Regulation of alpha operon gene expression in Escherichia coli. A novel form of translational coupling

Extraribosomal Functions of Bacterial Ribosomal Proteins-An Update, 2023

Ribosomal proteins (r-proteins) are abundant, highly conserved, and multifaceted cellular proteins in all domains of life. Most r-proteins have RNA-binding properties and can form protein-protein contacts. Bacterial r-proteins govern the co-transcriptional rRNA folding during ribosome assembly and participate in the formation of the ribosome functional sites, such as the mRNA-binding site, tRNA-binding sites, the peptidyl transferase center, and the protein exit tunnel. In addition to their primary role in a cell as integral components of the protein synthesis machinery, many r-proteins can function beyond the ribosome (the phenomenon known as moonlighting), acting either as individual regulatory proteins or in complexes with various cellular components. The extraribosomal activities of r-proteins have been studied over the decades. In the past decade, our understanding of r-protein functions has advanced significantly due to intensive studies on ribosomes and gene expression mechanisms not only in model bacteria like Escherichia coli or Bacillus subtilis but also in little-explored bacterial species from various phyla. The aim of this review is to update information on the multiple functions of r-proteins in bacteria.

Systematic analysis of the underlying genomic architecture for transcriptional-translational coupling in prokaryotes

Transcriptional-translational coupling is accepted to be a fundamental mechanism of gene expression in prokaryotes and therefore has been analyzed in detail. However, the underlying genomic architecture of the expression machinery has not been well investigated so far. In this study, we established a bioinformatics pipeline to systematically investigated >1800 bacterial genomes for the abundance of transcriptional and translational associated genes clustered in distinct gene cassettes. We identified three highly frequent cassettes containing transcriptional and translational genes, i.e. rplk-nusG (gene cassette 1; in 553 genomes), rpoA-rplQ-rpsD-rpsK-rpsM (gene cassette 2; in 656 genomes) and nusA-infB (gene cassette 3; in 877 genomes). Interestingly, each of the three cassettes harbors a gene (nusG, rpsD and nusA) encoding a protein which links transcription and translation in bacteria. The analyses suggest an enrichment of these cassettes in pathogenic bacterial phyla with >70% for cassette 3 (i.e. Neisseria, Salmonella and Escherichia) and >50% for cassette 1 (i.e. Treponema, Prevotella, Leptospira and Fusobacterium) and cassette 2 (i.e. Helicobacter, Campylobacter, Treponema and Prevotella). These insights form the basis to analyze the transcriptional regulatory mechanisms orchestrating transcriptional-translational coupling and might open novel avenues for future biotechnological approaches.

Coupled Transcription-Translation in Prokaryotes: An Old Couple With New Surprises

Coupled transcription-translation (CTT) is a hallmark of prokaryotic gene expression. CTT occurs when ribosomes associate with and initiate translation of mRNAs whose transcription has not yet concluded, therefore forming "RNAP.mRNA.ribosome" complexes. CTT is a well-documented phenomenon that is involved in important gene regulation processes, such as attenuation and operon polarity. Despite the progress in our understanding of the cellular signals that coordinate CTT, certain aspects of its molecular architecture remain controversial. Additionally, new information on the spatial segregation between the transcriptional and the translational machineries in certain species, and on the capability of certain mRNAs to localize translation-independently, questions the unanimous occurrence of CTT. Furthermore, studies where transcription and translation were artificially uncoupled showed that transcription elongation can proceed in a translation-independent manner. Here, we review studies supporting the occurrence of CTT and findings questioning its extent, as well as discuss mechanisms that may explain both coupling and uncoupling, e.g., chromosome relocation and the involvement of cis- or trans-acting elements, such as small RNAs and RNA-binding proteins. These mechanisms impact RNA localization, stability, and translation. Understanding the two options by which genes can be expressed and their consequences should shed light on a new layer of control of bacterial transcripts fate.

