Autogenous regulation of the synthesis of ribosomal proteins, L10 and L7/12, in Escherichia coli

RplI interacts with 5’ UTR of exsA to repress its translation and type III secretion system in Pseudomonas aeruginosa

Pseudomonas aeruginosa is an important opportunistic pathogen capable of causing variety of infections in humans. The type III secretion system (T3SS) is a critical virulence determinant of P. aeruginosa in the host infections. Expression of the T3SS is regulated by ExsA, a master regulator that activates the expression of all known T3SS genes. Expression of the exsA gene is controlled at both transcriptional and posttranscriptional levels. Here, we screened a P. aeruginosa transposon (Tn5) insertional mutant library and found rplI, a gene coding for the ribosomal large subunit protein L9, to be a repressor for the T3SS gene expression. Combining real-time quantitative PCR (qPCR), western blotting and lacZ fusion assays, we show that RplI controls the expression of exsA at the posttranscriptional level. Further genetic experiments demonstrated that RplI mediated control of the exsA translation involves 5’ untranslated region (5’ UTR). A ribosome immunoprecipitation assay and qPCR revealed higher amounts of a 24 nt fragment from exsA mRNA being associated with ribosomes in the ΔrplI mutant. An interaction between RplI and exsA mRNA harboring its 24 nt, but not 12 nt, 5’ UTR was confirmed by RNA Gel Mobility Shift and Microscale Thermophoresis assays. Overall, this study identifies the ribosomal large subunit protein L9 as a novel T3SS repressor that inhibits ExsA translation in P. aeruginosa.

Ribosomes provide all living organisms the capacity to synthesize proteins. The production of many ribosomal proteins is often controlled by an autoregulatory feedback mechanism. P. aeruginosa is an opportunistic human pathogen and its type III secretion system (T3SS) is a critical virulence determinant in host infections. In this study, by screening a Tn5 mutant library, we identified rplI, encoding ribosomal large subunit protein L9, as a novel repressor for the T3SS. Further exploring the regulatory mechanism, we found that the RplI protein interacts with the 5’ UTR (5’ untranslated region) of exsA, a gene coding for transcriptional activator of the T3SS. Such an interaction likely blocks ribosome loading on the exsA 5’ UTR, inhibiting the initiation of exsA translation. The significance of this work is in the identification of a novel repressor for the T3SS and elucidation of its molecular mechanism. Furthermore, this work provides evidence for individual ribosomal protein regulating mRNA translation beyond its autogenous feedback control.

Journey of a Molecular Biologist

My journey into a research career began in fermentation biochemistry in an applied science department during the difficult post-World War II time in Japan. Subsequently, my desire to do research in basic science developed. I was fortunate to be a postdoctoral fellow in the United States during the early days of molecular biology. From 1957 to 1960, I worked with three pioneers of molecular biology, Sol Spiegelman, James Watson, and Seymour Benzer. These experiences helped me develop into a basic research scientist. My initial research projects at Osaka University, and subsequently at the University of Wisconsin, Madison, were on the mode of action of colicins as well as on mRNA and ribosomes. Following success in the reconstitution of ribosomal subunits, my efforts focused more on ribosomes, initially on the aspects of structure, function, and in vitro assembly, such as the construction of the 30S subunit assembly map. After this, my laboratory studied the regulation of the synthesis of ribosomes and ribosomal components in Escherichia coli. Our achievements included the discovery of translational feedback regulation of ribosomal protein synthesis and the identification of several repressor ribosomal proteins used in this regulation. In 1984, I moved to the University of California, Irvine, and initiated research on rRNA transcription by RNA polymerase I in the yeast Saccharomyces cerevisiae. The use of yeast genetics combined with biochemistry allowed us to identify genes uniquely involved in rRNA synthesis and to elucidate the mechanism of initiation of transcription. This essay is a reflection on my life as a research scientist.

