationships of Solanum subsection Lycopersicon, our results suggest that the distribution of ToRTL1, T135 and Tnt1 may essentially be determined by selection removing strongly deleterious insertions, with genetic drift and mating system, but not recombination rate, playing important roles.     

Distribution of the Tnt1 retrotransposon family in the amphidiploid tobacco (Nicotiana tabacum) and its wild Nicotiana relatives

Transposable elements can generate considerable genetic diversity. Here we examine the distribution of the Tnt1 retrotransposon family in representative species of the genus Nicotiana . We show that multiple Tnt1 insertions are found in all Nicotiana species. However, Tnt1 insertions are too polymorphic to reveal species relationships. This indicates that Tnt1 has amplified rapidly and independently after Nicotiana speciation. We compare patterns of Tnt1 insertion in allotetraploid tobacco ( N. tabacum ) with those in the diploid species that are most closely related to the progenitors of tobacco, N. sylvestris (S-genome donor) and N. tomentosiformis (T-genome donor). We found no evidence for Tnt1 insertion sites of N. otophora origin in tobacco. Nicotiana sylvestris has a higher Tnt1 content than N. tomentosiformis and the elements are distributed more uniformly across the genome. This is reflected in tobacco where there is a higher Tnt1 content in S-genome chromosomes. However, the total Tnt1 content of tobacco is not the sum of the two modern-day parental species. We also observed tobacco-specific Tnt1 insertions and an absence of tobacco Tnt1 insertion sites in the diploid relatives. These data indicate Tnt1 evolution subsequent to allopolyploidy. We explore the possibility that fast evolution of Tnt1 is associated with 'genomic-shock' arising out of interspecific hybridization and allopolyploidy.  © 2004 The Linnean Society of London, Biological Journal of the Linnean Society , 2004, 82 , 639–649.     

The evolutionary analysis of the Tnt1 retrotransposon in Nicotiana species reveals the high variability of its regulatory sequences

We studied the evolution of the tobacco Tnt1 retrotransposon by analyzing Tnt1 partial sequences containing both coding domains and U3 regulatory sequences obtained from a number of Nicotiana species. We detected three different subfamilies of Tnt1 elements, Tnt1A, Tnt1B, and Tnt1C, that differ completely in their U3 regions but share conserved flanking coding and LTR regions. U3 divergence between the three subfamilies is found in the region that contains the regulatory sequences that control the expression of the well-characterized Tnt1-94 element. This suggests that expression of the three Tnt1 subfamilies might be differently regulated. The three Tnt1 subfamilies were present in the Nicotiana genome at the time of species divergence, but have evolved independently since then in the different genomes. Each Tnt1 subfamily seems to have conserved its ability to transpose in a limited and different number of Nicotiana species. Our results illustrate the high variability of Tnt1 regulatory sequences. We propose that this high sequence variability could allow these elements to evolve regulatory mechanisms in order to optimize their coexistence with their host genome.      

Distribution dynamics of the Tnt1 retrotransposon in tobacco

Retrotransposons contribute significantly to the size, organization and genetic diversity of plant genomes. Although many retrotransposon families have been reported in plants, to this day, the tobacco Tnt1 retrotransposon remains one of the few elements for which active transposition has been shown. Demonstration that Tnt1 activation can be induced by stress has lent support to the hypothesis that, under adverse conditions, transposition can be an important source of genetic variability. Here, we compared the insertion site preference of a collection of newly transposed and pre-existing Tnt1 copies identified in plants regenerated from protoplasts or tissue culture. We find that newly transposed Tnt1 copies are targeted within or close to host gene coding sequences and that the distribution of pre-existing insertions does not vary significantly from this trend. Therefore, in spite of their potential to disrupt neighboring genes, insertions within or near CDS are not preferentially removed with age. Elimination of Tnt1 insertions within or near coding sequences may be relaxed due to the polyploid nature of the tobacco genome. Tnt1 insertions within or near CDS are thus better tolerated and can putatively contribute to the diversification of tobacco gene function. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The Tnt1 family member Retrosol copy number and structure disclose retrotransposon diversification in different <Emphasis Type="Italic">Solanum</Emphasis> species

