Analysis of the 5'-terminal nucleotide sequences of ribonucleic acids. II. Comparison of the 5'-terminal nucleotide sequences of ribosomal RNA's from different organisms

Ribosomal RNA precursors of Bacillus subtilis

The DNA sequence of the region corresponding to the 5'-end of a 16S rRNA gene of B. subtilis 168 was determined. Comparison of this sequence with the sequences flanking other 16S and 23S rRNA coding regions (1-4) indicated that large RNA stem structures, surrounding the mature 16S and 23S rRNAs, could form in a precursor rRNA. The 5'-ends of the precursors of 16S and 23S rRNAs (p16S and p23S) were mapped to the middles of these potential RNA stem structures. We propose that the initial cleavages of the primary rRNA transcript occur near the "opposed G's" which interrupt the basepairing of each of these stem structures. This model is supported by the finding that the 5'-end of the 5S rRNA precursor, p5A (5), maps to the region of the "opposed G's" in the 23S rRNA stem structure.

DNA sequence of the tandem ribosomal RNA promoter for B. subtilis operon rrnB

A new ribosomal RNA operon designated rrnB has been identified by screening a Charon 4a library of cloned B. subtilis sequences. Clones containing the promoter region of this operon are unstable in E. coli unless a special vector possessing a transcriptional terminator is used. DNA sequence data suggests that this operon contains two tandem putative promotor regions not unlike those found in E. coli. There are 92 base pairs separating the two "-10 regions" of the promotors. The second is 180 bp upstream from the start site for mature 16S RNA. A potential 29 base pair stem structure necessary for processing of the mature 16S RNA sequence can also be predicted from this analysis.

The nucleotide sequence of 5S rRNA from a red alga, Porphyra yezoensis

The nucleotide sequence of 5S rRNA from Porphyra yezoensis has been determined to be: pACGUACGGCCAUAUCCGAGACACGCGUACCGGAACCCAUUCCGAAUUCCGAAGUCAAGCGUCCGCGAGUUGGGUUAGU - AAUCUGGUGAAAGAUCACAGGCGAACCCCCAAUGCUGUACGUC. This 5S rRNA sequence is most similar to that of Euglena gracilis (63% homology).

The nucleotide sequence of chloroplast 5S ribosomal RNA from a fern, Dryopteris acuminata

Dryopteris acuminata chloroplasts were found to contain three species of 5S rRNAs with different electrophoretic mobility. The large 5S rRNA species is composed of 122 nucleotides and its sequence is: pUAUUCUGGUGUCCCAGGCGUAGAGGAACCACAC-CGAUCCAUCUCGAACUUGGUGGUGAAACUCUGCCGCGGUAACCA AUACUCGGGGGGGGCCCU-GCGGAAAAAUAGCUCGAUGCCAGGAUAOH. This 5S rRNA shows high sequence homology with those from chloroplasts of flowering plants and from a blue-green alga, Anacystis nidulans.

The complete nucleotide sequence of a 23-S rRNA gene from tobacco chloroplasts

The nucleotide sequence of a tobacco chloroplast 23-S rRNA gene, including the spacer between it and the 4.5-S rRNA gene, has been determined. The 23-S rRNA coding region is 2804-base-pairs long. A comparison with the 23-S rRNA sequence of Escherichia coli reveals strong homology and further shows a similarity between the chloroplast 4.5-S rRNA and the 3'-terminal region of E. coli 23-S rRNA. However, the 101-base-pair spacer sequence between the 23-S and 4.5-S rRNA genes has little homology with E. coli 23-S rRNA.

