Mobilization of retrotransposons in synthetic allotetraploid tobacco.

Allopolyploidy is a major driving force in plant evolution and can induce rapid structural changes in the hybrid genome. As major components of plant genomes, transposable elements are involved in these changes. In a previous work, we observed turnover of retrotransposon insertions in natural allotretraploid tobacco (Nicotiana tabacum). Here, we studied the early stages of allopolyploid formation by monitoring changes at retrotransposon insertion sites in the Th37 synthetic tobacco. We used sequence-specific amplification polymorphism (SSAP) to study insertion patterns of two populations of the Tnt1 retrotransposon in Th37 S4 generation plants, and characterized the nature of polymorphic insertion sites. We observed significant amplification of young Tnt1 populations. Newly transposed copies were amplified from maternal elements and were highly similar to Tnt1A tobacco copies amplified in response to microbial factors. A high proportion of paternal SSAP bands were not transmitted to the hybrid, corresponding to various rearrangements at paternal insertion sites, including indels or the complete loss of the Tnt1/flanking junction. These data indicate that major changes, such as retrotransposon amplification and molecular restructuring in or around insertion sites, occur rapidly in response to allopolyploidy.

The Tnt1 family member Retrosol copy number and structure disclose retrotransposon diversification in different Solanum 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.

Retroelements in higher plants.

Representatives of several classes of retroelements have been characterized in a broad range of plant species, where they appear at variable and sometimes very high copy numbers. So far, only a very small number of plant elements have been shown to be active, and this activity seems to be restricted to specific situations of 'genomic shock'. Although it is not yet known whether the presence of retroelements is linked to the high level of variability found in plant genomes, it is now clear that retrotransposons are ancient and ubiquitous components of plant genomes, and could play an important role in plant evolution.

Stress activation and genomic impact of Tnt1 retrotransposons in Solanaceae.

Tnt1 elements are a superfamily of LTR-retrotransposons distributed in the Solanaceae plant family and represent good model systems for studying regulatory and evolutionary controls established between hosts and transposable elements. Tnt1 retrotransposons tightly control their activation, by restricting expression to specific conditions. The Tnt1A element, originally discovered in tobacco, is expressed in response to stress, and its activation by microbial factors is followed by amplification, demonstrating that factors of pathogen origin can generate genetic diversity in plants. The Tnt1A promoter has the potential to be activated by various biotic and abiotic stimuli but a number of these are specifically repressed in tobacco and are revealed only when the LTR promoter is placed in a heterologous context. We propose that a tobacco- and stimulus-specific repression has been established in order to minimize activation in conditions that might generate germinal transposition. In addition to tight transcriptional controls, Tnt1A retrotransposons self-regulate their activity through gradual generation of defective copies that have reduced transcriptional activity. Tnt1 retrotransposons found in various Solanaceae species are characterized by a high level of variability in the LTR sequences involved in transcription, and have evolved by gaining new expression patterns, mostly associated with responses to diverse stress conditions. Tnt1A insertions associated with genic regions are initially favored but seem subsequently counter-selected, while insertions in repetitive DNA are maintained. On the other hand, amplification and loss of insertions may result from more brutal occurrences, as suggested by the large restructuring of Tnt1 populations observed in tobacco compared to each of its parental species. The distribution of Tnt1 elements thus appears as a dynamic flux, with amplification counterbalanced by loss of insertions. Tnt1 insertion polymorphisms are too high to reveal species relationships in the Nicotiana genus, but can be used to evaluate species relationships in the Lycopersicon and Capsicum genera. This also demonstrates that the behavior of Tnt1 retrotransposons differs between host species, most probably in correlation to differences in expression conditions and in the evolutionary and environmental history of each host.

Valine-Resistance, a Potential Marker in Plant Cell Genetics. II. Optimization of Uv Mutagenesis and Selection of Valine-Resistant Colonies Derived from Tobacco Mesophyll Protoplasts.