Role of ribosomal protein L12 in gonococcal invasion of Hec1B cells

Previous studies led to the development of a model of contact-induced enhanced gonococcal invasion of human reproductive cells that utilizes the lutropin receptor (LHr) as both the induction signal for conversion to this enhanced-gonococcal-invasion phenotype (Inv(+) GC) and as the specific Inv(+) GC uptake mechanism. This model proposes that gonococci express a surface feature that mimics human chorionic gonadotropin (hCG), the cognate ligand for LHr, and that this structure is responsible for the specific and productive interaction of GC with LHr. In this report, we identify a 13-kDa gonococcal protein with immunological similarities to hCG. The antiserum reactivity is specific since interaction with the 13-kDa gonococcal protein can be blocked by the addition of highly purified hCG. This gonococcal "hCG-like" protein, purified from two-dimensional gels and by immunoprecipitation, was determined by N-terminal sequencing to be the ribosomal protein L12. We present evidence that gonococcal L12 is membrane associated and surface exposed in gonococci, as shown by immunoblot analysis of soluble and insoluble gonococcal protein and antibody adsorption studies with fixed GC. Using highly purified recombinant gonococcal L12, we show that preincubation of Inv(-) GC with micromolar amounts of rL12 leads to a subsequent five- to eightfold increase in invasion of the human endometrial cell line, Hec1B. In addition, nanomolar concentrations of exogenous L12 inhibits gonococcal invasion to approximately 70% of the level in controls. Thus, we propose a novel cellular location for the gonococcal ribosomal protein L12 and concomitant function in LHr-mediated gonococcal invasion of human reproductive cells.

Long-range translational coupling in the rplJL-rpoBC operon of Escherichia coli

In Escherichia coli the genes encoding ribosomal proteins L10 and L7/L12, rplJ and rplL, are cotranscribed, and translation of both cistrons is regulated by binding of L10 or a complex of L10 and L7/L12 to a single target in the mRNA leader region. Co-ordinated regulation is assured by some kind of translational coupling, the mechanism of which was investigated here by deletion analysis of plasmids carrying either the intact rplL gene or rplL-lacZ gene fusions. Unless the rplL ribosome binding site was modified by deletion, efficient initiation of translation required translation of a region located more than 500 nucleotides upstream on the transcript within the rplJ cistron. It is proposed that the wild-type rplL ribosome binding site is blocked by long-range RNA base-pairing to this region, when translation of the rplJ sequence is inhibited.

Effects of induction of rRNA overproduction on ribosomal protein synthesis and ribosome subunit assembly in Escherichia coli

Overproduction of rRNA was artificially induced in Escherichia coli cells to test whether the synthesis of ribosomal protein (r-protein) is normally repressed by feedback regulation. When rRNA was overproduced more than twofold from a hybrid plasmid carrying the rrnB operon fused to the lambda pL promoter (pL-rrnB), synthesis of individual r-proteins increased by an average of about 60%. This demonstrates that the synthesis of r-proteins is repressed under normal conditions. The increase of r-protein production, however, for unknown reasons, was not as great as the increase in rRNA synthesis and resulted in an imbalance between the amounts of rRNA and r-protein synthesis. Therefore, only a small (less than 20%) increase in the synthesis of complete 30S and 50S ribosome subunits was detected, and a considerable fraction of the excess rRNA was degraded. Lack of complete cooperativity in the assembly of ribosome subunits in vivo is discussed as a possible explanation for the absence of a large stimulation of ribosome synthesis observed under these conditions. In addition to the induction of intact rRNA overproduction from the pL-rrnB operon, the effects of unbalanced overproduction of each of the two large rRNAs, 16S rRNA and 23S rRNA, on r-protein synthesis were examined using pL-rrnB derivatives carrying a large deletion in either the 23S rRNA gene or the 16S rRNA gene. Operon-specific derepression after 23S or 16S rRNA overproduction correlated with the overproduction of rRNA containing the target site for the operon-specific repressor r-protein. These results are discussed to explain the apparent coupling of the assembly of one ribosomal subunit with that of the other which was observed in earlier studies on conditionally lethal mutants with defects in ribosome assembly.

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.

