Unique arrangement of coding sequences for 5 S, 5.8 S, 18 S and 25 S ribosomal RNA in Saccharomyces cerevisiae as determined by R-loop and hybridization analysis.

The arrangement of the coding sequences for the 5 S, 5.8 S, 18 S and 25 S ribosomal RNA from Saccharomyces cerevisiae was analyzed in λ-yeast hybrids containing repeating units of the ribosomal DNA. After mapping of restriction sites, the positions of the coding sequences were determined by hybridization of purified rRNAs to restriction fragments, by R-loop analysis in the electron microscope, and by electrophoresis of S₁ nuclease-treated rRNA/rDNA hybrids in alkaline agarose gels. The R-loop method was improved with respect to the length calibration of RNA/DNA duplexes and to the spreading conditions resulting in fully extended 18 S and 25 S rRNA R-loops. The qualitative results are: (1) the 5 S rRNA genes, unlike those in higher eukaryotes, alternate with the genes of the precursor for the 5.8 S, 18 S and 25 S rRNA; (2) the coding sequence for 5.8 S rRNA maps, as in higher eukaryotes, between the 18 S and 25 S rRNA coding sequences. The quantitative results are: (1) the tandemly repeating rDNA units have a constant length of 9060 ± 100 nucleotide pairs with one SstI, two HindIII and, dependent on the strain, six or seven EcoRI sites; (2) the 18 S and 25 S rRNA coding regions consist of 1710 ± 80 and 3360 ± 80 nucleotide pairs, respectively; (3) an 18 S rRNA coding region is separated by a 780 ± 70 nucleotide pairs transcribed spacer from a 25 S rRNA coding region. This is then followed by a 3210 ± 100 nucleotide pairs mainly non-transcribed spacer which contains a 5 S rRNA gene.     

Ribosomal DNA in Drosophila melanogaster. I. Isolation and characterization of cloned fragments.

Fragments of rDNA3 from Drosophila melanogaster produced by the restriction endonuclease EcoRI were cloned in the form of recombinant plasmids in Escheriehia coli. Maps were prepared showing the location of the coding regions and of several restriction endonuclease sites. Most rDNA repeats have a single EcoRI site in the 18 S gene region. Thus, 19 of 24 recombinant clones contained a full repeat of rDNA. Ten repeats with continuous 28 S genes and repeats containing insertions in the 28 S gene of 0.5, 1 and 5 kb were isolated. The 0.5 and 1 kb insertion sequences are homologous to segments of the 5 kb insertions; because of this homology they are grouped together and identified as type 1 insertions. Four recombinant clones contain an rDNA fragment that corresponds to only a portion of a repeating unit. In these fragments the 28 S gene is interrupted by a sequence which had been cleaved by EcoRI. The interrupting sequences in these clones are not homologous to any portion of type 1 insertions and are therefore classified as type 2. In one of the above clones the 28 S gene is interrupted at an unusual position; such a structure is rare or absent in genomic rDNA from the fly. Another unusual rDNA fragment was isolated as a recombinant molecule. In this fragment the entire 18 S gene and portions of the spacer regions surrounding it are missing from one repeat. A molecule with the same structure has been found in uncloned genomic rDNA by electron microscopic examination of RNA/DNA hybrids.     

Characterization of a cloned ribosomal fragment from mouse which contains the 18S coding region and adjacent spacer sequences.

The large EcoRI fragment of mouse ribosomal genes containing parts of the non-transcribed spacer, the external transcribed spacer located at the 5' end of the precursor molecule and about two thirds of the 18S sequence has been cloned in bacteriophage lambda gtWES. A physical map of the DNA was constructed by cleavage with several restriction endonucleases and hybridization of the restriction fragments of the recombinant DNA with labelled 18S and 45S rRNA. The orientation of the inserted fragment as well as the length of the 18S sequence was determined by electron microscopy of R-loop containing molecules. The absence of hybridization of the cloned fragment to other fragments in the genome shows that the non-transcribed spacer does not have a significant length of sequences in common with other sequences in the genome.     

