Isolation of genomic DNA from defatted oil seed residue of rapeseed (Brassica napus).

A simple protocol for obtaining pure, restrictable and amplifiable megabase genomic DNA from oil-free seed residue of Brassica napus, an important oil seed plant, has been developed. Oil from the dry seeds was completely recovered in an organic solvent and quantified gravimetrically followed by processing of the residual biomass (defatted seed residue) for genomic DNA isolation. The isolated DNA can be cut by a range of restriction enzymes. The method enables simultaneous isolation and recovery of lipids and genomic DNA from the same test sample, thus allowing two independent analyses from a single sample. Multiple micro-scale oil extraction from the commercial seeds gave approximately 39% oil, which is close to the usual oil recovery from standard oil seed. Most of the amplified fragments were scored in the range of 2.5 to 0.5 kb, best suited for scoring as molecular diagnostics.

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.

Development and validation of a screening test for 12 common mutations of the cystic fibrosis CFTR gene.

The results obtained using deoxyribonucleic acid (DNA) amplification-based tests must be accurate and reproducible. One such test that simultaneously detects any of 12 of the most common mutations of the cystic fibrosis transmembrane conductance regulator gene is presented in this report. An investigation was conducted into how changes of primer, DNA template and Taq DNA polymerase concentrations and of polymerase chain reaction annealing temperatures affect the test. A total of 383 DNA samples obtained from different laboratories was then examined. The preliminary studies defined the conditions under which accurate results are obtained even if the test is performed under suboptimal conditions. Subsequently, 377 (98.4%) of the DNA samples analysed were in full agreement with DNA typing results derived by other methods. The remaining 1.6% of samples were not mistyped, rather they were not scored owing to failure to detect control DNA sequences. These were also archival DNA preparations rather than freshly prepared samples from venous blood. Careful primer design and optimization of reaction conditions are important in the development of multiplex deoxyribonucleic acid amplification-based diagnostic tests. Providing the recommended protocols are followed, the test described here is simple to carry out, gives accurate results and works well if performed within defined operational windows for each reaction variable.

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.

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.

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.

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 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 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.

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.

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.

Sequence characterization of ENU-induced mutants of glucose phosphate isomerase in mouse.

Four of five mutations producing GPI1 null lethal phenotypes in the homozygous state, which were previously identified from the offspring of male mice, spermatogonially treated with N-ethyl N-nitrosourea (ENU), have been characterized at the nucleotide level by reverse transcription of RNA from heterozygotes for mutant and wild-type alleles and cycle sequencing with cDNA-derived primers. In three of the mutations studied, a single nucleotide substitution, altering the predicted amino acid on translation, was observed in the mutant allele. In Gpi1-sam1H amino acid residue 277, TCA Ser (wild type), is altered to CCA Pro, and in Gpi1-sbm3H and Gpi1-sbm4H amino acid residue 510 Asp GAC (wild type) is altered to GGC Gly. These ENU-induced mutations occur at A-T base pairs in agreement with the current view of the mechanism of action for this mutagen. These changes also occur at residues implicated as being important in the catalytic functioning of the enzyme, from crystallographic studies, and may explain the loss of enzyme function. The fourth identified mutation, Gpi1-sbm2H, is a deletion of amino acid residues Arg134 to Leu162 inclusive, which may arise from incorrect splicing of mRNA; a fifth mutation has remained undetermined.

Sequence characterization of alleles Gpi1-Sa and Gpi1-Sb at the glucose phosphate isomerase structural locus.

The sequences of alleles Gpi1-sa and Gpi1-sb at the glucose phosphate isomerase structural locus have been determined from cDNA of the mouse inbred strains 101/H Gpi1-sa and C3H/HeH Gpi1-sb by RT PCR and direct sequencing of the amplified products. Four individual nucleotide differences were observed between the two alleles. The difference at amino acid residue 94, (Gpi1-sa GAT Asp, Gpi1-sb AAT Asn) may account for the differing electrophoretic migration, isoelectric point, and thermostability of the two alleles. Two of the other observed differences in the coding region (amino acid residue 12 Leu, Gpi1-sa CTC, Gpi1-sb CTG and amino acid residue 17 Arg, Gpi1-sa CGC, Gpi1-sb CGT) are silent and do not affect the predicted amino acid residues on translation. The fourth observed difference is located within the 3' noncoding sequences of the cDNA. The change at amino acid residue 94 is associated with the presence of a Hinf1 restriction site in Gpi1-sb, which is absent in Gpi1-sa, and may be a useful method for determining this marker.

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.

Differential Expression and Sequence Analysis of Ribosomal Protein Genes Induced in Stolon Tips of Potato (Solanum tuberosum L.) during the Early Stages of Tuberization.

cDNA clones of two genes, TUBS19 and TUBL7, which show a 15- to 20-fold increase in transcript level in the stolon tip during the early stages of tuberization, 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 tuberization. Southern analysis shows that there are similar sequences in the genome of nontuberizing wild-type potato species Solanum brevidens and in Lycopersicon esculentum (tomato). Sequence analysis reveals a high degree of similarity between the TUBS19 cDNA and the eukaryotic S19 ribosomal protein gene. TUBL7 cDNA shows similarity to another eukaryotic ribosomal protein gene, L7.

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.