Variation in the ribosomal RNA genes among individuals of Vicia faba

Comparative Cytogenetic of the 36-Chromosomes Genera of Orchidinae Subtribe (Orchidaceae) in the Mediterranean Region: A Summary and New Data

This article provides a summary of the current knowledge on the cytogenetics of four genera, which are all composed of 36 chromosomes, within the Orchidinae subtribe (Orchidaceae). Previous classical studies have revealed differences in karyomorphology among these genera, indicating genomic diversity. The current study includes an analysis of the current knowledge with an update of the karyotype of 47 species with 36 chromosomes from the genera Anacamptis, Serapias, Himantoglossum, and Ophrys. The study discusses comparisons of karyotypes among these genera that used traditional techniques as well as karyotype asymmetry relationships with various asymmetry indices. Additionally, the study reports new findings on polyploidy in Anacamptis pyramidalis and Serapias lingua, which were observed through karyotype and meiotic metaphase analyses in EMC. Moreover, the study detected B chromosomes for the first time in A. papilionacea and A. palustris. The article also describes the use of fluorescent in situ hybridization in some specimens of A. papilionacea and A. collina to locate different sites of the 18S-5.8S-25S rDNA and 5S rDNA ribosomal complexes on chromosomes. The information derived from these cytogenetic analyses was used to refine the classification of these orchids and identify evolutionary relationships among different species and genera.

Personal Perspectives on Plant Ribosomal RNA Genes Research: From Precursor-rRNA to Molecular Evolution

The history of rDNA research started almost 90 years ago when the geneticist, Barbara McClintock observed that in interphase nuclei of maize the nucleolus was formed in association with a specific region normally located near the end of a chromosome, which she called the nucleolar organizer region (NOR). Cytologists in the twentieth century recognized the nucleolus as a common structure in all eukaryotic cells, using both light and electron microscopy and biochemical and genetic studies identified ribosomes as the subcellular sites of protein synthesis. In the mid- to late 1960s, the synthesis of nuclear-encoded rRNA was the only system in multicellular organisms where transcripts of known function could be isolated, and their synthesis and processing could be studied. Cytogenetic observations of NOR regions with altered structure in plant interspecific hybrids and detailed knowledge of structure and function of rDNA were prerequisites for studies of nucleolar dominance, epistatic interactions of rDNA loci, and epigenetic silencing. In this article, we focus on the early rDNA research in plants, performed mainly at the dawn of molecular biology in the 60 to 80-ties of the last century which presented a prequel to the modern genomic era. We discuss - from a personal view - the topics such as synthesis of rRNA precursor (35S pre-rRNA in plants), processing, and the organization of 35S and 5S rDNA. Cloning and sequencing led to the observation that the transcribed and processed regions of the rRNA genes vary enormously, even between populations and species, in comparison with the more conserved regions coding for the mature rRNAs. Epigenetic phenomena and the impact of hybridization and allopolyploidy on rDNA expression and homogenization are discussed. This historical view of scientific progress and achievements sets the scene for the other articles highlighting the immense progress in rDNA research published in this special issue of Frontiers in Plant Science on "Molecular organization, evolution, and function of ribosomal DNA."

Integrated evolution of ribosomal RNAs, introns, and intron nurseries

The initial components of ribosomes first appeared more than 3.8 billion years ago during a time when many types of RNAs were evolving. While modern ribosomes are complex molecular machines consisting of rRNAs and proteins, they were assembled during early evolution by the association and joining of small functional RNA units. Introns may have provided the means to ligate many of these pieces together. All four classes of introns (group I, group II, spliceosomal, and archaeal) are present in many rRNA gene loci over a broad phylogenetic range. A survey of rRNA intron sequences across the three major life domains suggests that some of the classes of introns may have diverged from one another within rRNA gene loci. Analyses of rRNA sequences revealed self-splicing group I and group II introns are present in ancestral regions of the SSU (small subunit) and LSU (large subunit), whereas spliceosomal and archaeal introns appeared in sections of the rRNA that evolved later. Most classes of introns increased in number for approximately 1 billion years. However, their frequencies are low in the most recently evolved regions added to the SSU and LSU rRNAs. Furthermore, many of the introns appear to have been in the same locations for billions of years, suggesting an ancient origin for these sequences. In this Perspectives paper, I reviewed and analyzed rRNA intron sequences, locations, structural characteristics, and splicing mechanisms; and suggest that rRNA gene loci may have served as evolutionary nurseries for intron formation and diversification.

