Organization of the ribosomal RNA gene cluster in Aspergillus nidulans

DNA coding for ribosomal RNA in Aspergillus nidulans was found to consist of a unit 7.8 kb in size which is tandemly repeated in the genome and codes for 5.8S, 18S and 26S rRNA. The repeat unit has been cloned, and its restriction map and the location of the individual rRNA coding sequences within the unit have been established.     

Structural dynamics of bacterial ribosomes. III. Quantitative conversion of vacant ribosome couples into an initiation complex with R17 RNA as messenger

The arrangement of the DNA sequences coding for the ribosomal 5.8 S RNA in the genome of Xenopus laevis has been studied. In Xenopus the 5.8 S cistrons, like the ribosomal 28 S and 18 S cistrons, are reiterated some 600-fold (Clarkson et al., 1973a). When banded in caesium chloride, the 5.8 S cistrons separate from somatic DNA of high molecular weight and band as a distinct satellite, indicating a clustered arrangement in the genome. The buoyant density of this satellite (1.723 g cm^?3) corresponds to that of the ribosomal DNA satellite.It has previously been shown that the ribosomal DNA sequences have been deleted from the genome of the anucleotide Xenopus mutant. Our findings, first that the anucleolate mutant does not synthesize 5.8 S RNA and second that somatic DNA from this mutant does not detectably hybridize with 5.8 S RNA, demonstrate that the 5.8 S cistronic complement has been similarly deleted. This finding supports our contention that 5.8 S sequences are clustered on chromosomal DNA and further suggests that they are located close to or within the rDNA complements in the nucleolus organizer region.Pre-hybridization to saturation with unlabelled 5.8 S RNA results in only a slight increase in the buoyant density of denatured 5.8 S coding sequences from low molecular weight DNA. Since a contiguous arrangement of the 5.8 S sequences would give rise to a much larger increase in density, it follows that, although clustered, the sequences must be intercalated within stretches of other DNA. By contrast, pre-hybridization of the somatic DNA with unlabelled 28 S or 18 S ribosomal RNAs results in large shifts in the buoyant density of the 5.8 S sequences. These shifts indicate that the 5.8 S sequences are closely linked to both 28 S and 18 S coding sequences.It is concluded that the 5.8 S cistrons are interspersed along the ribosomal DNA sense strand and that each is located together with a 28 S and an 18 S cistron in a ribosomal repeat unit. Estimates, obtained from the pre-hybridization experiments, of the separations between the 5.8 S and the 28 S and 18 S sequences, are combined in a model of the ribosomal repeat unit. In this model the 5.8 S cistron is located within the transcribed spacer which links the 28 S and 18 S coding sequences.     

Ribosomal RNA genes of Trypanosoma brucei: mapping the regions specifying the six small ribosomal RNAs

There are six small ribosomal RNAs in trypanosome ribosomes. sRNA3 and sRNA5 of Trypanosoma brucei brucei have been partially sequenced. Sequence homologies indicate that sRNA3 is 5.8S RNA and sRNA5 is 5S RNA of T. b. brucei. The regions specifying these two, and the remaining four small RNAs, have been identified within clones of rRNA genes and in the genome. Five of the small RNAs, 1, 2, 3, 4 and 6, hybridise exclusively within the major rRNA gene repeat. A map of the regions specifying these small RNAs is presented. sRNA3 (5.8S RNA) hybridises to a region corresponding to the transcribed spacer of other eukaryotes. sRNA1 hybridises to a region between sequences specifying the two large subunit RNA molecules of 2.3 kb and 1.8 kb. Sequences specifying sRNAs 2 and 4 are present near the sequence specifying sRNA1, while sRNA6 appears to be specified 3' to the sequence specifying the 1.8-kb RNA sequence. In addition regions of secondary hybridisation for small RNAs 2, 3, 4 and 6 have also been identified. Though sRNA5 (5S RNA) hybridises within the major rRNA repeat, a separate 5S RNA gene repeat with unit size of 760 bp is also present. It is 10 to 20 times more abundant than the major rRNA gene repeat.     