The nucleotide sequence of chloroplast 4.5S rRNA from a fern, Dryopteris acuminata

The 4.5S rRNA was isolated from the chloroplast ribosomes from Dryopteris acuminata. The complete nucleotide sequence was determined to be: OHUAAGGUCACGGCAAGACGAGCCGUUUAUCACCACGAUAGGUGCUAAGUGGAGGUGCAGUAAUGUAUGCAGCUGAGGC AUCCUAAUAGACCGAGAGGUUUGAACOH. The 4.5S rRNA is composed of 103 nucleotides and shows strong homology with those from flowering plants.

tRNA genes are found between 16S and 23S rRNA genes in Bacillus subtilis

There are at least nine, and probably ten, ribosomal RNA gene sets in the genome of Bacillus subtilis. Each gene set contains sequences complementary to 16S, 23S and 5S rRNAs. We have determined the nucleotide sequences of two DNA fragments which each contain 165 base pairs of the 16S rRNA gene, 191 base pairs of the 23S rRNA gene, and the spacer region between them. The smaller space region is 164 base pairs in length and the larger one includes an additional 180 base pairs. The extra nucleotides could be transcribed in tRNAIIe and tRNA Ala sequences. Evidence is also presented for the existence of a second spacer region which also contains tRNAIIe and tRNA Ala sequences. No other tRNAs appear to be encoded in the spacer regions between the 16S and 23S rRNA genes. Whereas the nucleotide sequences corresponding to the 16S rRNA, 23S rRNA and the spacer tRNAs are very similar to those of E. coli, the sequences between these structural genes are very different.

The nucleotide sequences of two tRNAAsn genes from tobacco chloroplasts

Recombinant plasmids which contain EcoRI fragments of tobacco chloroplast DNA carrying tRNA genes were constructed. Plasmids pTC211 and pTC293 contain the base sequences for tRNAAsn in their 1.4 and 1.1 Md EcoRI fragments, respectively. These two tRNA sequences are identical and are; 5'-TCCTCAGTAGCTCAGTGGTAGAGCGGTCGGCTGTTAACCGATTGGTCGTAGGTTCGAATCCTACTTGGGGAG-3'. Each tRNAAsn gene is located at about 0.9 kb apart from the distal end of each 5S rRNA gene and is coded for by the DNA strand opposite from that of the rRNA genes.

The nucleotide sequence of the intergenic region between the 5.8S and 26S rRNA genes of the yeast ribosomal RNA operon. Possible implications for the interaction between 5.8S and 26S rRNA and the processing of the primary transcript

We have determined the nucleotide sequence of part of a cloned yeast ribosomal RNA operon extending from the 5.8S RNA gene downstream into the 5' -terminal region of the 26S RNA gene. We mapped the pertinent processing sites, viz. the 5' end of 26S rRNA and the 3'ends of 5.8S rRNA and its immediate precursor, 7S RNA. At the 3' end of 7S RNA we find the sequence UCGUUU which is very similar to the type I consensus sequence UCAUUA/U present at the 3' ends of 17S, 5.8S and 26S rRNA as well as 18S precursor rRNA in yeast. At the 5' end of the 26S RNA gene we find a sequence of thirteen nucleotides which is homologous to the type II sequence present at the 5' termini of both the 17S and the 5.8S RNA gene. These findings further support the suggestion put forward earlier (G.M. Veldman et al. (1980) Nucl. Acids Res. 8, 2907-2920) that both consensus sequences are involved in the recognition of precursor rRNA by the processing nuclease(s). We discuss a model for the processing of yeast rRNA in which a processing enzyme sequentially recognizes several combinations of a type I and a type II consensus sequence. We also describe the existence of a significant base complementarity between sequences in the 5' -terminal region of 26S rRNA and the 3' -terminal region of 5.8S rRNA. We suggest that base pairing between these sequences contributes to the binding between 5.8S and 26S rRNA.