The induction and selection of valine-resistant mutants from haploid tobacco (Nicotiana tabacum L.) mesophyll protoplast-derived cells have been studied. Using cells from an original mutant plant obtained previously, we performed reconstruction experiments in order to determine the best conditions for the recovery of resistant cells among a population of sensitive cells. Optimal selective conditions were shown to depend on various factors including cell density, time of addition of valine and seasonal variations affecting the mother plants.-Using cell densities of approximately 10( 4) cells/ml, we defined efficient selective conditions: more than 25% of the putative mutant clones selected from UV-mutagenized protoplasts were reproducibly confirmed to be valine resistant. Further characterization of some regenerated mutant plants indicated that valine-resistance was associated with an uptake deficiency, as in the case of the original mutant plant of the Val(r)-2 line used for reconstruction experiments. Spontaneous mutation rates for valine-resistance were below accurately detectable levels, i.e., less than 10(-6) per cell per generation. Induced mutation frequency varied nonlinearily with UV dose from 10(-5) to 5 x 10(-4) resistant clones per surviving colony. Two independent loci (vr2 and vr3) were previously shown to be involved in valine-resistance due to amino acid uptake deficiency. Haploid tobacco plants were produced through anther culture from an F(1) double-heterozygous plant obtained from a cross between the original mutant plant and a wild-type plant. Study of the level of resistance to valine of protoplast-derived cells allowed the classification of these haploid plants in four types: sensitive, resistant and two intermediary resistant types believed to result from the presence of a mutant allele at only one of the two loci involved. The frequencies of UV-induced mutations in cells derived from haploid plants of one of the intermediary types were compared to those observed in wild-type cells. The results are considered in light of the amphidiploid structure of the tobacco genome.

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.

Sequence of events leading to near-complete genome turnover in allopolyploid Nicotiana within five million years.

Analyses of selected bacterial artificial chromosomes (BACs) clones suggest that the retrotransposon component of angiosperm genomes can be amplified or deleted, leading to genome turnover. Here, Nicotiana allopolyploids were used to characterize the nature of sequence turnover across the whole genome in allopolyploids known to be of different ages. Using molecular-clock analyses, the likely age of Nicotiana allopolyploids was estimated. Genomic in situ hybridization (GISH) and tandem repeat characterization were used to determine how the parental genomic compartments of these allopolyploids have diverged over time. Paternal genome sequence losses, retroelement activity and intergenomic translocation have been reported in early Nicotiana tabacum evolution (up to 200,000 yr divergence). Here it is shown that within 1 million years of allopolyploid divergence there is considerable exchange of repeats between parental chromosome sets. After c. 5 million years of divergence GISH fails. This GISH failure may represent near-complete genome turnover, probably involving the replacement of nongenic sequences with new, or previously rare sequence types, all occurring within a conserved karyotype structure. This mode of evolution may influence or be influenced by long-term diploidization processes that characterize angiosperm polyploidy-diploid evolutionary cycles.

Characterisation of LTR sequences involved in the protoplast specific expression of the tobacco Tnt1 retrotransposon.

The tobacco Tnt1 retrotransposon is the only plant retrotransposon that has been shown to be transcriptionally active, and its transcription is strongly induced when preparing leaf-derived protoplasts. We have analysed in this paper the LTR sequences important for Tnt1 expression in tobacco protoplasts. We show that LTR sequences upstream of the TATA box are sufficient to confer protoplast-dependent induction to a heterologous promoter. We also show that this region contains two short activator elements, and that one of these sequences, BII, interacts with protoplast-specific nuclear factors.

Tnt1, a mobile retroviral-like transposable element of tobacco isolated by plant cell genetics.

