Genetic diversity in European Pisum germplasm collections

The distinctness of, and overlap between, pea genotypes held in several Pisum germplasm collections has been used to determine their relatedness and to test previous ideas about the genetic diversity of Pisum. Our characterisation of genetic diversity among 4,538 Pisum accessions held in 7 European Genebanks has identified sources of novel genetic variation, and both reinforces and refines previous interpretations of the overall structure of genetic diversity in Pisum. Molecular marker analysis was based upon the presence/absence of polymorphism of retrotransposon insertions scored by a high-throughput microarray and SSAP approaches. We conclude that the diversity of Pisum constitutes a broad continuum, with graded differentiation into sub-populations which display various degrees of distinctness. The most distinct genetic groups correspond to the named taxa while the cultivars and landraces of Pisum sativum can be divided into two broad types, one of which is strongly enriched for modern cultivars. The addition of germplasm sets from six European Genebanks, chosen to represent high diversity, to a single collection previously studied with these markers resulted in modest additions to the overall diversity observed, suggesting that the great majority of the total genetic diversity collected for the Pisum genus has now been described. Two interesting sources of novel genetic variation have been identified. Finally, we have proposed reference sets of core accessions with a range of sample sizes to represent Pisum diversity for the future study and exploitation by researchers and breeders.

Analysis of plant diversity with retrotransposon-based molecular markers

Retrotransposons are both major generators of genetic diversity and tools for detecting the genomic changes associated with their activity because they create large and stable insertions in the genome. After the demonstration that retrotransposons are ubiquitous, active and abundant in plant genomes, various marker systems were developed to exploit polymorphisms in retrotransposon insertion patterns. These have found applications ranging from the mapping of genes responsible for particular traits and the management of backcrossing programs to analysis of population structure and diversity of wild species. This review provides an insight into the spectrum of retrotransposon-based marker systems developed for plant species and evaluates the contributions of retrotransposon markers to the analysis of population diversity in plants.

Effects of ascertainment bias and marker number on estimations of barley diversity from high-throughput SNP genotype data

The capability of molecular markers to provide information of genetic structure is influenced by their number and the way they are chosen. This study evaluates the effects of single nucleotide polymorphism (SNP) number and selection strategy on estimates of germplasm diversity and population structure for different types of barley germplasm, namely cultivar and landrace. One hundred and sixty-nine barley landraces from Syria and Jordan and 171 European barley cultivars were genotyped with 1536 SNPs. Different subsets of 384 and 96 SNPs were selected from the 1536 set, based on their ability to detect diversity in landraces or cultivated barley in addition to corresponding randomly chosen subsets. All SNP sets except the landrace-optimised subsets underestimated the diversity present in the landrace germplasm, and all subsets of SNP gave similar estimates for cultivar germplasm. All marker subsets gave qualitatively similar estimates of the population structure in both germplasm sets, but the 96 SNP sets showed much lower data resolution values than the larger SNP sets. From these data we deduce that pre-selecting markers for their diversity in a germplasm set is very worthwhile in terms of the quality of data obtained. Second, we suggest that a properly chosen 384 SNP subset gives a good combination of power and economy for germplasm characterization, whereas the rather modest gain from using 1536 SNPs does not justify the increased cost and 96 markers give unacceptably low performance. Lastly, we propose a specific 384 SNP subset as a standard genotyping tool for middle-eastern landrace barley.

Ty1-copia retrotransposon-based SSAP marker development in cashew (Anacardium occidentale L.)

The most popular retrotransposon-based molecular marker system in use at the present time is the sequence-specific amplification polymorphism (SSAP) system . This system exploits the insertional polymorphism of long terminal repeat (LTR) retrotransposons around the genome. Because the LTR sequence is used to design primers for this method, its successful application requires sequence information from the terminal region of the mobile elements . In this study, two LTR sequences were isolated from the cashew genome and used successfully to develop SSAP marker systems. These were shown to have higher levels of polymorphism than amplified fragment length polymorphic markers for this species.

Retrotransposon-based molecular markers for linkage and genetic diversity analysis in wheat

Retrotransposon-based molecular markers have been developed to study bread wheat ( Triticum aestivum) and its wild relatives. SSAP (Sequence-Specific Amplification Polymorphism) markers based on the BARE-1/ Wis-2-1A retrotransposons were assigned to T. aestivum chromosomes by scoring nullisomic-tetrasomic chromosome substitution lines. The markers are distributed among all wheat chromosomes, with the lowest proportion being assigned the D wheat genome. SSAP markers for BARE-1/ Wis-2-1A and three other wheat retrotransposons, Thv19, Tagermina and Tar1, are broadly distributed on a wheat linkage map. Polymorphism levels associated with these four retrotransposons vary, with BARE-1/ Wis-2-1A and Thv19 both showing approximately 13% of bands polymorphic in a mapping population, Tagermina showing approximately 17% SSAP band polymorphism and Tar1 roughly 18%. This suggests that Tagermina and Tar1 have been more transpositionally active in the recent evolutionary past, and are potentially the more useful source of molecular markers in wheat. Lastly, BARE-1 / Wis-2-1A markers have also been used to characterise the genetic diversity among a set of 35 diploid and tetraploid wheat species including 26 Aegilops and 9 Triticum accessions. The SSAP-based diversity tree for Aegilops species agrees well with current classifications, though the Triticum tree shows several significant differences, which may be associated with polyploidy in this genus.