Eukaryotic genome expansion/retraction caused by LTR-retrotransposon activity is dependent on the expression of full length copies to trigger efficient transposition and recombination-driven events. The Tnt1 family of retrotransposons has served as a model to evaluate the diversity among closely related elements within Solanaceae species and found that members of the family vary mainly in their U3 region of the long terminal repeats (LTRs). Recovery of a full length genomic copy of Retrosol was performed through a PCR-based approach from wild potato, Solanum oplocense. Further characterization focusing on both LTR sequences of the amplified copy allowed estimating an approximate insertion time at 2 million years ago thus supporting the occurrence of transposition cycles after genus divergence. Copy number of Tnt1-like elements in Solanum species were determined through genomic quantitative PCR whereby results sustain that Retrosol in Solanum species is a low copy number retrotransposon (1–4 copies) while Retrolyc1 has an intermediate copy number (38 copies) in S. peruvianum. Comparative analysis of retrotransposon content revealed no correlation between genome size or ploidy level and Retrosol copy number. The tetraploid cultivated potato with a cellular genome size of 1,715 Mbp harbours similar copy number per monoploid genome than other diploid Solanum species (613–884 Mbp). Conversely, S. peruvianum genome (1,125 Mbp) has a higher copy number. These results point towards a lineage specific dynamic flux regarding the history of amplification/activity of Tnt1-like elements in the genome of Solanum species. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Short‐term hybridisation activates Tnt1 and Tto1 Copia retrotransposons in wild tuber‐bearing Solanum species

Interspecific hybridisation in tuber‐bearing species of Solanum is a common phenomenon and represents an important source of variability, crucial for adaptation and speciation of potato species. In this regard, the effects of interspecific hybridisation on retrotransposon families present in the genomes, and their consequent effects on generation of genetic variability in wild tuber‐bearing Solanum species, are poorly characterised. The aim of this study was to analyse the activity of retrotransposons in inter‐ and intraspecific hybrids between S. kurtzianum and S. microdontum, obtained by controlled crosses, and the effects on morphological, genetic and epigenetic variability. For genetic and epigenetic analysis, S‐SAP (sequence‐specific amplification polymorphism) and TMD (transposon methylation display) techniques were used, respectively, with specific primers for Tnt1 and Tto1 retrotransposon families (Order LTR, Superfamily Copia). The results indicate that at morphological level, interspecific hybrid genotypes differ from their parental species, whereas derived intraspecific hybrids do not. In both cases, we observed significant reductions in pollen grain viability, and a negative correlation with Tnt1 mobility. Both retrotransposons, Tto1 and Tnt1, were mobilised in the genotypes analysed, with mobility ranging from 0 to 7.8%. Furthermore, at the epigenetic level, demethylation was detected in the vicinity of Tnt1 and Tto1 in the hybrids compared with the parental genotypes. These patterns were positively correlated with the activity of the retrotransposons. The results suggest a possible mechanism through which hybridisation events generate genetic variability in tuber‐bearing species of Solanum through retrotranposon activation.     

Efficient transposition of the Tnt1 tobacco retrotransposon in the model legume Medicago truncatula

The tobacco element, Tnt1, is one of the few active retrotransposons in plants. Its transposition is activated during protoplast culture in tobacco and tissue culture in the heterologous host Arabidopsis thaliana. Here, we report its transposition in the R108 line of Medicago truncatula during the early steps of the in vitro transformation-regeneration process. Two hundred and twenty-five primary transformants containing Tnt1 were obtained. Among them, 11.2% contained only transposed copies of the element, indicating that Tnt1 transposed very early and efficiently during the in vitro transformation process, possibly even before the T-DNA integration. The average number of insertions per transgenic line was estimated to be about 15. These insertions were stable in the progeny and could be separated by segregation. Inspection of the sequences flanking the insertion sites revealed that Tnt1 had no insertion site specificity and often inserted in genes (one out of three insertions). Thus, our work demonstrates the functioning of an efficient transposable element in leguminous plants. These results indicate that Tnt1 can be used as a powerful tool for insertion mutagenesis in M. truncatula.