Purification and restriction endonuclease mapping of soybean 18 S and 25 S ribosomal RNA genes

The restriction endonuclease map of the 25 S and 18 S ribosomal RNA genes of a higher plant is presented. Soybean (Glycine max) rDNA was enriched by preparative buoyant density centrifugation in CsCl-actinomycin D gradients. The buoyant density of the rDNA was determined to be 1.6988 g cm^–3 by analytical centrifugation in CsCl. Saturation hybridization showed that 0.1% of the total DNA contains 25 S and 18 S rRNA coding sequences. This is equivalent to 800 rRNA genes per haploid genome (DNA content: 1.29 pg) or 3200 for the tetraploid genome. Restriction endonuclease mapping was performed with Bam H I, Hind III, Eco R I, and BstI. The repeating unit of the soybean ribosomal DNA has a molecular weight of 5.9·10⁶ or approximately 9,000 kb. The 25 S and 18 S rRNA coding sequences were localized within the restriction map of the repeating unit by specific hybridization with either [¹²⁵I]25 S or [¹²⁵I]18 S rRNA. It was demonstrated that there is no heterogeneity even in the spacer region of the soybean rDNA.     

A comparison of the structural organization of amplified ribosomal DNA from Xenopus mulleri and Xenopus laevis.

Secondary structure maps of long single strands of amplified ribosomal DNA from two closely related species of frogs, Xenopus laevis and X. mulleri, have been compared. The secondary structure pattern of the gene region is identical in both ribosomal DNAs while the patterns in the non-transcribed spacers² differ. In X. mulleri, the spacer shows an extended region without any secondary structure adjacent to the 28 S ribosomal RNA sequence. In contrast, the same region in the X. laevis spacer has extensive secondary structure. A comparison of secondary structure maps and denaturation maps of these two ribosomal DNAs (Brown et al., 1972) reveals that the portion without secondary structure in the X. mulleri spacer corresponds to an early melting A + T-rich region. As in X. laevis ribosomal DNA, Escherichia coli restriction endonuclease (EcoRI) makes two cuts in each repeating unit of amplified ribosomal DNA from X. mulleri. The position of the cleavage sites is identical in the two species as judged from secondary structure mapping of the two classes of EcoRI fragments generated. The small fragments of X. mulleri ribosomal DNA are homogeneous in size with a duplex molecular weight of 3.0 × 10⁶, and contain about 85% of the 28 S ribosomal RNA gene and about 17% of the 18 S ribosomal RNA gene. The large fragments are heterogeneous in size with molecular weights ranging from 4.2 to 4.9 × 10⁶, and contain the remaining portions of the gene regions and the nontranscribed spacer. Heteroduplexes made between large fragments of different lengths show only deletion loops. The position of these loops indicates that the length heterogeneity resides in the non-transcribed spacer region. Electrophoretic analysis of EcoRI digests of chromosomal ribosomal DNA from X. mulleri demonstrates that this DNA is heterogeneous in length as well.     

Characterization of cloned rat ribosomal DNA fragments

Summary Two Charon 4A lambda bacteriophage clones were characterized which contain all and part of the 18S ribosomal DNA of the rat. One clone contained two Eco RI fragments which include the whole 18S ribosomal RNA region and part of 28S ribosomal RNA region. The other clone contained an Eco RI fragment which covers part of 18S ribosomal RNA region. There were differences between the two clones in the non-transcribed spacer regions suggesting that there is heterogeneity in the non-transcribed spacer regions of rat ribosomal genes. The restriction map of the cloned mouse ribosomal DNA. Eco RI, Hind III, Pst I, and Bam HI sites in 18S ribosomal RNA region were in the same places in mouse and rat DNA but the restriction sites in the 5-spacer regions were different.     

Physical mapping of the pea chloroplast DNA and localization of the ribosomal RNA genes

The closed circular DNA of pea chloroplast has been digested with restriction endonucleases SalI, SmaI, BamHI, XbaI, XhoI, HindIII, and EcoRI. A physical restriction map of pea ctDNA has been constructed by mapping the SalI and SmaI sites. The pea ctDNA has been found to contain one set of ribosomal RNA genes by Southern hybridization of restriction endonuclease digest, R-loop studies, and DNA-DNA heteroduplex mapping. The 23 S and 16 S RNA genes are confined to a DNA region of 3.0 and 1.5 kbp, respectively. The two rRNA chains are separated by a spacer region of 2.2 kbp.     

