A very large repeating unit of mouse DNA containing the 18S, 28S and 5.8S rRNA genes

The organization of the 18S, 28S and 5.8S rRNA genes in the mouse has been elucidated by mapping with restriction endonucleases Eco RI, Hind III and Bam HI. Ribosomal DNA fragments were detected in electrophoretically fractionated digests of total nuclear DNA by in situ hybridization with radioiodinated rRNAs or with complementary RNA synthesized directly on rRNA templates. A map of the rDNA which includes 13 restriction sites was constructed from the sizes of rDNA fragments and their labeling by different probes The map indicates that the rRNA genes lie within remarkably large units of reiterated DNA, at least 44,000 base pairs long. At least two, and possibly four, classes of repeating unit can be distinguished, the heterogeneity probably residing in the very large nontranscribed spacer region. The 5.8S rRNA gene lies in the transcribed region between the 18S and 28S genes.     

Physical and genetic mapping of cloned ribosomal DNA from Toxoplasma gondii: primary and secondary structure of the 5S gene.

The ribosomal DNA (rDNA encoding rRNA) of the obligately intracellular protozoan parasite, Toxoplasma gondii, was identified, cloned, physically mapped, its copy number determined, and the 5S gene sequenced. Using total RNA as a probe, a collection of recombinant lambda phages containing copies of rDNA were isolated from a lambda 2001 tachyzoite genomic library. Northern gel hybridization confirmed specific homology of the 7.5-kb rDNA unit, subcloned into pTZ18R, to T. gondii rRNA. The mapped rDNA found in pTOX1 contained small ribosomal subunit (SS; 18S)- and large ribosomal subunit (LS; 26S)-encoding genes localized using intragenic heterologous probes from the conserved sequences of the SS (18S) and LS (28S) Xenopus laevis genes. the physical mapping data, together with partial digestion experiments and Southern gel hybridization, confirmed a 7.5-kb rDNA unit arranged in a simple head-to-tail fashion that is tandemly repeated. We estimated the rDNA repeat copy number in T. gondii to be 110 copies per haploid tachyzoite genome. Parts of the SS gene and the complete 5S gene were sequenced. The 5S gene was found to be within the rDNA locus, a rare occurrence found only in some fungi and protozoa. Secondary-structure analysis revealed an organization remarkably similar to the 5S RNA of eukaryotes.     

Repeated reunions and splits feature the highly dynamic evolution of 5S and 35S ribosomal RNA genes (rDNA) in the Asteraceae family

Background  

In flowering plants and animals the most common ribosomal RNA genes (rDNA) organisation is that in which 35S (encoding 18S-5.8S-26S rRNA) and 5S genes are physically separated occupying different chromosomal loci. However, recent observations established that both genes have been unified to a single 35S-5S unit in the genus Artemisia (Asteraceae), a genomic arrangement typical of primitive eukaryotes such as yeast, among others. Here we aim to reveal the origin, distribution and mechanisms leading to the linked organisation of rDNA in the Asteraceae by analysing unit structure (PCR, Southern blot, sequencing), gene copy number (quantitative PCR) and chromosomal position (FISH) of 5S and 35S rRNA genes in ~200 species representing the family diversity and other closely related groups.     

5S rRNA Gene Arrangements in Protists: A Case of Nonadaptive Evolution

Given their high copy number and high level of expression, one might expect that both the sequence and organization of eukaryotic ribosomal RNA genes would be conserved during evolution. Although the organization of 18S, 5.8S and 28S ribosomal RNA genes is indeed relatively well conserved, that of 5S rRNA genes is much more variable. Here, we review the different types of 5S rRNA gene arrangements which have been observed in protists. This includes linkages to the other ribosomal RNA genes as well as linkages to ubiquitin, splice-leader, snRNA and tRNA genes. Mapping these linkages to independently derived phylogenies shows that these diverse linkages have repeatedly been gained and lost during evolution. This argues against such linkages being the primitive condition not only in protists but also in other eukaryote species. Because the only characteristic the diverse genes with which 5S rRNA genes are found linked with is that they are tandemly repeated, these arrangements are unlikely to provide any selective advantage. Rather, the observed high variability in 5S rRNA genes arrangements is likely the result of the fact that 5S rRNA genes contain internal promoters, that these genes are often transposed by diverse recombination mechanisms and that these new gene arrangements are rapidly homogenized by unequal crossingovers and/or by gene conversions events in species with short generation times and frequent founder events.     

