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.     

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.     

Identification of cis-acting sequences required for translational autoregulation of the ermC methylase.

ermC methylase gene expression has been shown to be limited by translational autorepression, presumably due to methylase binding to ermC mRNA. It was found that this repression occurs in trans, yielding a 50% reduction in translation of an ermC-lacZ fusion mRNA. We investigated the ermC mRNA sequences required for translational repression in vivo. A series of deletions identified sequences in the 5' regulatory region that were required for translational repression. These included sequences of the 5' stem-loop structure that were not required for induction, as well as some that were required. The implications of these results for regulation are discussed.     

Characterization of a plasmid-specified ribosome methylase associated with macrolide resistance.

The ermC gene of plasmid pE194 specifies resistance to the macrolidelincosamide-streptogramin B antibiotics. This resistance, as well as synthesis of the 29,000 dalton protein product of ermC, has been shown to be induced by erythromycin. Weisblum and his colleagues have established that macrolide resistance is associated with a specific dimethylation of adenine in 23 S rRNA. We show that pE194 specifies an RNA methylase that can utilize either 50 S ribosomes or 23 S rRNA as substrates. Synthesis of this methylase is induced by low concentrations of erythromycin, and the enzyme is produced in elevated amounts by strains carrying a high copy number mutant of pE194. The methylase comigrates with the 29K ermC product on polyacrylamide gels. The purification and some properties of this methylase are described.     

Ribosomal RNA methylation in Staphylococcus aureus and Escherichia coli: effect of the "MLS" (erythromycin resistance) methylase

Classical acquired resistance to erythromycin in Staphylococcus aureus ("MLS," or macrolide-lincosamide-streptogramin, resistance) was shown by Weisblum and colleagues to be a direct consequence of the conversion of one or more adenosine residues of 23S rRNA, within the subsequence(s) GA3G, to N6-dimethyladenosine (m62A). The methylation reaction is effected by a class of methylase, whose genes are typically plasmid- or transposon-associated, and whose synthesis is inducible by erythromycin. Using a recently obtained clinical MLS isolate of S. aureus, we have further defined the methylation locus as YGG X m62A X AAGAC; and have shown that this subsequence occurs once in the 23S RNA and that it is essentially completely methylated in all copies of 23S RNA that accumulate in induced cultures. Similar findings were obtained with laboratory S. aureus strains containing two well-characterized evolutionary variants (ermB, ermC) of MLS methylase genes. Analyses of a strain of E. coli containing the ermC gene indicated that the specificity of the methylase gene was unchanged, but that its expression was muted. Even after prolonged periods of induction, the strain manifested only partial resistance to erythromycin, and only about one-third of the copies of the MLS subsequence were methylated in such "induced" cultures. Since the E. coli 23S RNA sequence is known in its entirety, localization of the MLS subsequence is in this case unambiguous; as inferred by homology arguments applied earlier to the S. aureus data, the subsequence is in a highly conserved region of 23S RNA considered to contribute to the peptidyl transferase center of the ribosome.     

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 of the psbA mRNA of Chlamydomonas reinhardtii requires a structured RNA element contained within the 5' untranslated region

Translational regulation is a key modulator of gene expression in chloroplasts of higher plants and algae. Genetic analysis has shown that translation of chloroplast mRNAs requires nuclear-encoded factors that interact with chloroplastic mRNAs in a message-specific manner. Using site-specific mutations of the chloroplastic psbA mRNA, we show that RNA elements contained within the 5' untranslated region of the mRNA are required for translation. One of these elements is a Shine- Dalgarno consensus sequence, which is necessary for ribosome association and psbA translation. A second element required for high levels of psbA translation is located adjacent to and upstream of the Shine-Dalgarno sequence, and maps to the location on the RNA previously identified as the site of message-specific protein binding. This second element appears to act as a translational attenuator that must be overcome to activate translation. Mutations that affect the secondary structure of these RNA elements greatly reduce the level of psbA translation, suggesting that secondary structure of these RNA elements plays a role in psbA translation. These data suggest a mechanism for translational activation of the chloroplast psbA mRNA in which an RNA element containing the ribosome-binding site is bound by message- specific RNA binding proteins allowing for increased ribosome association and translation initiation. These elements may be involved in the light-regulated translation of the psbA mRNA.     

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.