Chloroplast ribosomal RNA genes in Euglena gracilis exist as three clustered tandem repeats

Chloroplast ribosomal DNA from Euglena gracilis was partially purified, digested with restriction endonucleases BamHI or EcoRI and cloned into bacterial plasmids. Plasmids containing the ribosomal DNA were identified by their ability to hybridize to chloroplast ribosomal RNA and were physically mapped using restriction endonucleases BamHI, EcoRI, HindIII and HpaI. The nucleotide sequences coding for the 16S and the 23S chloroplast ribosomal RNAs were located on these plasmids by hybridizing the individual RNAs to denatured restriction endonuclease DNA fragments immobilized on nitrocellulose filters. Restriction endonuclease fragments from chloroplast DNA were analyzed in a similar fashion. These data permitted the localization on a BamHI map of the chloroplast DNA three tandemly arranged chloroplast ribosomal RNA genes. Each ribosomal RNA gene consisted of a 4.6 kilobase pair region coding for the 16S and 23S ribosomal RNAs and a 0.8 kilobase pair spacer region. The chloroplast ribosomal DNA represented 12% of the chloroplast DNA and is G + C rich.     

The Relationship between Satellite Deoxyribonucleic Acid, Ribosomal Ribonucleic Acid Gene Redundancy, and Genome Size in Plants

The buoyant density of ribosomal DNA is similar in species with or without satellite DNA, and in all species examined was distinguishable from that of the satellite DNA. In melon tissues (Cucumus melo) the percentage satellite DNA is not correlated with the percentage hybridization to ribosomal RNA. Satellite DNA sequences do not appear to be dispersed between those coding for ribosomal RNA. There is no correlation between the presence of satellite DNA and high ribosomal RNA gene redundancy, but there is a correlation between satellite DNA and small genome size, which results in a correlation between satellite DNA and a high percentage hybridization to ribosomal RNA. Satellite DNAs are defined as minor components after CsCI centrifugation.     

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.     

A new electron microscopic technique for establishing the positions of genes: an analysis of the yeast ribosomal RNA coding region.

A new technique has been developed for distinguishing RNA/DNA or DNA/DNA duplex regions from single-stranded DNA in the electron microscope by thickness enhancement of the single-stranded DNA. This enhancement is achieved by reacting the single-stranded DNA with Escherichia coli DNA binding protein and monovalent antibody prepared from anti-E. coli DNA binding protein γ-globulin. A general application of this technique is the mapping of coding regions after hybridization with complementary RNA, which can vary in size from 100 to several thousand nucleotides. As an example, the coding sequences for the four yeast ribosomal RNAs were located in heteroduplex molecules constructed between DNA of a λ-yeast hybrid carrying a single rDNA repeat unit and DNA of λimm434.     

The genes for cytoplasmic ribosomal ribonucleic Acid in higher plants

The genes for cytoplasmic ribosomal RNA are partially resolved from the bulk of the DNA by CsCl equilibrium centrifugation. Although in some plants the buoyant density of the ribosomal RNA genes is as expected from the base composition of ribosomal RNA, others show a large discrepancy which cannot be due to the presence of low G-C spacer-DNA. The cross-hybridization observed with 1.3 and 0.7 × 10⁶ molecular weight ribosomal RNAs and DNA, which varies greatly with different plant species, is not due to contamination of the ribosomal RNAs, and is specific for the ribosomal DNA of each species, probably largely restricted to those sequences coding for the two stable ribosomal RNAs. The double reciprocal plot may be used for the extrapolation of saturation values only with caution, because in these cases such plots are not linear over the whole of the hybridization reaction.     