Transposable elements can be identified by their ability to induce mutant alleles at new loci. The retrotransposon family is thought to transpose through an RNA intermediate and has many similarities to vertebrate proretroviruses. In plants, retrotransposons have been described in maize, Arabidopsis and wheat, and non-viral retroposons in maize. Most of these elements, however, have been found as non-mobile integrated units. Here, we report the isolation of the first tobacco (Nicotiana tabacum) transposable element, Tnt1, which seems to be the most complete mobile retrotransposon characterized in higher plants. Tnt1 has been isolated after its transposition into the nitrate reductase (NR) structural gene of tobacco, and transposition events have been detected through in vitro selection of spontaneous NR-deficient (NR-) mutant lines in cell cultures derived from tobacco mesophyll protoplasts. Tnt1 is 5,334 nucleotides long, contains two 610-base-pair-long terminal repeats and a single open reading frame of 3,984 nucleotides. Comparison of the Tnt1 open reading frame coding potential with those of the Drosophila melanogaster copia retrotransposon, yeast Ty retrotransposon, and vertebrate proretroviruses revealed that Tnt1 is closely related to copia and carries all the functions known to be required for autonomous transposition by reverse transcription.

Sequence variability within the tobacco retrotransposon Tnt1 population.

Retroviruses consist of populations of different but closely related genomes referred to as quasispecies. A high mutation rate coupled with extremely rapid replication cycles allows these sequences to be highly interconnected in a rapid equilibrium. It is not known if other retroelements can show a similar population structure. We show here that when the tobacco Tnt1 retrotransposon is expressed, its RNA is not a unique sequence but a population of different but closely related sequences. Nevertheless, this highly variable population is not in a rapid equilibrium and could not be considered as a quasispecies. We have thus named the structure presented by Tnt1 RNA quasispecies-like. We show that the expression of Tnt1 in different situations gives rise to different populations of Tnt1 RNA sequences, suggesting an adaptive capacity for this element. The analysis of the variability within the total genomic population of Tnt1 elements shows that mutations frequently occur in important regulatory elements and that defective elements are often produced. We discuss the implications that this population structure could have for Tnt1 regulation and evolution.

In vivo characterization of transcriptional regulatory sequences involved in the defence-associated expression of the tobacco retrotransposon Tnt1.

The expression of the tobacco retrotransposon Tnt1 is induced by wounding, pathogen infections as well as microbial elicitors and abiotic factors known to induce the plant defence response. We report here that the LTR U3 region is sufficient to mediate transcriptional activation by biotic and abiotic elicitors in stable transgenic conditions. We have used in vivo footprinting techniques in order to analyse the cis-regulatory elements of the LTR U3 region that mediate the induction of Tnt1 expression. Our results indicate that a tandemly repeated short element, named BII box, is involved in the transcriptional activation of the tobacco retrotransposon Tnt1 in association with the plant defence signaling cascade.

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.

Specific expression of the tobacco Tnt1 retrotransposon in protoplasts.

The Tnt1 transposable element of tobacco belongs to the retrotransposon family and shares the structural features of viral retroelements including two long terminal repeats (LTRs) which are known to contain promoter regions. We show that two Tnt1 RNAs of 5.2 and 6.5 kb can be found. The 5.2 kb RNA matches with the size of the Tnt1 elements so far isolated (5.3 kb), whilst the evidence suggests that the 6.5 kb RNA could be a chimaeric RNA initiated in a gene in which Tnt1 has inserted. The Tnt1 5.2 kb RNA starts in the LTR, and the LTR can promote the expression of a translational LTR-beta-glucuronidase (GUS) fusion at a high level in transient expression assays. The Tnt1 5.2 kb RNA and the LTR-GUS fusion of transgenic tobacco plants are specifically expressed in leaf-derived protoplasts whereas they are not expressed in leaf tissue. The 5.2 kb RNA is also transcribed at low levels in roots. This RNA is induced after 2 h of maceration in the protoplast isolation medium, and its level declines rapidly after protoplast isolation. The induction requires only the presence of cell wall hydrolases, and is independent of wounding and plasmolysis. The induction of Tnt1 expression is not mediated by typical oligosaccharide elicitors released from the cell wall known to mediate defense gene responses. Tnt1 transcription features provide a first example of tissue culture-induced mutagenesis in plants and a molecular basis for some of the somaclonal variation events.