Antimicrobial mechanism of strictinin isomers extracted from the root of Rosa roxburghii Tratt (Ci Li Gen)

ETHNOPHARMACOLOGICAL RELEVANCE

The root of Rosa roxburghii Tratt (Ci Li Gen) is a kind of Chinese ethnomedicine in Gui Zhou province, used for the treatment of abdominal pain, acute bacillary dysentery, gastroenteritis and other diseases in human and livestock.

AIM OF THE STUDY

The aim of this study was to isolate and identify the effective antimicrobial components from the ethyl acetate extract of the Ci Li Gen and to investigate its antimicrobial mechanism afterwards.

MATERIALS AND METHODS

The effective antimicrobial components in the ethyl acetate extract from the Ci Li Gen were isolated by high-performance liquid chromatography (HPLC) and identified by high-resolution mass spectrometry (HRMS) and nuclear magnetic resonance (NMR). The antibacterial activity was evaluated by the minimum inhibition concentration (MIC) measured by microdilution technique. The antibacterial mechanism was investigated by the time-kill curve, sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) combined with NanoLC-ESI-MS/MS, intracellular esterase activity detected by Flow cytometry, and the ultrastructural changes of the Escherichia coli ATCC 25922 observed by scanning electron microscope (SEM).

RESULTS

The effective antimicrobial component (peak 4) was identified as strictinin isomers by HRMS and NMR. The MIC of strictinin isomers against E. coli was 0.125 mg/mL. With respect to the negative control group, the results of SDS-PAGE and NanoLC-ESI-MS/MS showed that the up-regulated proteins of the strictinin isomers treated group were Metal-binding protein ZinT, 30S ribosomal protein S4 and 50S ribosomal protein L4, while the down-regulated protein was hydroperoxide reductase subunit C. Moreover, in the strictinin isomers treated group, the esterase activity in the E. coli cells was reduced and the bacteria E. coli became atrophied, pitted and contorted, and the surface of E. coli was rough and blurred.

CONCLUSIONS

According to the above results, the antimicrobial mechanism of strictinin isomers against E. coli were oxidative stress and protein synthesis disorder, which inhibited the activity of the enzymes required for bacterial growth and metabolism. These findings reflected the pleiotropic effects of strictinin isomers, making it a promising antimicrobial agent for pharmaceutical research.

Pervasive Regulatory Functions of mRNA Structure Revealed by High-Resolution SHAPE Probing

mRNAs can fold into complex structures that regulate gene expression. Resolving such structures de novo has remained challenging and has limited our understanding of the prevalence and functions of mRNA structure. We use SHAPE-MaP experiments in living E. coli cells to derive quantitative, nucleotide-resolution structure models for 194 endogenous transcripts encompassing approximately 400 genes. Individual mRNAs have exceptionally diverse architectures, and most contain well-defined structures. Active translation destabilizes mRNA structure in cells. Nevertheless, mRNA structure remains similar between in-cell and cell-free environments, indicating broad potential for structure-mediated gene regulation. We find that the translation efficiency of endogenous genes is regulated by unfolding kinetics of structures overlapping the ribosome binding site. We discover conserved structured elements in 35% of UTRs, several of which we validate as novel protein binding motifs. RNA structure regulates every gene studied here in a meaningful way, implying that most functional structures remain to be discovered.

Translation efficiency is maintained at elevated temperature in Escherichia coli

Cellular protein levels are dictated by the balance between gene transcription, mRNA translation, and protein degradation, among other factors. Translation requires the interplay of several RNA hybridization processes, which are expected to be temperature-sensitive. We used ribosome profiling to monitor translation in Escherichia coli at 30 °C and to investigate how this changes after 10-20 min of heat shock at 42 °C. Translation efficiencies are robustly maintained after thermal heat shock and after mimicking the heat-shock response transcriptional program at 30 °C by overexpressing the heat shock σ factor encoded by the rpoH gene. We compared translation efficiency, the ratio of ribosome footprint reads to mRNA reads for each gene, to parameters derived from gene sequences. Genes with stable mRNA structures, non-optimal codon use, and those whose gene product is cotranslationally translocated into the inner membrane are generally less highly translated than other genes. Comparison with other published datasets suggests a role for translational elongation in coupling mRNA structures to translation initiation. Genome-wide calculations of the temperature dependence of mRNA structure predict that relatively few mRNAs show a melting transition between 30 and 42 °C, consistent with the observed lack of changes in translation efficiency. We developed a linear model with six parameters that can predict 38% of the variation in translation efficiency between genes, which may be useful in interpreting transcriptome data.

