Ribosomal ribonucleic acid synthesis in Bacillus subtilis

The mode of biosynthesis of the 16S and 23S ribosomal ribonucleic acids (rRNA) was studied in Bacillus subtilis 168thy(-). Three criteria were used to define the characteristics of the rRNA species: (i) the time required at 37 degrees C to synthesize 16S and 23S rRNA chains de novo in growing cultures; (ii) the degree of reactivity of the 3'-terminal groups of the rRNA molecules with periodate and [carbonyl-(14)C]isonicotinic acid hydrazide; and (iii) the reactivity of the 5'-terminal regions of the rRNA molecules with the bacterial exonuclease purified by Riley (1969). The 16S and 23S chains of B. subtilis were synthesized at rates of 22+/-2 and 21+/-2 nucleotides added/s. The periodate-[(14)C]isonicotinic acid hydrazide and the exonuclease techniques for estimating apparent chain lengths of RNA indicated that the chain length of the 23S rRNA was 1.8 times that of the 16S fraction. The apparent chain lengths of each rRNA species were: 16S rRNA, 1650+/-50 nucleotide residues; 23S rRNA, 3050+/-90 nucleotide residues. It appears that, the 16S and 23S rRNA molecules in B. subtilis are synthesized in the expected manner, by simple polymerization of the final products on independent cistrons.     

The messenger ribonucleic acid content of Bacillus subtilis 168

Bacillus subtilis 168 messenger RNA was determined by DNA-RNA hybridization techniques, with denatured DNA immobilized upon cellulose nitrate membrane filters. The following results were obtained. (1) Cultures of B. subtilis, growing exponentially in enriched glucose-salts medium at 37 degrees , incorporated [5-(3)H]uracil into both ribosomal and messenger RNA fractions without the kinetic delay expected from the presence of the intracellular nucleotide pools. (2) However short the time of labelling with exogenous labelled uracil (down to 7sec.), 32-36% of the rapidly labelled RNA was messenger RNA and 68-64% was an RNA with the hybridization characteristics of ribosomal RNA. Analysis of the apparent nucleotide base composition of total (32)P-labelled rapidly labelled RNA and the two RNA fractions separated by hybridization at a DNA/RNA ratio 5:1 confirmed this finding. Of the rapidly labelled RNA, 31% readily hybridized with DNA at low DNA/RNA ratios and had an apparent base composition like that of the DNA, whereas 69% was hybridized only at low efficiency at low DNA/RNA ratios and had a composition identical with that of ribosomal RNA. (3) In cultures dividing every 48min. at 37 degrees , kinetic analysis of RNA labelled over a 20min. period showed that the average life-time of messenger RNA was 2.7-3.0min. and that its amount was 3.0% of the total RNA. (4) The hybridization of (3)H-labelled randomly labelled RNA with DNA at a DNA/RNA ratio 5:1 showed that 2.9% of the randomly labelled RNA had the characteristics of messenger RNA. (5) Experiments carried out as described by Pigott & Midgley (1968) indicated that hybridization at low DNA/RNA ratios (5:1) effectively accounted for all the messenger RNA in a given specimen. The efficiency coefficient of RNA hybridization lay within the range of 90-95% input, if an excess of DNA sites was offered for RNA binding. (6) These measurements are compared with other results obtained by different methods, and reasons for any major disagreement are suggested.     

Stringent control of ribonucleic acid synthesis in Bacillus subtilis treated with granaticin.