Incomplete sequence homogenization in 45S rDNA multigene families: intermixed IGS heterogeneity within the single NOR locus of the polyploid species Medicago arborea (Fabaceae)

BACKGROUND AND AIMS

Ribosomal sequences have become the classical example of the genomic homogenization of nuclear multigene families. Despite theoretical advantages and modelling predictions that support concerted evolution of the 45S rDNA, several reports have found intragenomic polymorphisms. However, the origins and causes of these rDNA polymorphisms are difficult to assess because seed plants show a wide range of 45S rDNA loci number variation, especially in polyploids. Medicago arborea is a tetraploid species that has a single 45S rDNA locus. This feature makes this species a suitable case study to assess the fate of ribosomal IGS homogenization in polyploid species showing nucleolus organizer region (NOR) reduction.

METHODS

The intergenic spacer (IGS) region was amplified by long PCR and the fragments were cloned and sequenced by a primer-walking strategy. The physical mapping of the whole and partial IGS variants was assessed by fluorescent in situ hybridization (FISH) and fibre-FISH methods on mitotic chromosomes and extended DNA fibres, respectively.

KEY RESULTS

Two IGS fragments of 4·8 and 3·5 kb were obtained showing structural features of functional sequences. The shorter variant appears to be a truncated copy of the 4·8 kb fragment that lacks the duplication of the transcription initiation site region and the entire D region. The physical localization of the two IGS variants on metaphase chromosomes and extended DNA fibres using FISH corroborated their joint presence within the same locus. In addition, no spatial structure of the two variants was detected within the NOR.

CONCLUSIONS

The results suggest that full sequence homogenization is not operating within the NOR locus of M. arborea. The structure of the NOR locus reported here departs from the models of IGS heterogeneity present in plants and caution against assuming the widespread belief that intragenomic ribosomal heterogeneity is mainly due to sequence variation between paralogous loci.

Organization of 5S ribosomal RNA genes in tea (Camellia sinensis)

The 5S rRNA genes in the Camellia sinensis (L.) O. Kuntze (tea) genome are arranged as tandem repeat units of 300 and 325 bps. The 2 classes of tandem repeats were discovered by Southern hybridisation of tea genomic DNA with a 5S rRNA gene PCR product.Key words: Camellia species, 5S rDNA, multigene family, tandem repeats, spacers.

Ribosomal DNA, species structure, and biogeography of the cactophilic yeast Clavispora opuntiae

The ribosomal DNA of the cactophilic yeast species Clavispora opuntiae was studied in order to clarify the global distribution of the yeast. Over 500 strains, including isolates from several new localities worldwide, were characterized by rDNA restriction mapping. An unusual restriction pattern previously encountered only in one strain, from Conception Island in the Bahamas, was found in several Brazilian isolates. Sequences of the D1/D2 and D7/D8 divergent domains of the large subunit (LSU) and of the intergenic spacers (IGS) confirmed that these strains represent a genetically distinct variety of Clavispora opuntiae. This divergence had previously been hypothesized on the basis of reduced genetic recombination in inter-varietal crosses and the presence of a polymorphic ApaI restriction site located in the LSU. The exact position of the ApaI site in the D8 divergent domain and the nature of the variation that it reveals were determined. The complete sequences of 12 intergenic spacers clarified the significance of the species-wide variation uncovered by restriction mapping. Most of the polymorphic sites occur in the IGS1 and IGS2 regions, on either side of the 5S gene, and the variation is largely due to differences in the numbers and the sequences of internal repeats. Two other polymorphic sites are located in the external transcribed spacer (ETS) region. The reliability of various sites as indicators of overall spacer sequence divergence differed from one case to another. Variety-specific probes were devised and used to screen 120 strains for the presence of recombinant rDNA spacers. Three strains gave ambiguous results, but these did not constitute evidence that inter-varietal recombination has taken place in nature. The hypothesis that the global movement of Clavispora opuntiae has been influenced by the worldwide biological control of prickly pear with Cactoblastis cactorum, a moth of Argentinian origin, has received additional support from the demonstration that Argentinian strains have rDNAs similar to those found where the moth has been introduced. A dramatic founder effect was identified in a yeast population collected in cacti (Maui, Hawaii) in a site where the moth had been recently introduced.