The evolution of Ty1-copia group retrotransposons in gymnosperms

A diverse collection of Ty1-copia group retrotransposons has been characterized from the genome of Picea abies (Norway spruce) by degenerate PCR amplification of a region of the reverse transcriptase gene. The occurrence of these retrotransposable elements in the gymnosperms was investigated by Southern blot hybridization analysis. The distribution of the different retrotransposons across the gymnosperms varies greatly. All of the retrotransposon clones isolated are highly conserved within the Picea (spruce) genus, many are also present in Pinus (pine) and/or Abies (fir) genera, and some share strongly homologous sequences with one or more of cedar, larch, Sequoia, cypress, and Ginkgo. Further subclones of one of the most strongly conserved retrotransposon sequences, Tpa28, were obtained from Ginkgo and P. abies. Comparisons of individual sequence pairs between the two species show nucleotide cross-homologies of around 80%-85%, corresponding to nucleotide substitution rates similar to those of nuclear protein-coding genes. Analysis of Tpa28 consensus sequences reveals that strong purifying selection has acted on this retrotransposon in the lineages connecting Ginkgo and Picea. Collectively, these data suggest, first, that the evolution of the Ty1-copia retrotransposon group in the gymnosperms is dominated by germ line vertical transmission, with strong selection for reverse transcriptase sequence, and, second, that extinction of individual retrotransposon types has been comparatively rare in gymnosperm species lineages compared with angiosperms. If this very high level of sequence conservation is a general property of the retrotransposons, then their extreme sequence diversity implies that they are extremely ancient, and the major element lineages seen today may have arisen early in eukaryote evolution. The data are also consistent with horizontal transmission of particular retrotransposons between species, but such a mechanism is unnecessary to explain the results.

Pea Ty1-copia group retrotransposons: transpositional activity and use as markers to study genetic diversity in Pisum

The variation in transposition history of different Ty1-copia group LTR retrotransposons in the species lineages of the Pisum genus has been investigated. A heterogeneous population of Ty1-copia elements was isolated by degenerate PCR and two of these (Tps12 and Tps19) were selected on the basis of their copy number and sequence conservation between closely related species for further in-depth study of their transpositional history in Pisum species. The insertional polymorphism of these elements and the previously characterised PDR1 element was studied by sequence-specific amplification polymorphism (SSAP). Each of these elements reveals a unique transpositional history within 55 diverse Pisum accessions. Phylogenetic trees based on the SSAP data show that SSAP markers for individual elements are able to resolve different species lineages within the Pisum genus. Finally, the SSAP data from all of these retrotransposon markers were combined to reveal a detailed picture of the intra and interspecies relationships within Pisum.

Rapid isolation of plant Ty1-copia group retrotransposon LTR sequences for molecular marker studies

The terminal sequences of long-terminal repeat (LTR) retrotransposons are a source of powerful molecular markers for linkage mapping and biodiversity studies. The major factor limiting the widespread application of LTR retrotransposon-based molecular markers is the availability of new retrotransposon terminal sequences. We describe a PCR-based method for the rapid isolation of LTR sequences of Ty1-copia group retrotransposons from the genomic DNA of potentially any higher plant species. To demonstrate the utility of this technique, we have identified a variety of new retrotransposon LTR sequences from pea, broad bean and Norway spruce. Primers specific for three pea LTRs have been used to reveal polymorphisms associated with the corresponding retrotransposons within the Pisum genus.

Phylogeny and transpositional activity of Ty1-copia group retrotransposons in cereal genomes

The Ty1-copia group retrotransposon populations of barley (Hordeum vulgare) and bread wheat (Triticum aestivum) have been characterised by degenerate PCR and sequence analysis of fragments of the reverse transcriptase genes. The barley population is comprised of a highly heterogeneous set of retrotransposons, together with a collection of sequences that are closely related to the BARE-1 element. Wheat also contains a highly diverse Ty1-copia retrotransposon population, together with a less prominent BARE-1 subgroup. These data have been combined with previously published Gramineae sequences to construct a composite phylogenetic tree for this class of retrotransposons in cereal grasses. The analysis indicates that the ancestral Gramineae genome contained a heterogeneous population of Ty1-copia group retrotransposons, the descendants of which have proliferated to differing degrees in present-day species. Lastly, the level of recent transpositional activity of two Ty1-copia elements has been estimated by measuring their insertional polymorphism within species. Both transposons are highly polymorphic within all species tested. These data suggest that transposition proficiency may be a common and evolutionarily stable feature of the Ty1-copia group retrotransposons of cereal grasses.

Retrotransposon-based insertion polymorphisms (RBIP) for high throughput marker analysis

Two assays based upon PCR detection of a polymorphic PDR1 retrotransposon insertion in Pisum sativum have been developed. Both methods involve PCR with primers derived from the transposon and flanking DNA. The first method uses a dot assay for PCR product detection which could be fully automated for handling thousands of samples. The second method, which is designed to handle lower numbers, requires a single PCR and gel lane per sample. Both methods yield co-dominant markers, with presence and absence of the transposon insertion independently scorable, and both could in principle be applied to any transposable element in any plant species.