Mutational alterations of translational coupling in the L11 ribosomal protein operon of Escherichia coli

The L11 operon in Escherichia coli consists of the genes coding for ribosomal proteins L11 and L1. It is known that translation of L1 does not take place unless the preceding L11 cistron is translated, that is, the two cistrons are translationally coupled, and this is the basis of coregulation of the translation of the two cistrons by a single repressor, L1. Several mutational analyses were carried out to define the region responsible for coupling L1 translation with L11 translation. First, by introducing several amber mutations into the L11 gene by a site-directed mutagenesis technique, it was shown that translation by ribosomes down to a position 21 nucleotides upstream, but not to a position 45 nucleotides upstream, from the end of the L11 cistron allowed the initiation of L11 translation. Second, deletion analysis indicated that a region located 23 to 20 nucleotides from the end of the L11 gene was involved in preventing independent initiation from L1 translation. Third, five different mutations obtained by screening for activation of the masked L1 initiation site were found to be clustered in a small region immediately upstream from the Shine-Dalgarno sequence of L1, and all of them were G-to-A transitions. These results, together with some additional experiments with oligonucleotide-directed mutagenesis, defined the region involved in the coupling and suggest that some special feature of this region, probably different from simple masking of the initiation site by base pairing, is responsible for translational coupling. The present results also suggest that there might be specific differences in the primary nucleotide sequence that distinguish independent translational initiation sites from translationally coupled (i.e., masked) initiation sites.

Chemical and functional characterization of an altered form of ribosomal protein S4 derived from a strain of E. coli defective in auto-regulation of the alpha operon

We have isolated a mutant form of Escherichia coli ribosomal protein S4. This mutant is temperature sensitive and apparently fails to autogenously regulate the gene products of the alpha operon, which consists of the genes for proteins S13, S11, S4, L17, and the alpha subunit of RNA polymerase (1). We have shown that this mutation results in the production of an S4 protein with a molecular weight approximately 4,000 daltons less than the wild-type protein. Our chemical analyses demonstrate that the mutant protein is missing its C-terminal section consisting of residues 170-203. However, our studies to determine the capacity of this mutant protein to bind 16S RNA show that this protein is unimpaired in RNA binding function. This observation suggests that the functional domain of protein S4 responsible for translational regulation of the S4 gene products requires more of the protein than the 16S RNA binding domain.

Prokaryotic gene expression in vitro: transcription-translation coupled systems

Transcription-translation coupled systems have been developed to study prokaryotic gene expression. Several types of expression system have been described. The original system consists of a crude unfractionated Escherichia coli extract, which supports protein synthesis directed by a template DNA. Control of gene expression at the transcriptional stage has been studied using this unfractionated system. In this respect, two examples of particular interest, lactose and tryptophan operons, are described. Other systems are either partially reconstituted or highly defined, containing up to 30 purified factors necessary for transcription (RNA polymerase) and translation (aminoacyl-tRNA synthetases, initiation, elongation and release factors). Additional differences between the various systems relate to the analysis of the gene products. Whereas most methods involve analysis of the totally synthesized protein, a particular system implies the formation of only the N-terminal di- or tripeptide of the gene product. Reconstituted systems have proved useful in studies on transcriptional, e.g., discovery and role of L factor, as well as translational regulation of gene expression, e.g., autogenous control of ribosomal protein synthesis.

Growth rate-dependent regulation of RNA polymerase synthesis in Escherichia coli

The rate of synthesis of the beta and beta' subunits of RNA polymerase relative to the rate of synthesis of total protein was found to remain constant with increasing steady state growth rate. This is in contrast to the relative synthesis rates of ribosomal proteins which are known to increase with growth rate. Yet the ratio of the rate of transcription of the ribosomal protein (rplJL) and RNA polymerase (rpoBC) domains of the rplKAJLrpoBC gene cluster was found to be invariant. Fusions to lacZ were used to relate the rate of transcription of the rplKAJL genes to the rate of synthesis of total protein. No change was seen at growth rates above 0.8 doublings per hour. This indicates that the growth rate-dependent expression of these ribosomal proteins is regulated at the post-transcriptional level. However because both the relative rate of transcription of rpoBC and rate of synthesis of beta and beta' were found to remain invariant over this growth range it suggests the expression of these RNA polymerase subunits is regulated at the transcriptional level.

