The organization and genetics of rDNA length variants in peas

Identification of Stipules reduced, a leaf morphology gene in pea (Pisum sativum)

Pea (Pisum sativum) is one of relatively few genetically amenable plant species with compound leaves. Pea leaves have a variety of specialized organs: leaflets, tendrils, pulvini and stipules, which enable the identification of mutations that transform or affect distinct parts of the leaf. Characterization of these mutations offers insights into the development and evolution of novel leaf traits. The previously characterized morphological gene Cochleata, conferring stipule identity, was known to interact with Stipules reduced (St), which conditions stipule size in pea, but the St gene remained unknown. Here we analysed Fast Neutron irradiated pea mutants by restriction site associated DNA sequencing. We identified St as a gene encoding a C2H2 zinc finger transcription factor that is regulated by Cochleata. St regulates both cell division and cell expansion in the stipule. Our approach shows how systematic genome-wide screens can be used successfully for the analysis of traits in species for which whole genome sequences are not available.

Functional ultrastructure of the plant nucleolus

Nucleoli are nuclear domains present in almost all eukaryotic cells. They not only specialize in the production of ribosomal subunits but also play roles in many fundamental cellular activities. Concerning ribosome biosynthesis, particular stages of this process, i.e., ribosomal DNA transcription, primary RNA transcript processing, and ribosome assembly proceed in precisely defined nucleolar subdomains. Although eukaryotic nucleoli are conservative in respect of their main function, clear morphological differences between these structures can be noticed between individual kingdoms. In most cases, a plant nucleolus shows well-ordered structure in which four main ultrastructural components can be distinguished: fibrillar centers, dense fibrillar component, granular component, and nucleolar vacuoles. Nucleolar chromatin is an additional crucial structural component of this organelle. Nucleolonema, although it is not always an unequivocally distinguished nucleolar domain, has often been described as a well-grounded morphological element, especially of plant nucleoli. The ratios and morphology of particular subcompartments of a nucleolus can change depending on its metabolic activity which in turn is correlated with the physiological state of a cell, cell type, cell cycle phase, as well as with environmental influence. Precise attribution of functions to particular nucleolar subregions in the process of ribosome biosynthesis is now possible using various approaches. The presented description of plant nucleolar morphology summarizes previous knowledge regarding the function of nucleoli as well as of their particular subdomains not only in the course of ribosome biosynthesis.

Molecular organization of the 25S-18S rDNA IGS of Fagus sylvatica and Quercus suber: a comparative analysis

The 35S ribosomal DNA (rDNA) units, repeated in tandem at one or more chromosomal loci, are separated by an intergenic spacer (IGS) containing functional elements involved in the regulation of transcription of downstream rRNA genes. In the present work, we have compared the IGS molecular organizations in two divergent species of Fagaceae, Fagus sylvatica and Quercus suber, aiming to comprehend the evolution of the IGS sequences within the family. Self- and cross-hybridization FISH was done on representative species of the Fagaceae. The IGS length variability and the methylation level of 18 and 25S rRNA genes were assessed in representatives of three genera of this family: Fagus, Quercus and Castanea. The intergenic spacers in Beech and Cork Oak showed similar overall organizations comprising putative functional elements needed for rRNA gene activity and containing a non-transcribed spacer (NTS), a promoter region, and a 5′-external transcribed spacer. In the NTS: the sub-repeats structure in Beech is more organized than in Cork Oak, sharing some short motifs which results in the lowest sequence similarity of the entire IGS; the AT-rich region differed in both spacers by a GC-rich block inserted in Cork Oak. The 5′-ETS is the region with the higher similarity, having nonetheless different lengths. FISH with the NTS-5′-ETS revealed fainter signals in cross-hybridization in agreement with the divergence between genera. The diversity of IGS lengths revealed variants from ∼2 kb in Fagus, and Quercus up to 5.3 kb in Castanea, and a lack of correlation between the number of variants and the number of rDNA loci in several species. Methylation of 25S Bam HI site was confirmed in all species and detected for the first time in the 18S of Q. suber and Q. faginea. These results provide important clues for the evolutionary trends of the rDNA 25S-18S IGS in the Fagaceae family.

High-throughput retrotransposon-based fluorescent markers: improved information content and allele discrimination

BACKGROUND

Dense genetic maps, together with the efficiency and accuracy of their construction, are integral to genetic studies and marker assisted selection for plant breeding. High-throughput multiplex markers that are robust and reproducible can contribute to both efficiency and accuracy. Multiplex markers are often dominant and so have low information content, this coupled with the pressure to find alternatives to radio-labelling, has led us to adapt the SSAP (sequence specific amplified polymorphism) marker method from a 33P labelling procedure to fluorescently tagged markers analysed from an automated ABI 3730 xl platform. This method is illustrated for multiplexed SSAP markers based on retrotransposon insertions of pea and is applicable for the rapid and efficient generation of markers from genomes where repetitive element sequence information is available for primer design. We cross-reference SSAP markers previously generated using the 33P manual PAGE system to fluorescent peaks, and use these high-throughput fluorescent SSAP markers for further genetic studies in Pisum.

