Escherichia coli ribosomal protein L10 is rapidly degraded when synthesized in excess of ribosomal protein L7/L12.

In Escherichia coli the genes encoding ribosomal proteins L10 and L7/12, rplJ and rplL, respectively, are cotranscribed and subject to translational coupling. Synthesis of both proteins is coordinately regulated at the translational level by binding of L10 or a complex of L10 and L7/L12 to a single target in the mRNA leader region upstream of rplJ. Unexpectedly, small deletions that inactivated the ribosome-binding site of the rplL gene carried on multicopy plasmids exerted a negative effect on expression of the upstream rplJ gene. This effect could be overcome by overproduction of L7/L12 in trans from another plasmid. This apparent stimulation resulted from stabilization of the overproduced L10 protein by L7/L12, presumably because free L10, in contrast to L10 complexed with L7/L12, is subject to rapid proteolytic decay. The contribution of this decay mechanism to the regulation of the rplJL operon is evaluated.     

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.     

RNA secondary structure and translation inhibition: analysis of mutants in the rplJ leader

We have carried out measurements of the stable binding of the ribosomal protein (r-protein) complex L10-L7/L12 to mutant forms of the mRNA leader of the rplJ operon of Escherichia coli. One of the point mutations, base 1548, which lies within the L10-L7/L12-protected region, almost completely abolishes in vitro formation of a stable complex of L10-L7/L12 with rplJ mRNA leader, and a second point mutation, base 1634, strongly reduces it. These observations constitute strong support for the proposition that L10-L7/L12 binds to the rplJ leader in bringing about translational feedback. To account for the action of these and other mutations, and to explain the mechanism of translation feedback inhibition, we suggest a secondary structure model involving alternate forms of the rplJ mRNA leader.     

Autogenous control: ribosomal protein L10-L12 complex binds to the leader sequence of its mRNA

Ribosomal proteins L10 and L12 are encoded in the L10 operon, situated at position 89.5 min on the Escherichia coli genetic map, and are able to regulate their own translation. The two proteins form a L10-L12 complex that is able to bind specifically to the leader sequence of the L10 operon mRNA and prevent translation. We show that the leader sequence: (i) is required for the translation of mRNA into L10 and L12 proteins; and (ii) contains a unique binding site for the inhibitory L10-L12 complex. We suggest that a specific secondary structure of the leader RNA is required for translation. When this structure is perturbed by L10-L12 binding, by deletion, or point mutations, translation is inhibited. The block on the synthesis of L10 and L12 can presumably be removed by the incorporation of the inhibitory L10-L12 complex into assembling 50S ribosome subunits. We observed that rRNA prevents the binding of L10-L12 to the mRNA. Furthermore, we have identified extended sequence homologies within the 23S rRNA and L10 leader region RNA. The L10-L12 binding site on the mRNA includes part of the homologous sequences.     

Translational coupling in Bacillus subtilis of a heterologous Bacillus subtilis-Escherichia coli gene fusion.

Translational coupling was demonstrated in a gene fusion in which the promoter and the N-terminal region of the Bacillus subtilis subtilisin (aprA) gene were fused to a promoterless Tn9-derived chloramphenicol acetyltransferase (CAT; EC 2.3.1.28) gene. Expression of this gene fusion results in the production of a native-sized CAT product, whereas the Tn9-derived CAT gene is usually not translated from its own ribosome binding site in B. subtilis (D. S. Goldfarb, R. L. Rodriguez, and R. H. Doi, Proc. Natl. Acad. Sci. USA 79:5886-5890, 1982). A 178-base-pair deletion, which removed part of the signal peptide and the propeptide of the aprA gene and created a translational stop codon 230 base pairs upstream of the CAT gene ribosome binding site, reduced expression of the CAT gene. A BamHI 10-mer linker insertion into this deletion site, which restored the reading frame and simultaneously removed the translation stop codon, restored CAT gene expression. The data indicate that expression of the CAT gene was dependent on translation of the truncated aprA gene into the ribosome binding site of the CAT gene.     