The antibiotic granaticin interferes in Bacillus subtilis with the charging process of tRNALeu causing both the arrest of protein synthesis and bacteriostasis [A. Ogilvie, K. Wiebauer & W. Kersten (1975) Biochem. J. 152, 511-515]. A concomitant inhibition of RNA synthesis is observed. This inhibition was studied with mutant strains of B. subtilis. 2. Granaticin inhibits protein and RNA synthesis in stringently controlled B. subtilis (rel+) to about the same extent. In a relaxed mutant strain (rel-) of B. subtilis, protein synthesis is also inhibited, but the accumulation of RNA continues after the addition of the drug. 3. Chloramphenicol, which is known to abolish the stringent control mechanism, added simultaneously with granaticin, allows the synthesis of RNA to proceed in the stringent strain. 4. Guanosine tetraphosphate (ppGpp) and guanosine pentaphosphate (pppGpp) accumulate in granaticin-treated stringently controlled B. subtilis but not in the rel- mutant. 5. It is concluded that the inhibition of RNA synthesis granaticin can adequately be explained as a stringent response caused by the interference by the drug with leucyl-tRNA synthetase.     

Characterization of Bacillus subtilis mutants temperature-sensitive in the synthesis of ribonucleic acid

Two mutants of Bacillus subtilis temperature-sensitive in RNA synthesis were isolated. One mutation (rna-20) was demonstrated to be an allele of a previously identified gene (Riva et al., 1976). The other mutation (rna-16) identified a different gene and was mapped near aroI. The rna-16 mutation at the permissive temperature affected the spore outgrowth process. Purified RNA polymerase from rna-16 did not show any temperature sensitivity or structural defect.     

The control of ribonucleic acid synthesis in bacteria. Fluctuations in messenger ribonucleic acid synthesis in cultures recovering from amino acid starvation

Changes in the cell content and rate of synthesis of mRNA were studied in auxotrophs of Escherichia coli recovering from a period of amino acid deprivation. Parallel studies were carried out on bacterial strains inhibited with trimethoprim, when glycine and methionine were added to relieve an amino acid deficiency. In the latter case, protein synthesis was still severely inhibited through a lack of N-formylmethionyl-tRNA(fMet) for chain initiation, so that fewer ribosomes were attached to mRNA chains. (1) In RC(str) strains recovering from amino acid starvation, there was a transient oversynthesis of mRNA, but the amounts returned to normal after about a 15-min period of recovery. RC(rel) strains did not show this effect; any extra mRNA accumulated during the previous starvation period was rapidly lost, but no oversynthesis occurred during the resumption of growth. (2) In trimethoprim-inhibited cultures supplemented with glycine and methionine, mRNA was produced at the same rate, relative to stable RNA species, as during normal growth. The evidence implied that decreased rates of ribosome attachment had no effect on the functional or chemical lifetime of the mRNA fraction. This suggests that mRNA stability does not depend on the frequency of translation by ribosomes. (3) Changes in the mRNA contents of trimethoprim-inhibited RC(str) and RC(rel) cultures were noted soon after supplementation with glycine and methionine. These closely followed those observed in cultures recovering from simple amino acid withdrawal.     

In vitro translation of messenger ribonucleic acid from sporulating and nonsporulating strains of Bacillus subtilis.

An Escherichia coli translation system supplemented with ribonucleic acid from sporulating Bacillus subtilis produces unique polypeptides which are missing among translation products of ribonucleic acid from six early sporulation mutants.     

Amino acid chemoreceptors of Bacillus subtilis.

Specificities of chemoreceptors for the 20 common amino acids, toward which Bacillus subtilis shows chemotaxis, were assessed by competition ("jamming") experiments using a modification of the traditional capillary assay, called the "sensitivity capillary assay." Many amino acids were sensed by at least two chemoreceptors. All the highest affinity chemoreceptors for the amino acids were distinct, except glutamate and aspartate, which may share one chemoreceptor, and tyrosine, for which the data could not be collected due to low solubility. The data suggest the hypothesis that each amino acid-chemoreceptor complex binds to a different signaler (from each amino acid-chemoreceptor complex binds to a different signaler (from which signals travel to the flagella to modify behavior appropriately), and that many of the signalers can also bind other attractant-chemoreceptor complexes as antagonists (no signals to flagella).     