Retrotransposons of the Tnt1B family are mobile in Nicotiana plumbaginifolia and can induce alternative splicing of the host gene upon insertion.

Active retrotransposons have been identified in Nicotiana plumbaginifolia by their ability to disrupt the nitrate reductase gene in chlorate-resistant mutants selected from protoplast-derived cultures. In mutants E23 and F97, two independent insertions of Tnp2, a new retrotransposon closely related to the tobacco Tnt1 elements, were detected in the nitrate reductase gene. These two Tnp2 elements are members of the Tnt1B subfamily which shows that Tnt1B elements can be active and mutagenic in the N. plumbaginifolia genome. Furthermore, these results suggest that Tnt1B is the most active family of Tntl elements in N. plumbaginifolia, whereas in tobacco only members of the Tnt1A subfamily were found inserted in the nitrate reductase gene. The transcriptional regulations of Tnp2 and Tnt1A elements are most probably different due to non-conserved U3 regions. Our results thus support the hypothesis that different Nicotiana species contain different active Tntl subfamilies and that only one active Tntl subfamily might be maintained in each of these species. The Tnp2 insertion found in the F97 mutant was found to be spliced out of the nitrate reductase mRNA by activation of cryptic donor and acceptor sites in the nitrate reductase and the Tnp2 sequences respectively.

RNA-mediated transposition of the tobacco retrotransposon Tnt1 in Arabidopsis thaliana.

The tobacco (Nicotiana tabacum) retrotransposon Tnt1 was introduced into Arabidopsis thaliana. In this heterologous host plant species, Tnt1 undergoes an RNA-mediated transposition and creates a 5 bp duplication at the insertion sites. This is the first report of transposition of a retrotransposon after introduction into a heterologous host species. Tnt1 transposed during in vitro regeneration of transformed A.thaliana, but no transposition event was detected as happening in T2 and T3 generation plants. Newly synthesized copies of Tnt1 can integrate into coding regions of the host DNA. Our results open up the possibility of using Tnt1 as a new tool for insertional mutagenesis and functional analysis of plant genomes, in addition to the strategies of T-DNA and transposon tagging.

Expression of the tobacco Tnt1 retrotransposon promoter in heterologous species.

The expression of the tobacco (Nicotiana tabacum) retrotransposon Tnt1 has previously been shown to be strongly regulated and driven from the 5' long terminal repeat (LTR). We report here that the Tnt1 LTR can promote activity of the beta-glucuronidase (GUS) reporter gene in two heterologous species of the Brassicaceae family, namely rapeseed (Brassica napus) and Arabidopsis thaliana. The translational LTR-GUS fusion was active in transient expression studies performed with tobacco and rapeseed protoplasts, indicating that the LTR sequences are recognized in heterologous species. Our results also showed that Tnt1 LTR-promoted GUS expression in transgenic Arabidopsis is strongly regulated, and that, in contrast to tobacco, hormonal activation plays a significant role in the expression of the Tnt1 LTR in Arabidopsis. LTR sequences were shown to be more effective than the CaMV 35S enhancer region in transient expression studies performed with tobacco or rapeseed protoplasts, and substitution of the LTR sequences upstream from the major transcriptional start with the CaMV 35S enhancer region gave high levels of expression in transgenic tobacco and Arabidopsis leaves, suggesting that a Tnt1 element with similar substitutions in its 5' LTR might be suited for gene-tagging experiments in heterologous species.

Two soybean ribulose-1,5-bisphosphate carboxylase small subunit genes share extensive homology even in distant flanking sequences.