Isolation and characterization of rat ribosomal DNA clones

Four EcoRI fragments, which contain the transcribed portion of the rat rDNA repeat, have been isolated from a rat genome library cloned in lambda Charon 4A vector. Three of the fragments, 9.6, 6.7, and 4.5 kb, from clones lambda ChR-B4, lambda Nr-42, and lambda ChR-C4B9, contained part of the 5'-NTS, the 5'-ETS, 18S rDNA, ITS-1, 5.8S rDNA, 28S rDNA and approximately 3.5 kb of the 3'-NTS. Two EcoRI fragments, from clones lambda ChR-B4 and lambda ChR-B7E12, which coded for the 5'-NTS, the ETS, and most of the 18S rDNA, differed by 1 kb near the EcoRI site upstream of the 5' terminus of 18S rRNA. Restriction maps of the cloned DNA fragments were constructed by cleavage of the fragments with various restriction endonucleases and Southern hybridization with 18S, 5.8S, and 28S rRNA. These maps were confirmed and extended by subcloning several regions of the repeat in pBR322.     

Patterns of ribosomal gene variation in elite commercial chicken pure line populations

The nucleolus organizer region (NOR) encodes the tandemly repeated 18S, 5.8S and 28S ribosomal (r) RNA genes. The NORs of broiler and layer commercial chicken pure lines were studied to establish the type and extent of genetic variation at this important locus. The parameters studied were gene copy number, repeat size, and diversity of NOR-types. The populations were organized into three groups for analysis including brown-egg broiler (13 lines), brown-egg layer (six lines), and white-egg layer (eight lines). The ribosomal gene copy number average of the white-egg layer populations was significantly lower (329 genes) than that of the brown-egg layers (372 genes); the brown-egg broiler ribosomal gene average was intermediate (350 genes). The white-egg layer populations exhibited a ribosomal repeat unit average size of 36 kb, significantly different from the brown-egg layer and brown-egg broiler average repeat unit size of 32.5 and 33.9 kb, respectively. NOR array size was similar among the three groups (6 mb). The brown-egg broiler populations exhibited polymorphic NOR patterns, intra- and interline, whereas the white-egg layer populations were essentially monomorphic for NOR-type; brown-egg layers exhibited an intermediate level of NOR diversity. Some NOR array characteristics may be a function of breed origin as brown-egg commercial populations, both broilers and layers, have similar breed origins and exhibited similarities for predominant repeat unit size as compared with white-egg layer populations. However, the finding that brown-egg broiler lines typically exhibit a greater number of segregating NOR-types than brown-egg layer lines suggests that the selection schemes of broiler vs. layer pure line populations may also have influenced the degree of variation at this gene complex.     

Molecular and chromosomal organization of DNA sequences coding for the ribosomal RNAs in cereals

The chromosomal locations of ribosomal DNA in wheat, rye and barley have been determined by in situ hybridization using high specific activity ¹²⁵I-rRNA. The 18S-5.8S-26S rRNA gene repeat units in hexaploid wheat (cv. Chinese Spring) are on chromosomes 1B, 6B and 5D. In rye (cv. Imperial) the repeat units occur at a single site on chromosome 1R(E), while in barley (cv. Clipper) they are on both the chromosomes (6 and 7) which show secondary constrictions. In wheat and rye the major 5S RNA gene sites are close to the cytological secondary constrictions where the 18S-5.8S-26S repeating units are found, but in barley the site is on a chromosome not carrying the other rDNA sequences. — Restriction enzyme and R-loop analyses showed the 18S-5.8S-26S repeating units to be approximately 9.5 kb long in wheat, 9.0 kb in rye and barley to have two repeat lengths of 9.5 kb and 10 kb. Electron microscopic and restriction enzyme data suggest that the two barley forms may not be interpersed. Digestion with EcoR1 gave similar patterns in the three species, with a single site in the 26S gene. Bam H1 digestion detected heterogeneity in the spacer regions of the two different repeats in barley, while in rye and wheat heterogeneity was shown within the 26S coding sequence by an absence of an effective Bam H1 site in some repeat units. EcoR1 and Bam H1 restriction sites have been mapped in each species. — The repeat unit of the 5S RNA genes was approximately 0.5 kb in wheat and rye and heterogeneity was evident. The analysis of the 5S RNA genes emphasizes the homoeology between chromosomes 1B of wheat and 1R of rye since both have these genes in the same position relative to the secondary constriction. In barley we did not find a dominant monomer repeat unit for the 5S genes.     