Within- and between-individual length heterogeneity of the rDNA-IGS in Miscanthus sinensis var. glaber (Poaceae): phylogenetic analyses

The variability in the intergenic spacer (IGS) region between 17S and 25S rRNA genes of ribosomal DNA (rDNA) gene family was surveyed in Miscanthus sinensis var. glaber. Length heterogeneity, with sizes from 1782 to 2212 base pairs, of the IGS resulted from the variation of copy numbers of the A and B subrepeats. These repeated elements were located upstream of the presumptive polymeraseII promoter, which was the region corresponding to the nontranscribed spacer (NTS). Length heterogeneity was detected both within and between individuals of Miscanthus sinensis var. glaber. Neighbor-joining analyses of repetitive A elements indicated that both unequal crossing-over and preferential conversion may have affected the hot-spot regions of the IGS in concert. Within-individual polymorphism and the reconstructed phylogeny suggested that interspecific hybridization has also contributed to length heterogeneity.

The nuclear ribosomal DNA intergenic spacers of wild and cultivated soybean have low variation and cryptic subrepeats

The intergenic ribosomal DNA spacers (IGSs) from cultivated soybean (Glycine max) and wild soybean (Glycine soja) were sequenced and compared with six other legumes. These IGS sequences were 1821 bp in length in G. soja and G. max cultivars Arksoy, Ransom, and Tokyo, and 1823 bp long in the G. max cultivar Columbus. These represent the smallest published plant IGS sequences to date. Two clones from each of the above five cultivars were sequenced and only 22 sites (1.2%) were polymorphic, thereby supporting previous work that showed low genetic variation in cultivated soybean. The amount of variation observed between different clones derived from the same individual was equal to the amount seen between different cultivars. The soybean IGS sequence was aligned with six other published legume sequences and two homologous regions were identified. The first spans positions 706-1017 in the soybean IGS sequence and ends at a putative promoter site that appears conserved among all legumes. The second is located within the 5' external transcribed spacer, spans positions 1251-1823 in soybean, and includes sequences first identified as subrepeats IV-1 and IV-2 in Vicia angustifolia. Sequences homologous to these two subrepeats were identified among all legume species examined and are here designated "cryptic subrepeats" (CS-1, CS-2) given the range in similarity value (79-96% for CS-1 and 60-95% for CS-2). Comparisons of CS-1 and CS-2 sequences within individual species show that divergence (substitutional mutations, insertions, and deletions) is sufficiently high to obscure recognition of the repeat nature of these sequences by routine dot plot analytical methods. The lack of subrepeats in the 5' half of the soybean IGSs raises questions regarding the role they play in transcription termination or enhancement.Key words: Glycine, Fabaceae, ribosomal DNA, promoter.

Genomic organization of ribosomal RNA genes inBromus(Poaceae)