RESULTS

The optimal conditions for the fluorescent-labelling method used a triplex set of primers in the PCR. These included a fluorescently labelled specific primer together with its unlabelled counterpart, plus an adapter-based primer with two bases of selection on the 3' end. The introduction of the unlabelled specific primer helped to optimise the fluorescent signal across the range of fragment sizes expected, and eliminated the need for extensive dilutions of PCR amplicons. The software (GeneMarker Version 1.6) used for the high-throughput data analysis provided an assessment of amplicon size in nucleotides, peak areas and fluorescence intensity in a table format, so providing additional information content for each marker. The method has been tested in a small-scale study with 12 pea accessions resulting in 467 polymorphic fluorescent SSAP markers of which 260 were identified as having been mapped previously using the radio-labelling technique. Heterozygous individuals from pea cultivar crosses were identifiable after peak area data analysis using the fluorescent SSAP method.

CONCLUSION

As well as developing a rapid, and high-throughput marker method for genetic studies, the fluorescent SSAP system improved the accuracy of amplicon scoring, increased the available marker number, improved allele discrimination, and was sensitive enough to identify heterozygous loci in F1 and F2 progeny, indicating the potential to develop high-throughput codominant SSAPs.

A crispa null mutant facilitates identification of a crispa-like pseudogene in pea

The genomes of several legume species contain two Phantastica-like genes. Previous studies on leaf development have found that Phantastica confers leaf blade adaxial identity in plant species with simple leaves and leaflet adaxial identity in pea (Pisum sativum L.), a legume with compound leaves. Previous characterisation of the phantastica mutant of pea, crispa, showed it had radialised leaflets, but stipules were not radialised. This suggested either that mutation of a second redundant gene was required for radialisation of stipules, or, that a null mutation was required. Previously characterised crispa mutants may not have exhibited radialised stipules because they were weak alleles. In this work we show that pea has a second Phantastica-like gene, which lies on a different chromosome to Crispa. The second gene was found to be a pseudogene in several genotypes of pea, therefore it would not have a role in conferring stipule adaxial identity. A new deletion mutant, crispa-4 was identified. The mutant has radialised stipules and leaflets, showing that Crispa confers adaxial identity on both these organs in pea. The nucleotide sequence data reported here are in the EMBL and GenBank Nucleotide Databases under the accession numbers DQ486060 (JI 2822), DQ486061 (JI 15), DQ486062 (JI 281) and DQ486063 (JI 399).

The ribosomal RNA gene region of Nosema apis (Microspora): DNA sequence for small and large subunit rRNA genes and evidence of a large tandem repeat unit size

The ribosomal RNA (rRNA) gene region of the microsporidium, Nosema apis, has been examined. A new method for extracting microsporidian genomic DNA from infected host tissue is described. Complete DNA sequence data are presented for the small subunit gene (1242 bp), the internal transcribed space (33 bp), and the large subunit gene (2481 bp to a putative termination point). This is the first time that the complete large subunit rRNA gene has been published for any microsporidian species. DNA sequence is also presented for the regions flanking the 5' end of the small subunit gene and the 3' end of the large subunit gene. The intergenic spacer is shown to be heterogeneous, showing variation in sequence and restriction sites rather than length and containing sequence repeats, which are a characteristic feature of intergenic spacers. The rRNA gene region of N. apis is shown to occur in a head-to-tail, tandemly repeated manner, as in other eukaryotes. This repeat unit is shown to be approximately 18 kb in length. The nucleotide sequence presented has been submitted to the Genbank database under the accession number U97150.

DNA profiling and plant variety registration: 1. The use of random amplified DNA polymorphisms to discriminate between varieties of oilseed rape

Before they can be marketed in the UK, newly bred varieties of crop species have to undergo a process of statutory testing, part of which involves the examination of the distinctness, uniformity and stability (DUS) of the variety. DUS testing is also used as the basis for the award of Plant Breeders' Rights. This paper examines the potential of DNA polymorphisms, amplified using arbitrary primers (RAPDs) for use in DUS testing of varieties of oilseed rape. RAPDs using suitable primers can produce high levels of discrimination (> 95%) between varieties, although there are certain problems in gel 'scoring' that are only partially resolved by computerised gel scanning/evaluation techniques. Varieties of oilseed rape are also heterogeneous in their RAPD profiles using certain primers, which could cause problems in the DUS testing context. DNA profiling with RAPDs could be used for discrimination between and identification of oilseed rape varieties, but its use for DUS testing needs to be considered carefully.

Hypervariability of ribosomal DNA at multiple chromosomal sites in lake trout (Salvelinus namaycush)

Variation in the intergenic spacer (IGS) of the ribosomal DNA (rDNA) of lake trout (Salvelinus namaycush) was examined. Digestion of genomic DNA with restriction enzymes showed that almost every individual had a unique combination of length variants with most of this variation occurring within rather than between populations. Sequence analysis of a 2.3 kilobase (kb) EcoRI-DraI fragment spanning the 3' end of the 28S coding region and approximately 1.8 kb of the IGS revealed two blocks of repetitive DNA. Putative transcriptional termination sites were found approximately 220 bases (b) downstream from the end of the 28S coding region. Comparison of the 2.3-kb fragments with two longer (3.1 kb) fragments showed that the major difference in length resulted from variation in the number of short (89 b) repeats located 3' to the putative terminator. Repeat units within a single nucleolus organizer region (NOR) appeared relatively homogeneous and genetic analysis found variants to be stably inherited. A comparison of the number of spacer-length variants with the number of NORs found that the number of length variants per individual was always less than the number of NORs. Examination of spacer variants in five populations showed that populations with more NORs had more spacer variants, indicating that variants are present at different rDNA sites on nonhomologous chromosomes.