Ribosomal RNA genes in Scots pine (Pinus sylvestris L.): Chromosomal organization and structure

The nuclear 18S, 5.8S and 25S rRNA genes exist as thousands of rDNA repeats in the Scots pine genome. The number and location of rDNA loci (nucleolus organizers, NORs) were studied by cytological methods, and a restriction map from the coding region of the Scots pine rDNA repeat was constructed using digoxigenin-labeled flax rDNA as a probe. Based on the maximum number of nucleoli and chromosomal secondary constrictions, Scots pine has at least eight NORs in its haploid genome. The size of the Scots pine rDNA repeat unit is approximately 27 kb, two- or threefold larger than the typical angiosperm rDNA unit, but similar in size to other characterized conifer rDNA repeats. The intergenic spacer region (IGS) of the rDNA repeat unit in Scots pine is longer than 20 kb, and the transcribed spacer regions surrounding the 5.8S gene (ITS1 and ITS2) span a region of 2.9 kb. Restriction analysis revealed that although the coding regions of rDNA repeats are homogeneous, heterogeneity exists in the intergenic spacer region between individuals, as well as among the rDNA repeats within individuals.     

Bryophyte 5S rDNA was inserted into 45S rDNA repeat units after the divergence from higher land plants

The 5S ribosomal RNA genes (5S rDNA) are located independently from the 45S rDNA repeats containing 18S, 5.8S and 26S ribosomal RNA genes in higher eukaryotes. Southern blot and fluorescence in situ hybridization analyses demonstrated that the 5S rDNAs are encoded in the 45S rDNA repeat unit of a liverwort, Marchantia polymorpha, in contrast to higher plants. Sequencing analyses revealed that a single-repeat unit of the M. polymorpha nuclear rDNA, which is 16103 bp in length, contained a 5S rDNA downstream of 18S, 5.8S and 26S rDNA. To our knowledge, this is the first report on co-localization of the 5S and 45S rDNAs in the rDNA repeat of land plants. Furthermore, we detected a 5S rDNA in the rDNA repeat of a moss, Funaria hygrometrica, by a homology search in a database. These findings suggest that there has been structural re-organization of the rDNAs after divergence of the bryophytes from the other plant species in the course of evolution.     

Intragenomic variation in ribosomal RNA gene of the sea urchin <Emphasis Type="Italic">Lytechinus variegatus</Emphasis>

The first series of studies on the rDNA satellite of the sea urchin, Lytechinus variegatus, based on saturation hybridization of rRNA-rDNA and renaturation kinetics, showed that repeat length of rRNA gene was of about 8 kb in which there was no provision for NTS. The EM denaturation mapping, however, revealed (1) that the gene was 75% larger (longer) than 8 kb, within which there was a NTS whose length varied in repeating units, (3) and there was a region of high GC almost in the middle of the transcribed part. The suggestion of length and sequential heterogeneity in the gene copies coming from the first denaturation mapping prompted further studies with techniques so that the conclusions of the previous results could be stated with finality. The results that emanated from further studies established that the rDNA repeat length of L. variegatuswas of about 12 kb and that the NTS ranged from 3.8 to 6.4 kb. Earlier demonstration of a moderately high-GC segment within the transcribed part was also confirmed by sequence analysis. However, the stipulations on the NTS regarding sequential and length heterogeneity, still awaits elucidation by sequence analysis.     

Cloning and characterization of the ribosomal RNA gene complex from the plant pathogen Verticillium albo-atrum

Abstract The DNA coding for the ribosomal RNA gene complex (rDNA) has been cloned from isolate 621P(PV1) of Verticillium albo-atrum which is pathogenic for hops ( Humulus lupulus ). The rDNA was mapped using a range of restriction enzymes. The functional units of the intergenic spacer (IGS), 18S, 5.8S and 25S regions were located by hybridization to specific gene probes from the rDNA complex of Aspergillus nidulans . The start points of the 18S and 5.8S regions were confirmed by partial sequencing. A genomic restriction enzyme map was found to be identical with the map of the cloned DNA. The rDNA repeat was 7.6 kb in length and this was used as an homologous probe to analyse the size of the repeat in 18 hop isolates of V. albo-atrum strains and in one isolate from alfalfa (Luc2). All of the isolates had a repeat size of 7.6 kb except for Luc2 where the rDNA complex was 8.4 kb.     

Evolution of the plastid ribosomal RNA operon in a nongreen parasitic plant: Accelerated sequence evolution,altered promoter structure,and tRNA pseudogenes

The nucleotide sequence of a 7.4 kb region containing the entire plastid ribosomal RNA operon of the nongreen parasitic plant Epifagus virginiana has been determined. Analysis of the sequence indicates that all four rRNA genes are intact and almost certainly functional. In contrast, the split genes for tRNA^Ile and tRNA^Ala present in the 16S-23S rRNA spacer region have become pseudogenes, and deletion upstream of the 16S rRNA gene has removed a tRNA^Val gene and most of the promoter region for the rRNA operon. The rate of nucleotide substitution in 16S and 23S rRNAs is several times higher in Epifagus than in tobacco, a related photosynthetic plant. Possible reasons for this, including relaxed translational constraints, are discussed.     

