Effect of ermC leader region mutations on induced mRNA stability.

Induction of translation of the ermC gene product in Bacillus subtilis occurs upon exposure to erythromycin and is a result of ribosome stalling in the ermC leader peptide coding sequence. Another result of ribosome stalling is stabilization of ermC mRNA. The effect of leader RNA secondary structure, methylase translation, and leader peptide translation on induced ermC mRNA stability was examined by constructing various mutations in the ermC leader region. Analysis of deletion mutations showed that ribosome stalling causes induction of ermC mRNA stability in the absence of methylase translation and ermC leader RNA secondary structure. Furthermore, deletions that removed much of the leader peptide coding sequence had no effect on induced ermC mRNA stability. A leader region mutation was constructed such that ribosome stalling occurred in a position upstream of the natural stall site, resulting in induced mRNA stability without induction of translation. This mutation was used to measure the effect of mRNA stabilization on ermC gene expression.     

Induction of ermC requires translation of the leader peptide.

ermC confers resistance to macrolide-lincosamide streptogramin B antibiotics by specifying a ribosomal RNA methylase, which results in decreased ribosomal affinity for these antibiotics. ermC expression is induced by exposure to erythromycin. We have previously proposed a translational regulation model in which erythromycin causes stalling of a ribosome, which is translating a leader peptide. Stalling causes a conformation shift in the ermC mRNA which in turn unmasks the methylase ribosomal binding site. A prediction of this translational attenuation model for ermC induction was tested by replacing the second codon of the putative ermC leader peptide coding region by TAA. As expected, the introduction of this mutation resulted in an uninducible phenotype which was suppressible by two ochre suppressor mutations in Bacillus subtilis. It is concluded that translation through the leader peptide coding region, in frame with the predicted leader peptide, is required for ermC induction.     

Erythromycin-induced ribosome stalling and RNase J1-mediated mRNA processing in Bacillus subtilis

Addition of erythromycin (Em) to a Bacillus subtilis strain carrying the ermC gene results in ribosome stalling in the ermC leader peptide coding sequence. Using Δ ermC , a deletion derivative of ermC that specifies the 254 nucleotide Δ ermC mRNA, we showed previously that ribosome stalling is concomitant with processing of Δ ermC mRNA, generating a 209 nucleotide RNA whose 5' end maps to codon 5 of the Δ ermC coding sequence. Here we probed for peptidyl-tRNA to show that ribosome stalling occurs after incorporation of the amino acid specified by codon 9. Thus, cleavage upstream of codon 5 is not an example of 'A-site cleavage' that has been reported for Escherichia coli . Analysis of Δ ermC mRNA processing in endoribonuclease mutant strains showed that this processing is RNase J1-dependent. Δ ermC mRNA processing was inhibited by the presence of stable secondary structure at the 5' end, demonstrating 5'-end dependence, and was shown to be a result of RNase J1 endonuclease activity, rather than 5'-to-3' exonuclease activity. Examination of processing in derivatives of Δ ermC that had codons inserted upstream of the ribosome stalling site revealed that Em-induced ribosome stalling can occur considerably further from the start codon than would be expected based on previous studies.     

Translation attenuation regulation of chloramphenicol resistance in bacteria — a review

The chloramphenicol (Cm)-inducible cat and cmlA genes are regulated by translation attenuation, a regulatory device that modulates mRNA translation. In this form of gene regulation, translation of the Cm^R coding sequence is prevented by mRNA secondary structure that sequesters its ribosome-binding site (RBS). A translated leader of nine codons precedes the secondary structure, and induction results when a ribosome becomes stalled at a specific site in the leader. Here we demonstrate that the site of ribosome stalling in the leader is selected by a cis effect of the nascent leader peptide on its translating ribosome.     

Chloramphenicol-induced stabilization of cat messenger RNA in Bacillus subtilis

The expression of the chloramphenicol-inducible chloramphenicol-acetyltransferase gene (cat), encoded on Staphylococcus aureus plasmid pUB112, is regulated via a translational attenuation mechanism. Ribosomes, which are arrested by chloramphenicol during synthesis of a short leader peptide, activate catmRNA translation by opening a 5'-located stem-loop structure, thus setting free the cat ribosome-binding site. We have determined the 5' and 3' ends of catmRNA and analysed its stability in Bacillus subtilis. In the absence of the antibiotic, the half-life of catmRNA is shorter than 0.5 min; it is enhanced to about 8 min by sub-inhibitory concentrations of the drug. No decay intermediates of catmRNA could be detected, indicating a very fast degradation after an initial rate-limiting step. ochre nonsense mutations in the 5' region of the cat structural gene, which eliminate catmRNA translation, did not affect its chloramphenicol-induced stabilization. Mutations in the leader-peptide coding region, which abolish ribosome stalling and, therefore, cat gene induction, also eliminate catmRNA stabilization. We conclude that catmRNA is stabilized on induction by a chloramphenicol-arrested ribosome, which physically protects a nuclease-sensitive target site in the 5' region of catmRNA against exo- or endonucleolytic initiation of degradation. This protection is analogous to ermA and ermC mRNA and seems to reflect a general mechanism for stabilization of mRNA derived from inducible antibiotic resistance genes in B. subtilis.     