Ribosomal DNA repeat unit polymorphism in 49 Vicia species

DNA restriction endonuclease fragment analysis was used to obtain new information on the genomic organization of Vicia ribosomal DNA (rDNA), more particularly among V. faba and its close relatives and the taxa within three (Narbonensis, Villosa, Sativa) species' complexes. Total genomic DNA of 90 accessions representing 49 Vicia species was restricted with 11 enzymes, and the restriction fragments were probed with three ribosomal clones. Twenty-eight repeat unit length classes were identified. The number of length classes (1-2) per accession did not correspond to the number of nucleolar organizing regions (NORs). The number of rRNA genes was independent of the 2C nuclear DNA amount present in the taxon. Each of the 90 accessions had 2 (rarely 1)-4 DraI sites. Those taxa with the same number of DraI sites generally could be distinguished from each other by different configurations. Probing of the DNA samples digested with tetranucleotide recognition restriction endonucleases emphasized differences between divergent spacer regions and enabled relative homologies between the coding regions to be established. Overall, rDNA restriction site variation among the species showed a good correlation with taxonomic classification. The rDNA analysis indicated evolutionary relatedness of the various taxa within the Narbonensis species complex. rDNA diversity within two other species complexes (Villosa, Sativa), on the other hand, was more extensive than expected. With few exceptions, data on the two complexes give evidence of taxon-specific divergences not seen with other approaches. The restriction site variability and repeat length heterogeneity in the rDNA repeat exhibited startling differences between V.faba and its close wild relatives included in the Narbonensis species complex. This analysis provides new evidence that none of the species within the complex can be considered to be putative allies of broad bean.

Multiple isoforms of Pisum trypsin inhibitors result from modification of two primary gene products

Characterization of Pisum (pea) seed trypsin inhibitors (TI) and their corresponding cDNAs indicates that the pea TI gene family contains two genes. The existence of multiple TI isoforms can be attributed to post-translational modifications of primary gene products. Post-translational processing at the C-terminus during the desiccation stage of seed development results in the appearance of TI isoforms with increased affinity for the target enzyme, trypsin.

Structural analysis of two length variants of the rDNA intergenic spacer from Eruca sativa

Restriction enzyme analysis of the rRNA genes of Eruca sativa indicated the presence of many length variants within a single plant and also between different cultivars which is unusual for most crucifers studied so far. Two length variants of the rDNA intergenic spacer (IGS) from a single individual E. sativa (cv. Itsa) plant were cloned and characterized. The complete nucleotide sequences of both the variants (3 kb and 4 kb) were determined. The intergenic spacer contains three families of tandemly repeated DNA sequences denoted as A, B and C. However, the long (4 kb) variant shows the presence of an additional repeat, denoted as D, which is a duplication of a 224 bp sequence just upstream of the putative transcription initiation site. Repeat units belonging to the three different families (A, B and C) were in the size range of 22 to 30 bp. Such short repeat elements are present in the IGS of most of the crucifers analysed so far. Sequence analysis of the variants (3 kb and 4 kb) revealed that the length heterogeneity of the spacer is located at three different regions and is due to the varying copy numbers of repeat units belonging to families A and B. Length variation of the spacer is also due to the presence of a large duplication (D repeats) in the 4 kb variant which is absent in the 3 kb variant. The putative transcription initiation site was identified by comparisons with the rDNA sequences from other plant species.

Genetic aspects of the organization of legumin genes in pea

We have compared physical and genetic maps of the region around the legJ gene in pea. In this vicinity there are four B-type legumin genes, arranged as two close pairs. The detection of a recombination event within this gene cluster allows the orientation of this group of genes within the surrounding linkage group to be determined. The relationship between physical and genetic distances in this region is discussed, as are the implications of this for relating physical and genetic maps elsewhere in the pea genome.

Different patterns of rDNA distribution in Pisum sativum nucleoli correlate with different levels of nucleolar activity

We have used in situ hybridization with probes to rDNA, labelled either with digoxygenin or directly with fluorescein, to determine the arrangement of these genes within the nucleoli of Pisum sativum L. root cells. Confocal laser scanning microscopy was used to image the three-dimensional structures revealed, but we have also compared this technique with deconvolution of conventional (wide-field) fluorescence images measured with a cooled CCD camera, and have shown that the results are remarkably similar. When the deconvolution technique was applied to the confocal data it gave clearer images than could be achieved by confocal microscopy alone. We have analysed the distribution of rDNA in the different cell types observable in root tips: the quiescent centre; active meristematic cells; and relatively differentiated root cap, epidermal and cortical cells. In addition to four perinucleolar knobs of condensed, inactive rDNA genes, corresponding to the four nucleolar organizers in P. sativum, which were the most brightly labelled structures, several characteristic patterns of intranucleolar labelling were apparent, including bright foci, large central chromatin masses, and fine, decondensed interconnecting fibres. The larger and more active the nucleolus, the smaller the proportion of condensed perinucleolar rDNA. In some large and active meristematic nucleoli, all the internal rDNA is decondensed, showing that transcription cannot be restricted to the bright foci, and is most likely to occur on the decondensed fibres.