Construction of the physical map of the chloroplast DNA of Phaseolus vulgaris and localization of ribosomal and transfer RNA genes

Construction of a physical map of the chloroplast DNA from Phaseolus vulgaris showed that this circular molecule is segmentally organized into four regions. Unlike other chloroplast DNAs which have analogous organization, two single-copy regions that separate two inverted repeats have been demonstrated to exist in both relative orientations, giving rise to two populations of DNA molecules.Hybridization studies using individual rRNA and tRNA species revealed the location of a set of rRNA genes and at least seven tRNA genes in each inverted repeat region, a minimum of 17 tRNA genes in the large single-copy region and one tRNA gene in the small single-copy region. The tRNA genes code for 24 tRNA species corresponding to 16 amino acids. Comparison of this gene map with those of other chloroplast DNAs suggests that DNA sequence rearrangements, involving some tRNA genes, have occurred.     

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

Summary 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.     

Sequence arrangement of the rDNA of Drosophila melanogaster.

The sequence arrangement of genes coding for stable rRNA species and of the interspersed spacers on long single strands of rDNA purified from total chromosomal DNA of Drosophila melanogaster has been determined by a study of the structure of rRNA:DNA hybrids which were mounted for electron microscope observation by the gene 32-ethidium bromide technique. One repeat unit contains the following sequences in the order given. First, an 18 S gene of length 2.13 +/- 0.17 kb. Second, an internal transcribed spacer (Spl) of length 1.58 +/- 0.15 kb. A short sequence coding for the 5.8S and perhaps the 2S rRNA species is located within this spacer. Third, the 28S gene with a length of 4.36 +/- 0.23 kb. About 55% of the 28S genes are unbroken or continuous (C genes). However, about 45% of the 28S genes contain an insertion of an additional segment of DNA that is not complementary to rRNA (l genes). The insertion occurs at a reproducible point 2.99 +/- 0.26 kb from the junction with Spl. The insertions are heterogeneous in length and occur in three broad size classes: 1.42 +/- 0.47, 3.97 +/- 0.55, and 6.59 +/- 0.62 kb. Fourth, an external spacer between the 28S gene and the next 18S gene which is presumably mainly nontranscribed and which has a heterogeneous length distribution with a mean length and standard deviation of 5.67 +/- 1.92 kb. Short inverted repeat stems (100-400 nucleotide pairs) occur at the base of the insertion. It is known from other studies that I genes occur only on the X chromosome. The present study shows that the I and C genes on the X chromosomes are approximately randomly assorted. The sequence arrangement on the plasmid pDm103 containing one repeat of rDNA (Glover et al., 1975) has been determined by similar methods. The I gene on this plasmid contains an inverted repeat stem. The occurrence of inverted repeat sequences flanking the insertion supports the speculation that these sequences are translocatable elements similar to procaryotic translocons.     

Ribosomal RNA genes ofEndomyces fibuliger: isolation, sequencing and the use of the 26S rRNA gene in integrative transformation ofSaccharomyces cerevisiae for efficient expression of the α-amylase gene ofEndomyces fibuliger

Endomyces fibuliger is a dimorphic yeast which is homothallic and exists predominantly in the diploid phase with a brief haploid phase. A repeat unit of the ribosomal RNA genes, or rDNA, from E. fibuliger 8014 met has been isolated, cloned and sequenced. In this report, the sequences of the 17S, 5.8S and 26S rRNA genes are presented. Homology between the sequenced rRNA genes and those of closely-related yeast strains, particularly Saccharomyes cerevisiae and Candida albicans, was observed. As a step towards the eventual development of a transformation system for the yeast E. fibuliger, an integrative plasmid containing the 5.8S and a part of the 26S rRNA gene, a selectable marker conferring resistance to the G418 antibiotic and a reporter gene, the α-amylase (ALP1) gene of E. fibuliger, was constructed. This plasmid was linearized at a unique restriction site within the 26S rRNA gene, and transformed into S. cerevisiae INVSC2 MATa his3 ura3 using the lithium acetate method to test the functionality of the vector system. Transformation into S. cerevisiae INVSC2 MATa his3 ura3 was by virtue of the extensive homology between the sequenced 26S rRNA gene of E. fibuliger 8014 met and that of S. cerevisiae, so that homologous pairing and integration into the recipient chromosome was possible. The G418-resistant S. cerevisiae transformants produced halos on starch medium due to hydrolysis by α-amylase, and they were further analysed by Southern hybridization with the ALP1 gene and the gene encoding the aminoglycoside 3′- phosphotransferase I enzyme which confers resistance to the G418 antibiotic. A band of 13.7 kb which corresponded to the linearized size of the transforming plasmid DNA was obtained on the autoradiogram, suggesting that tandem copies of the plasmid DNA are present in the chromosome. Finally, an assay of the α-amylase enzyme secreted extracellularly was performed on the transformants.     