Protein synthesis by long-lived messenger ribonucleic acid in bacteria

1. Experiments were performed to investigate two hypotheses about the function of long-lived messenger RNA in bacteria. After RNA synthesis had been stopped by the addition of actinomycin, continuing protein synthesis was used as a measure of persistent messenger RNA. 2. The hypothesis that messenger RNA responsible for the synthesis of membrane protein is exceptionally long-lived was tested in experiments with protoplasts of Bacillus megaterium. However, this messenger RNA proved to be of approximately average stability. 3. The hypothesis that long-lived messenger RNA is responsible for the synthesis of constitutive proteins was tested by comparing the synthesis of penicillinase in an inducible and a constitutive strain of Bacillus licheniformis. After the addition of actinomycin, penicillinase synthesis continued for far longer in the constitutive than in the inducible strain. This difference is attributed to a difference in stability of the penicillinase-messenger RNA in the two strains, which does not extend to all messenger RNA indiscriminately. 4. A model is tentatively proposed to account for the altered stability of messenger RNA in the constitutive mutant.     

Nucleic acid synthesis and ribonucleic acid polymerase specificity in germinating and outgrowing spores of Bacillus subtilis.

Nucleic acid synthesis was studied during germination and outgrowth of normal spores of Bacillus subtilis, as well as of spores carrying the genome of phage phie. In a system in which development was restricted to the spore-darkening phase, synthesis of ribonucleic acid (RNA), but not deoxyribonucleic acid (DNA), was detected. The extent of RNA synthesis and turnover, during this phase was similar for the two types of spores. In a partially darkened population of spores of either type, there was little RNA degradation, whereas there was considerable turnover in a fully darkened population. The DNA-dependent RNA polymerase of dormant or dark spores was not active in vitro with phi DNA as template, although a sigma-like factor could be separated from the polymerizing activity by zone centrifugation. Within 40 min after resuspension of dark spores in a medium that allows outgrowth, the enzyme acquired the ability to transcribe the phage DNA efficiently. During outgrowth, both normal and carrier spores synthesized DNA, but in carrier spores this DNA was almost entirely phage specific. The pattern of RNA accumulation in normal spores was in two distinct phase (0 to 60 min and 90 to 180 min). The second phase was absent in outgrowing carrier spores. The burst of phage in carrier spores occurred at 160 to 180 min.     

Mutant of Bacillus subtilis with a temperature-sensitive lesion in ribonucleic acid synthesis during germination.

We have isolated a mutant of Baccillus subtilis with a temperature-sensitive lesion in the process of spore germination. The temperature-sensitive mutation affects only germination and outgrowth, and the earliest defect observed is an early block of ribonucleic acid synthesis during germination at 46 C. Upon return to 35 C there is a complete repair of the impaired function, even in the absence of protein synthesis. Protein synthesis inhibition during germination of the mutant spores at 46 C has the effect of increasing the amount of ribonucleic acid made. The temperature-sensitive mutation is located near aroI.     

Genetic analysis of ribonucleic acid polymerase mutants of Bacillus subtilis

Deoxyribonucleic acid-dependent ribonucleic acid polymerase mutants of Bacillus subtilis strain Marburg were isolated after mutagenesis of spores with ethyl methane sulfonate. Genetic analysis by PBS1-mediated transduction and by transformation indicated that mutations responsible for all of the four phenotypic classes studied (rifampin resistance, streptovaricin resistance, streptolydigin resistance, and temperature sensitivity) were clustered close to the cysA14 locus. Three-factor transformation analysis has indicated the most probable marker order as follows: Rif(R)(Stv)(R)-Std(R)-Ts(418)-Ts(427). In addition, further characterization of the classical group I reference marker, cysA14, is reported.     

Possible inhibitory effect of teichoic acid on Bacillus subtilis transfer ribonucleic acid

1. tRNA of Bacillus subtilis was found to be variably contaminated with membrane teichoic acid. 2. Samples with high contents of teichoic acid showed no accepting activity for tRNA(Phe) and tRNA(Tyr). 3. Removal of teichoic acid restored accepting activity and fractions containing teichoic acid, separated on Sephadex G-150, inhibited the charging of tRNA(Tyr). 4. The presence of teichoic acid did not inhibit the charging of tRNA(His).