An S6:S18 complex inhibits translation of E. coli rpsF

More than half of the ribosomal protein operons in Escherichia coli are regulated by structures within the mRNA transcripts that interact with specific ribosomal proteins to inhibit further protein expression. This regulation is accomplished using a variety of mechanisms and the RNA structures responsible for regulation are often not conserved across bacterial phyla. A widely conserved mRNA structure preceding the ribosomal protein operon containing rpsF and rpsR (encoding S6 and S18) was recently identified through comparative genomics. Examples of this RNA from both E. coli and Bacillus subtilis were shown to interact in vitro with an S6:S18 complex. In this work, we demonstrate that in E. coli, this RNA structure regulates gene expression in response to the S6:S18 complex. β-galactosidase activity from a lacZ reporter translationally fused to the 5' UTR and first nine codons of E. coli rpsF is reduced fourfold by overexpression of a genomic fragment encoding both S6 and S18 but not by overexpression of either protein individually. Mutations to the mRNA structure, as well as to the RNA-binding site of S18 and the S6-S18 interaction surfaces of S6 and S18, are sufficient to derepress β-galactosidase activity, indicating that the S6:S18 complex is the biologically active effector. Measurement of transcript levels shows that although reporter levels do not change upon protein overexpression, levels of the native transcript are reduced fourfold, suggesting that the mRNA regulator prevents translation and this effect is amplified on the native transcript by other mechanisms.

Most RNAs regulating ribosomal protein biosynthesis in Escherichia coli are narrowly distributed to Gammaproteobacteria

In Escherichia coli, 12 distinct RNA structures within the transcripts encoding ribosomal proteins interact with specific ribosomal proteins to allow autogenous regulation of expression from large multi-gene operons, thus coordinating ribosomal protein biosynthesis across multiple operons. However, these RNA structures are typically not represented in the RNA Families Database or annotated in genomic sequences databases, and their phylogenetic distribution is largely unknown. To investigate the extent to which these RNA structures are conserved across eubacterial phyla, we created multiple sequence alignments representing 10 of these messenger RNA (mRNA) structures in E. coli. We find that while three RNA structures are widely distributed across many phyla of bacteria, seven of the RNAs are narrowly distributed to a few orders of Gammaproteobacteria. To experimentally validate our computational predictions, we biochemically confirmed dual L1-binding sites identified in many Firmicute species. This work reveals that RNA-based regulation of ribosomal protein biosynthesis is used in nearly all eubacterial phyla, but the specific RNA structures that regulate ribosomal protein biosynthesis in E. coli are narrowly distributed. These results highlight the limits of our knowledge regarding ribosomal protein biosynthesis regulation outside of E. coli, and the potential for alternative RNA structures responsible for regulating ribosomal proteins in other eubacteria.

Quantitation of the ribosomal protein autoregulatory network using mass spectrometry

Relative levels of ribosomal proteins were quantified in crude cell lysates using mass spectrometry. A method for quantifying cellular protein levels using macromolecular standards is presented that does not require complex sample separation, identification of high-responding peptides, affinity purification, or postgrowth modifications. Perturbations in ribosomal protein levels by overexpression of individual proteins correlate to known autoregulatory mechanisms and extend the network of ribosomal protein regulation.

