Physical linkage between 5 s, 16 s and 23 s ribosomal RNA genes in Bacillus subtilis

Structure and organization of rRNA operons in the region of the replication origin of the Bacillus subtilis chromosome

Structure and organization of two complete ribosomal RNA (rRNA) gene sets, rrnO and rrnA, were determined for the first time in Bacillus subtilis. They are located at the region of the replication origin of the chromosome. Each set constitutes a single operon of: two tandem promoters - leader sequence - 16S rRNA gene - Ile-tRNA gene - Ala-tRNA gene - 23S rRNA gene - 5S rRNA gene - termination signal. The first promoter (P1) of rrnO differs from that of rrnA in sequence and function. P1 of rrnO was used very little for transcription either in vivo or in vitro while P1 was predominantly used in rrnA. A putative transcript of the entire operon was determined and constructed into a secondary structure. Analysis of in vivo transcripts by S1 mapping revealed primary processing sites at the loop and stem structure of 16S rRNA in rrnO and rrnA. A unique sequence in the leader region of rrnO can be formed into a highly complexed secondary structure and affects processing of mature 16S rRNA. The sequences of the two spacer tRNA genes are highly conserved between B. subtilis and Escherichia coli.

Deletion of an rRNA gene set in Bacillus subtilis

One of the 10 rRNA gene sets found in a wild-type strain of Bacillus subtilis 168 was deleted, apparently by recombination between two tandemly repeated rRNA gene sets. The deletion strain grew as well as the wild-type strain under a variety of growth conditions and also showed no change in the sporulation efficiency.

Detailed physical mapping of the ribosomal RNA genes of Bacillus subtilis

Characterization of patterns of ribosomal RNA (rRNA) homology with restriction digests of Bacillus subtilis 168 chromosomal DNA and with cloned DNA sequences has resulted in the construction of a physical map of the rRNA gene sets. There are two types of gene sets which differ in the size of "spacer" DNA sequences separating the 16S and 23S rRNA determinants. It was estimated that there are ten rRNA gene sets on the B. subtilis chromosome.

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.

Genetic mapping of a linked cluster of ribosomal ribonucleic acid genes in Bacillus subtilis

A ribosomal ribonucleic acid gene set consisting of genes for 16S, 23S, 5S, and 4S ribonucleic acid species has been genetically mapped to a position between the markers recG13 and abrB74 on the Bacillus subtilis chromosome and designated rrnA. A ribosomal mutation, ksgA, was found to be linked to rrnA. This places rrnA in a region of the chromosome where ribosome-related genes occur but that is not directly adjacent to the major cluster of ribosome-related markers.

Restriction enzyme analysis of Bacillus subtilis ribosomal ribonucleic acid genes

The organization of the ribosomal ribonucleic acid (rRNA) genes (rDNA) of Bacillus subtilis was examined by cleaving the genome with several restriction endonucleases. The rDNA sequences were assayed by hybridization with purified radioactive rRNA's. Our interpretation of the resulting electrophoretic patterns is strengthened by an analysis of a fragment of B. subtilis rDNA cloned in Escherichia coli. The results indicated that there are eight rRNA operons in B. subtilis. Each operon contains one copy of the sequences coding for 16S, 23S, and 5S rRNA. The sequences coding for 5S rRNA were shown to be more closely linked to the 23S rRNA genes than to the 16S rRNA genes.

The organisation of genes for transfer RNA and ribosomal RNA in amoebae and plasmodia of Physarum polycephalum

1. Using hybridisation techniques nuclei from both amoebae and plasmodia of Physarum polycephalum were found to contain 275 genes each coding for 5.8-S, 19-S and 26-S rRNA, 685 genes for 5-S rRNA and 1050 genes for tRNA. 2. Hybridisation of these RNA species to both amoebal and plasmodial DNA fractionated on CsCl gradients reveal that the 5.8-S, 19-S and 26-S rRNA genes are located at a satellite position (formula: see text) with respect to the main band of DNA, whereas 4-S RNA genes are located exclusively in the main band of DNA (formula: see text). 3. This result was confirmed by demonstrating that only the 5.8-S, 19-S and 26-S rRNA species hybridise to purified plasmodial ribosomal DNA. 4. The 19-S and 26-S rRNA genes of amoebae are located on extrachromosomal DNA molecules of a discrete size (Mr = 38 X 10(6)) with identical properties to plasmodial ribosomal DNA.

Chloramphenicol-induced changes in the synthesis of ribosomal, transfer, and messenger ribonucleic acids in Escherichia coli B/r

