A conditional lethal mutant of Escherichia coli which affects the processing of ribosomal RNA.

A temperature-sensitive mutant strain was isolated from an RNase III-(rnc) strain of Escherichia coli. At the permissive temperature it behaves like the parental strain, but at the nonpermissive temperature it fails to produce normal levels of 23 S and 5 S rRNA, while instead the 25 S rRNA species becomes very prominent. (The 25 S molecule appears in rnc cells and contains 23 S rRNA sequences). When an rnc+ mutation was introduced to such a strain, or when the rnc mutation was replaced by an rnc+ allele, the strain remained temperature-sensitive. At the permissive temperature such strains synthesized rRNA like any other E. coli strain, but at the nonpermissive temperature they remained unable to synthesize normal levels of 5 S rRNA, and instead a larger molecule was accumulated. The simplest interpretation of theses findings is that the mutant strain contains a temperature-sensitive processing endoribonuclease, RNase E, which normally introduces a cut in the growing rRNA chain somewhere between the 23 S and the 5 S rRNA cistrons. These findings help also to explain the nature and origin of the various rRNA species observed in RNase III- cells and add to our understanding of processing of ribosomal RNA in normal cells of Escherichia coli.     

Functional Escherichia coli 23S rRNAs containing processed and unprocessed intervening sequences from Salmonella typhimurium.

We have introduced the intervening sequence (IVS) from 23S rRNA of the rrnD operon of Salmonella typhimurium into the equivalent position of Escherichia coli 23S rRNA. Salmonella typhimurium 23S rRNA is fragmented due to the RNase III-dependent removal of the approximately 100 nt stem-loop structure that comprises the IVS. In this study, we have found that insertion of the S. typhimurium IVS into E. coli 23S rRNA causes fragmentation of the RNA but does not affect ribosome function. Cells expressing the fragmented 23S rRNA exhibited wild-type growth rates. Fragmented RNA was found in the actively translating polysome pool and did not alter the sedimentation profile of ribosomal subunits, 70S ribosomes or polysomes. Finally, hybrid 23S rRNA carrying the A2058G mutation conferred high level erythromycin resistance indistinguishable from that of intact 23S rRNA carrying this mutation. These observations indicate that the presence of this IVS and its removal are phenotypically silent. As observed in an RNase III-deficient strain, processing of the IVS was not required for the production of functional ribosomes.     

Mini-III, an unusual member of the RNase III family of enzymes, catalyses 23S ribosomal RNA maturation in B. subtilis

The late steps of both 16S and 5S ribosomal RNA maturation in the Gram-positive bacterium Bacillus subtilis have been shown to be catalysed by ribonucleases that are not present in the Gram-negative paradigm, Escherichia coli. Here we present evidence that final maturation of the 5' and 3' extremities of B. subtilis 23S rRNA is also performed by an enzyme that is absent from the Proteobacteria. Mini-III contains an RNase III-like catalytic domain, but curiously lacks the double-stranded RNA binding domain typical of RNase III itself, Dicer, Drosha and other well-known members of this family of enzymes. Cells lacking Mini-III accumulate precursors and alternatively matured forms of 23S rRNA. We show that Mini-III functions much more efficiently on precursor 50S ribosomal subunits than naked pre-23S rRNA in vitro, suggesting that maturation occurs primarily on assembled subunits in vivo. Lastly, we provide a model for how Mini-III recognizes and cleaves double-stranded RNA, despite lacking three of the four RNA binding motifs of RNase III.     

Identification and analysis of the rnc gene for RNase III in Rhodobacter capsulatus.

The large subunit ribosomal RNA of the purple bacterium Rhodobacter capsulatus shows fragmentation into pieces of 14 and 16S, both fragments forming the functional equivalent of intact 23S rRNA. An RNA-processing step removes an extra stem-loop structure from the 23S rRNA [Kordes, E., Jock, S., Fritsch, J., Bosch, F. and Klug, G. (1994) J. Bacteriol., 176, 1121-1127]. Taking advantage of the fragmentation deficient mutant strain Fm65, we used genetic complementation to find the mutated gene responsible for this aberration. It was identified as the Rhodobacter homologue to mc from Escherichia coli encoding endoribonuclease III (RNase III). The predicted protein has 226 amino acids with a molecular weight of 25.5 kDa. It shares high homology with other known RNase III enzymes over the full length. In particular it shows the double-stranded RNA-binding domain (dsRBD) motif essential for binding of dsRNA substrates. The Fm65 mutant has a frame shift mutation resulting in complete loss of the dsRBD rendering the enzyme inactive. The cloned Rhodobacter enzyme can substitute RNase III activity in an RNase III deficient E. coli strain. Contrary to E. coli, the Rhodobacter mc is in one operon together with the lep gene encoding the leader peptidase.     