Quantitative genetic analysis of copia retrotransposon activity in inbred Drosophila melanogaster lines

The rates of transcription and transposition of retrotransposons vary between lines of Drosophila melanogaster. We have studied the genetics of differences in copia retrotransposon activity by quantitative trait loci (QTL) mapping. Ninety-eight recombinant inbred lines were constructed from two parental lines exhibiting a 10-fold difference in copia transcript level and a 100-fold difference in transposition rate. The lines were scored for 126 molecular markers, copia transcript level, and rate of copia transposition. Transcript level correlated with copia copy number, and the difference in copia copy number between parental lines accounted for 45.1% of copia transcript-level difference. Most of the remaining difference was accounted for by two transcript-level QTL mapping to cytological positions 27B-30D and 50F-57C on the second chromosome, which accounted for 11.5 and 30.4%, respectively. copia transposition rate was controlled by interacting QTL mapping to the region 27B-48D on the second and 61A-65A and 97D-100A on the third chromosome. The genes controlling copia transcript level are thus not necessarily those involved in controlling copia transposition rate. Segregation of modifying genes, rather than mutations, might explain the variability in copia retrotransposon activity between lines.

The chromosomal distributions of Ty1-copia group retrotransposable elements in higher plants and their implications for genome evolution

Retrotransposons make up a major fraction--sometimes more than 40%--of all plant genomes investigated so far. We have isolated the reverse transcriptase domains of the Ty1-copia group elements from several species, ranging in genome size from some 100 Mbp to 23,000 Mbp, and determined the distribution patterns of these retrotransposons on metaphase chromosomes and within interphase nuclei by DNA:DNA in situ hybridization. With some exceptions, the reverse transcriptase domains were distributed over the length of the chromosomes. Exclusion from rDNA sites and some centromeres (e.g., slash pine, 23,000 Mbp, or barley, 5500 Mbp) is frequent, whereas many species exclude retrotransposons from other sites of heterochromatin (e.g., intercalary and centromeric sites in broad bean). In contrast, in the plant Arabidopsis thaliana, widely used for plant molecular genetic studies because of its small genome (c. 100 Mbp), the Ty1-copia group reverse transcriptase gene domains are concentrated in the centromeric regions, colocalizing with the 180 bp satellite sequence pAL1. Unlike the pAL1 sequence, however, the Ty1-copia signal is also detectable as weaker, diffuse hybridization along the lengths of the chromosomes. Possible mechanisms for evolution of the contrasting distributions are discussed. Understanding the physical distribution of retrotransposons and comparisons of the distribution between species is critical to understanding their evolution and the significance for generation of the new patterns of variability and in speciation.

The evolution of Ty1-copia group retrotransposons in eukaryote genomes

The Ty1-copia group of LTR retrotransposons has been studied extensively in yeast and Drosophila, the organisms in which they were first discovered, and more recently in higher plant and vertebrate species. Their properties, such as copy number, sequence homogeneity, transcriptional and transpositional activity vary greatly between these different hosts. We will try to resolve these apparent discrepancies between these properties, explain any fundamental differences in the biology of the Ty1-copia group between hosts, and propose a general model for LTR retrotransposon evolution.

The Ty1-copia group of retrotransposons in plants: genomic organisation, evolution, and use as molecular markers

The genomic organisation and diversity of the Ty1-copia group retrotransposons has been investigated in several crop plants and their relatives from both dicotyledonous and monocotyledonous families, including potato (Solanum tuberosum), faba beans (Vicia faba), Vicia melanops, Vicia sativa, barley (Hordeum vulgare), rye (Secale cereale), and onion (Allium cepa). Extreme heterogeneity in the sequence of the Ty1-copia retrotransposons from all these plants was revealed following sequence analysis of reverse transcriptase fragments. The estimated copy numbers of the Ty1-copia group retrotransposons for the genomes of S. tuberosum, L. esculentum, A. cepa, S. cereale, and V. faba is highly variable, ranging from a few hundred to approximately a million copies per genome. In situ hybridisation data from metaphase and prophase chromosomes of V. faba, S. cereale, and H. vulgare suggest that retrotransposon sequences are dispersed throughout the euchromatic regions of the genome but are almost undetectable in most heterochromatic regions. In contrast, similar data from metaphase chromosomes of A. cepa suggests that although retrotransposon sequences are dispersed throughout the euchromatic regions of the genome, they are predominantly concentrated in the terminal heterochromatin. These results are discussed in the context of the role played by the Ty1-copia group retrotransposons in the evolution of the plant genome. Lastly, the application of retrotransposon sequences as genetic markers for mapping genomes and for studying genetic biodiversity in plants is presented.