Berkleasmium crunisia sp. nov. and its phylogenetic affinities to the Pleosporales based on 18S and 28S rDNA sequence analyses

Berkleasmium crunisia sp. nov. is described from a decaying rachis of Calamus sp. (Arecaceae) from Khuan Ka Long, Satun Province, Thailand. This Berkleasmium species differs morphologically from other species in possessing subtending cells and larger conidia. The phylogenetic relationship of the genus Berkleasmium among sexual ascomycetes also was examined. Sequence analyses from 18S, 28S and ITS-5.8S rDNA were analyzed phylogenetically under maximum parsimony, Bayesian and neighbor joining criteria. Phylogenies revealed that Berkleasmium is not monophyletic. Berkleasmium micronesicum and B. nigroapicale are related to Westerdykella cylindrica and Sporormia australis, which are members of the family Sporormiaceae (Pleosporales). Other species, including our new taxon, appear to share phylogenetic affinities with other anamorphic fungi, whose classification within the Pleosporales is still obscure. Analyses of 18S, 28S, ITS (+5.8S) rDNA and combined (18S+28S) gene sequences fail to give sufficient phylogenetic resolution within the Pleosporales.     

Physical mapping of rRNA genes by fluorescent in-situ hybridization and structural analysis of 5S rRNA genes and intergenic spacer sequences in sugar beet (Beta vulgaris)

A digoxigenin-labelled 5S rDNA probe (pTa-794) and a rhodamine-labelled 18S-5.8S-25S rDNA probe (pTa71) were used for double-target in-situ hybridization to root-tip metaphase, prophase and interphase chromosomes of cultivated beet,Beta vulgaris L. After in-situ hybridization with the 18S-5.8S-25S rDNA probe, one major pair of sites was detected which corresponded to the secondary constriction at the end of the short arm of chromosome 1. The two rDNA chromosomes were often associated and the loci only contracted in late metaphase. In the majority of the metaphase plates analyzed, we found a single additional minor hybridization site with pTa71. One pair of 5S rRNA gene clusters was localized near the centromere on the short arm of one of the three largest chromosomes which does not carry the 18S-5.8S-25S genes. Because of the difficulties in distinguishing the very similarly-sizedB. vulgaris chromosomes in metaphase preparations, the 5S and the 18S-5.8S-25S rRNA genes can be used as markers for chromosome identification. TwoXbaI fragments (pXV1 and pXV2), comprising the 5S ribosomal RNA gene and the adjacent intergenic spacer, were isolated. The two 5S rDNA repeats were 349 bp and 351 bp long, showing considerable sequence variation in the intergenic spacer. The use of fluorescent in-situ hybridization, complemented by molecular data, for gene mapping and for integrating genetic and physical maps of beet species is discussed.     

Assessment of Hansenula polymorpha and Arxula adeninivorans-derived rDNA-targeting elements for the design of Arxula adeninivorans expression vectors

Different targeting sequences derived from the Arxula adeninivorans and Hansenula polymorpha rDNA clusters were tested in A. adeninivorans integration/expression vectors. For element identification, the rDNA unit of A. adeninivorans (accession number ) was first isolated and characterized in addition to the known H. polymorpha unit. The rDNA is a cluster of some forty 7653-bp units without the 5S rDNA gene. The selected elements were integrated into a set of A. adeninivorans expression/integration vectors harbouring a TEF1 promoter - amyA ORF - PHO5 terminator sequence as reporter gene. No differences in mitotic stability, copy number and transformation frequency were observed. All transformants harboured a single copy integrated into the rDNA by a homologous recombination. In contrast, the choice of the rDNA targeting sequence was found to be of impact on productivity. Use of ETS-18S-5.8S fragments from both organisms resulted in a more than 50% increase in comparison to the use of other elements, independent of the orientation within the vector.     