An in vitro system to measure gene expression based on dipeptide synthesis

A simplified E. coli in vitro system has been developed to study gene expression based on the synthesis of the first di- or tripeptide of the gene product. Plasmids containing bacterial and chloroplast genes have been used as templates in this system. The expression of the E. coli L10 operon, which is under both transcriptional and translational control, has been investigated in some detail using the dipeptide system. A similar system has been developed, using eukaryotic translation components, to measure the expression of eukaryotic mRNA based on dipeptide formation.

Nucleotide sequence of the gene for Escherichia coli ribosomal protein S15 (rpsO)

The nucleotide sequence of the ribosomal protein gene rpsO (S15) and its flanking region were determined. The amino acid sequence of S15 protein deduced from the nucleotide sequence is in good agreement with the published amino acid sequence with one exception. The nucleotide sequence shows two probable promoter sites about 100 nucleotides upstream from the initiation codon (AUG) of rpsO. Inspection of the sequence also revealed structural homology between the distal part of rpsO and the reported S15 binding region in 16S rRNA.

Unbalanced ribosomal protein synthesis in a strain of Escherichia coli containing a cloned, truncated 16-S ribosomal RNA gene

An Escherichia coli K12 strain, carrying the promotor and proximal portion of the 16-S rRNA gene from rrnB cloned in the high-copy-number plasmid psF2124, has been examined for abnormalities in ribosome biogenesis. Both ribosomal RNA accumulation and ribosome content are depressed in this strain as compared to the control strain carrying the plasmid vector alone. The rate of total protein synthesis, however, appears to be normal. In contrast, the rate of ribosomal protein synthesis, relative to total protein synthesis, is elevated. The rates of synthesis of individual ribosomal proteins were determined and found to vary greatly, ranging from severe under-synthesis (displayed especially by proteins L7/L12) to massive over-synthesis (displayed particularly in the case of protein S7). Analysis of the rates of synthesis of other proteins coded for by the S12 operon revealed that protein S12 was moderately over-produced, but elongation factors EF-G and EF-Tu appear to be synthesized at the same rate as EF-Ts, all three being moderately under-synthesized relative to total soluble proteins.

Mutations in the rpIJ leader of Escherichia coli that abolish feedback regulation

We have isolated mutants that fail to exhibit biosynthetic feedback regulation of a rpIJ-lacZ fusion. Analysis of these mutants and of others that were isolated earlier indicates that crucial sequences for both translational feedback regulation and efficient translation lie closely intermingled in the central region of the rpIJ mRNA leader 70-195 bases upstream from the translation start of rpIJ. We suggest that our point mutations define a region of the rpIJ leader mRNA to which L10 binds in effecting autogenous translational regulation.

Cloning of rpsO, the gene for ribosomal protein S15 of Escherichia coli

The gene for Escherichia coli ribosomal protein S15 (rpsO) was cloned on the vector pBR322 from F-prime JCH55 DNA. The recombinant plasmid was transformed to Serratia marcescens cells and it was proved that E. coli S15 was synthesized and incorporated into ribosome particles in S. marcescens cells. A DNA fragment containing rpsO was also inserted into the vector pRF3, which changes its copy number depending on the growth temperature in a temperature-sensitive polA host. By use of this recombinant plasmid it was shown that the relative synthesis rate of S15 increased about twice even when the copy number of the plasmid increased more than twenty-fold.