Ribosomal DNA variation and population differentiation in Salicornia L

Analysis of nuclear rDNA variation within and between populations of Salicornia from the salt marsh at Stiffkey, Norfolk has detected new patterns of genetic differentiation. Individual plants may have alternative 10.5 and 12 kb repeat units. A strong association between the frequency of particular genetic variants and the environmental gradient of tidal inundation was evident. Salicornia dolichostachya Moss from sandy flats on the lowest parts of the marsh, near to the seaward edge, and S. fragilis Ball & Tutin from deep creeks were both monomorphic for the 12 kb variant; in contrast, S. pusilla J. Woods, characteristic of the highest parts of the tidal range, was monomorphic for the 10-5 kb variant. The more phenotypically variable S. europaea L. and S. ramosissima J. Woods populations that are found in large areas of lower and upper marsh, respectively, were heterogeneous for rDNA variant type. Nevertheless, the frequency of the 12 kb variant was significantly higher in plants from the lower marsh than in those from upper marsh, and in plants from low-lying pans than in those from raised interfluves; the 10.5 kb variant had the converse distribution. Variation in rDNA was not obviously associated with variation in morphology, or with variations in isozyme frequency established previously. Comparison of these results with those for populations from an extensive study, ranging from Anglesey (N. Wales) to S.W. Spain and the Gulf coast of Saudi Arabia, suggested that the rDNA variation and its association with environmental variation are complex and site-dependent. Plants from Anglesey had 10.5 and 11.5 kb variants, whereas only a 10-75 kb variant was detected in material from Spain and Saudi Arabia. rDNA variants were used as genetic markers in order to test the hypothesis that Salicornia is predominantly an inbreeder; conventional breeding experiments have been hampered by its highly specialized morphology and this represents the first direct, sensitive test of an idea that has been suggested mainly on morphological and phenological grounds. Analysis of rDNA in 38 maternal plants from Stiffkey and 2112 of their progeny provided no evidence for out-crossing.

Ribosomal DNA variation in finger millet and wild species of Eleusine (Poaceae)

Finger millet is an important cereal crop in the semi-arid regions of Africa and India. The crop belongs to the grass genus Eleusine, which includes nine annual and perennial species native to Africa except for the New World species E. tristachya. Ribosomal DNA (rDNA) variation in finger millet and related wild species was used to provide information on the origin of the genomes of this tetraploid crop and point out genetic relationships of the crop to other species in the genus. The restriction endonucleases used revealed a lack of variability in the rDNA spacer region in domesticated finger millet. All the rDNA variants of the crop were found in the proposed direct tetraploid ancestor, E. coracana subsp. africana. Wild and domesticated finger millet displayed the phenotypes found in diploid E. indica. Diploid Eleusine tristachya showed some similarity to the crop in some restriction sites. The remaining species were quite distinct in rDNA fragment patterns. The study supports the direct origin of finger millet from subspecies africana shows E. indica to be one of the genome donors of the crop, and demonstrates that none of the other species examined could have donated the second genome of the crop. The rDNA data raise the possibility that wild and domesticated finger millet could have originated as infraspecific polyploid hybrids from different varieties of E. indica.

rDNA intergenic region from Arabidopsis thaliana. Structural analysis, intraspecific variation and functional implications

The ribosomal gene intergenic region from Arabidopsis thaliana contains four clusters of mutually unrelated repeated sequences. By comparison with the respective regions in two other Brassicaceae, Raphanus and Sinapis, the putative promoter sequence for RNA polymerase I was located. The homologies suggest that the RNA polymerase I promoter in Brassicaceae ranges further upstream than in animals. Upstream duplications of at least a part of the promoter region were found to be located between individual blocks of the largest internal repeat family ("A" repeats), which is made up of multiple repeats of two closely related sequences 21 or 20 bp in length. Overall structural similarities of the A. thaliana rDNA intergenic region with those from wheat and from Xenopus laevis are discussed. We also present data on the range of intraspecific length heterogeneities found in the central EcoRI fragment of the intergenic region and on the frequencies with which specific length variants occur in the genome. To determine the nature of the length heterogeneities, we sequenced the central EcoRI fragments from four independently isolated genomic clones. Three levels of rearrangements were detected. Length variation can be caused by duplication of a whole A repeat block, or, most frequently, by insertion and/or deletion of one or a few A repeat units. Surprisingly, single base mutations are extremely rare, which hints at some mechanism of homogenization which might be acting on the intergenic region. A possible function of the described sequences in transcriptional regulation is discussed and will be the aim of further investigations.