Molecular Cytogenetics ofMusaSpecies, Cultivars and Hybrids: Location of 18S-5.8S-25S and 5S rDNA and Telomere-like Sequences

The physical sites of 18S-5.8S-25S and 5S rRNA genes and telomericsequences in theMusaL. genome were localized by fluorescentinsituhybridization on mitotic chromosomes of selected lines.A single major intercalary site of the 18S-5.8S-25S rDNA wasobserved on the short arm of the nucleolar organizing chromosomein each genome. AA and BB genome diploids had a single pairof sites, triploids had three sites while a tetraploid hybridhad four sites. The probe is useful for quick determinationof ploidy, even using interphase nuclei from slowly growingtissue culture material. Variation in the intensity of signalswas observed among heterogeneousMusalines indicating variationin the number of copies of the 18S-5.8S-25S rRNA genes. Eightsubterminal sites of 5S rDNA were observed in Calcutta 4 (AA)while Butohan 2 (BB) had six sites; some were weaker in bothgenotypes. Triploid lines showed six to nine major sites of5S rDNA of widely varying intensity and near the limit of detection.The diploid hybrids had five to nine sites of 5S rDNA whilethe tetraploid hybrid had 11 sites. The telomeric sequence wasdetected as pairs of dots at the ends of all the chromosomesanalysed but no intercalary sequences were seen. The molecularcytogenetic studies ofMusausing repetitive and single copy DNAprobes should yield insight into the genome and its evolutionand provide data forMusabreeders, as well as generating geneticmarkers inMusa.Copyright 1998 Annals of Botany Company Genome evolution, nucleolar organizing regions, telomeres,in situhybridization, genetic markers, banana, plantain.     

Phylogenetic position of Creptotrema funduli in the Allocreadiidae based on partial 28S rDNA sequences

The infrequently reported allocreadiid digenean Creptotrema funduli Mueller, 1934 is documented from the blackstripe topminnow, Fundulus notatus (Cyprinodontiformes: Fundulidae), in the headwaters of the Biloxi River, Harrison County, Mississippi. Specimens from Mississippi were compared with the type material from Fundulus diaphanus menona from Oneida Lake, New York, and no substantial difference was found. A fragment of ribosomal DNA, comprising a short portion of the 3' end of 18S nuclear rDNA gene, internal transcribed spacer (ITS) genes (including ITS1, 5.8S, and ITS2), and the 5' end of the 28S gene including variable domains D1-D3 was sequenced for the species. A portion of the 28S rDNA gene from C. funduli, plus similar fragments from 8 other allocreadiids and the callodistomatid Prosthenhystera sp., were aligned and subjected to maximum likelihood and Bayesian inference analyses. Resulting phylogenetic trees were derived from the analyses and used to estimate the relationship of Creptotrema Travassos, Artigas, and Pereira, 1928 with other allocreadiids. Creptotrema was found to be closely related to Megalogonia Surber, 1928 and 3 Neotropical genera, i.e., Wallinia Pearse, 1920, Creptotrematina Yamaguti, 1954, and Auriculostoma Scholz, Aguirre-Macedo, and Choudhury, 2004. No molecular data were available for species in Creptotrema prior to this study, so the ITS1, 5.8S, and ITS2 genes have been made available for comparative studies involving neotropical species in the genus.     

Cloning of the 18S rDNA gene, an internal transcribed spacer, and the 5' region of the 28S rDNA gene of Cope's gray treefrog, Hyla chrysoscelis

The location of rDNA genes on the chromosomes of most species is identical within that species, usually occurring on the same chromosome or chromosomes. This is not the case in Cope's gray treefrog, Hyla chrysoscelis, where the rDNA genes are polymorphic for chromosome location. The occasions leading to this polymorphism have yet to be determined. The first step in understanding the nature of the polymorphism is the characterization of the ribosomal gene array. Here we describe the cloning, sequencing, and confirmation, by fluorescence in situ hybridization, of the 18S rDNA gene, a region which includes the end of the 18S rDNA gene, an internal transcribed spacer, and a portion of the 5' end of the 28S rDNA gene in H. chrysoscelis.     