Characterization and genomic organization of Ty1-copia group retrotransposons in rye (Secale cereale)

The genomic organisation of the Ty1-copia retrotransposons in rye (Secale cereale) has been studied. We have used the polymerase chain reaction (PCR) to amplify sequences from a conserved domain of the reverse transcriptase gene of the Ty1-copia retrotransposons in this species. Sequence analysis of 26 of these PCR products shows them to be a highly heterogeneous population, a feature that is common in plants. Slot blot analysis shows that there are about 100,000 individual Ty1-copia retrotransposons in rye. In situ hybridization of a heterogeneous probe, representing the whole population of rye Ty1-copia retrotransposon sequences, to chromosome spreads of triticale (xTriticosecale), a rye-wheat hybrid, shows that these sequences are present throughout all the rye chromosomes but absent from the centromeric regions and, in particular, from the terminal heterochromatin. Southern analysis of oat, barley, wheat, and rye, using as a probe R9, one of the rye sequences that is closely similar to the BARE-1 element of barley, shows that close relatives of this retrotransposon subgroup are present in all these species in high copy number. Northern analysis on RNAs from seedlings shows that the BARE-1 subgroup is transcribed in all these cereal plants but in variable amounts: high in barley, moderate in wheat and rye, and extremely low in oat.

Germ line transposition of the copia retrotransposon in Drosophila melanogaster is restricted to males by tissue-specific control of copia RNA levels

Germ line transposition rates of the retrotransposon copia were directly measured in males and females of an inbred Drosophila melanogaster line, 2b3, which is highly polymorphic for copia insertion sites. The elevated germ line transposition rate of copia in this line (3-8 x 10(-3) per generation per element) is confined to males, with transposition in females being undetectable under the conditions of the experiment but at most 50-fold lower than the rate for males. To determine the molecular basis of this effect, copia RNA levels were measured in whole bodies and germ lines of male and female flies of both the unstable 2b3 line and a stable line, Oregon RC-iso, which shows normal rates of copia transposition. Both male and female 2b3 flies contain much more copia RNA than flies of the stable line. However, 2b3 male germinal tissues contain much higher levels of copia RNA than the equivalent female tissues. The highest copia expression is detected in maturing primary spermatocytes. Our data show that high rates of germ line copia transposition are restricted to males by tissue-specific control of RNA levels and suggest that transposition of copia only occurs in fly tissues containing more than a relatively high threshold level of copia RNA.

Genetic and molecular analysis of smooth, a quantitative trait locus affecting bristle number in Drosophila melanogaster

A semi-lethal, sterile allele of the smooth locus (2-91.5), sm3, was discovered in an artificial selection line for low abdominal bristle number that had been started from a P-M dysgenic cross. The fitness effects and extremely low bristle number phenotype of the allele could not be separated by recombination from a P-element insertion at cytological location 56E, and precise excision of the P-element at this site was associated with reversion to wild type. The smooth gene was cloned using the P-element insertion as a tag. The gene encodes a 2.6-kb transcript derived from 10 exons and covers a genomic region of at least 80 kb. The Drosophila smooth gene shares substantial sequence identity with a group of RNA binding proteins, with the closest relationship being to the human heterogeneous nuclear ribonucleoprotein L gene. The smooth gene is by definition an abdominal bristle number quantitative trait locus, but further work is required to discern whether naturally occurring allelic variation at this locus is a source of genetic variation for abdominal bristle number in natural populations.

Genetic distribution of Bare-1-like retrotransposable elements in the barley genome revealed by sequence-specific amplification polymorphisms (S-SAP)

Retrotransposons are present in high copy number in many plant genomes. They show a considerable degree of sequence heterogeneity and insertional polymorphism, both within and between species. We describe here a polymerase chain reaction (PCR)-based method which exploits this polymorphism for the generation of molecular markers in barley. The method produces amplified fragments containing a Bare-1-like retrotransposon long terminal repeat (LTR) sequence at one end and a flanking host restriction site at the other. The level of polymorphism is higher than that revealed by amplified fragment length polymorphism (AFLP) in barley. Segregation data for 55 fragments, which were polymorphic in a doubled haploid barley population, were analysed alongside an existing framework of some 400 other markers. The markers showed a widespread distribution over the seven linkage groups, which is consistent with the distribution of the Bare-1 class of retrotransposons in the barley genome based on in situ hybridisation data. The potential applicability of this method to the mapping of other multicopy sequences in plants is discussed.

Activation of the Ty1-copia group retrotransposons of potato (Solatium tuberosum) during protoplast isolation

The potato (Solanum tuberosum) genome contains a highly heterogeneous population of Ty1-copia group retrotransposons. Here we identify the first such transposable element known to be transcribed in this species. The elements are transcriptionally activated during protoplast isolation. The majority of the activated Ty1-copia sequences are similar to elements which are transcriptionally induced under the same conditions in tobacco (Nicotiana tabacum). We also show that a previously identified potato element M166, which has no known equivalent in tobacco is also transcribed under these conditions. It appears that the control of transcription of this particular Ty1-copia group retrotransposons has been broadly conserved between these two species.

The Ty1-copia group retrotransposons of Allium cepa are distributed throughout the chromosomes but are enriched in the terminal heterochromatin

The genomic organization and diversity of the Ty1-copia group retrotransposons has been investigated in a monocotyledonous plant, Allium cepa. We used the polymerase chain reaction (PCR) to generate sequences corresponding to a conserved domain of the reverse transcriptase gene of Ty1-copia retrotransposons in this plant. Sequence analysis of 27 of these PCR products shows that they are a highly heterogeneous population, a feature which is common in plants but not in yeast and Drosophila. Slot-blot analysis shows there are 100,000-200,000 copies of Ty1-copia group retrotransposons within the A. cepa genome (2C = 31.7 pg), indicating that they are a significant component of the genome of this plant. In situ hybridization to metaphase chromosomes reveals that Ty1-copia retrotransposons are distributed throughout the euchromatin of all chromosomes of A. cepa but are enriched in the terminal heterochromatic regions, which contain tandem arrays of satellite sequences. This is the first clear evidence for the presence of Ty1-copia retrotransposons in the terminal heterochromatin of plants and contrasts with the distribution of these elements in other plant species.

