Enhancement of ribosomal ribonucleic acid synthesis by deoxyribonucleic acid gyrase activity in Escherichia coli.

The effect of the deoxyribonucleic acid (DNA) gyrase inhibitors coumermycin A1, novobiocin, and oxolinic acid on ribonucleic acid (RNA) synthesis in Escherichia coli was studied in vivo and in vitro. Preferential inhibition of ribosomal RNA (rRNA) synthesis was observed. No effect of oxolinic acid and coumermycin on rRNA synthesis was seen in mutants having a DNA gyrase which is resistant to these inhibitors. In a temperature-sensitive DNA gyrase mutant rRNA synthesis was decreased at nonpermissive temperatures. Thus, a functional DNA gyrase is required for rRNA synthesis. Purified DNA gyrase had no effect on rRNA synthesis in a purified system. However, DNA gyrase does show preferential stimulation of rRNA synthesis in a system supplemented with other proteins. Apparently, DNA gyrase stimulation of rRNA synthesis requires another protein.     

The mechanism of action of ppGpp on rRNA synthesis in vitro.

We have studied the mechanism of the specific inhibition of ribosomal RNA synthesis by ppGpp in a purified system using as templates E. coli DNA and DNA from lambdad5ilv, which carries a rRNA cistron from E. coli. Ribosomal RNA synthesis, as well as its inhibition by ppGpp, are critically salt-dependent. Of a number of guanosine phosphates tested, only pppGpp (MS II) mimicked the action of ppGpp, establishing the specificity of ppGpp. The two templates gave similar results for rRNA synthesis in all experiments. By using the initiation inhibitor rifampicin, we could show that the specific inhibition of rRNA synthesis by ppGpp is due to its effect on rRNA initiation. The somewhat variable inhibition of RNA synthesis in general by ppGpp is mainly or wholly a consequence of premature chain termination. We propose that ppGpp specifically inhibits rRNA synthesis by acting on the formation of the so-called "closed-promoter complex".     

Specific stimulation of ribosomal RNA synthesis in E. coli by a protein factor

Summary Ribosomal RNA synthesis in a purified system is stimulated by a crude protein fraction prepared from E. coli. The positive effector which is not associated with RNA polymerase, nor is the sigma factor, increases the initiation frequency on a rRNA operon. The additional rRNA synthesis is inhibited by ppGpp to the same extent as the basal one.The evidence presented points to the existence of a positive control element for rRNA synthesis, which activity depends upon the physiological state of the cell.     

Control of ribosomal RNA synthesis in Escherichia coli. III. Cytoplasmic factors for ribosomal RNA synthesis.

The ribosomal RNA synthesis in a cell-free system containing the nucleoids and the cytoplasmic fraction prepared from Escherichia coli cells has been investigated. The addition of the "4S" fraction from the cytoplasm to the isolated nucleoids induces RNA synthesis by a new chain initiation. In this system a preferential initiation or rRNA chains occurs. The experimental results suggest that the 4S fraction contains at least two activities, one for releasing RNA-polymerases from the nucleoids, and another for the frequent initiation of rRNA chains. No restriction of the rRNA synthesis has been observed in the nucleoids and the 4S fraction from the amino acid-starved rel+ cells. The rRNA synthesized in the above system is detected at about 23S and 16S rRNA regions.     

Purification and properties of a new bacillus subtilis RNA processing enzyme. Cleavage of phage SP82 mRNA and Bacillus subtilis precursor rRNA

An RNA processing activity capable of cleaving Bacillus subtilis phage SP82 early mRNA has been purified to apparent homogeneity from crude extracts of uninfected B. subtilis. The enzyme, a functional monomer of Mr approximately 27,000, cleaves only at the 5' side of adenosine residues at processing sites and is competitively inhibited by double-stranded synthetic RNA polymers. Processed SP82 mRNAs were translated in an Escherichia coli cell-free system and no qualitative or quantitative effects of processing on the synthesis of polypeptides was observed. The processing enzyme does not cleave T7 mRNA, E. coli precursor rRNA, or double-stranded poly(AU). A recombinant plasmid containing portions of two B. subtilis rRNA gene sets was transcribed in vitro and the resulting RNA was cleaved in the spacer region between the 16 S and 23 S rRNA genes. The ability of the B. subtilis processing enzyme to cleave SP82 mRNA and B. subtilis precursor rRNA and the fact that the enzyme has high affinity for double-stranded RNA suggest that it is the functional analog of E. coli RNase III.     

Replacement of the L11 binding region within E.coli 23S ribosomal RNA with its homologue from yeast: in vivo and in vitro analysis of hybrid ribosomes altered in the GTPase centre.

Replacement of the protein L11 binding domain within Escherichia coli 23S ribosomal RNA (rRNA) by the equivalent region from yeast 26S rRNA appeared to have no effect on the growth rate of E.coli cells harbouring a plasmid carrying the mutated rrnB operon. The hybrid rRNA was correctly processed and assembled into ribosomes, which accumulated normally in polyribosomes. Of the total ribosomal population, < 25% contained wild-type, chromosomally encoded rRNA; the remainder were mutant. The hybrid ribosomes supported GTP hydrolysis dependent upon E.coli elongation factor G, although at a somewhat reduced rate compared with wild-type particles, and were sensitive to the antibiotic, thiostrepton, a potent inhibitor of ribosomal GTPase activity that binds to 23S rRNA within the L11 binding domain. That thiostrepton could indeed bind to the mutant ribosomes, although at a reduced level relative to that seen with wild-type ribosomes, was confirmed in a non-equilibrium assay. The rationale for the ability of the hybrid ribosomes to bind the antibiotic, given that yeast ribosomes do not, was provided when yeast rRNA was shown by equilibrium dialysis to bind thiostrepton only 10-fold less tightly than did E.coli rRNA. The extreme conservation of secondary, but not primary, structure in this region between E.coli and yeast rRNAs allows the hybrid ribosomes to function competently in protein synthesis and also preserves the interaction with thiostrepton.     

Organization of transfer and ribosomal ribonucleic acid genes in Bacillus subtilis.

The structural relationship between the transfer ribonucleic acid (tRNA) and the ribosomal RNA (rRNA) genes of Bacillus subtilis has been studied by restriction endonuclease analysis of total chromosomal deoxyribonucleic acid (DNA) and characterization of DNA fragments cloned in Escherichia coli. The DNA sequences encoding rRNA and tRNA were assayed by hybridization to radioactive RNA. The results support the conclusion that the tRNA genes are interspersed between and closely linked to the rRNA genes of B. subtilis. They probably do not appear between the 16S and 23S rRNA genes as in E. coli.