Characterization of the rDNA repeat units in the MitchellPetunia genome

The principal rDNA repeating unit in the MitchellPetunia genome has a length of 8.5 kb. In addition there is a major variant of length 9.7 kb, and two minor variants of 9.3 kb and 10.4 kb. The size heterogeneity of the rDNA repeating units results from length differences in the non-transcribed spacer regions. These differences may reflect simple insertions into the non-transcribed spacer region of the major ‘short’ repeat; however, additional sequence changes have occurred since the ‘short’ repeat is characterized by restriction endonuclease cleavage sites which are absent in the longer variant units.     

Free ribosomal DNA molecules from Tetrahymena pyriformis GL are giant palindromes

Restriction ondonuclease EcoRI was used to study the structure of the free ribosomal DNA molecules from Tetrahymena pyriformis, strain GL. From the following observations we conclude that the free rDNA molecules from Tetrahymena are giant palindromes³, each containing two genes for preribosomal RNA arranged in rotational symmetry as inverted repeating sequences. Analyses of the sizes of products of partial or complete digestion and quantitative analyses of the products of complete digestion of uniformly ³²P-labeled rDNA yielded an RI endonucleolytic cleavage map which showed that the EcoRI recognition sites are arranged symmetrically about the center of the rDNA molecule.When heat-denatured rDNA was rapidly cooled under conditions in which no renaturation would occur between separated complementary strands of DNA, molecules of half the size of the original rDNA molecule were produced. These were double-stranded DNA molecules as evidenced by their resistance to digestion with S1 nuclease. Moreover, they could be digested with EcoRI to produce fragments of sizes which would be predicted from the assumption that each single strand of the original rDNA molecule had folded back on itself to form a “hair-pin” double-stranded DNA structure. Hybridization experiments between ribosomal RNA and purified rDNA showed that each rDNA molecule contains two genes for rDNA. Hybridization of the isolated EcoRI fragments of rDNA with 25 S or 17 S rRNA suggested that the two structural genes for 17 S rRNA are located near the center of the rDNA molecule and the two genes for 25 S rRNA are found in distal positions.     

Ribosomal DNA of Caenorhabditis elegans

We have characterized the organization of the genes coding for 18 S, 5·8 S and 26 S ribosomal RNAs in the nematode Caenorhabditis elegans. These ribosomal genes, present in about 55 copies per haploid genome, alternate in a repeating tandem array. The repeating unit is only 7000 base-pairs, containing a non-transcribed spacer of no more than 1000 base-pairs. Most of the repeating units have identical restriction maps, but one repeat contains a deletion of 2900 base-pairs, which eliminates all or part of the 18 S coding region. We have found no difference in the major ribosomal DNA restriction endonuclease cleavage patterns between two interbreeding strains of C. elegans, but found differences between C. elegans and the closely related Caenorhabditis briggsae.     

Ribosomal DNA in Drosophila melanogaster. II. Heteroduplex mapping of cloned and uncloned rDNA.

Sequences in the cloned Drosophila melanogaster rDNA fragments described by Dawid et al. (1978) were compared by heteroduplex mapping. The nontranscribed spacer regions in all fragments are homologous but vary in length. Deletion loops were observed at variable positions in the spacer region suggesting that spacers are internally repetitious.Many rDNA repeats in D. melanogaster have a 28 S gene interrupted by a region named the ribosomal insertion. Insertions of 0.5, 1 and 5 kb were found in repeat-length EcoRI fragments. These DNA regions, named type 1 insertions, are homologous at their right ends. Although 1 kb insertions are quite precisely twice as large as 0.5 kb insertions they do not represent a duplication of the shorter sequence. Some insertions have at least one EcoRI site and therefore yield EcoRI fragments which are only part of a repeat. The sequences in two cloned right-hand partial insertion sequences are homologous, but the sequences in two lefthand partial insertions are not. None of the EcoRI-restrictable insertion sequences has any homology to any part of type 1 insertions; they are thus grouped together as type 2. Evidence for insertion sequences of at least two types in uncloned rDNA was obtained by annealing a cloned fragment with a 1 kb insertion to genomic rDNA. About 15% of the rDNA repeats show substitution type loops between the 1 kb type 1 insertion derived from the cloned fragment and type 2 insertions in the rDNA.     