Restriction site maps of the rDNA genes of nine Bromus species are described. The rDNA repeat units ranged from 8.2 to 11.1 kbp in length. Intraspecific length variation was observed in the BamHI digestions in three of the nine species. Restriction site variation was observed mainly in the intergenic spacer (IGS) but was also detected in the coding region. A unique KpnI site was present in the IGS of Bromus tectorum and Bromus sericeus (subgenus Stenobromus); in addition, B. sericeus contained an extra EcoRI site. An additional DraI site was observed in the IGS of Bromus trinii (subgenus Neobromus). A BstEII site in the IGS, common to seven of the species, was absent in B. tectorum and B. sericeus. In the coding region, a 2.1-kbp BstEII fragment was present in four subgenera represented by Bromus inermis and Bromus erectus (subgenus Festucaria), Bromus marginatus and Bromus carinatus (subgenus Ceratochloa), B. tectorum and B. sericeus (subgenus Stenobromus), and B. trinii (subgenus Neobromus); a similar fragment of only 1.1 kbp was present in Bromus mollis and Bromus arvensis (subgenus Bromus). An additional BamHI site was present in the coding region of B. erectus. Ribosomal DNA data suggested that B. mollis and B. arvensis (subgenus Bromus) are genetically isolated from the other subgenera, which showed a derived relationship. Restriction site mapping of the rDNA genes could provide useful molecular data for species identification and population and evolutionary studies in Bromus. Key words : Bromus, ribosomal DNA, restriction maps, evolutionary relationships.

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.

Chromosomal homogeneity of Drosophila ribosomal DNA arrays suggests intrachromosomal exchanges drive concerted evolution

BACKGROUND

The individual copies of tandemly repeated genes, such as ribosomal DNA (rDNA), evolve coordinately within a species. This phenomenon has been called concerted evolution, and is thought to be caused by sequence-homogenizing mechanisms, such as gene conversion or unequal crossing-over between individual copies of the gene family. As these processes would act between the arrays on homologous and non-homologous chromosomes, the whole family of repeats would be expected to undergo homogenization in a given interbreeding population.

RESULTS

In order to study the homogenization process, we have examined polymorphisms within the internal transcribed spacer (ITS) of the rDNA in populations of Drosophila melanogaster at the sequence level, by DNA sequencing and temperature-gradient gel electrophoresis. Among 84 ITS clones sequenced from five different wild-type strains, we found three polymorphic sites that are apparently in the process of homogenization. However, these three sites, as well as combinations of them, occurred at different frequencies in the different strains. Moreover, temperature-gradient gel electrophoresis analysis of an ITS fragment including these three sites shows that single chromosomes from locally interbreeding populations can harbor rDNA arrays that are largely homogenized for different sequence variants.

CONCLUSIONS

The presence of chromosomal arrays that are homogeneous for different variants in interbreeding populations of Drosophila melanogaster indicates that there is little recombination between the chromosomes while new mutations are being homogenized along the individual arrays. The most likely explanation for this finding is that intrachromosomal recombination events occur at much higher rates than recombination between homologous chromosomes. Thus, the first step of the homogenization process would occur mainly within chromosomal lines. Such behavior of tandem repeat arrays suggests a simple explanation of how selection can act on a multigene family, namely by acting on whole chromosomally confined repeat arrays rather than on individual repeat units.

Restriction site and length polymorphism of the rDNA unit in the cultivated basidiomycetePleurotus cornucopiae

In the ribosomal DNA unit ofPleurotus cornucopiae, the rDNA coding regions are in the order 5', 5S-18S-5.8S-25S, 3', with the 5' location of the 5S gene differing from its 3' location found in other basidiomycetes. The most discriminating probe used to study the rDNA polymorphism consisted of a fragment that included the 5S, 18S and part of the 5.8S and 25S genes flanking three intergenic sequences. A high degree of rDNA polymorphism was observed in the sevenP. cornucopiae dikaryons studied. For the first time within a basidiomycete species, the restrictions maps distinguished two types of rDNA units (I and II). In each rDNA type, length variations in the external intergenic sequence IGS 1 located between the 25S and 5S genes allowed characterization of two different rDNA units in type I and four rDNA units in type II. This suggested that theP. cornucopiae rDNA units were derived from two kinds of ancestors (type I and II) by insertion or deletion events (100-700 bp) in the IGS 1. In four dikaryotic strains, two rDNA units of the same type (I or II) differing only by the IGS 1 length, were found in a similar number of copies, and presented a meiotic segregation in homokaryotic progeny. In one progeny, some homokaryotic strains possessed two different rDNA units: one with a high copy number and another with a lower one, showing that two different rDNA units could coexist in a single nucleus.