Phylogenetic and genomic relationships in Setaria italica and its close relatives based on the molecular diversity and chromosomal organization of 5S and 18S-5.8S-25S rDNA genes

We have analyzed the phylogenetic and genomic relationships in the genus Setaria Beauv. including diploid and tetraploid species, by means of the molecular diversity of the 5S rDNA spacer and chromosomal organization of the 5S and 18S-5.8S-25S rDNA genes. PCR amplification of the 5S rDNA sequences gave specific patterns. All the species studied here share a common band of about 340 bp. An additional band of an approximately 300-bp repeat unit was found for Setaria verticillata and the Chinese accessions of Setaria italica and Setaria viridis. An additional band of 450 bp was found in the sole species Setaria faberii. Fluorescent in situ hybridization was used for physical mapping of the 5S and 18S-5.8S-25S rDNA genes and showed that they are localized at two separate loci with no polymorphism of chromosome location among species. Two chromosome pairs carrying the 5S and 18S-5.8S-25S rDNA clusters can now be unambiguously identified using FISH. Phylogenetic trees based on the variation of the amplified 5S rDNA sequences showed a clear separation into four groups. The clustering was dependent on the genomic composition (genome A versus genome B) and confirmed the closest relationship of S. italica and S. viridis accessions from the same geographical region. Our results confirm previous hypotheses on the domestication centers of S. italica. They also show the wide difference between the A and B genomes, and even clarify the taxonomic position of S. verticillata. Received: 28 August 2000 / Accepted: 27 January 2001     

Distribution of 5S ribosomal RNA genes in somatic and germ cells of the house cricket,Acheta domesticus

In the house cricket,Acheta domesticus, the 110 genes per haploid genome encoding 18S and 28S rRNA are contained within rDNA repeats which are amplified during oogenesis. The 5S rRNA coding sequences of this cricket are found in two sizes of 5S DNA repeating units (measuring 2.1 and 3.0 kb). The 3.0 kb repeats account for more than 90% of the totalAcheta 5S DNA. We have determined the number of cricket 5S rRNA genes by RNA-DNA hybridization analysis: 310 5S DNA repeats/haploid genome clearly approximates the number of 18S and 28S rRNA genes. Because of the relatively low copy number of 5S rRNA genes the possibility of 5S DNA amplification in oocytes ofA. domesticus was also examined. Although amplification of rDNA is readily detectable, amplification of 5S DNA is not observed in oocytes ofA. domesticus. Unlike the genes coding for 18S and 28S rRNA which are localized at a single chromosomal site in the genome ofA. domesticus, the 5S rRNA genes occupy numerous sites distributed along the length of most chromosomes.     

Chromosomal Mapping and Molecular Characterization of Ribosomal RNA Genes in Lebias fasciata (Teleostei, Cyprinodontidae)

Chromosome location of major (18S, 5.8S and 28S) and 5S ribosomal RNA genes (rDNAs) was examined in Lebias fasciata collected from different Italian blackish-waters, using silver (Ag)- and chromomycin A3 (CMA3)-staining and/or fluorescence in situ hybridization (FISH). Both 18S and 5S rDNA probes for FISH were obtained with polymerase chain reaction-directed cloning from genomic DNA of the examined species. Nucleolar organizer regions (NORs) containing the major rDNAs showed intraspecific polymorphism in number as detected by Ag-and CMA3-staining and FISH with the 18S rDNA probe. On the other hand, 5S rDNA loci constantly occurred on one chromosome pair and co-localized with a pair of the major rDNA loci as evidenced by two-color FISH using the 5S and 18S rDNA probes. Sequential CMA3- and Ag-NOR staining and FISH revealed apparent inactivation of some NORs. The cloned 5S rDNA was found to contain some TATA-like sequences that might play an important role in the regulation of gene expression.     

Molecular characterization of ribosomal gene variation within and among NORs segregating in specialized populations of chicken.