Translational coupling of the maize chloroplast atpB and atpE genes

The genes for the beta and epsilon subunits of maize chloroplast ATP synthase are encoded by the organelle genome, are cotranscribed, and have overlapping translation initiation and termination codons. To determine whether the atpB and atpE genes are translationally coupled, they were transformed into Escherichia coli on a multicopy plasmid. Synthesis of full-length beta and epsilon polypeptides demonstrated correct initiation of translation by the bacterial ribosomes. To assay for translational coupling, the promoter-distal atpE gene was fused to lacZ, resulting in the synthesis of an active hybrid beta-galactosidase. A frameshift mutation was introduced into the promoter-proximal atpB gene, and its effect on the transcription and translation of the atpE::lacZ fusion was measured. The mutation resulted in a 1000- to 2000-fold reduction in beta-galactosidase activity, but only a 2-fold decrease in LacZ mRNA synthesis rates or galactoside transacetylase levels. Similar results were obtained when the atpB/atpE::lacZ fusion and the atpB frameshift mutation were introduced into the photosynthetic cyanobacterium Synechocystis sp. PCC6803. We show that >99% of atpE translation depends on successful translation of atpB and, thus, conclude that the two genes are translationally coupled.

Growth phase-dependent expression of the Pseudomonas putida KT2440 transcriptional machinery analysed with a genome-wide DNA microarray

Bacterial transcriptional networks are built on a hierarchy of regulators, on top of which lie the components of the RNA polymerase (in particular the sigma factors) and the global control elements, which play a pivotal role. We have designed a genome-wide oligonucleotide-based DNA microarray for Pseudomonas putida KT2440. In combination with real-time reverse transcription polymerase chain reaction (RT-PCR), we have used it to analyse the expression pattern of the genes encoding the RNA polymerase subunits (the core enzyme and the 24 sigma factors), and various proteins involved in global regulation (Crc, Lrp, Fur, Anr, Fis, CsrA, IHF, HupA, HupB, HupN, BipA and several MvaT-like proteins), during the shift from exponential growth in rich medium into starvation and stress brought about by the entry into stationary phase. Expression of the genes encoding the RNA polymerase core and the vegetative sigma factor decreased in stationary phase, while that of sigma(S) increased. Data obtained for sigma(N), sigma(H), FliA and for the 19 extracytoplasmic function (ECF)-like sigma factors suggested that their mRNA levels change little upon entry into stationary phase. Expression of Crc, BipA, Fis, HupB, HupN and the MvaT-like protein PP3693 decreased in stationary phase, while that of HupA and the MvaT-like protein PP3765 increased significantly. Expression of IHF was indicative of post-transcriptional control. These results provide the first global study of the expression of the transcriptional machinery through the exponential stationary-phase shift in P. putida.

A Small Protein Unique to Bacteria Organizes rRNA Tertiary Structure Over an Extensive Region of the 50S Ribosomal Subunit

A number of small, basic proteins penetrate into the structure of the large subunit of the ribosome. While these proteins presumably aid in the folding of the rRNA, the extent of their contribution to the stability or function of the ribosome is unknown. One of these small, basic proteins is L36, which is highly conserved in Bacteria, but is not present in Archaea or Eucarya. Comparison of ribosome crystal structures shows that the space occupied by L36 in a bacterial ribosome is empty in an archaeal ribosome. To ask what L36 contributes to ribosome stability and function, we have constructed an Escherichia coli strain lacking ribosomal protein L36; cell growth is slowed by 40-50% between 30 degrees C and 42 degrees C. Ribosomes from this deletion strain sediment normally and have a full complement of proteins, other than L36. Chemical protection experiments comparing rRNA from wild-type and L36-deficient ribosomes show the expected increase in reagent accessibility in the immediate vicinity of the L36 binding site, but suggest that a cooperative network of rRNA tertiary interactions has been disrupted along a path extending 60 A deep into the ribosome. These data argue that L36 plays a significant role in organizing 23 S rRNA structure. Perhaps the Archaea and Eucarya have compensated for their lack of L36 by maintaining more stable rRNA tertiary contacts or by adopting alternative protein-RNA interactions elsewhere in the ribosome.

Escherichia coli cells bearing a ribosomal ambiguity mutation in rpsD have a mutator phenotype that correlates with increased mistranslation

Escherichia coli cells bearing certain mutations in rpsD (coding for the 30S ribosomal protein S4) show a ribosomal ambiguity (Ram) phenotype characterized by increased translational error rates. Here we show that spontaneous mutagenesis increases in Ram cells bearing the rpsD14 allele, suggesting that the recently described translational stress-induced mutagenesis pathway is activated in Ram cells.