The Ty1-copia group retrotransposons in Vicia species: copy number, sequence heterogeneity and chromosomal localisation

We present an in-depth study of the Ty1-copia group of retrotransposons within the plant genus Vicia, which contains species with widely differing genome sizes. We have compared the numbers and sequence heterogeneities of these genetic elements in three diploid Vicia species chosen to represent large (V. faba, 1C = 13.3 pg), medium (V. melanops, 1C = 11.5 pg) and small (V. sativa, 1C = 2.3 pg) genomes within the genus. The copy numbers of the retrotransposons are all high but vary greatly, with V. faba containing approximately 10(6) copies, V. melanops about 1000 copies and V. sativa 5000 copies. The degree of sequence heterogeneity of Ty1-copia group elements correlates with their copy number within each genome, but neither heterogeneity nor copy number are related to the genome size of the host. In situ hybridization to metaphase chromosomes shows that the retrotransposons in V.faba are distributed throughout all chromosomes but are much less abundant in certain heterochromatic regions. These results are discussed in the context of plant retrotransposon evolution.

Ty1-copia group retrotransposon sequences in amphibia and reptilia

We have isolated sequences belonging to Ty1-copia group retrotransposons from the genomes of an amphibian (Pyxicephalus adspersa) and three reptiles (Conolophus subscristatus, Amblyrynchus cristatus and Pytas mucosus). Two different sequences were found in the amphibian (Tpa1 and Tpa2). Each is present in several copies per genome and absent from the genomes of two other amphibian species. The C. subcristatus sequence Tcs1 is present in multiple copies in both its host genome (Galapagos land iguana) and the genome of the related Galapagos marine iguana (A. cristatus). There is little or no polymorphism in Tcs1 insertions between different individual animals, suggesting that this sequence is not transposing rapidly in either iguana genome. The P. mucosus sequence Tpm1 shows a discontinuous distribution in snake species, suggesting that it has either been lost from many lineages during vertical germline transmission or has been transferred horizontally in some snake species. Phylogenetic comparisons of all these sequences with each other and with other members of this retrotransposon group from other animals and plants show that sequences within a particular vertebrate species are most closely related to each other, consistent with a vertical transmission model for their evolution.

Retroelements, reverse transcriptase and evolution

Retroelements are genetic elements that can exist as DNA or RNA or DNA/RNA duplexes. Although retroviruses are the best known retroelements, there are many other types, including close relatives of retroviruses like LTR retrotransposons, more distant relatives like non-LTR retrotransposons, caulimoviruses and hepadnaviruses and elements with virtually no similarity, like retrons. Virtually all retroelements are 'selfish DNAs' with no involvement with the normal development or maintenance of their host cells, the only known exception being telomereres/telomerases which maintain the ends of chromosomes. Virtually all retroelements use tRNA, or RNA with strong secondary structure, to initiate their reverse transcription. The coincidence between the use of tRNA, a molecule central to the conversion of RNA to protein, with reverse transcriptase, an enzyme which is crucial for the conversion of RNA to DNA is striking, because RNA probably preceded DNA and protein in evolution. It seems plausible that retroelements were present at the genesis of living systems.

Plant transposable elements and the genome

Transposable elements are ubiquitous in the plant kingdom and share many common features, both structural and mechanistic, with mobile elements from other eukaryotes. Transposition of these elements can influence plant genes and genomes in many ways. It is also becoming clear that transposable element derived sequences can be a major component of plant genomes. These sequences are probably, therefore, very significant factors in plant evolution.

Expression and sequence analysis of cDNAs induced during the early stages of tuberisation in different organs of the potato plant (Solanum tuberosum L.)

cDNA clones of two genes (TUB8 and TUB13) which show a 25-30-fold increase in transcript in the stolon tip during the early stages of tuberisation, have been isolated by differential screening. These genes are also expressed in leaves, stems and roots and the expression pattern in these organs changes on tuberisation. Southern analysis shows homologous sequences in the non-tuberising wild type potato species Solanum brevidens and in Lycopersicon esculentum (tomato). Sequence analysis reveals a high degree of similarity between the TUB13 cDNA, and a human S-adenosylmethionine decarboxylase gene. The predicted TUB8 peptide sequence shows several repeats of alanine, glutamate and proline which suggests a structural role for the encoded protein.

Ty1-copia group retrotransposons are ubiquitous and heterogeneous in higher plants

We have used the polymerase chain reaction to isolate fragments of Ty1-copia group retrotransposons from a wide variety of members of the higher plant kingdom. 56 out of 57 species tested generate an amplified fragment of the size expected for reverse transcriptase fragments of Ty1-copia group retrotransposons. Sequence analysis of subclones shows that the PCR fragments display varying degrees of sequence heterogeneity. Sequence heterogeneity therefore seems a general property of Ty1-copia group retrotransposons of higher plants, in contrast to the limited diversity seen in retrotransposons of Saccharomyces cerevisiae and Drosophila melanogaster. Phylogenetic analysis of all these sequences shows, with some significant exceptions, that the degree of sequence divergence in the retrotransposon populations between any pair of species is proportional to the evolutionary distance between those species. This implies that sequence divergence during vertical transmission of Ty1-copia group retrotransposons within plant lineages has been a major factor in the evolution of Ty1-copia group retrotransposons in higher plants. Additionally, we suggest that horizontal transmission of this transposon group between different species has also played a role in this process.