Distribution of 18+28S ribosomal genes in mammalian genomes

In situ hybridization with ³H 18S and 28S ribosomal RNA from Xenopus laevis has been used to study the distribution of DNA sequences coding for these RNAs (the nucleolus organizing regions) in the genomes of six mammals. Several patterns of distribution have been found: 1) A single major site (rat kangaroo, Seba's fruit bat), 2) Two major sites (Indian muntjac), 3) Multiple sites in centromeric heterochromatin (field vole), 4) Multiple sites in heterochromatic short arms (Peromyscus eremicus), 5) Multiple sites in telomeric regions (Chinese hamster). — The chromosomal sites which bind ³H 18S and 28S ribosomal RNA correspond closely to the sites of secondary constrictions where these are known. However, the correlation is not absolute. Some secondary constrictions do not appear to bind ³H ribosomal RNA. Some regions which bind ribosomal RNA do not appear as secondary constrictions in metaphase chromosomes. — Although the nucleolus organizing regions of most mammalian karyotypes are found on the autosomes, the X chromosomes in Carollia perspicillata and C. castanea carry large clusters of sequences complementary to ribosomal RNA. In situ hybridization shows that the Y chromosome in C. castanea also has a large nucleolus organizing region.     

The Nucleolus Organizer Region of Maize (ZEA MAYS L.): Tests for Ribosomal Gene Compensation or Magnification

Ribosomal gene compensation and magnification that might be detected on a whole-plant basis was not found in maize. Plants monosomic for chromosome 6 (the NOR chromosome) were compared with monosomic-8 and monosomic-10 plants, disomic sibs, and parental lines. Assuming no rDNA compensation, monosomic-6 plants showed approximately the decrease expected in rRNA cistron number. Monosomic-8 had a normal ribosomal gene number, while monosomic-10 showed a decrease; but further documentation is needed. Besides demonstrating the absence of gene compensation, the results document our previous conclusion that maize chromosome 6 carries DNA complementary to ribosomal RNA. Further documentation was provided from studies with trisomic chromosome 6 plants showing proportional increases in ribosomal gene number. Progeny of the monosomic plants crossed as males to a standard singlecross hybrid possessed expected ribosomal gene numbers suggesting the lack of ribosomal gene magnification.—The ragged (rgd) mutant of maize, suspected of being deficient in rRNA cistrons, had a normal number.     

Variability in Complementarity for Chloroplastic and Cytoplasmic Ribosomal Ribonucleic Acid among Plant Nuclear Deoxyribonucleic Acids

The nuclear DNAs from a number of angiosperm species were tested for hybridization to the RNAs contained in 70 S (chloroplastic) and 80 S (cytoplasmic) ribosomes. All of the DNAs contained regions complementary to RNAs from chloroplastic as well as cytoplasmic ribosomes. DNAs from closely related plants varied widely in their proportion of coding for these RNAs. About 0.15% of the DNAs from a number of different species of Nicotiana were found to be complementary to the RNAs of each kind of ribosome; however, DNAs from some other members of this genus had more than three times this proportion of coding for ribosomal RNAs. These and other data suggest that hybridization percentage for ribosomal RNA is not a familial or generic characteristic.     

Comparative Study of Ribosomal Ribonucleic Acid Cistrons in Enterobacteria and Myxobacteria

Deoxyribonucleic acid (DNA)-ribonucleic acid (RNA) hybrids are formed by Escherichia coli 16S or 23S ribosomal RNA or pulse-labeled RNA with the DNA of various species of the Enterobacteriaceae. The relative extent of hybrid formation is always greater for ribosomal RNA. These DNA-RNA hybrids have been further characterized by their stability to increasing temperature, and, in every case, the stability of pulse-labeled RNA hybrids was lower than that of the corresponding ribosomal RNA hybrids, although 16S and 23S ribosomal RNA hybrids had very similar stabilities. Therefore, ribosomal RNA showed a greater degree of apparent conservation in base sequence than pulse-labeled or messenger RNA both in the extent of cross-reaction and in the stability of hybrid structures. Similar results were obtained with Myxococcus xanthus RNA. Since in this case the base composition of the pulse-labeled or messenger RNA is richer in guanine plus cytosine than ribosomal RNA, the higher cross-reaction of ribosomal RNA is more readily attributable to conservation of base sequence in these cistrons than to its base composition. Thus, the base sequence of ribosomal RNA cistrons of bacilli, enteric bacteria, and myxobacteria is conserved relative to those of the rest of the genomes. This conservation is, however, not absolute since the stability of heterologous ribosomal RNA hybrids is always lower than that of homologous hybrids.     

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.     