5S ribosomal RNA is contained within a 25 S ribosomal RNA that accumulates in mutants of Escherichia coli defective in processing of ribosomal RNA.

A temperature-sensitive mutant strain of Escherichia coli defective in two RNA processing enzymes, RNase III and RNase E (rnc. rne), fails to produce normal levels of 23 S and 5 S rRNA at the non-permissive temperature. Instead, a molecule larger than 23 S is produced. This molecule, designated 25 S rRNA, can be processed in vitro to produce p5 rRNA. These findings further our understanding of the overall processing events of ribosomal RNA which take place in the bacterial cell.     

Mini-III, a fourth class of RNase III catalyses maturation of the Bacillus subtilis 23S ribosomal RNA

Ribonuclease III (RNase III) type of enzymes are double-stranded RNA (dsRNA)-specific endoribonucleases that have important roles in RNA maturation and mRNA decay. They are involved in processing precursors of ribosomal RNA (rRNA) in bacteria as well as precursors of short interfering RNAs (siRNAs) and microRNAs (miRNAs) in eukaryotes. RNase III proteins have been grouped in three major classes according to their domain organization. In this issue of Molecular Microbiology, Redko et al. identified a novel class of bacterial RNase III, named Mini-III, consisting only of the RNase III catalytic domain and functioning in the maturation of the 23S rRNA in Bacillus subtilis. Its absence from proteobacteria reveals that this step is mechanistically different from the corresponding step in Escherichia coli. The fact that Mini-III orthologues are present in unicellular photosynthetic eukaryotes and in plants opens new opportunities for functional studies of this type of RNases.     

Expression of a polycistronic messenger RNA involved in antibiotic production in an rnc mutant of Streptomyces coelicolor

RNase III is a double strand specific endoribonuclease that is involved in the regulation of gene expression in bacteria. In Streptomyces coelicolor, an RNase III (rnc) null mutant manifests decreased ability to synthesize antibiotics, suggesting that RNase III globally regulates antibiotic production in that species. As RNase III is involved in the processing of ribosomal RNAs in S. coelicolor and other bacteria, an alternative explanation for the effects of the rnc mutation on antibiotic production would involve the formation of defective ribosomes in the absence of RNase III. Those ribosomes might be unable to translate the long polycistronic messenger RNAs known to be produced by operons containing genes for antibiotic production. To examine this possibility, we have constructed a reporter plasmid whose insert encodes an operon derived from the actinorhodin cluster of S. coelicolor. We show that an rnc null mutant of S. coelicolor is capable of translating the polycistronic message transcribed from the operon. We show further that RNA species with the mobilities expected for mature 16S and 23S ribosomal RNAs are produced in the rnc mutant even though the mutant contains higher levels of the 30S rRNA precursor than the wild-type strain.     

Degradation of ribosomal RNA during starvation: comparison to quality control during steady-state growth and a role for RNase PH

Ribosomal RNAs are generally stable in growing Escherichia coli cells. However, their degradation increases dramatically under conditions that lead to slow cell growth. In addition, incomplete RNA molecules and molecules with defects in processing, folding, or assembly are also eliminated in growing cells in a process termed quality control. Here, we show that there are significant differences between the pathways of ribosomal RNA degradation during glucose starvation and quality control during steady-state growth. In both processes, endonucleolytic cleavage of rRNA in ribosome subunits is an early step, resulting in accumulation of large rRNA fragments when the processive exoribonucleases, RNase II, RNase R, and PNPase are absent. For 23S rRNA, cleavage is in the region of helix 71, but the exact position can differ in the two degradative processes. For 16S rRNA, degradation during starvation begins with shortening of its 3' end in a reaction catalyzed by RNase PH. In the absence of this RNase, there is no 3' end trimming of 16S rRNA and no accumulation of rRNA fragments, and total RNA degradation is greatly reduced. In contrast, the degradation pattern in quality control remains unchanged when RNase PH is absent. During starvation, the exoribonucleases RNase II and RNase R are important for fragment removal, whereas for quality control, RNase R and PNPase are more important. These data highlight the similarities and differences between rRNA degradation during starvation and quality control during steady-state growth and describe a role for RNase PH in the starvation degradative pathway.