Ribosomal protein S4 acts in trans as a translational repressor to regulate expression of the alpha operon in Escherichia coli

Ribosomal protein (r-protein) S4 is the translational repressor which regulates the synthesis rates of r-proteins whose genes are in the alpha operon: r-proteins S13, S11, S4, and L17. In a strain having a mutation in the gene for r-protein S4 (rpsD), the mutant S4 fails to regulate expression of the alpha operon, resulting in specific and significant overproduction of r-proteins S13, S11, and S4. This confirms and extends similar observations made with rpsD mutants (M. O. Olsson and L. A. Isaksson, Mol. Gen. Genet. 169:271-278, 1979) before post-transcriptional regulation of r-protein synthesis was proposed and is consistent with the established regulatory role of r-protein S4. The rpsD mutant has been used to study the question of whether regulatory r-proteins function in trans or strictly in cis as translational repressors. The mutant strain was lysogenized with one or two specialized transducing phages carrying a wild-type S4 gene to obtain strains which were diploid or triploid with respect to the alpha operon. The wild-type and mutant forms of S4 were separated by two-dimensional polyacrylamide gel electrophoresis, which allowed accurate measurement of the relative contributions of r-proteins from different alpha operons within a single cell. We found that expression of r-proteins from the chromosomal alpha operon containing the rpsD allele was reduced when the wild-type S4 was present, with the effect being greater in the triploid strain than in the diploid strain. We conclude that the wild-type S4 acts in trans as a translational repressor to regulate expression from the chromosomal alpha operon.

Expression of the gene for Escherichia coli initiation factor IE-3 in vivo and in vitro

Expression of protein synthesis initiation factor IF-3 in vivo was studied by measuring its level in exponentially growing cells as a function of gene dosage. A strain haploid for infC, the gene for IF-3, was modified to carry one or two additional infC genes giving diploid and triploid strains. Polyploid strains were achieved by the presence of multicopy plasmids expressing the infC gene. When IF-3 levels were measured by quantitative immunoblotting they were found to be proportional to the gene dosage; the presence of a multicopy plasmid thus causes considerable overproduction of IF-3, enabling large quantities to be purified. When lysates were prepared from freshly grown cells, only IF-3 alpha (the long form) was detected; however when IF-3 was purified from a strain containing a multicopy plasmid which overproduced it, the major product found was IF-3 beta (the short form, lacking six amino acids from the N terminus). The synthesis of the two IF-3 forms was also studied by using a cell-free coupled transcription-translation system dependent on exogenous DNA: the IF-3 gene was found to be very efficiently expressed. IF-3 alpha increased more rapidly than IF-3 beta but following the cessation of protein synthesis IF-3 alpha decreased while IF-3 beta still increased. The results suggest that IF-3 alpha is slowly degraded to the beta form. Addition of non-radioactive IF-3 alpha, up to fivefold molar excess over ribosomes, to the synthesizing system in vitro did not inhibit IF-3 synthesis. Synthesis of IF-3 in vitro appears to be sensitive to guanosine 3'-diphosphate 5'-diphosphate.

Nucleotide sequence at the end of the gene for the RNA polymerase beta' subunit (rpoC)

We have determined the DNA sequence surrounding the transcription terminator following rpoC, the gene that codes for the beta' subunit of RNA polymerase in E. coli K12. The 2044 bp sequence obtained contains the distal 335 codons of rpoC followed by a 212 bp non-coding region and a second open reading frame (ORFa) of 179 codons. The final 181 nucleotides of the sequence form the 5' end of a third open reading frame (ORFb). The in vivo 3' end of the rpoC mRNA was located by analysis of RNA/DNA hybrids cleaved with nuclease S1 (S1 mapping). These results indicated that the major transcription termination of the rplJL-rpoBC transcription unit occurs a short distance past the translation stop codon for rpoC. Four regions of symmetry, suggesting secondary structure in the mRNA, were found in the DNA sequence near the rpoC translation termination codon. The last of these hairpin structures is similar to other rho-independent transcription terminators and its 3' end coincides with the end of the rpoC mRNA as predicted by S1-mapping. Inspection of the open reading frames indicates that rpoC uses a high percentage of codons that are recognized by the major tRNA species of E. coli while ORFa and ORFb contain many codons recognized by minor tRNA species. ORFa specifies a very basic peptide.