A Ty1-copia group retrotransposon sequence in a vertebrate

We have used the polymerase chain reaction (PCR) to isolate a sequence characteristic of a Ty1-copia group retrotransposon from the genome of the herring (Clupea harengus). This is the first Ty1-copia group retrotransposon sequence described in a vertebrate. Phylogenetic comparison of this sequence with other members of this group of retrotransposons shows that it resembles more closely some Ty1-copia group members from Drosophila melanogaster than other group members in plants and fungi. These observations provide further evidence that the Ty1-copia group LTR retrotransposons span many of the major eukaryote species boundaries, suggesting that horizontal transmission between different species has played a role in the evolution of this retrotransposon group.

Extreme heterogeneity of Ty1-copia group retrotransposons in plants

We have used the polymerase chain reaction to analyse Ty1-copia group retrotransposons of flowering plants. All eight species studied contain reverse transcriptase fragments from Ty1-copia group retrotransposons. Sequence analysis of 31 subcloned fragments from potato reveals that each is different from the others, with predicted amino acid diversities between individual fragments varying between 5% and 75%. Such sequence heterogeneity within a single species contrasts strongly with the limited diversity seen in such retrotransposons in yeast and Drosophila. The fragments from the other seven plant species examined are also heterogeneous, both within and between species, showing that this is a general property of this transposon group in plants. Phylogenetic analysis of all these sequences reveals that many of them fall into subgroups which span species boundaries, such that the closest homologue of one sequence is often from a different species. We suggest that both vertical transmission of Ty1-copia group retrotransposons within plant lineages and horizontal transmission between different species have played roles in the evolution of Ty1-copia group retrotransposons in flowering plants.

Ty1-copia group retrotransposons and the evolution of retroelements in the eukaryotes

Ty1-copia group retrotransposons are among the best studied transposable elements in the eukaryotes. This review discusses the extent of these transposons in the eukaryote kingdoms and compares models for the evolution of these genetic elements in the light of recent phylogenetic data. These data show that the Ty1-copia group is widespread among invertebrate eukaryotes, especially in the higher plant kingdom, where these genetic elements are unusually common and heterogeneous in their sequence. The phylogenetic data also suggest that the present day spectrum of Ty1-copia group retrotransposons has been influenced both by divergence during vertical transmission down evolving lineages and by horizontal transmission between distantly related species. Lastly, the factors affecting Ty1-copia group retrotransposon copy number and sequence heterogeneity in eukaryotic genomes and the effects of transpositional quiescence and defective retrotransposons upon evolution of Ty1-copia group retrotransposons are discussed.

The retrotransposon copia regulates Drosophila gene expression both positively and negatively

The D. melanogaster transposable element copia is structurally similar to retroviral proviruses. We have asked whether copia encodes regulatory functions which have been observed in certain other proviruses. We have introduced reporter constructs based on the copia promoter and other Drosophila promoters into Drosophila cells and asked if copia has any affect on their expression. We find that, whilst copia negatively regulates expression from its own promoter, it also positively regulates expression from the larval serum protein 1 promoter. Analysis of RNA suggests that both regulatory functions occur by post-transcriptional mechanisms.

The retrotransposon copia controls the relative levels of its gene products post-transcriptionally by differential expression from its two major mRNAs

All retroviruses and retrotransposons studied to date regulate the relative levels of gag and pol/int gene products post-transcriptionally from a single mRNA. In these genetic elements the production of protein encoded by the pol and int genes is attenuated by a translational stop or frameshift in the reading frame preceding their coding regions in the mRNA. We show here that the Drosophila retrotransposon copia also produces lower amounts of gene products from its int/pol region than gag region but this is achieved by a mechanism which is novel for this class of genetic element. We show by the use of gene fusion constructs that the subgenomic 2 kilobase copia RNA, encoding gag products, is expressed as protein in cultured cells at least ten-fold more efficiently than the full genome length RNA, which additionally contains the pol and int open reading frames.

Complete reversions of a gypsy retrotransposon-induced cut locus mutation in Drosophila melanogaster involving jockey transposon insertions and flanking gypsy sequence deletions

We have analysed the structures of three phenotypic revertant alleles of a gypsy retrotransposon-induced mutation at the cut locus of Drosophila melanogaster. All three revertants are associated with the insertion of jockey transposons into a common region of gypsy. Two of these alleles are complete reversions to wild type. One complete revertant (ct+D) is derived from a third allele, a partial revertant (ctMRpD) by a deletion of part of the gypsy sequence flanking the jockey transposon. Sequence differences between the jockey elements in ctMRpD and ct+D suggest that this deletion may have been created by the insertion of a second jockey near to the first, followed by recombinational excision of a composite jockey and the region between the two genetic elements. The other complete revertant also carries a deletion of gypsy DNA flanking the jockey insertion. The deleted regions of both complete revertants and the target region for all the jockey insertions contain a repeated sequence that resembles a transcriptional enhancer. The strength of the cut phenotype in these mutants correlates with the proportion of this region remaining near the gypsy transcriptional start site, suggesting that the jockey insertions relieve the gypsy-induced mutation at cut by interfering with a region which is required for the transcriptional competence of gypsy.