ermC leader peptide. Amino acid sequence critical for induction by translational attenuation

The ermC mRNA leader segment, which encodes a 19 amino acid leader peptide, MGIFSIFVISTVHYQPNKK, plays a key role in regulating expression of the ErmC methylase. The contribution of specific leader peptide amino acid residues to induction of ermC was studied using a model system in which the ErmC methylase was translationally fused to Escherichia coli beta-galactosidase as indicator gene. Codons of the ermC leader peptide were altered systematically by replacement of leader DNA segments with double-stranded DNA constructed from chemically synthesized oligonucleotides. Missense mutations that resulted in reduced efficiency of induction involved codons for amino acid residues 5 to 9 (-SIFVI-). Nonsense mutations causing termination of the leader peptide at codons 10 (-S-) or 12 (-V-) remained inducible. These findings suggest that the codons for residues 5 to 9 of the leader peptide comprise the critical region in which ribosomes stall in the presence of erythromycin.     

A variation of the translation attenuation model can explain the inducible regulation of the pBC16 tetracycline resistance gene in Bacillus subtilis

Expression of the tet resistance gene from plasmid pBC16 is induced by the antibiotic tetracycline, and induction is independent of the native promoter for the gene. The nucleotide sequence at the 5' end of the tet mRNA (the leader region) is predicted to assume a complex secondary structure that sequesters the ribosome binding site for the tet gene. A spontaneous, constitutively expressed tet gene variant contains a mutation predicted to provide the tet gene with a nonsequestered ribosome binding site. Lastly, comparable levels of tet mRNA can be demonstrated in tetracycline-induced and uninduced cells. These results are consistent with the idea that the pBC16 tet gene is regulated by translation attenuation, a model originally proposed to explain the inducible regulation of the cat and erm genes in gram-positive bacteria. As with inducible cat and erm genes, the pBC16 tet gene is preceded by a translated leader open reading frame consisting of a consensus ribosome binding site and an ATG initiation codon, followed by 19 sense codons and a stop codon. Mutations that block translation of cat and erm leaders prevent gene expression. In contrast, we show that mutations that block translation of the tet leader result in constitutive expression. We provide evidence that translation of the tet leader peptide coding region blocks tet expression by preventing the formation of a secondary-structure complex that would, in the absence of leader translation, expose the tet ribosome binding site. Tetracycline is proposed to induce tet by blocking or slowing leader translation. The results indicate that tet regulation is a variation of the translation attenuation model.     

Mechanism of erythromycin-induced ermC mRNA stability in Bacillus subtilis.

In Bacillus subtilis, the ermC gene encodes an mRNA that is unusually stable (40-min half-life) in the presence of erythromycin, an inducer of ermC gene expression. A requirement for this induced mRNA stability is a ribosome stalled in the ermC leader region. This property of ermC mRNA was used to study the decay of mRNA in B. subtilis. Using constructs in which the ribosome stall site was internal rather than at the 5' end of the message, we show that ribosome stalling provides stability to sequences downstream but not upstream of the ribosome stall site. Our results indicate that ermC mRNA is degraded by a ribonucleolytic activity that begins at the 5' end and degrades the message in a 5'-to-3' direction.     

Site in the cat-86 regulatory leader that permits amicetin to induce expression of the gene.

Expression of the plasmid gene cat-86 is induced in Bacillus subtilis by two antibiotics, chloramphenicol and the nucleoside antibiotic amicetin. We proposed that induction by either drug causes the destabilization of a stem-loop structure in cat-86 mRNA that sequesters the ribosome-binding site for the cat coding sequence. The destabilization event frees the ribosome-binding site, permitting the initiation of translation of cat-86 mRNA. cat-86 induction is due to the stalling of a ribosome in a leader region of cat-86 mRNA, which is located 5' to the RNA stem-loop structure. A stalled ribosome that is active in cat-86 induction has its aminoacyl site occupied by leader codon 6. To test the hypothesis that a leader site 5' to codon 6 permits a ribosome to stall in the presence of an inducing antibiotic, we inserted an extra codon between leader codons 5 and 6. This insertion blocked induction, which was then restored by the deletion of leader codon 6. Thus, induction seems to require the maintenance of a precise spatial relationship between an upstream leader site(s) and leader codon 6. Mutations in the ribosome-binding site for the cat-86 leader, RBS-2, which decreased its strength of binding to 16S rRNA, prevented induction. In contrast, mutations that significantly altered the sequence of RBS-2 but increased its strength of binding to 16S rRNA did not block induction by either chloramphenicol or amicetin. We therefore suspected that the proposed leader site that permitted drug-mediated stalling was located between RBS-2 and leader codon 6. This region of the cat-86 leader contains an eight-nucleotide sequence (conserved region I) that is largely conserved among all known cat leaders. The codon immediately 5' to conserved region I differs, however, between amicetin-inducible and amicetin-noninducible cat genes. In amicetin-inducible cat genes such as cat-86, the codon 5' to conserved region I is a valine codon, GTG. The same codon in amicetin-noninducible cat genes is a lysine codon, either AAA or AAG. When the GTG codon immediately 5' to conserved region I in cat-86 was changed to AAA, amicetin was no longer active in cat-86 induction, but chloramphenicol induction was unaffected by the mutation. The potential role of the GTG codon in amicetin induction is discussed.     