In vivo synthesis of a polycistronic messenger RNA for the ribosomal proteins L11, L1, L10 and L7/12 in Escherichia coli

Sucrose density gradient centrifugation and DNA/RNA hybridization have been used to analyse the mRNA synthesized from the ribosomal protein - RNA polymerase subunits gene cluster rplKAJL-rpoBC in Escherichia coli. DNA/RNA hybrids obtained from total E. coli RNA and specific DNA restriction fragments from this chromosomal area were further subjected to endonuclease S1 digestion. This analysis permits the mapping of the ends of mRNA molecules for specific genes or operons by sizing the S1 resistant hybrids. Our results show that the predominant mRNA synthesized under conditions of balanced growth from the rplKAJL-rpoBC region codes for the four ribosomal proteins L11, L1, L10 and L7/12. This tetracistronic mRNA puts the transcription of the following rpoBC genes under the main control of the L11 promoter. Smaller distinct mRNA species could also be detected by this technique. They originate from intercistronic transcription termination and re-initiation as well as from processing of the larger polycistronic mRNA.

Regulation of the S10 ribosomal protein operon in E. coli: nucleotide sequence at the start of the operon

We have determined the DNA sequence of a 1250 base pair segment of the Escherichia coli chromosome that carries the promoter for the S10 ribosomal protein operon, the S10 gene and part of the L3 gene. A DNA fragment carrying the putative S10 promoter was cloned into the plasmid mini-Col E1, which contains a transcription termination signal close to the single Hind II site. Cells harboring the hybrid plasmid produced a relatively stable hybrid mRNA with the expected sequence, demonstrating that the promoter functions in vivo. Comparison of the mRNA sequence around the start of the S10 coding region, the presumed target site for L4 repressor protein, with the known binding site for L4 on 23S rRNA revealed the presence of sequence homologies. This supports the model of the translational feedback regulation of the S10 operon by L4.

Transcriptional and post-transcriptional control of ribosomal protein and ribonucleic acid polymerase genes

A partial restriction of ribonucleic acid (RNA) polymerase activity has been used to dissociate the coordinate synthesis of ribosomal proteins and subunits of RNA polymerase and to identify transcriptional and post-transcriptional control signals which regulate the expression of these component genes. Within the beta operon [which has the genetic organization: promoter (p beta), rplJ (L10), r;lL (L7/L12), attenuator, rpoB (beta), rpoC (beta'), terminator], the restriction caused a disproportionate increase between proximal and distal gene transcriptions; the transcriptional intensities of the proximal ribosomal protein genes and the distal RNA polymerase genes were elevated about two- and fourfold, respectively. Transcription within the operon containing four ribosomal protein genes and the RNA polymerase alpha gene was also enhanced, whereas transcription within operons containing only ribosomal protein genes was virtually unaffected by the restriction. It was thus concluded that the mechanisms controlling transcription initiation or attenuation or both in operons containing RNA polymerase subunit genes are coupled to the global rate of RNA synthesis. By introducing the composite ColE1 plasmid pJC701 carrying the proximal portion of the L10 operon, including the beta subunit gene, it was possible to achieve a 10- and a 30-fold range in the transcriptional intensities of the genes specifying L10 and L7/L12 and beta, respectively. Under these conditions, the relative synthesis rates of L7/L12 and beta protein varied by less than 2-fold and by about 15-fold, respectively. These observations corroborate the existence of a post-transcriptional mechanism which severely restricts translation of excess L7/L12 and L10 ribosomal protein messenger RNA; this mechanism is probably important in maintaining the balanced synthesis of ribosome components under conditions in which their messenger RNA levels are dissociated. Furthermore, the observed reduction in the translation efficiency of beta subunit messenger RNA may be related to an inhibitory effect caused by accumulation of RNA polymerase assembly intermediates.

Translational control of ribosomal protein L10 synthesis occurs prior to formation of first peptide bond

A simplified DNA-directed in vitro system has been developed to study the regulation of the synthesis of ribosomal protein L10 by measuring the formation of the first dipeptide, fMet-Ala. The results show that the inhibition of L10 synthesis by L10 (autoregulation) occurs at or prior to the formation of the first peptide bond.