The structure of the yeast ribosomal RNA genes. 3. Precise mapping of the 18 S and 25 S rRNA genes and structure of the adjacent regions

The 5'-terminal of Saccharomyces cerevisiae 18 S and 25 S rRNA are precisely mapped within the sequence of the rDNA repeating unit. The 3'-terminal of 25 S rRNA and 37 S pre-rRNA are located within a 548 bp segment of the rDNA repeating unit by the use of a DNA polymerase I extension technique. The analysis of the rDNA sequences at the structural gene boundaries reveals the presence of oligonucleotide repeats which may be involved in transcription or processing control mechanisms. The sequence of rDNA in the transcription termination region is determined and possible mechanisms shaping the 3'-end of 25 S rRNA are discussed.

The nucleotide sequence of 4.5S ribosomal RNA from tobacco chloroplasts

The nucleotide sequence of tobacco chloroplast 4.5S ribosomal RNA has been determined to be: OHG-A-A-G-G-U-C-A-C-G-G-C-G-A-G-A-C-G-A-G-C-C-G-U-U-U-A-U-C-A-U-U-A-C-G-A-U-A-G-G-U-G-U-C-A-A-G-U-G-G-A-A-G-U-G-C-A-G-U-G-A-U-G-U-A-U-G-C-(G-A)-C-U-G-A-G-G-C-A-U-C-C-U-A-A-C-A-G-A-C-C-G-G-U-A-G-A-C-U-U-G-A-A-COH. The 4.5S RNA is 103 nucleotides long and its 5'-terminus is not phosphorylated.

Specific cleavage of ribosomal RNA caused by alpha sarcin

Alpha sarcin causes the specific cleavage of RNA from 80S ribosomes and 60S subunits of yeast, but not from the 40S subunits to produce a small RNA fragment. The fragment was also produced on treatment of the 60S subunits of wheat germ ribosomes. The fragment has a molecular weight of 100,000 and is a cleavage product of the large RNA species in the 60S subunits. The fragment is not derived from the 5'end of the yeast 25S RNA nor does it bind to 5.8S RNA and we propose that the fragment represents the 3' terminal 320 nucleotides of 25S rRNA. The ability to produce fragment could not be separated from the ability of alpha sarcin to inhibit protein synthesis. Alpha sarcin also causes the specific cleavage of the 23S RNA of the E. coli subunit to produce a smaller fragment of RNA than that produced from eukaryote ribosomes.

Terminal nucleotide sequences of 17-S ribosomal RNA and its immediate precursor 18-S RNA in yeast

The 5' and 3'-terminal nucleotide sequences of 17-S rRNA and its immediate precursor 18-S RNA from the yeast Saccharomyces carlsbergensis have been analysed. Identification of the terminal oligonucleotides, as present in Ti ribonuclease digests, was performed by diagonal procedures. The major (molar yield 0.9) 5'-terminal oligonucleotide (molar yield 0.15) with the overall composition pU (U2,C2)G was observed. 18-S precursor RNA was found to contain the same 5'-terminal sequences as 17-S rRNA. However, the 3'-terminal sequences of the two types of RNA appeared to be different. The 17-S rRNA yields the oligonucleotide A-U-C-A-U-U-AOH while at least half of the 18-S RNA molecules contain the sequence U-U-U-C-A-A-U-AOH. In addition 18-S RNA yields several minor 3'-terminal oligonucleotides which appear to be structurally related to the major 3'-terminal sequence. These results demonstrate that the extra nucleotides in 18-S RNA relative to 17-S RNA are located exclusively at the 3'-terminus of the 18-S RNA molecule. The possibility that the 3'-terminal nucleotide sequence of 18-S RNA plays a role in the maturation process is discussed.

Heterogeneity of 5' -termini of nucleolar 45S, 32S and 28S RNA in mouse hepatoma

The 5'-termini of nucleolar 45S, 32S and 28S RNA's were analyzed by means of thin layer chromatography and Dowex-1 colum chromatography. 45S RNA did not bear a triphosphate at the 5'-terminus, but various monophosphates are found. 5'-termini of 32S and 28S RNA's were also heterogeneous. These results indicate that 45S molecules as isolated with the conventional procedure may not contains the primary transcript of the ribosomal gene, but a collection of large precursors with different degrees of processing at the 5'-terminus. The processing of the primary transcript may thus involve some unknown trimming processes at the 5'-terminus before the first major cleavage takes place.

