A mutation in an Escherichia coli ribosomal RNA operon that blocks the production of precursor 23 S ribosomal RNA by RNase III in vivo and in vitro

Multiple functions of the transcribed spacers in ribosomal RNA operons

rRNA operons contain about 25% transcribed spacer sequences in addition to the 16S, 23S, 5S and tRNA genes. The spacer sequences are removed from the primary rRNA transcript by a series of co-ordinated nucleolytic events. Besides the role in rRNA processing, the spacer sequences are also involved in transcription and the ribosome assembly. In this study we analyze the spacer between tRNA and 23S rRNA genes. Based on computer modeling and chemical probing data, a model for the transient secondary structure of the intergenic spacer is proposed. Mutational analysis has shown that the transient secondary structure around the 5' end of 23S rRNA is involved in ribosome assembly. We propose that the transient structure at the 5' end of 23S rRNA directs 23S rRNA folding into the mature structure and facilitates ribosomal large subunit assembly.

Base-pairing of 23 S rRNA ends is essential for ribosomal large subunit assembly

In ribosomal RNA precursors the spacer sequences bracketing mature 16 S and 23 S rRNA are base-paired to form long helices (processing stems). In pre-23 S rRNA, the processing stem is continued by eight base-pairs of mature 23 S rRNA known as helix 1. Recently, we have found that any part of 23 S rRNA between positions 40 and 2773 could be deleted without the loss of ribosome-like particle formation, while both end regions were indispensable. In this paper we have analyzed the role of the 5' and 3' end regions of 23 S rRNA during ribosomal 50 S assembly in vivo by using mutants of the 23 S rRNA gene. Deletions and substitutions in both strands of the helix 1 lead to the loss of plasmid derived 50 S formation. Compensatory mutations restoring helix 1 were assembled into functional 50 S subunits. We conclude that the helix 1 of 23 S rRNA is the main RNA determinant for ribosomal large-subunit assembly. Deletions in both the 5' and 3' strand of the processing stem reduced the ability of the 23 S rRNA to form ribosomal 50 S subunits. However, even the complete removal of either the 5' or the 3' strand of the processing stem did not abolish the 50 S assembly completely. Thus, processing stem facilitates, but is not essential for assembly.

rRNA transcription and growth rate-dependent regulation of ribosome synthesis in Escherichia coli

The synthesis of ribosomal RNA is the rate-limiting step in ribosome synthesis in bacteria. There are multiple mechanisms that determine the rate of rRNA synthesis. Ribosomal RNA promoter sequences have evolved for exceptional strength and for regulation in response to nutritional conditions and amino acid availability. Strength derives in part from an extended RNA polymerase (RNAP) recognition region involving at least two RNAP subunits, in part from activation by a transcription factor and in part from modification of the transcript by a system that prevents premature termination. Regulation derives from at least two mechanistically distinct systems, growth rate-dependent control and stringent control. The mechanisms contributing to rRNA transcription work together and compensate for one another when individual systems are rendered inoperative.

Site-directed mutagenesis of Escherichia coli 23 S ribosomal RNA at position 1067 within the GTP hydrolysis centre

Site-directed mutagenesis has been used to change, specifically, residue 1067 within 23 S ribosomal RNA of Escherichia coli. This nucleoside (adenosine in the wild-type sequence) lies within the GTPase centre of the larger ribosomal subunit and is normally the target for the methylase enzyme responsible for resistance to the antibiotic thiostrepton. The performance of the altered ribosomes was not impaired in cell-free protein synthesis nor in GTP hydrolysis assays (although the 3 mutant strains grew somewhat more slowly than wild-type) but their responses to thiostrepton did vary. Thus, ribosomes containing the A to C or A to U substitution at residue 1067 of 23 S rRNA were highly resistant to the drug, whereas the A to G substitution resulted in much lesser impairment of thiostrepton binding and the ribosomes remained substantially sensitive to the antibiotic. These data reinforce the hypothesis that thiostrepton binds to 23 S rRNA at a site that includes residue A1067. They also exclude any possibility that the insensitivity of eukaryotic ribosomes to the drug might be due solely to the substitution of G at the equivalent position within eukaryotic rRNA.