The 5.8S RNA gene sequence and the ribosomal repeat of Schizosaccharomyces pombe

We have characterized the rRNA gene repeat in Schizosaccharomyces pombe. This repeat, which does not contain the 5S RNA gene, is found in a 10.4 kb HindIII DNA fragment. We have determined the nucleotide sequences of the S. pombe 5.8S RNA gene and intergenic spacers from two different 10.4 kb DNA fragments. Analysis of isolated total cellular 5.8S RNA revealed the presence of eight species of 5.8S RNA, differing in the number of nucleotides at the 5'-end. The eight 4.8S RNA species vary in length from 158 to 165 nucleotides. Apart from the heterogeneity observed at the 5'-end, the sequence of the eight 5.8S RNA species appears to be identical and is the same sequence as coded for by the 5.8S genes. The gene sequence shows great homology to the 5.8S RNA genes or S. cerevisiae and N. crassa. Most of the base differences are confined to the highly variable stem though to be involved in co-axial helix stacking with the 25S RNA, where base pairing is nearly identical despite the sequence differences. Secondary structure models are examined in light of 5.8S RNA oligonucleotide conservation across species from yeasts to higher eukaryotes.     

Nol9 is a novel polynucleotide 5'-kinase involved in ribosomal RNA processing

In a cell, an enormous amount of energy is channelled into the biogenesis of ribosomal RNAs (rRNAs). In a multistep process involving a large variety of ribosomal and non-ribosomal proteins, mature rRNAs are generated from a long polycistronic precursor. Here, we show that the non-ribosomal protein Nol9 is a polynucleotide 5'-kinase that sediments primarily with the pre-60S ribosomal particles in HeLa nuclear extracts. Depletion of Nol9 leads to a severe impairment of ribosome biogenesis. In particular, the polynucleotide kinase activity of Nol9 is required for efficient generation of the 5.8S and 28S rRNAs from the 32S precursor. Upon Nol9 knockdown, we also observe a specific maturation defect at the 5' end of the predominant 5.8S short-form rRNA (5.8S(S)), possibly due to the Nol9 requirement for 5'>3' exonucleolytic trimming. In contrast, the endonuclease-dependent generation of the 5'-extended, minor 5.8S long-form rRNA (5.8S(L)) is largely unaffected. This is the first report of a nucleolar polynucleotide kinase with a role in rRNA processing.     

Cloning in a cosmid vector of complete 37 kb and 25 kb ribosomal DNA repeat units from the chicken

DNA fragments of up to 40 kb containing rRNA-coding sequences have been isolated from a chicken liver DNA library prepared in the cosmid pHC79. Characterization of the cloned DNA by R-loop and restriction mapping has shown that there are two size classes of repeat unit, one of 37 kb and one of 25 kb, the larger of which is a family of units which vary slightly in size. These two classes were shown to be present in the DNA of a single chicken. The size of the internal transcribed spacer in the chicken was measured to be 4.4 kb from analysis of R-loops and heteroduplexes between chicken and Xenopus laevis rDNAs. No introns were observed in either the 18 S or the 28 S coding sequences. The number of copies of the chicken rDNA unit was measured by titration against the cloned sequences to be 202±51 per haploid genome.     

RNase J is involved in the 5′-end maturation of 16S rRNA and 23S rRNA in Sinorhizobium meliloti

Sinorhizobium meliloti harbours genes encoding orthologs of ribonuclease (RNase) E and RNase J, the principle endoribonucleases in Escherichia coli and Bacillus subtilis, respectively. To analyse the role of RNase J in S. meliloti, RNA from a mutant with miniTn5-insertion in the RNase J-encoding gene was compared to the wild-type and a difference in the length of the 5.8S-like ribosomal RNA (rRNA) was observed. Complementation of the mutant, Northern blotting and primer extension revealed that RNase J is necessary for the 5′-end maturation of 16S rRNA and of the two 23S rRNA fragments, but not of 5S rRNA.