Chemistry and biology of E. coli ribosomal protein L12

E. coli ribosomal protein L12, because of its unique features, has been studied in more detail than perhaps any of the other ribosomal proteins. Unlike the other ribosomal proteins that are generally present in stoichiometric amounts, there are four copies of L12 per ribosome, some of which are acetylated on the N-terminal serine. The acetylated species, referred to as L7, has not been shown, as yet, to possess any different biological activity than L12. A specific enzyme that acetylates L12 to form L7, using acetyl-CoA as the acetyl donor, has been purified from E. coli extracts. L12 is also unique in that it does not contain cysteine, tryptophan, histidine, or tyrosine, is very acidic (pI: 4.85) and has a high content of ordered secondary structure (approximately 50%). The protein is normally found in solution as a dimer and also forms a tight complex with ribosomal protein L10. There are three methionine residues in L12, located in the N-terminal region of the protein, one or more of which are essential for biological activity. Oxidation of the methionines to methionine sulfoxide prevents dimer formation and inactivates the protein. The four copies of L12 are located in the crest region(s) of the 50S ribosomal subunit. There is good evidence that the soluble factors, such as IF-2, EF-Tu, EF-G and RF, interact with L12 on the ribosome during the process of protein synthesis. This interaction is essential for the proper functioning of each of the factors and for GTP hydrolysis associated with the individual partial reactions of protein synthesis. The L12 gene is located on an operon that contains the genes for L10 and beta beta' subunits of RNA polymerase at about 88 min on the bacterial chromosome. DNA-directed in vitro systems have been used to study the unique regulation of the expression of these genes. Autogenous regulation, translational control, and transcription attenuation are regulatory mechanisms that function to control the synthesis of these proteins.

Translational regulation by ribosomal protein S8 in Escherichia coli: structural homology between rRNA binding site and feedback target on mRNA

It has been previously shown that ribosomal protein synthesis in Escherichia coli is regulated at the level of translation by certain key ribosomal proteins. In the spc operon, S8 regulates the expression of L5 and some of the subsequent genes, while the first two genes (L14 and L24) are regulated independently. We therefore determined the DNA sequence at the junction of the L24 and L5 genes, which corresponds to the putative feedback target for S8. We show that there is a striking homology between the structure of the mRNA for this region and the known binding site for S8 on 16S rRNA. These results support the theory that the regulation of ribosomal protein synthesis is based on competition between rRNA and mRNA for regulatory ribosomal proteins.

Regulation of ribosomal protein synthesis in an Escherichia coli mutant missing ribosomal protein L1

In an Escherichia coli B strain missing ribosomal protein L1, the synthesis rate of L11 is 50% greater than that of other ribosomal proteins. This finding is in agreement with the previous conclusion that L1 regulates synthesis of itself and L11 and indicates that this regulation is important for maintaining the balanced synthesis of ribosomal proteins under physiological conditions.

Factors modulating transcription and translation in vitro of ribosomal protein S20 and isoleucyl-tRNA synthetase from Escherichia coli

The DNA-dependent protein-synthesizing system developed by Zubay [Zubay, G. (1973) Annu. Rev. Genet. 7, 267--287] was optimized for the transcription and translation of genes from the 0.5-min region of the Escherichia coli chromosome carried by transducing lambda phages. The E. coli gene products synthesized were isoleucyl tRNA synthetase, ribosomal protein S20, dihydrodipicolinic acid reductase and (possibly) the two subunits carbamoyl-phosphate synthetase. Formation of ribosomal protein S20 is specifically stimulated by the addition of 16-S rRNA and not by 5-S or 23-S rRNA. 16-S rRNA increases the rate of S20 synthesis, the final yield of product depends on the duration of persistence of the RNA added. Addition of 16-S rRNA to the separate transcription and translation systems showed that it is the translation of the S20 mRNA which is enhanced. Furthermore, S20 synthesis is stimulated more than fourfold when concomitant synthesis of rRNA occurs from a plasmid carrying an rrn transcriptional unit. The results described are explained in terms of a model which suggests that ribosomal protein S20 feedback inhibits its synthesis at the translational level and that removal of S20 into ribosomal assembly (i.e. binding to 16-S rRNA) releases inhibition. The model postulates a direct link between synthesis of ribosomal RNA and ribosomal protein and between the rates of ribosomal assembly and ribosomal protein synthesis. The stimulatory effect of guanosine 3'-diphosphate 5'-diphosphate on isoleucyl-tRNA synthetase formation and its inhibition of the synthesis of ribosomal protein S20 in vitro occurs at the level of transcription. Its relevance in vivo, however, remains to be demonstrated. Formation of isoleucyl-tRNA synthetase in vitro is not influenced either by the addition of a surplus of purified enzyme nor by the limitation of protein synthesis by the addition of anti-(isoleucyl-tRNA synthetase) serum. There is no evidence, therefore, that isoleucyl-tRNA synthetase is autogenously regulated.