Evidence for the presence of hairpin chloroplast DNA molecules in barley cultivars

Total DNA was extracted from young green and etiolated barley leaf shoots and run on 2D neutral/alkaline agarose gels. This technique showed the presence of molecules which behaved as though their single-stranded length was twice their double-stranded length. This behaviour was sensitive to S1 nuclease. Our conclusion is that these DNAs are hairpin molecules. They are homologous to sequences found throughout the barley chloroplast genome. This type of molecule is present in uncut DNA with a continuous range of sizes varying between 0.5 and 15 kbp in our experimental conditions. The origin and possible biological function of these molecules is discussed.

A copia-like element in Pisum demonstrates the uses of dispersed repeated sequences in genetic analysis

A DNA sequence between two legumin genes in Pisum is a member of the copia-like class of retrotransposons and represents one member of a polymorphic and heterogeneous dispersed repeated sequence family in Pisum. This sequence can be exploited in genetic studies either by RFLP analysis where several markers can be scored together, or the segregation of individual elements can be followed after PCR amplification of specific members.

The wrinkled-seed character of pea described by Mendel is caused by a transposon-like insertion in a gene encoding starch-branching enzyme

We describe the cloning of the r (rugosus) locus of pea (Pisum sativum L.), which determines whether the seed is round or wrinkled. Wrinkled (rr) seeds lack one isoform of starch-branching enzyme (SBEI), present in round (RR or Rr) seeds. A major polymorphism in the SBEI gene between near-isogenic RR and rr lines shows 100% cosegregation with the r locus, establishing that the SBEI gene is at the r locus. An aberrant transcript for SBEI is produced in rr embryos. In rr lines the SBEI gene is interrupted by a 0.8 kb insertion that is very similar to the Ac/Ds family of transposable elements from maize. Failure to produce SBEI has complex metabolic consequences on starch, lipid, and protein biosynthesis in the seed.

Methylated and undermethylated rDNA repeats are interspersed at random in two higher plant species

The organization of methylated rDNA repeats of radish and pea is described and it is shown that methylated repeats and non-methylated repeats are interspersed one with another. Methylated arrays are not much longer than 100 kb, or about 10 repeat units in length.

Ribosomal DNA repeat unit polymorphism in 25 Hordeum species

Tandemly repeated DNA sequences containing structural genes encoding ribosomal RNA (rDNA) were investigated in 25 species of Hordeum using the wheat rDNA probe pTA71. The rDNA repeat unit lengths were shown to vary between 8.5 and 10.7 kb. The number of length classes (1-3) per accession generally corresponded to the number of nucleolar organizing regions (NORs). Intraspecific variation was found in H. parodii, H. spontaneum and H. leporinum, but not in H. bulbosum. Restriction analysis showed that the positions of EcoRI, SacI and certain BamHI cleavage sites in the rRNA structural genes were highly conserved, and that repeat unit length variation was generally attributable to the intergenic spacer region. Five rDNA BamHI restriction site maps corresponded to the following groups of species: Map A - H. murinum, H. glaucum, H. leporinum, H. bulbosum, H. marinum, H. geniculatum; Map B - H. leporinum; Map C - H. vulgare, H. spontaneum, H. agriocrithon; Map D - H. chilense, H. bogdanii; and Map E - remaining 14 Hordeum species. The repeat unit of H. bulbosum differed from all other species by the presence of a HindIII site. The closer relationship of H. bulbosum to H. leporinum, H. murinum and H. glaucum than to H. vulgare was indicated by their BamHI restriction maps.

The Cucurbita maxima ribosomal DNA intergenic spacer has a complex structure

The nucleotide (nt) sequence of the 5508-nt intergenic spacer (IGS), between the 25S- and the 18S-coding regions of Cucurbita maxima rDNA, was determined. The fragment sequenced is 6142 nt long and includes 472 nt of 25S- and 162 nt of 18S-coding regions. The IGS has a complex primary structure, composed of five repetitive families (A-E) and three unique domains. It is dominated by the presence of nine, tandemly-repeating units of approximately 250 nt (repeat D), each unit containing four copies of an internal subrepeat (repeat E). The repetitive units show sequence variability consisting of nt changes, insertions and deletions. Upstream of the nine D repeats and between two copies of the B repeat is a 575-nt region, highly G + C rich (83%) and heavily biased toward C (58%) in the sense strand. Within this region are six repetitive units, averaging 42 nt (repeat C) each, containing but a single A nt. Downstream from the terminus of the 25S-coding sequence, are two tandem copies of the 103-nt A repeat. The IGS of C. maxima is longer and more complex than that of other plant IGSs described to date. The 600 nt at the 5' portion of cucurbit IGS is more conserved in evolution than the remainder, as revealed by comparison of C. maxima and C. pepo IGS restriction maps and by nucleotide sequence comparison of C. maxima and Cucumis sativa IGSs.