Linkage among isozyme, RFLP and RAPD markers in Vicia faba

Segregating allozyme and DNA polymorphisms were used to construct a preliminary linkage map for faba bean. Two F2 populations were analyzed, the most informative of which was segregating for 66 markers. Eleven independently assorting linkage groups were identified in this population. One of the groups contained the 45s ribosomal array and could be assigned to the large metacentric chromosome I on which the nucleolar organizer region is located. This linkage group also contained two isozyme loci, Est and Tpi-p, suggesting that it may share some homology with chromosome 4 of garden pea on which three similar markers are syntenic. Additional aspects of the map and the extent of coverage of the total nuclear genome are discussed.

Length heterogeneity in ITS 2 and the methylation status of CCGG and GCGC sites in the rRNA genes of the genus Peronosclerospora

The polymerase chain reaction (PCR) was used with primers complementary to conserved flanking sequences to amplify the internal transcribed spacer 2 (ITS 2) of the rDNA repeat units of five Peronoscleropora isolates, one each of P. sorghi, P. maydis, P. sacchari and two of P. zeae. In contrast to the situation found in most-fungi that have been examined, length heterogeneity was evident in each sample. The rDNA composition of the amplified bands was confirmed by Southern hybridizations using an ITS 2 amplified from P. sorghi and cloned rDNA from Neurospora crassa as probes. Length heterogeneity was also detected in genomic DNA digests using the same probes. In addition to one dominant fragment for each isolate, there were several less frequent fragments of different sizes, and the isolate(s) for each species had a unique banding pattern for ITS 2. The absence of 5-methylcytosine residues in CCGG and GCGC sequences in the ribosomal genes of these four Peronosclerospora species was demonstrated by the production of identical banding patterns with ribosomal DNA probes following digestion of genomic DNA with MspI and HpaII, and by complete digestion with CfoI.

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.

Variability and inheritance of histone genes H3 and H4 in Vicia faba

We have compared copy numbers and blothybridization patterns of histone genes (H3 plus H4) between and within individuals of broad bean (Vicia faba). Copy number differences among individuals in the population of 200 individuals were as great as 27 fold, and as much as 3.2 fold among separate leaves of the same plant. Among F2 progeny from genetic crosses, up to a 5.4-fold range was seen (mean=3.5 fold), and among F1 progeny of self-pollinated plants, up to a 5.9-fold range was observed (mean=2.3 fold). Histone gene blot-hybridization patterns for EcoRI and HindIII were also variable among individuals and indicated that the genes are probably clustered in only a few chromosomal loci. The degree of variation in histone gene copy number per haploid genome (2-55 copies, or 27 fold) was similar to that found previously for ribosomal RNA genes (230-22000, or 95 fold) of V. faba. However, the two gene families change independently, since individuals with a high or low copy number for one gene can have either a high or low copy number for the other. The mechanisms(s) for rapid gene copy number change may be similar for these gene families.

Use of the polymerase chain reaction to detect spacer size heterogeneity in plant 5S-rRNA gene clusters and to locate such clusters in wheat (Triticum aestivum L.)

We have used the polymerase chain reaction to analyse variation in the size of individual 5S-ribosomal gene spacer sequences. This reaction can be used to demonstrate inter- and intraspecific variation in spacer size, and combined with DNA sequencing it may thus be a valuable taxonomic tool. Two sets of nested polymerase chain reaction primers were designed to amplify the nontranscribed spacer DNA between repeated 5S-rRNA genes. These "universal" primers were used to generate fragments from the genomic DNA from several unrelated monocotyledonous plants. Ribosomal RNA spacer sequences generated in these experiments could also be used to locate 5S-rRNA gene clusters on specific chromosomes in hexaploid wheat (Triticum aestivum). Three distinct spacer sizes were observed after amplification. These were assigned locations on chromosomes by analysing amplification products of genomic DNA from nullisomic/tetrasomic and ditelosomic wheat stocks. "Large" 508-bp 5S repeats are located on the short arm of chromosome 5B and "short" 416-bp and 425-bp repeat unit variants are located on the short arms of chromosomes 1B and 1D, respectively. No other loci were detected. The spacer fragments were cloned, sequenced, and shown to be homologous to wheat 5S-rRNA spacers previously identified. Spacers of uniform size but with some sequence heterogeneity were shown to be located at each locus.