The molecular organization of the 18S, 5.8S, and 28S ribosomal RNA gene repeat units, located at the single nucleolus organizer region (NOR) locus in the chicken, was investigated in genetically distinct populations of research and commercial chickens. Substantial gene repeat variation within and among NORs was documented. Intact ribosomal gene repeat size ranged from 11 kb to over 50 kb. Unique combinations of ribosomal genes, of different size, were specific to particular populations. It was determined that the basis for the ribosomal gene repeat size variation was intergenic spacer (IGS) length heterogeneity. Interestingly, in different populations, the location of the variation that contributes to length heterogeneity was specific to particular IGS subregions. In addition to IGS variation, an inbred line of Red Jungle Fowl exhibited coding region variation. Ribosomal gene copy number variation was also studied, and line averages ranged from 279 to 368. Average rDNA array size (a function of copy number and gene repeat length) was calculated for each of the populations and found to vary over a range of two megabases, from 5 to 7 Mb.     

Completion of the sequence of the nuclear ribosomal DNA subunit of Simulium sanctipauli,with descriptions of the 18S, 28S genes and the IGS

We describe the IGS-ETS, 18S and 28S ribosomal gene sequences of Simulium sanctipauli Vajime & Dunbar, a member of the S. damnosum Theobald (Diptera: Simuliidae) complex of blackflies (Diptera: Simuliidae). These regions, together with the ITS-1, ITS-2 and 5.8S rDNA presented elsewhere (accession number U36206), constitute the composite sequence of the entire rDNA unit, making S. sanctipauli the second dipteran species of medical importance for which the entire rDNA has been sequenced. Despite the lack of sequence identity, the IGS of S. sanctipauli showed some structural similarities to other Diptera, i.e. the mosquito Aedes albopictus Skuse (Culicidae), the fruitfly Drosophila melanogaster Meigen (Drosophilidae) and the tsetse Glossina (Glossinidae). Two blocks of tandemly repeated subunits were present in the IGS of S. sanctipauli and, unlike other species of Diptera, they contained no duplications of promoter-like sequences. However, two promoter-like sequences were identified in the unique DNA stretches of the IGS by their sequence similarity to the promoter of Aedes aegypti L. (Diptera: Culicidae). The observed sequence variation can be explained, as in the case of Drosophila spp., by the occurrence of slippage-like and point mutation processes, with unequal crossing-over homogenizing (to a certain extent) the region throughout the gene family and blackfly population. The 18S and 28S rDNA genes show more intraspecific variability within the expansion segments than in the core regions. This is also the case in the interspecific comparison of these genes from S. sanctipauli with those of Simulium vittatum, Ae. albopictus and D. melanogaster. This pattern is typical of many eukaryotes and likely to be the result of a more relaxed functional selection in the expansion segments than on the core regions. The A + T content of the S. sanctipauli genes is high and similar to those of other Diptera. This could be the result of a change in the mutation pressure towards AT in the Diptera lineage.     

Asexuality Associated with Marked Genomic Expansion of Tandemly Repeated rRNA and Histone Genes

How does asexual reproduction influence genome evolution? Although is it clear that genomic structural variation is common and important in natural populations, we know very little about how one of the most fundamental of eukaryotic traits—mode of genomic inheritance—influences genome structure. We address this question with the New Zealand freshwater snail Potamopyrgus antipodarum, which features multiple separately derived obligately asexual lineages that coexist and compete with otherwise similar sexual lineages. We used whole-genome sequencing reads from a diverse set of sexual and asexual individuals to analyze genomic abundance of a critically important gene family, rDNA (the genes encoding rRNAs), that is notable for dynamic and variable copy number. Our genomic survey of rDNA in P. antipodarum revealed two striking results. First, the core histone and 5S rRNA genes occur between tandem copies of the 18S–5.8S–28S gene cluster, a unique architecture for these crucial gene families. Second, asexual P. antipodarum harbor dramatically more rDNA–histone copies than sexuals, which we validated through molecular and cytogenetic analysis. The repeated expansion of this genomic region in asexual P. antipodarum lineages following distinct transitions to asexuality represents a dramatic genome structural change associated with asexual reproduction—with potential functional consequences related to the loss of sexual reproduction.