Feedback regulation of the rplJL-rpoBC ribosomal protein operon of Escherichia coli requires a region of mRNA secondary structure

The rplJ-rpoBC (L10) operon of Escherichia coli is regulated in part through translational repression (feedback regulation) by ribosomal protein L10 or a complex of ribosomal proteins L10 and L7/L12 (L10-L7/L12). We have constructed mutants in the untranslated leader region of a rplJ-lacZ fusion by oligonucleotide-directed mutagenesis. The mutations include several deletions and a number of single base changes, all of which fail to exhibit normal feedback regulation. Chemical probing of part of the rplJ mRNA leader in the mutagenized region confirms that all of the mutations lie in a stem structure located 140 nucleotides upstream from the translation start-site. The structure includes a 12 base-pair stem, a four base stem-loop, and a six base bulge-loop. Point mutations that abolish feedback regulation are presumed to disrupt this stem structure. Pseudorevertants of selected point mutations were constructed by combining pairs of single base mutations. In these cases, both the secondary structure of the RNA and feedback regulation were restored. The results allow us to define a region of secondary structure in the rplJ mRNA leader that is necessary for feedback regulation.     

A ribosome binding site sequence is necessary for efficient expression of the distal gene of a translationally-coupled gene pair

Expression of trpB and trpA of the Escherichia coli tryptophan operon is shown to be "translationally coupled", i.e., efficient translation of the trpA coding region is dependent on prior translation of the trpB coding region and termination of translation at the trpB stop codon. To examine the dependence of trpA expression on the ribosome binding site sequence in the distal segment of trpB, deletions were produced that replaced this trpB sequence. Analysis of trpA expression in these deletion mutants established that the ribosome binding site sequence is required for efficient translation of the trpA segment of trp mRNA. A modest effect of translation over the trpA ribosome binding site on independent initiation at that site was also observed.     

Primary structures of mutationally altered ribosomal protein L7/L12 and their effects on cellular growth and translational accuracy

The amino acid sequences of mutationally altered ribosomal protein L7/L12 from four different rplL mutants of Escherichia coli were determined and correlated with some features of the mutant ribosomes. Two of the rplL mutations are deletions around position 40, which give rise to a shortened hinge region between the two domains of L7/L12. The other two mutants harbor point mutations at position 74 (Gly----Asp) or at position 82 (Glu----Lys), which are in or close to an evolutionarily conserved sequence in the C-terminal domain. The two latter mutations are associated with decreased rates of growth and translational elongation. All four mutants show increased nonsense codon read-through in vivo. Ribosomes from one of the deletion mutants show clearly increased missense error rates in vitro.     

Deletion of C-terminal residues of Escherichia coli ribosomal protein L10 causes the loss of binding of one L7/L12 dimer: ribosomes with one L7/L12 dimer are active

Escherichia coli ribosomal protein L10 binds the two L7/L12 dimers and thereby anchors them to the large ribosomal subunit. C-Terminal deletion variants (Delta10, Delta20, and Delta33 amino acids) of ribosomal protein L10 were constructed in order to define the binding sites for the two L7/L12 dimers and then to make and test ribosomal particles that contain only one of the two dimers. None of the deletions interfered with binding of L10 variants to ribosomal core particles. Deletion of 20 or 33 amino acids led to the inability of the proteins to bind both dimers of protein L7/L12. The L10 variant with deletion of 10 amino acids bound one L7/L12 dimer in solution and when reconstituted into ribosomes promoted the binding of only one L7/L12 dimer to the ribosome. The ribosomes that contained a single L7/L12 dimer were homogeneous by gel electrophoresis where they had a mobility between wild-type 50S subunits and cores completely lacking L7/L12. The single-dimer ribosomal particles supported elongation factor G dependent GTP hydrolysis and protein synthesis in vitro with the same activity as that of two-dimer particles. The results suggest that amino acids 145-154 in protein L10 determine the binding site ("internal-site") for one L7/L12 dimer (the one reported here), and residues 155-164 ("C-terminal-site") are involved in the interaction with the second L7/L12 dimer. Homogeneous ribosomal particles containing a single L7/L12 dimer in each of the distinct sites present an ideal system for studying the location, conformation, dynamics, and function of each of the dimers individually.     