The synthesis of ribosomal ribonucleic acid (rRNA), transfer RNA (tRNA) and messenger RNA (mRNA) was measured in Escherichia coli B/r after the addition of 100 mug of chloramphenicol (CAM) per ml to cultures growing either in one of three minimal media (succinate, glycerol, or glucose) or in one of the same three media supplemented with 20 amino acids. (i) During CAM treatment, rRNA and tRNA were synthesized in the same relative proportions (85:15) as during exponential growth. The faster accumulation of tRNA relative to rRNA in CAM was due to a decreased stability of rRNA that is synthesized in the presence of or immediately before the addition of CAM. (ii) CAM stimulated the synthesis of rRNA and tRNA two- to eightfold. The results fell into two groups; one group was from studies done in minimal media and the other was from amino acid-supplemented media. In each group the stimulation decreased with increasing growth rate of the culture during exponential growth before the addition of CAM; however, the stimulation in minimal media was lower than that in amino acid-supplemented media. (iii) CAM caused an increase in the proportion of rRNA and tRNA synthesis and a corresponding decrease in the proportion of mRNA synthesis. In minimal media, the residual proportion of mRNA synthesis after CAM treatment was 10 to 15% of total RNA synthesis; in amino acid-supplemented media this proportion was 0 to 10%. In either case, the residual proportion of mRNA synthesis was independent of the proportions observed during exponential growth in these media. (iv) The absolute rate of mRNA synthesis decreased severalfold with the addition of CAM; i.e., the rate of synthesis of rRNA and tRNA was increased at the expense of mRNA synthesis. (v) During exponential growth, the fraction of the instantaneous rate of total RNA synthesis that corresponds to mRNA is a function of both the growth rate and the presence or absence of amino acids in the growth medium: in the absence of amino acids, this fraction decreased with increasing growth rate; in the presence of amino acids, the fraction increased slightly with growth rate. These results are consistent with a regulation of rRNA and tRNA synthesis at the transcriptional level, e.g., with a CAM-induced increase in the affinity of RNA polymerase for the rRNA and tRNA promoters. The results also suggest the occurrence of a regulation of RNA polymerase enzyme activity, i.e., of an activation of RNA polymerase that is inactive during exponential growth. A distinction between these alternatives requires measurements of the rRNA chain growth rates during CAM treatment.

Ribosomal RNA genes in Bacillus subtilis. Evidence for a cotranscription mechanism

The analysis of the transcriptional mechanism of the ribosomal RNA genes in Bacillus subtilis was undertaken by a study of the rRNA chain elongation in the presence of rifampicin. The residual RNA synthesis after the addition of rifampicin and [3H] uridine to exponentially growing cells has shown that 56% of the radioactivity incorporated into total RNA belongs to the unstable fraction and 44% to the fraction containing mature rRNA and tRNA. Such study allowed an estimation of the half-life of messenger RNAs as being approximately 2 min. The analysis of the transcription pattern of the ribosomal RNA genes, as measured by the amount of radioactivity found in the ribosomal subunits, was complicated by a contamination of the 30 S subunits by 50 S subunits. A contamination of approximately 15% was estimated by polyacrylamide gel electrophoresis and competitive hybridization. The ratios of incorporated radioactivity at zero time when drug and label were concomitantly added ranged between 5.4-6.0, after correction for this contamination. The decay of the 23 S rRNA followed a straight line which became parabolic in its final portion. These results, and theoretical considerations on the lag of rifampicin action and on the variance of the specific activity of the nucleotide pool at the very early times of the experimental observation, favor the interpretation that the 16 and 23 S rRNA genes in B. subtilis belong to the same transcriptional unit, being cotranscribed, in that order, by the same molecule of RNA polymerase. The transcriptional times of the 16 and 23 S rRNA genes were estimated as being 30 and 60 s, respectively.

Two-dimensional restriction analysis of the Bacillus subtilis genome: gene purification and ribosomal ribonucleic acid gene organization

With two-dimensional restriction enzyme analysis we have been able to cleave the Bacillus subtilis genome and resolve the resulting deoxyribonucleic acid (DNA) segments into discrete bands on agarose gels. A general procedure for gene purification has been developed by coupling multidimensional restriction analysis with a biological assay for gene detection. The organization of ribosomal ribonucleic acid (rRNA) genes was studied by hybridizing 16S and 23S rRNA probes to the two-dimensional DNA banding patterns.

Control of 5S RNA synthesis during early development of anucleolate and partial nucleolate mutants of Xenopus laevis

Ribosomes of all eukaryotes contain a single molecule of 5S, 18S, and 28S RNA. In the frog Xenopus laevis the genes which code for 18S and 28S RNA are located in the nucleolar organizer, but these genes are not linked to the 5S RNA genes. Therefore the synthesis of the three ribosomal RNAs provides a model system for studying interchromosomal aspects of gene regulation. In order to determine if the synthesis of the three ribosomal RNAs are interdependent, the relative rate of 5S RNA synthesis was measured in anucleolate mutants (o/o), which do not synthesize any 18S or 28S RNA, and in partial nucleolate mutants (p(l-1)/o), which synthesize 18S and 28S RNA at 25% of the normal rate. Since the o/o and p(l-1)/o mutants have a complete and partial deletion of 18S and 28S RNA genes respectively, but the normal number of 5S RNA genes, they provide a unique system in which to study the dependence of 5S RNA synthesis on the synthesis of 18S and 28S RNA. Total RNA was extracted from embryos labeled during different stages of development and analyzed by polyacrylamide gel electrophoresis. Quite unexpectedly it was found that 5S RNA synthesis in o/o and p(l-1)/o mutants proceeds at the same rate as it does in normal embryos. Furthermore, 5S RNA synthesis is initiated normally at gastrulation in o/o mutants in the complete absence of 18S and 28S RNA synthesis.

Transcriptional organization of the ribosomal RNA cistrons in Escherichia coli

The data presented support the hypothesis that 16S, 23S, and 5S ribosomal RNAs of Escherichia coli are transcribed in vivo from transcriptional units consisting of single cistrons for these species arranged in the order 16S-23S-5S, with transcription beginning at the 16S end.