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.

Variation of ribosomal gene spacer length among wild and cultivated banana

The diversity of rDNA spacer length (IGS) of 107 wild and cultivated clones of banana belonging to different genetic groups, was studied using a sulphonated wheat rDNA probe. The length of the rDNA unit was between 10 and 12.6 kb and was highly variable. Fifteen different types of IGS could be observed. IGS diversity within the acuminata complex was greater among the diploid cultivars than among the triploid cultivars. Variation was also found among BB genotypes and confirms the diversity of this species. As opposed to previous studies, based on enzymatic or poly-phenolic markers, there was no obvious relation between the rDNA structure and the classification into genetic groups. More particularly, the IGS variations did not differentiate between the A and B genomes. This analysis, however, indicates a relationship between the geographical origin and the IGS structure of Thai and Indonesian clones.

Structure and chromosomal localization of DNA sequences related to ribosomal subrepeats in Vicia faba

Subrepeating sequences of 325 bp found in the ribosomal intergenic spacer (IGS) of Vicia faba and responsible for variations in the length of the polycistronic units for rRNA were isolated and used as probes for in situ hybridization. Hybridization occurs at many regions of the metaphase chromosomes besides those bearing rRNA genes, namely chromosome ends and all the heterochromatic regions revealed by enhanced fluorescence after quinacrine staining. The DNA homologous to the 325 bp repeats that does not reside in the IGS was isolated, cloned and sequenced. It is composed of tandemly arranged 336 bp elements, each comprising two highly related 168 bp sequences. This structure is very similar to that of the IGS repeats and ca. 75% nucleotide sequence identity can be observed between these and the 168 bp doublets. The most obvious difference lies in the deletion, in the former, of a 14 bp segment from one of the two related sequences. It is hypothesized that the IGS repeats are derived from the 336 bp elements and have been transposed to ribosomal cistrons from other genome fractions. The possible relations between these sequences and others with similar structural features found in other species are discussed.

Variation in the ribosomal DNA intergenic spacer of a maize population mass-selected for high grain yield

Variation in the intergenic spacer of ribosomal DNA (rDNA) was detected among individual plants of the open-pollinated maize variety 'Hays Golden' and populations derived from this variety. rDNA intergenic spacer-length variants were detected at approximately 200 bp intervals, consistent with the number of 200 bp subrepeats as the basis for this variation. Inheritance data revealed that more than one spacer-length class may be present on an individual chromosome. Fourteen different predominant rDNA intergenic spacer hybridization fragment patterns were detected. C-29, a population developed by 29 cycles of mass-selecting Hay Golden for high grain yield, exhibited a significant change in rDNA intergenic spacer hybridization fragment pattern composition in comparison to Hays Golden. This change included a reduction in frequency of the shortest predominant space-length variant (3.4 kb) and an increase in a 5.2 -kb hybridization fragment. I-31, a population developed through thermal neutron irradiation of Hays Golden and 31 generations of mass selection for high grain yield, did not exhibit a significant change in overall rDNA intergenic spacer composition. I-31 did exhibit an increase in frequency of the 5.2-kb hybridization fragment and a significant change in two specific hybridization fragment patterns that had also changed in C-29. These data, particularly for the C-29 population, suggest that rDNA intergenic spacer-length variants and/or associated loci were influenced by selection.

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.