The 9S RNA precursor of Escherichia coli 5S RNA has three structural domains: implications for processing

The secondary structure of the 9S RNA precursor to ribosomal 5S RNA in Escherichia coli has been determined using chemical reagents and ribonucleases in combination with a reverse transcription procedure. The 9S RNA precursor was generated in vitro by T7 RNA polymerase, and the rrnB operon terminator, T1, was able to terminate the in vitro transcript. The secondary structure model exhibits three structural domains corresponding to a 5' region, a mature region and a terminator region. The mature domain is structurally identical to 5S RNA, and the ribosomal proteins L18 and L25 are able to bind to the precursor. The processing endoribonuclease RNase E cleaves between the structural domains. Moreover, an intramolecular refolding of the nascent transcript must take place if the current view of RNase III processing stems is correct.

Processing of Escherichia coli 16S rRNA with bacteriophage lambda leader sequences

To test whether any specific 5' precursor sequences are required for the processing of pre-16S rRNA, constructs were studied in which large parts of the 5' leader sequence were replaced by the coliphage lambda pL promoter and adjacent sequences. Unexpectedly, few full-length transcripts of the rRNA were detected after the pL promoter was induced, implying that either transcription was poor or most of the rRNA chains with lambda leader sequences were unstable. Nevertheless, sufficient transcription occurred to permit the detection of processing by S1 nuclease analysis. RNA transcripts in which 2/3 of the normal rRNA leader was deleted (from the promoter up to the normal RNase III cleavage site) were processed to form the normal 5' terminus. Thus, most of the double-stranded stem that forms from sequences bracketing wild-type 16S pre-rRNA is apparently not required for proper processing; the expression of such modified transcripts, however, must be increased before the efficiency of processing of the 16S rRNA formed can be assessed.

Effects of deletions in the spacer region of the rrnB operon on the transcription of the large ribosomal RNAs from Escherichia coli

A series of deletions was constructed within the spacer region of the genes for the 16S and 23S RNA on plasmids bearing the rrnB operon. The accumulation and synthesis rates for the 16S and 23S RNAs were determined from normal growing cells and maxicells after transformation with the mutated plasmids. A marked difference in the transcription efficiency of the plasmid-encoded ribosomal 16S and 23S RNAs was observed with cells carrying plasmids, where a sequence motif analogous to the antitermination recognition sequence (Box A) had been deleted. The overall synthesis rate of ribosomal RNAs of such cells was not altered, however, indicating that the difference in transcription rates from the plasmid genes is compensated by altered transcription rates of the corresponding chromosomal genes. In addition, the accumulation of various tRNA species encoded on rRNA operons and non rRNA operons was quantitated and compared. From these results we infer that the regulation of ribosomal RNA transcription does not only occur at the promoter sites but sequence regions possibly involved in antitermination within the operon are crucial for a coordinated synthesis of all ribosomal RNAs.

RNase III stimulates the translation of the cIII gene of bacteriophage lambda

The bacteriophage lambda cIII gene product regulates the lysogenic pathway by stabilizing the lambda cII regulatory protein. Our results show that the expression of the lambda cIII gene is subject to specific requirements. Tests of a set of cIII-lacZ gene and operon fusions reveal that a sequence upstream of the cIII ribosome binding site is needed for cIII translation. The sequence contains an inefficient RNase III processing site. Furthermore, expression of cIII is drastically reduced in cells lacking RNase III. We have isolated a phage carrying a mutation (r1), which lies in the upstream sequence, that leads to a reduction in cIII translation and inactivates the RNase III processing site. The r1 mutant is nevertheless still dependent on RNase III for cIII translation; r1 reduces cIII translation by a factor of 3 in wild-type cells and by a factor of approximately equal to 30 in an RNase III mutant host. We propose that RNase III stimulates cIII translation by binding to the upstream sequence and thereby exposing the cIII ribosome binding site. This stimulation does not involve RNA cleavage. Consistent with this hypothesis is our finding that, in vitro, unprocessed cIII mRNA is translated, whereas RNase III-cleaved cIII mRNA is not.