Replication termini in the rDNA of synchronized pea root cells (Pisum sativum)

In synchronized root cells of Pisum sativum (cv. Alaska) the joining of nascent replicons is delayed until cells reach the S-G(2) boundary or early G(2) phase. To determine if the delayed ligation of nascent chains occurs at specific termination sites, we mapped the location of arrested forks in the ribosomal DNA (rDNA) repeats from cells in late S and G(2) phases. Two-dimensional (neutral-alkaline) agarose electrophoresis and Southern blot hybridization with specific rDNA sequences show that only cells located at the S-G(2) boundary and early G(2) phase produce alkali-released rDNA fragments of discrete size. The released fragments are from a particular restriction fragment, demonstrating that the replication forks stop non-randomly within the rDNA repeats. Indirect end-labeling with probes homologous to one or the other end of the fork-containing restriction fragment shows that there are two termination regions, T(1) and T(2), where forks stop. T(1) is located in the non-transcribed spacer and T(2) is at the junction between the non-transcribed spacer and the 18S gene. The two termini are separated by 1.3 kb. Replication forks stop at identical sites in both the 8.6- and 9.0-kb rDNA repeat size classes indicating that these sites are sequence determined.     

Arrangement of the rRNA sequences in the rDNA of Lytechinus variegatus

The arrangement of the 26S RNA and 18S RNA sequences of the ribosomal DNA (rDNA) from the sea urchin Lytechinus variegatus was investigated by an electron microscopic analysis of R-loops formed between the ribosomal RNA genes and the mature ribosomal RNAs. Ninety-eight percent of observed molecules contained R-loops clearly seen as a three-stranded complex. The size of DNA complementary to mature cytoplasmic 18S and 26S ribosomal RNA (rRNA) was calculated by measuring the double-strand (ds) and single-strand (ss) part of the R-loops separately. The values for the 18S R-loop are 1.75±0.24 kb¹ (ss) and 1.56±0.23 kb (ds). The 26S R-loop is 3.34±0.39 kb (ss) and 3.33±0.33 kb (ds). These measurements agree fairly well with the rRNA sizes measured on denaturing sucrose density gradients: 3.23±0.22 kb for the 26S and 1.93±0.10 kb for 18S. The short spacer between the 18S and 26S R-loops is 1.03±0.24 kb and the longer spacer is 5.36±0.53 kb. In long molecules a repeating pattern was observed. The average length of an rDNA repeat unit is 11.33±0.64 kb when computed using double-strand R-loop measurements and 11.50±0.72 when computed using R-loop single-strand lengths.Abbreviations kb kilobases, 1000 bases of RNA or single-strand DNA, and kilobase pairs, 1000 base pairs of duplex DNA or DNA/RNA hybrid - EDTA ethylenediaminetetraacetate - SSC 0.15 M NaCl, 0.015 M sodium citrate - PIPES piperazine-N,N-bis (2-ethanesulfonic acid)-Na_1.4     

Restriction site patterns in the ribosomal DNA of Camelidae

The restriction map of rDNA from South American camelids and the Bactrian camel was analyzed by digestion of high-molecular-weight DNA with endonucleases EcoRI, BamHI and the two combined followed by Southern blot hybridization with probes for the 18S and 28S rDNA sequences. We scored a total of 17 restriction sites, six of which were mapped conserved in all the species. The other eleven corresponded to spacer regions and revealed variations between these taxa. The study showed that the two groups differ in the length of the internal transcribed spacer. Also they showed the existence of two regions of fast evolution on the opposite termini of the external spacer. A restriction site present at low frequency in the non-transcribed spacer of guanaco and llama was the only difference encountered within the South American group.     

Study of polymorphism in human rRNA gene clusters

Human ribosomal DNA (rDNA) probe specific for the 3' end of the 28S rRNA gene was used for detecting standard restriction fragments' length polymorphism (RFLPs) in the non-transcribed spacer. The conditions for hybridization of rDNA probe which eliminate cross hybridization of parts of 28S rRNA gene were developed. A test for detecting incompletely restricted DNA was also developed which may be used in experiments for detecting new RFLPs. It was found that a set of standard RFLPs was identical in various human tissues for one individual. Frequency of standard RFLPs in the non-transcribed spacer of human rRNA gene clusters was calculated.