Four codons in the cat-86 leader define a chloramphenicol-sensitive ribosome stall sequence.

Genes encoding chloramphenicol acetyltransferase in gram-positive bacteria are induced by chloramphenicol. Induction reflects an ability of the drug to stall a ribosome at a specific site in cat leader mRNA. Ribosome stalling at this site alters downstream RNA secondary structure, thereby unmasking the ribosome-binding site for the cat coding sequence. Here, we show that ribosome stalling in the cat-86 leader is a function of leader codons 2 through 5 and that stalling requires these codons to be presented in the correct reading frame. Codons 2 through 5 specify Val-Lys-Thr-Asp. Insertion of a second copy of the stall sequence 5' to the authentic stall sequence diminished cat-86 induction fivefold. Thus, the stall sequence can function in ribosome stalling when the stall sequence is displaced from the downstream RNA secondary structure. We suggest that the stall sequence may function in cat induction at two levels. First, the tetrapeptide specified by the stall sequence likely plays an active role in the induction strategy, on the basis of previously reported genetic suppression studies (W. W. Mulbry, N. P. Ambulos, Jr., and P.S. Lovett, J. Bacteriol. 171:5322-5324, 1989). Second, we show that embedded within the stall sequence of cat leaders is a region which is complementary to a sequence internal in 16S rRNA of Bacillus subtilis. This complementarity may guide a ribosome to the proper position on leader mRNA or potentiate the stalling event, or both. The region of complementarity is absent from Escherichia coli 16S rRNA, and cat genes induce poorly, or not at all, in E. coli.     

Properties of a pentapeptide inhibitor of peptidyltransferase that is essential for cat gene regulation by translation attenuation.

Inducible chloramphenicol resistance genes cat and cmlA are regulated by translation attenuation. For both genes, the leader codons that must be translated to deliver a ribosome to the induction site specify a peptide that inhibits peptidyltransferase in vitro. The antipeptidyltransferase activity of the peptides is thought to select the site of ribosome stalling that is essential for induction. Using variations of the cat-86 leader-encoded 5-mer peptide MVKTD, we demonstrate a correlation between the in vitro antipeptidyltransferase activity and the ability of the same peptide to support induction by chloramphenicol in vivo. MVKTD footprints to nucleotides 2058, 2059, and 2060 in 23S rRNA. In vivo methylation of nucleotide 2058 by the ermC methylase interferes neither with cat-86 induction nor with peptide inhibition of peptidyltransferase. The methylation eliminates the competition that normally occurs in vitro between erythromycin and MVKTD. MVKTD inhibits the peptidyltransferase of several eubacteria, a representative Archaea species, and the eukaryote Saccharomyces cerevisiae. Bacillus stearothermophilus supports the in vivo induction of cat-86, and the RNA that is phenol extracted from the 50S ribosomes of this gram-positive thermophile is catalytically active in the peptidyltransferase assay and sensitive to peptide inhibition. Our results indicate that peptidyltransferase inhibition by a cat leader peptide is essential to induction, and this activity can be altered by minor changes in the amino acid sequence of the peptide. The broad range of organisms shown to possess peptide-inhibitable peptidyltransferase suggests that the target is a highly conserved component of the ribosome and includes 23S rRNA.     

In vivo and in vitro structural analysis of the rplJ mRNA leader of Escherichia coli. Protection by bound L10-L7/L12

The rplJL-rpoBC operon of Escherichia coli is regulated in part at the level of translation by an autogenous mechanism (feedback regulation) that involves ribosomal protein L10-L7/L12. Feedback regulation occurs as the result of L10-L7/L12 binding to a site on the untranslated leader region of the rplJ mRNA that is located more than 100 nucleotides upstream from the translation start site. Previous studies have indicated that the secondary structure of the rplJ leader region is important for efficient translation and feedback regulation. We have done chemical modification experiments to examine the secondary structure of approximately 200 nucleotides of the rplJ leader region, and we propose a secondary structure that is consistent with the experimental data. RNA structure was probed in vitro by treating samples of total cellular RNA with diethyl pyrocarbonate and in vivo by treating log-phase cultures with dimethyl sulfate. Modified bases were detected by primer extension using three different oligonucleotide primers. The proposed structure includes five double-stranded regions designated I to V, separated by single-stranded segments numbered 1 to 5. We have also identified specific nucleotides in the rplJ mRNA leader that are protected by purified L10-L7/L12 from methylation by dimethyl sulfate in vitro. The protected bases are located within a bulge-loop of region IV, a portion of the mRNA that has been shown genetically to be necessary for feedback regulation.