Instability in the ctMR2 strain of Drosophila melanogaster: role of P element functions and structure of revertants

Simultaneous multiple transpositions and long-term genetic instability have been described in the ctMR2 strain of Drosophila melanogaster and its derivatives. This strain originated from a cross that was dysgenic in the P-M system. While spontaneous instability declined over 2 years, instability has been reactivated by backcross to the progenitor P element bearing strain MRh12/Cy. We show here using germline transformation that active P factor alone cannot mimic the effect of this cross, suggesting that MRh12/Cy contains some other activator. In addition, we have observed that ct+ exceptional progeny arise in the F1 as well as the F2 generations. Molecular analysis of X chromosomes from some ct+ progeny indicates that phenotypic reversion of the ct mutation can arise through two unrelated mechanisms.

The transcriptional control regions of the copia retrotransposon

We have analysed the sequence elements that control expression of the copia retrotransposon. Expression of copia fusion constructs containing DNA sequence deletions and rearrangements was assayed by transient expression analysis. Progressive deletion and linker substitution identifies two regions on either side of the major transcriptional start sites in the copia long terminal repeat These regions are both required for high level expression in a cultured Drosophila melanogaster cell line but only the upstream region is required for copia expression in a Drosophila hydei cell line. A third control region lies downstream of the long terminal repeat in a region previously believed to contain no cis-acting regulatory sequences. We show by displacement and inversion of this region that it contains a transcriptional enhancer.

A novel GC-rich dispersed repeat sequence in Drosophila melanogaster

A novel family of dispersed repeat sequences from Drosophila melanogaster is described. Sequence analysis of two members of this family show them to contain greater than 75% GC bases. These are comprised of multiple repeats of GGX triplets interspersed occasionally with CGPy and TTPy. Southern blotting shows that these repeats are not transposable elements. Twenty four homologous recombinants have been localised by in situ hybridization to seven sites in the Drosophila genome. Polyadenylated RNAs homologous to this repeat family are expressed in a complex pattern which is developmentally regulated. We suggest that this family encodes a set of glycine-rich domains in Drosophila proteins.

The termini of extrachromosomal linear copia elements

Extrachromosomal linear copia elements were isolated and cloned from cultured Drosophila melanogaster cells. Four full length copia recombinants were characterised. Each contains a full sized copy of copia bounded by its direct repeats. The sequences of the ends of the copia inserts were determined. All of the termini are identical to those of genomic copias except for a single base deletion from one end of one clone. These results suggest that the priming for initiation of copia reverse transcription differs from normal retroviral models. Southern blot analysis of uncloned full length copia circles shows that approximately 50% correspond to the predicted circularisation product of such linears. We propose that this class of circles and the linear DNAs described here are precursors to integrated genomic copia elements.

Role of reverse transcription in the generation of extrachromosomal copia mobile genetic elements

The Drosophila genetic element copia is one of the best studied eukaryotic transposable sequences. Copia shares structural features with a wide variety of mobile elements in Drosophila, Lepidoptera, yeast and vertebrates, the last class being the retrovirus proviruses. Furthermore, retrovirus-like particles containing copia RNA have been isolated from Drosophila cells and extrachromosomal circular copias with structures closely resembling circular retrovirus proviruses have been isolated and cloned. Therefore, copia-like elements and retroviruses may be members of a class of mobile genetic elements existing throughout the eukaryotic kingdom. Consequently, there has been speculation that retroviruses evolved from transposable elements and, conversely, that copia-like elements transpose as retroviruses or retrovirus-like particles. To date, however, there has been no demonstration that copia RNA is reverse transcribed into copia DNA. The present report describes the isolation of linear extrachromosomal copias whose structure closely resembles the analogous retrovirus provirus linears and whose synthesis is unaffected by inhibitors of the cellular DNA polymerase responsible for chromosomal DNA replication.

The origin of extrachromosomal circular copia elements

Cloned extrachromosomal circular copia elements were studied by nucleotide sequence and restriction enzyme analysis to determine their mechanisms of formation and their possible roles in copia transposition. Rearranged circular copias containing inverted segments flanked by 5 bp sequence duplication were observed, suggesting that circular copias are capable of integrating into their own sequences. Such copia circles are analogous to similarly rearranged retrovirus circles, strengthening the relationship between the copia-like elements and retroviruses. There is marked sequence heterogeneity at the junction between the fused terminal direct repeats of seven copia circles. The junctions contain 0-15 bp inserts, the sequences of which are inconsistent with the creation of these particular molecules by reverse transcription.

The 5' termini of RNAs encoded by the transposable element copia

The 5' termini of copia-specific RNAs in Drosophila melanogaster tissue culture cells were determined by S1 nuclease mapping and cap analysis. Both major copia RNAs share an identical set of heterogeneous 5' ends. Three major cap 1 structures M7GpppCmpUp, M7GpppCmpCp and M7GpppGmpUp together with several other minor caps were found. Almost all the 5' termini, as judged by S-1 nuclease mapping, were located either in a pyrimidine-rich part of the terminal direct repeat or apparently outside of the copia element, suggesting that a proportion of copia transcripts derive from promoters external to the genetic element.