Conservation of the 5'-terminal nucleotide sequences of ribosomal 18-S RNA in eukaryotes. Differential evolution of large and small ribosomal RNA

The 5'-terminal nucleotide sequences of ribosomal 18-S and 28-S RNA of seven species of eukaryotes including three mammals, one bird, one amphibian, one echinoderm and one slime mold, were analyzed either by means of terminal phosphorylation of RNA with polynucleotide kinase of by fingerprint analysis of uniformly labeled RNA. The following conclusions were obtained. 1. The 5'-terminal sequences of the 18-S RNA of the mouse, chicken and Dictyostelium discoideum were pUpApCp(Cp,Up)Gp---, suggesting strongly that all the eukaryotes had this same sequence at the 5'-terminus. Preliminary analysis of the 5'-termini of the 18-S RNA from human, rat, Xenopus and sea urchin cells revealed the same pUp(Np)Gp--- type 5'-terminal structure, supporting the above hypothesis. 2. The 5'-terminal sequences of the 28-S RNA of the human, rat, mouse and chicken cells were all pCpGp---, whereas those of the lower animals such as Xenopus, sea urchin and Dictyostelium were different.

Control of RNA synthesis in yeast

During the cell cycle in Saccharomyces cerevisiae there is an ordered appearance of a number of enzymes and various physiological properties but a continuous increase in the rate of rRNA synthesis. A detailed study of rRNA synthesis has shown that there are reiterated genes for rRNA which are largely clustered on chromosome I and appear to be transcribed continuously during the cell cycle. However, the level of activity of polymerase I is proportional to the level of rRNA during the cell cycle and is correlated with the growth rate of the culture. In contrast, the level of polymerase II, thought to be involved in mRNA synthesis, increases during a definite period of the cell cycle characteristic of step enzymes in yeast. It would appear that the level of the activity of polymerase I is involved in the regulation of rRNA synthesis. Possible other mechanisms for the regulation of rRNA are discussed.

A new approach to the analysis of hybridization of bacterial nucleic acids. Analysis of the ribosomal ribonucleic acids of Bacillus subtilis

A new graphical analytical technique is described for the hybridization of bacterial RNA with denatured homologous DNA immobilized on cellulose nitrate membrane filters. To a constant amount of DNA, various amounts of bacterial RNA were added and the percentage of input RNA bound was plotted against the DNA/RNA weight ratio in a given experiment. When RNA samples were used that hybridize to denatured DNA as a single species, the resulting curves (RNA-hybridization-efficiency curves) could be analysed to show the percentage of the DNA capable of specifically binding the RNA and could also be used to detect the presence of minor RNA contaminants in a purified specimen. The method could also estimate the relative amounts of two species of RNA in a mixture when these were hybridized independently to different DNA cistrons or cistron groups. As an example of RNA that can be studied in this way, the 16s and 23s ribosomal RNA species of Bacillus subtilis were chosen. These each behave in DNA-RNA hybridization as a single species and bind independently to different groups of DNA cistrons. The results obtained from hybridization-efficiency curves were compared with those obtained by the more usual method of saturating the specific DNA regions with excess of ribosomal RNA (hybridization-saturation curves). It was confirmed by both approaches that 0.15 (+/-0.02)% of B. subtilis DNA would hybridize with 16s ribosomal RNA, 0.30 (+/-0.02)% would hybridize with 23s ribosomal RNA, and 0.46 (+/-0.02)% would hybridize with (16s+23s) ribosomal RNA. This agreement suggested that mass-action equilibria between hybridized and free RNA had a negligible effect on the hybridization curves over the range of DNA and RNA concentrations employed.