Variability of human rRNA genes: inheritance and nonrandom chromosomal distribution of structural variants of nontranscribed spacer sequences

Human rRNA genes contain variable regions, one of which is located in nontranscribed spacers (NTSs) closely downstream from the 3'-end of the transcribed region. This polymorphism may be detected by means of blot hybridization analysis as a set of distinct restriction fragments corresponding to this part of the rRNA genes. We have analyzed DNA of 51 individuals and found eight structural NTS variants of this region; two of these were common to all individuals analyzed, and six others were found in different combinations and with different frequencies. The copy number of each variant also differed but was not less than 10-20 copies per cell. The analysis of DNA isolated from leukocytes of the members of 11 families indicated that some of the structural variants (of the NTS region) are inherited as a single Mendelian locus. We propose that rRNA genes that belong to one particular structural variant form clusters on separate chromosomes. To test this proposition, we developed a combined method, including AgNO3-staining of chromosomes, in situ hybridization, and DNA analysis with methylation-sensitive restrictases, and used it for study of persons who had methylated rRNA genes located on AgNO3-negative nucleolar organizers. It was found that in three of four cases methylated genes really belonged to one structural variant. This approach may be used for detailed localization of separate classes of NTS structural variants of human rRNA genes.

Structure of melon rDNA and nucleotide sequence of the 17-25S spacer region

Restriction enzyme and hybridization analysis of melon nuclear DNA suggests a homogenous rDNA population with a repeat unit of 10.2 kb. Several full length Hind III rDNA repeat units were cloned and one of these is described in detail. The regions coding for 25S, 17S and 5.8S rRNAs were located by crossed-contact hybridization and R-loop mapping. Introns were not observed. The nucleotide sequence of the internal transcribed spacer and flanking regions was determined and compared with the corresponding region from rice rDNA by dot matrix analysis. In addition, the extent of gross sequence homology between cloned melon and pea rDNA units was determined by heteroduplex mapping.

5S rRNA genes in Pisum: sequence, long range and chromosomal organization

We have employed a combination of techniques to examine the organization of pea 5S rRNA genes. These include the analysis of length variant interspersion patterns in cosmid clones, sequence analysis, Southern analysis of both conventional gels and field inversion gels and in situ hybridization. From these analyses we conclude that the 5S rRNA genes of pea are arranged in three major tandem arrays which are represented by three large EcoRI fragments and that these correspond to the three sites of in situ hybridization in the haploid pea complement.

Proximity of an ARS consensus sequence to a replication origin of pea (Pisum sativum)

The replication origin (ori-r9) of the 9.0 kb rDNA repeats of pea (Pisum sativum, cv. Alaska) was cloned and found to reside in a 1.5 kb fragment of the non-transcribed spacer region located between the 25 S and 18 S genes. Labeled rDNA rich in replication forks, from cells positioned at the G1/S phase boundary, was used to map ori-r9 by hybridization procedures. Ori-r9 is in a 210-base fragment that is 1.6 kb from the 5' end of the 18 S gene and about 1.5 kb from the 3' end of the 25 S gene. The same procedures, using labeled synthetic ARS consensus sequence as a probe, showed than an ARS consensus sequence is located 3' to ori-r9 in a 710-base fragment. An ARS consensus sequence is, therefore, adjacent to ori-r9 but not coincidental with it.

Structure and evolution of the intergenic region in a ribosomal DNA repeat unit of wheat

The complete nucleotide sequence of the intergenic region between the 25 S and 18 S wheat ribosomal RNA genes has been determined from a 4.6 kb EcoRI-BamHI fragment (1 kb = 10(3) bases or base-pairs) subcloned from the plasmid pTa71. Within this subclone the intergenic DNA is flanked by the 3' end of the 25 S and the 5' end of the 18 S ribosomal RNA sequences. Four repeat families are present within the intergenic region. The major repeat family A, consists of 12 direct repeat units of 135 or 136 base-pairs (bp) flanked by diverged truncated copies. Within each A repeat a subrepeat structure has been revealed. Family B, which is localized to the 5' side of the A repeats, contains three repeat units, one of 152 bp, the second of 150 bp and a truncated unit of 107 bp. Family C, which is localized in the transcribed rRNA precursor, consists of two direct repeat units of 172 and 174 bp and possesses some short subrepeat motifs. The C repeats may have evolved by and diverged from one another by the insertion of short transposable sequences. Family D consists of two direct repeat units of 30 bp located 5' to the start of transcription. Statistical analysis of repeat family A showed that there is a significant association between the similarity of any two repeat units and their distance apart in the array. The near identity of members of the A family is maintained presumably by processes such as unequal crossing over and gene conversion, but the members at each end of the array show more divergence. Sequence motifs in the A and C repeat families and in other regions including the 5' end of 18 S RNA are related, implying that much of the intergenic DNA may have evolved from a few short ancestral sequences. The B and D repeats or their equivalent are not found in a maize ribosomal DNA repeat unit. The DNA in the external transcribed spacer DNA 5' to the 18 S RNA sequence is longer in wheat than in maize. This is due principally to two duplications and insertion of a sequence with dyad symmetry in the wheat gene.