Regulation of the inducible chloramphenicol acetyltransferase gene of the Staphylococcus aureus plasmid pUB112.

Analyses of deletion mutants of the gene for chloramphenicol (Cm) acetyltransferase (CAT) carried by the staphylococcal plasmid pUB112 revealed a regulatory region, which is indispensable for Cm-inducible cat gene expression, located 70 bp in front of the CAT-coding sequence. This region consists of a possible ribosome binding site followed by an open reading frame coding for a peptide of nine amino acids and overlaps partially with an inverted repeat capable of forming a stem-loop structure. Deletion of the ribosome binding site and of parts of the open reading frame abolishes inducibility and results in a low-level cat gene expression, if the inverted repeat remains intact. Deletion of the 5' part of the possible stem leads to high-level constitutive CAT synthesis. The inverted repeat, therefore, exhibits negative control on cat gene expression whereas the preceding ribosome binding site is needed to enhance CAT synthesis in the presence of an inducer. These results suggest that translation of a leader peptide is a prerequisite for Cm-induced cat gene expression and that ribosome stalling on cat leader mRNA caused by Cm opens the stem-loop structure thereby releasing its negative effect on CAT synthesis.     

GTPase activation of elongation factors Tu and G on the ribosome

The GTPase activity of elongation factors Tu and G is stimulated by the ribosome. The factor binding site is located on the 50S ribosomal subunit and comprises proteins L7/12, L10, L11, the L11-binding region of 23S rRNA, and the sarcin-ricin loop of 23S rRNA. The role of these ribosomal elements in factor binding, GTPase activation, or functions in tRNA binding and translocation, and their relative contributions, is not known. By comparing ribosomes depleted of L7/12 and reconstituted ribosomes, we show that, for both factors, interactions with L7/12 and with other ribosomal residues contribute about equally and additively to GTPase activation, resulting in an overall 10(7)-fold stimulation. Removal of L7/12 has little effect on factor binding to the ribosome. Effects on other factor-dependent functions, i.e., A-site binding of aminoacyl-tRNA and translocation, are fully explained by the inhibition of GTP hydrolysis. Based on these results, we propose that L7/12 stimulates the GTPase activity of both factors by inducing the catalytically active conformation of the G domain. This effect appears to be augmented by interactions of other structural elements of the large ribosomal subunit with the switch regions of the factors.     

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.     

Monoclonal antibodies to Escherichia coli ribosomal proteins L9 and L10. Effects on ribosome function and localization of L9 on the surface of the 50 S ribosomal subunit

Monoclonal antibodies against Escherichia coli ribosomal proteins L9 and L10 were obtained and their specificity confirmed by Western blot analysis of total ribosomal protein. This was particularly important for the L9 antibody, since the immunizing antigen mixture contained predominantly L11. Each antibody recognized both 70 S ribosomes and 50 S subunits. Affinity-purified antibodies were tested for their effect on in vitro assays of ribosome function. Anti-L10 and anti-L9 inhibited poly(U)-directed polyphenylalanine synthesis almost completely. The antibodies had no effect on subunit association or dissociation and neither antibody inhibited peptidyltransferase activity. Both antibodies inhibited the binding of the ternary complex that consisted of aminoacyl-tRNA, guanylyl beta, gamma-methylenediphosphonate, and elongation factor Tu, and the binding of elongation factor G to the ribosome. The intact antibodies were more potent inhibitors than the Fab fragments. In contrast to the previously established location of L10 at the base of the L7/L12 stalk near the factor-binding site, the site of anti-L9 binding to 50 S subunits was shown by immune electron microscopy to be on the L1 lateral protuberance opposite the L7/L12 stalk as viewed in the quasisymmetric projection. The inhibition of factor binding by both antibodies, although consistent with established properties of L10 in the ribosome, suggests a long range effect on subunit structure that is triggered by the binding of anti-L9.