Termination of transcription of ribosomal RNA genes of mung bean occurs within a 175 bp repetitive element of the spacer region

In mung bean (Vigna radiata, formerly Phaseolus aureus) one length heterogeneity in the intergenic spacer (IGS) of the ribosomal DNA (rDNA) is due to a variable number of 175-bp subrepeats. This spacer region downstream of the 25S rRNA coding region was characterized by sequencing the 2.4 kb EcoRI/HindIII fragment of a 10.5 kb mung bean rDNA repeat. Within the 175-bp repetitive elements a sequence was detected showing strong similarity to the T2/T3-box (GACTTGC) found in Xenopus rDNA and involved in termination and enhancing transcription. In mung bean this sequence partly forms the stem of a possible stem-loop structure at the 3'end of each subrepeat. Nuclease mapping of transcription termination sites (TTS) results in two signals, 65 bp and 315 bp downstream of the 3'end of the 25S rRNA coding region. The longer transcript terminates 20 bp downstream of the stem-loop structure at the end of the first 175-bp subrepeat. A spacer model is proposed which allows "readthrough enhancement". No cross-hybridization was observed between the 180-bp subrepeats in pea (Pisum sativum) rDNA and the mung bean 175-bp subrepeat.

Genomic organization of the ribosomal DNA of sorghum and its close relatives

The structure and organization of the ribosomal DNA (rDNA) of sorghum (Sorghum bicolor) and several closely related grasses were determined by gel blot hybridization to cloned maize rDNA. Monocots of the genus Sorghum (sorghum, shattercane, Sudangrass, and Johnsongrass) and the genus Saccharum (sugarcane species) were observed to organize their rDNA as direct tandem repeats of several thousand rDNA monomer units. For the eight restriction enzymes and 14 cleavage sites examined, no variations were seen within all of the S. bicolor races and other Sorghum species investigated. Sorghum, maize, and sugarcane were observed to have very similar rDNA monomer sizes and restriction maps, befitting their close common ancestry. The restriction site variability seen between these three genera demonstrated that sorghum and sugarcane are more closely related to each other than either is to maize. Variation in rDNA monomer lengths were observed frequently within the Sorghum genus. These size variations were localized to the intergenic spacer region of the rDNA monomer. Unlike many maize inbreds, all inbred Sorghum diploids were found to contain only one rDNA monomer size in an individual plant. These results are discussed in light of the comparative timing, rates, and modes of evolutionary events in Sorghum and other grasses. Spacer size variation was found to provide a highly sensitive assay for the genetic contribution of different S. bicolor races and other Sorghum species to a Sorghum population.

Structure and variability of nuclear ribosomal genes in the genus Helianthus

The restriction map of the rDNA unit of Helianthus annuus was constructed using EcoRI, BamHI, HindIII, KpnI and SacI restriction enzymes. Variations in this map among 61 ecotypes representing 39 species of the genus Helianthus were analyzed. The sizes of the rDNA unit ranged from 9.8 to 11.0 kbp, due to a length-repeat heterogeneity of the external non-transcribed spacer by increments of 200 base pair segments. Lengthrepeat heterogeneity and restriction polymorphism were found to be characteristic of populations or species of Helianthus. Restriction patterns and thermal melting with probes of a cloned H. annuus ENTS segment allowed us to differentiate species from each other. However, most lines of the cultivated sunflower were found to be identical on the basis of the physical properties of their ribosomal DNA.

Complex structure of the ribosomal DNA spacer of Cucumis sativus (cucumber)

The nuclear 18 S, 5.8 S and 25 S ribosomal RNA genes (rDNA) of Cucumis sativus (cucumber) occur in at least four different repeat types of 10.2, 10.5, 11.5, and 12.5 kb in length. The intergenic spacer of these repeats has been cloned and characterized with respect to sequence organization. The spacer structure is very unusual compared to those of other eukaryotes. Duplicated regions of 197 bp and 311 bp containing part of the 3'end of the 25 S rRNA coding region and approximately 470 bp of 25 S rRNA flanking sequences occur in the intergenic spacer. The data from sequence analysis suggest that these duplications originate from recombination events in which DNA sequences of the original rDNA spacer were paired with sequences of the 25 S rRNA coding region. The duplicated 3'ends of the 25 S rRNA are separated from each other mostly by a tandemly repeated 30 bp element showing a high GC-content of 87.5%. In addition, another tandemly repeated sequence of 90 bp was found downstream of the 3'flanking sequences of the 25 S rRNA coding region. These results suggest that rRNA coding sequences can be involved in the generation of rDNA spacer sequences by unequal crossing over.

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.