Soybean contains a multigene family which encodes the small subunit of ribulose-1,5-bisphosphate carboxylase (RuBPCss). A member of this gene family, SRS4, has been isolated from a soybean genomic DNA library. Its nucleotide sequence has been determined and compared to the sequence of SRS1, a previously characterized RuBPCss gene from soybean. Relevant regulatory sequences such as the PuPuCCAAT boxes, TATA box, the actual start of transcription and poly A addition sites are conserved between the two genes. Using a gene specific synthetic probe to the 3' flanking region the steady state mRNA levels of SRS4, like SRS1, are shown to be very high in light grown soybean seedlings and low in seedlings grown in darkness. SRS1 and SRS4 are very closely related, the three exons being 96%, 93% and 96.5% homologous in nucleotide sequence. The polypeptide sequences are nearly identical with only one amino acid change in each of the three exons encoding the 178 amino acid precursor polypeptide. The two introns are about 75% homologous and the flanking regions are more than 85% homologous (700 base pairs on the 5' end and 300 base pairs on the 3' end). Furthermore, hybridization studies between lambda clones containing the SRS1 and SRS4 genes reveal that a region of strong homology extends at least 4 kb on the 5' end and about 1.1 kb on the 3' end. We propose that these two genes may be alloalleles or homeologous alleles. This proposal is consistent with soybean having an allotetraploid origin, and would imply that the divergence of two ancient Papilionoidae species gave rise to these two genes.

Molecular and functional characterization of Slide, an Ac-like autonomous transposable element from tobacco.

A new transposable element of tobacco, Slide, was isolated from the tl 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 of Ac, Tam3 and hobo. 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 by Ac and Tam3. Tobacco lines derived from the tl 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 autonomous Ac-like element characterized in Solanaceae species.

Effects of Tnt1 tobacco retrotransposon insertion on target gene transcription.

The effects of Tnt1 retrotransposon insertion on nitrate reductase (NR) gene transcription have been analyzed in three NR-deficient insertional, mutants of Nicotiana tabacum. In the three mutants, named h9-Nia4, h9-Nia5 and h9-Nia6, Tnt1 was inserted into exon 3, exon 2 and exon 1 of the nia2 NR alloallelle, respectively. The mutants h9-Nia4 and h9-Nia6, which contained Tnt1 insertions that were oriented opposite to the direction of nia2 gene transcription, expressed chimaeric nia2-Tnt1 RNAs, respectively 12 kb and 10 kb long. The size observed in h9-Nia6 was close to the expected size for a full-length hybrid transcript starting and ending under the control of nia2 signals (about 9 kb). The larger transcript found in h9-Nia4 was shown to be due to a failure to splice the nia2 intron 2. The mutant h9-Nia5, which contained a Tnt1 insertion oriented in parallel with the direction of nia2 transcription expressed two truncated nia2-Tnt1 RNAs, 2 kb and 6.7 kb long. These transcripts arose from termination in the long terminal repeats (LTRs) of Tnt1. Since no full-length hybrid RNA was detected, we suggest that Tnt1 carries efficient termination signals, which are more efficiently recognized in the 3' LTR than in the 5' LTR.

Three Tnt1 subfamilies show different stress-associated patterns of expression in tobacco. Consequences for retrotransposon control and evolution in plants.

The genomes of most Nicotiana species contain three different subfamilies of the Tnt1 retrotransposon, which differ completely in their U3 sequence, whereas the rest of the sequence is relatively constant. The results presented here show that all three Tnt1 subfamilies are expressed in tobacco (Nicotiana tabacum) and that the U3 sequence variability correlates with differences in the pattern of expression of the Tnt1 elements. Each of the three Tnt1 subfamilies is induced by stress, but their promoters have a different response to different stress-associated signaling molecules. The Tnt1A subfamily is particularly strongly induced by elicitors and methyl jasmonate, whereas expression of the Tnt1C subfamily is more sensitive to salicylic acid and auxins. The direct relationship between U3 sequence variability and differences in the stress-associated expression of the Tnt1 elements present in a single host species gives support to our model that postulates that retrotransposons have adapted to their host genomes through the evolution of highly regulated promoters that mimic those of the stress-induced plant genes. Moreover, here we show that the analysis of the transcriptional control of a retrotransposon population such as Tnt1 provides new insights into the study of the complex and still poorly understood network of defense- and stress-induced plant signal transduction pathways.