Translation and developmental regulation of RNA encoded by the eukaryotic transposable element copia

copia-specific RNA was isolated from Drosophila melanogaster tissue culture cells by hybridization of cytoplasmic polyadenylylated RNA to copia DNA immobilized on cellulose. The purified RNA was translated in reticulocyte lysates. One major polypeptide of approximately 51,000 daltons was synthesized in addition to several others between 18,000 and 38,000 daltons. The 51,000-dalton polypeptide and several of the others are encoded by mRNAs of about 2000 nucleotides. The approximate locations on the copia element of the coding sequences for the 51,000-dalton polypeptide and several other proteins were determined by hybrid-arrested translation with copia restriction fragments. The relative abundance of copia-specific RNA was determined at various stages of the Drosophila life cycle. The level of copia-specific RNA is modulated during development of the organism, with the highest level occurring during the larval stages.

Localization of three major cappe 5' ends of polyoma virus late mRNA's within a single tetranucleotide sequence in the viral genome

The nucleotide sequences at the 5' ends of polyoma virus late mRNA's were determined by direct RNA sequencing of decapped and 5'-(32)P-labeled RNase T1 oligoribonucleotides. Virus-specific polyadenylated cytoplasmic RNA, which was isolated from mouse cells late during productive infection, was enzymatically or chemically treated to specifically remove the cap structure (m(7)Gppp). The unblocked 5' ends of the viral mRNA's were then labeled enzymatically with (32)P, and the RNAs were digested with RNase T1 and fingerprinted. Three oligonucleotides derived from capped termini were isolated, and their sequences were determined to be pGmACAUUUUCUAUUUUAAGp, p(m)AmCAUUUUCUAUUUUAAGp, and p(m)AmUUUUCUAUUUUAAGp. These oligonucleotides comprise a staggered set with members 15, 17, and 18 nucleotides long, which share a common 3' sequence for 15 nucleotides. The sequences correspond exactly to the polyoma virus DNA sequence (Arrand et al., J. Virol. 33:606-618, 1980) from 66.79 to 66.46 map units (between 75 and 92 nucleotides preceding the ATG initiation codon for the capsid protein VP2). Previous results showed that the sequence between 13 and 64 nucleotides preceding the VP2 initiation codon corresponds to oligonucleotides reiterated in the leader sequence which is spliced onto the bodies of the three functionally distinct viral late mRNA's (Flavell et al., Cell 16:357-372, 1979; Legon et al., Cell 16:373-388, 1979). The three capped oligonucleotides we sequenced are derived from the first large predicted T1 oligonucleotide 5' to those detected in the leader sequence. The occurrence of a cap at each purine of a single tetranucleotide sequence reflects micro-heterogeneity either in transcriptional initiation or in processing cleavage involved in cap syntheses.

Amplification in the leader sequence of late polyoma virus mRNAs

Ribonuclease T1 fingerprints of the three "late" polyoma virus mRNAs show that oligonucleotides of the leader sequence are present in multiple copies in each mRNA. These oligonucleotides, however, appear unimolar in fingerprints of complete, continuous transcripts of the late strand of the viral DNA. Oligonucleotides which are represented only once in the DNA are thus reiterated in the mature mRNAs. Consequently, when mRNA was hybridized to the leader region of immobilized viral DNA, those copies present in excess of their genomic representation failed to hybridize and were released by RNAase treatment. Analysis of the RNAase-resistant hybrids revealed a series of leader species with complex sequence arrangements. We suggest that these complicated reiterated sequences are generated during the processing of a precursor RNA which extends several times around the genome. This RNA would be shortened by a series of splicing reactions which conserve sequences from the leader region and attach them to a suitable coding sequence.

Multiple 5' terminal cap structures in late polyoma virus RNA

Nuclear and cytoplasmic polyoma virus-specific RNA extracted from 32P-labeled mouse embryo cells late during productive viral infection was analyzed for the presence of 5' terminal capped structures by complete digestion with RNAases T1, T2 and A, followed by two-dimensional electrophoretic fractionation. Seven major cap I structures (m7 GpppNm1pN2p) were observed in both cases. These termini were further characterized by digestion with penicillium nuclease P1, followed by product analysis in a variety of alternative separate systems. Each structure had an individual combination of N1 and N2 nucleotides, where N1 was always a purine nucleotide but N2 was any nucleotide subject to the single exception that m7GpppGmpCp is found only in low yield. Four different cap II derivatives (m7GpppNm1pNm2pN3p) of four of the cap I structures were also detected in cytoplasmic RNA. None of the termini described derived from contaminating host cell RNA. All of these cap structures mapped on the polyoma viral DNA genome between 66 and 71 map units, a region distant from the 5' end of the bodies of two of the three late polyoma mRNAs. All the polyoma virus-specific cap structures, however, were present in each of the purified 16S, 18S and 19s late mRNAs. These data suggested that families of capped leader sequences of varying sizes are attached to the main body of each late polyoma mRNA species by a splicing mechanism.