Nucleotide sequence from the genetic left end of bacteriophage T7 DNA to the beginning of gene 4

The nucleotide sequence running from the genetic left end of bacteriophage T7 DNA to within the coding sequence of gene 4 is given, except for the internal coding sequence for the gene 1 protein, which has been determined elsewhere. The sequence presented contains nucleotides 1 to 3342 and 5654 to 12,100 of the approximately 40,000 base-pairs of T7 DNA. This sequence includes: the three strong early promoters and the termination site for Escherichia coli RNA polymerase: eight promoter sites for T7 RNA polymerase; six RNAase III cleavage sites; the primary origin of replication of T7 DNA; the complete coding sequences for 13 previously known T7 proteins, including the anti-restriction protein, protein kinase, DNA ligase, the gene 2 inhibitor of E. coli RNA polymerase, single-strand DNA binding protein, the gene 3 endonuclease, and lysozyme (which is actually an N-acetylmuramyl-l-alanine amidase); the complete coding sequences for eight potential new T7-coded proteins; and two apparently independent initiation sites that produce overlapping polypeptide chains of gene 4 primase. More than 86% of the first 12,100 base-pairs of T7 DNA appear to be devoted to specifying amino acid sequences for T7 proteins, and the arrangement of coding sequences and other genetic elements is very efficient. There is little overlap between coding sequences for different proteins, but junctions between adjacent coding sequences are typically close, the termination codon for one protein often overlapping the initiation codon for the next. For almost half of the potential T7 proteins, the sequence in the messenger RNA that can interact with 16 S ribosomal RNA in initiation of protein synthesis is part of the coding sequence for the preceding protein. The longest non-coding region, about 900 base-pairs, is at the left end of the DNA. The right half of this region contains the strong early promoters for E. coli RNA polymerase and the first RNAase III cleavage site. The left end contains the terminal repetition (nucleotides 1 to 160), followed by a striking array of repeated sequences (nucleotides 175 to 340) that might have some role in packaging the DNA into phage particles, and an A · T-rich region (nucleotides 356 to 492) that contains a promoter for T7 RNA polymerase, and which might function as a replication origin.     

The relationship between ribosomal repeat length and genome size in Vicia

The organization of the ribosomal RNA genes was examined in several species of Vicia in an attempt to determine whether a relationship exists between genome size and ribosomal repeat length. Species within this genus exhibit a sevenfold variation in haploid DNA content. Our data suggest that species with an intermediate genome size maintain one predominant Eco RI class of ribosomal repeat of about 9 kilobases (kb). In contrast, the smallest and largest genomes of Vicia possess one major and several minor classes. The possible relationship between repeat classes among species is discussed. We examined the species with the smallest (V. villosa) and largest (V. faba) genomes in closer detail by R-loop analysis of a satellite DNA from Hoechst 33258 dye-CsCl gradients. Heterogeneity was found in the length of the ribosomal repeat for both species, but no appreciable difference was observed in the distribution of these lengths, which averaged 11–12 kb. This heterogeneity is associated with the nontranscribed spacer region. Intervening sequences were not found in either the 25S or 18S coding regions of the ribosomal repeat of either of these two plants. A putative ribosomal RNA precursor of 7 kb was identified for both species.     

Chloroplast ribosomal RNA genes in the chloroplast DNA of Euglena gracilis

Euglena chloroplast DNA has a buoyant density in CsCI of 1.686. Shearing this DNA produces a satellite band at density 1.700. The satellite, easily lost during preparative CsCI gradient centrifugation of chloroplast DNA, contains the genes for chloroplast ribosomal RNA. Pure Euglena chloroplast DNA is shown to contain one set of ribosomal RNA genes for each 90 × 10⁶ daltons of DNA.     

Isolation and Characterization of Bacterial Ribosomal RNA Cistrons

The DNA sequences which code for ribosomal DNA have been isolated and purified. The technique used has general application for RNA:DNA hybridization studies and enables the isolation of any gene for which sufficient gene product can be obtained. Experiments with isolated ribosomal RNA cistrons demonstrated that (a) the majority of the ribosomal cistrons are similar to one another; (b) the cistrons which are similar to one another are virtually identical to one another; (c) ribosomal cistrons of different bacterial species are closely related to one another.