Structural and transcriptional characterization of the external spacer of a ribosomal RNA nuclear gene from a higher plant

A lambda recombinant phage, carrying a radish rDNA fragment spanning the complete external spacer and its borders, has been isolated and characterized by sequencing. The fragment is 2911 bp long and includes 486 bp of the 3' end of the 25S rRNA sequence, 2349 bp of spacer and the first 76 bp of the 5' end of the 18S rRNA sequence. The spacer can be divided into three regions: two unique domains flanking a 830-bp region of repeated sequences. Seven repeats ranging from 80 to 103 bp can be recognized. They are separated by short arrays of 12-21 adenylic residues. Each repeat slightly differs from the others by single-nucleotide changes or short deletions. Examination of single-nucleotide changes common to two units suggests that a duplication arose during the evolution of this sequence. The repeated region was subcloned and used as a probe to demonstrate that it is highly species-specific: in stringent conditions it does not cross-hybridize with the spacer of ribosomal genes from closely related species such as Brassica. Transcription products, starting or finishing within the spacer sequence, were mapped by northern blotting, primer extension and S1 mapping. Two major precursors were identified starting respectively at positions 2095 and 2280. The region surrounding the start at 2095 presents extensive homology with an analogous region in maize, rye, mung bean, Xenopus and tse-tse fly. However, longer transcripts can be detected. Several 3' ends downstream of the 25S terminus were also observed. Taken together these results indicate that rDNA transcription and pre-rRNA processing in plants are more complex than anticipated from previous studies.

Ribosomal RNA genes in plants: variability in copy number and in the intergenic spacer

Ribosomal RNA genes in plants are highly variable both in copy number and in intergenic spacer (IGS) length. This variability exists not only between distantly related species, but among members of the same genus and also among members of the same population of a single species. Analysis of inheritance indicates that copy number change is rapid, occurring even among somatic cells of individual plants, and that up to 90% or more of the gene copies are superfluous. Subrepetitive sequences within the IGS appear to be changing rapidly as well. They are not only variable in sequence from one species to the next, but can vary in number between neighboring gene repeats on the chromosome. In all species examined in detail they are located in the same region of the IGS and contain sequences that can be folded into stem-loop structures flanked by a pyrimidine-rich region. It has been suggested that these subrepeats function in transcriptional enhancement, termination or processing, or in recombination events generating the high multiplicity of ribosomal genes.

Replication of the rRNA and legumin genes in synchronized root cells of pea (Pisum sativum): evidence for transient EcoR I sites in replicating rRNA genes

The temporal pattern of replication of the rRNA and legumin genes differs in synchronized pea root cells. The relative number of rRNA genes replicated hourly during the first five hours of S phase ranges between 5 and 10 percent. In late S phase, during hours six through nine, the number of rRNA genes replicated increases reaching a maximum of about 25 percent at the ninth hour. Unlike the rRNA genes, the legumin genes have a wave-like pattern of replication peaking in early S phase at the third hour and again in late S phase at the eighth hour.Replicating rDNA, isolated by benzoylated naphthoylated DEAE-column chromatography, has EcoR I restriction sites that are absent in non-replicating rDNA sequences. The cleavage of these sites is independent of the time of rDNA replication. The transient nature of the EcoR I sites suggests that they exist in a hemimethylated state in parental DNA.The two Hind III repeat-size classes of rDNA of var. Alaska peas are replicated simultaneously as cells progress through S phase. Thus, even if the 9.0 kb and 8.6 kb repeat classes are located on different chromosomes, their temporal order of replication is the same.

Location of the replication origin in the 9-kb repeat size class of rDNA in pea (Pisum sativum)

The replication origin of the 9-kb rDNA repeat size class of pea (Pisum sativum cv. Alaska) was identified by benzoylated naphthoylated DEAE-cellulose column chromatography and Southern blotting procedures. The origin is located at or near a 0.19-kb EcoR I fragment in the non-transcribed spacer region between the 25S and 18S rRNA genes. Identification of the origin was based on three criteria: (i) an enrichment of the 0.19-kb fragment in replicating rDNA from asynchronously dividing root meristematic cells, (ii) the scarcity of the 0.19-kb fragment in rDNA from non-dividing carbohydrate starved cells, and (iii) a 60-min periodic enrichment of the 0.19-kb fragment in replicating rDNA that temporally coincides with the sequential initiation of replication of replicon families in synchronized pea root cells.

Developmental regulation of cytosine methylation in the nuclear ribosomal RNA genes of Pisum sativum

Prominent features of the cytosine methylation pattern of the Pisum sativum nuclear ribosomal RNA genes have been defined. Cytosine methylation within the C-C-G-G sequence was studied using the restriction enzymes HpaII and MspI and gel blot hybridizations of the restriction digests. The extent to which particular features of the methylation pattern change during seedling development has also been determined. Total cellular DNA, purified from defined sections of pea seedlings grown under different lighting conditions, was analyzed with DNA hybridization probes derived from different portions of a cloned member of the nuclear rRNA gene family. By use of an indirect end-labeling technique, a map of 23 cleavable HpaII and/or MspI sites in genomic rDNA was constructed. The map covers about 90% of the rDNA repeat including the entire non-transcribed spacer region and most of the rRNA coding sequences. One notable feature of the map is that the most prominent HpaII site, located about 800 base-pairs upstream from the 5' end of the mature 18 S rRNA, is cleaved only in one of the two most abundant rDNA length variants (the short variant). With a gel blot assay specific for cleavage at this site, we estimated the HpaII sensitivity of DNA preparations from several stages of pea seedling development. We find that, while methylation is generally low in young seedlings, DNA obtained from the apical buds of pea seedlings is highly methylated. Further, the methylation level of rDNA within the pea bud decreases as the buds are allowed to develop under continuous white light. Our data, taken together with published studies on pea seedling development, indicate that cytosine methylation levels may be related to the regulated expression of the nuclear rRNA genes in pea.