The secondary structure of the protein L1 binding region of ribosomal 23S RNA. Homologies with putative secondary structures of the L11 mRNA and of a region of mitochondrial 16S rRNA

An heterologous complex was formed between E. coli protein L1 and P. vulgaris 23S RNA. We determined the primary structure of the RNA region which remained associated with protein L1 after RNase digestion of this complex. We also identified the loci of this RNA region which are highly susceptible to T1, S1 and Naja oxiana nuclease digestions respectively. By comparison of these results with those previously obtained with the homologous regions of E. coli and B. stearothermophilus 23S RNAs, we postulate a general structure for the protein L1 binding region of bacterial 23S RNA. Both mouse and human mit 16S rRNAs and Xenopus laevis and Tetrahymena 28S rRNAs contain a sequence similar to the E. coli 23s RNS region preceding the L1 binding site. The region of mit 16S rRNA which follows this sequence has a potential secondary structure bearing common features with the L1-associated region of bacterial 23S rRNA. The 5'-end region of the L11 mRNA also has several sequence potential secondary structures displaying striking homologies with the protein L1 binding region of 23S rRNA and this probably explains how protein L1 functions as a translational repressor. One of the L11 mRNA putative structures bears the features common to both the L1-associated region of bacterial 23S rRNA and the corresponding region of mit 16S rRNA.

Escherichia coli ribosomal protein S8 feedback regulates part of spc operon

In Escherichia coli the genes coding for the 52 ribosomal proteins (r-proteins) are organized into a number of transcription units located at various regions on the bacterial genome. The expression of r-protein genes is balanced so that individual r-protein synthesis rates change coordinately in response to changing environmental conditions, and significant amounts of free r-proteins do not exist in the cellular pool. We have suggested a model for the balanced regulation of r-protein gene expression, namely that r-protein synthesis and ribosome assembly are coupled so that r-proteins not incorporated into ribosomes prevent the further translation of r-protein mRNA by a feedback regulatory mechanism. The model was tested in vitro by examining the effect of purified r-proteins on DNA directed r-protein synthesis, and in vivo by examining the effect of overproduction of certain r-proteins on the synthesis rates of other r-proteins. In vitro experiments have revealed that some r-proteins (L1, L4, L10, S4 and S8) can selectively inhibit the synthesis of r-proteins whose genes are in the same operon as their own, and that this specific feedback regulation occurs at the level of translation rather than at the level of transcription of mRNA. Regulatory roles for L1, S4 and L4 have also been established by in vivo experiments. We have studied further the feedback regulatory properties of S8 in vivo and in vitro, and report here that the protein regulates a part of the spc operon.

Feedback regulation of ribosomal protein gene expression in Escherichia coli: structural homology of ribosomal RNA and ribosomal protein MRNA

Certain ribosomal proteins (r proteins) in Escherichia coli, such as S4 and S7, function as feedback repressors in the regulation of r-protein synthesis. These proteins inhibit the translation of their own mRNA. The repressor r proteins so far identified are also known to bind specifically to rRNA at an initial stage in ribosome assembly. We have found structural homology between the S7 binding region on 16S rRNA and a region of the mRNA where S7 acts as a translational repressor. Similarly, there is structural homology between one of the reported S4 binding regions on 16S rRNA and the mRNA target site for S4. The observed homology supports the concept that regulation by repressor r proteins is based on competition between rRNA and mRNA for these proteins and that the same structural features and of the r proteins are used in their interactions with both rRNA and mRNA.