Structure and variation in ribosomal RNA genes of pea : Characterization of a cloned rDNA repeat and chromosomal rDNA variants

A complete ribosomal DNA (rDNA) repeat unit has been cloned from the genome of Pisum sativum (garden pea) and used to construct a map containing a total of 58 cleavage sites for 23 different restriction enzymes. Regions encoding 18s and 25s ribosomal RNA (rRNA) were identified by R-loop analysis. A 180 bp sequence element is repeated eight times in the intergenic 'nontranscribed spacer' (NTS) region, as defined by eight evenly spaced RsaI cleavage sites. Sequence heterogeneity among these elements (subrepeats) is indicated by the presence of an NcoI site within the five RsaI subrepeats distal to the 25s rRNA gene but not in the three subrepeats proximal to this gene, and also by the presence of an additional RsaI cleavage site in one subrepeat.The approximately 4000 copies of the rDNA repeat in the pea nuclear genome show considerable heterogeneity with respect to the length of the NTS region, and differences are also frequently observed between different genotypes. In both cases the length variation appears to be due primarily to differences in the number of subrepeat elements.Comparison of rDNA restriction maps for two pea genotypes separated for hundreds or perhaps thousands of generations reveals that they contain many rDNA identical repeat units. This data is consistent with the view that new rDNA variants are fixed only infrequently in the evolution of a species.Differences also exist between the rDNA repeats of a single genotype with respect to the degree of base modification at certain restriction sites. A large number of sites known to exist in the pea rDNA clone are not cleaved at all in genomic rDNA, or are cleaved in only some copies of the rDNA repeat. We believe these examples of incomplete cleavage results mostly from methylation, although it is difficult to rule out the possibility of sequence variation in all cases. Most putative modifications are best interpreted in terms of cytosine methylation in CG and CXG sequences, but at least one example is more consistent with adenine methylation.We also have constructed a more detailed restriction map of the wheat rDNA clone pTA71 and present a comparison of this map to our map of pea, pumpkin, and wheat in order to assess the amount of useful evolutionary information that can be obtained by comparison of such maps.

Variation in the ribosomal RNA genes among individuals of Vicia faba

Length heterogeneity in the ribosomal repeat of Vicia faba is due to the presence of variable numbers of a 325 bp subrepetitive element within the nontranscribed spacer region. The distribution of size classes among 88 individuals within a population was investigated by blot-hybridization. We find that individual plants can exhibit more than 20 size classes and that hybridization patterns are highly diverse from individual to individual, more so than for any species so far investigated. In contrast, no such differences are observed in patterns for different tissues from a single plant or from parental to F1 generation. Some changes were observed in the F2 generation. We conclude that unequal recombination can give rise to the diversity that we observe for the V. faba rDNA repeats.

Distribution, inheritance and linkage relationships of ribosomal DNA spacer length variants in pea

DNA restriction endonuclease fragment analysis is used to examine the genetic organization, inheritance and linkage associations of the ribosomal DNA in pea. The substantial variation observed in the length of the intergenic spacer region is shown to segregate in Mendelian fashion involving two independent genetic loci, designated Rrn1 and Rrn2. Linkage between Rrn1 and two marker loci on chromosome 4 establishes the approximate location of this tandem array. Rrn2 shows linkage with a set of isozyme loci which assort independently of other markers on all seven chromosomes. Combining these observations with previous cytological data, we suggest that Rrn2 and the isozyme loci linked to it constitute a new linkage group on chromosome 7. The general absence of spacer length classes common to both rRNA loci in any of the lines we examined indicates that little or no genetic exchange occurs between the nonhomologous nucleolar organizer regions.

Heterogeneity in cucumber ribosomal DNA

Restriction and hybridization analysis of cucumber native ribosomal (r) DNA purified from actinomycin-D/CsCl gradients suggested that the repeat units were heterogeneous in both length and sequence. Several full length rDNA repeat units were cloned and five are described which account for all the EcoR I and Xba I fragments present in native DNA. One of a number of BamH I sites found in the clones is not found in a proportion of native rDNA because of base modification. Restriction maps are described for the representative clones and aligned with R-loop maps obtained from electron microscope analysis of each type of repeat unit hybridized under R-loop conditions to pure 18S and 25S rRNAs. The major heterogeneity is explained by differences in length of the external spacer region and by a proportion of the repeat units showing a restriction fragment length polymorphism on EcoR I digestion. The regions coding for 18S and 25S rRNA are uninterrupted and highly conserved.

Restriction fragment length polymorphism markers in relation to quantitative characters

A simple consideration of the potential of restriction fragment length polymorphism mapping, as a method of analysing the inheritance of quantitative characters, suggests that there are severe limitations to the utility of this approach.