Translational repression of the Escherichia coli alpha operon mRNA: importance of an mRNA conformational switch and a ternary entrapment complex

Ribosomal protein S4 represses synthesis of the four ribosomal proteins (including itself) in the Escherichia coli alpha operon by binding to a nested pseudoknot structure that spans the ribosome binding site. A model for the repression mechanism previously proposed two unusual features: (i) the mRNA switches between conformations that are "active" or "inactive" in translation, with S4 as an allosteric effector of the inactive form, and (ii) S4 holds the 30 S subunit in an unproductive complex on the mRNA ("entrapment"), in contrast to direct competition between repressor and ribosome binding ("displacement"). These two key points have been experimentally tested. First, it is found that the mRNA pseudoknot exists in an equilibrium between two conformers with different electrophoretic mobilities. S4 selectively binds to one form of the RNA, as predicted for an allosteric effector; binding of ribosomal 30 S subunits is nearly equal in the two forms. Second, we have used S4 labeled at a unique cysteine with either of two fluorophores to characterize its interactions with mRNA and 30 S subunits. Equilibrium experiments detect the formation of a specific ternary complex of S4, mRNA pseudoknot, and 30 S subunits. The existence of this ternary complex is unambiguous evidence for translational repression of the alpha operon by an entrapment mechanism.

The crystal structure of ribosomal protein S4 reveals a two-domain molecule with an extensive RNA-binding surface: one domain shows structural homology to the ETS DNA-binding motif

We report the 1.7 A crystal structure of ribosomal protein S4 from Bacillus stearothermophilus. To facilitate the crystallization, 41 apparently flexible residues at the N-terminus of the protein have been deleted (S4Delta41). S4Delta41 has two domains; domain 1 is completely alpha-helical and domain 2 comprises a five-stranded antiparallel beta-sheet with three alpha-helices packed on one side. Domain 2 is an insertion within domain 1, and it shows significant structural homology to the ETS domain of eukaryotic transcription factors. A phylogenetic analysis of the S4 primary structure shows that the likely RNA interaction surface is predominantly on one side of the protein. The surface is extensive and highly positively charged, and is centered on a distinctive canyon at the domain interface. The latter feature contains two arginines that are totally conserved in all known species of S4 including eukaryotes, and are probably crucial in binding RNA. As has been shown for other ribosomal proteins, mutations within S4 that affect ribosome function appear to disrupt the RNA-binding sites. The structure provides a framework with which to probe the RNA-binding properties of S4 by site-directed mutagenesis.

MvaL1 autoregulates the synthesis of the three ribosomal proteins encoded on the MvaL1 operon of the archaeon Methanococcus vannielii by inhibiting its own translation before or at the formation of the first peptide bond

The control of ribosomal protein synthesis has been investigated extensively in Eukarya and Bacteria. In Archaea, only the regulation of the MvaL1 operon (encoding ribosomal proteins MvaL1, MvaL10 and MvaL12) of Methanococcus vannielii has been studied in some detail. As in Escherichia coil, regulation takes place at the level of translation. MvaL1, the homologue of the regulatory protein L1 encoded by the L11 operon of E. coli, was shown to be an autoregulator of the MvaL1 operon. The regulatory MvaL1 binding site on the mRNA is located about 30 nucleotides downstream of the ATG start codon, a sequence that is not in direct contact with the initiating ribosome. Here, we demonstrate that autoregulation of MvaL1 occurs at or before the formation of the first peptide bond of MvaL1. Specific interaction of purified MvaL1 with both 23S RNA and its own mRNA is confirmed by filter binding studies. In vivo expression experiments reveal that translation of the distal MvaL10 and MvaL12 cistrons is coupled to that of the MvaL1 cistron. A mRNA secondary structure resembling a canonical L10 binding site and preliminary in vitro regulation experiments had suggested a co-regulatory function of MvaL10, the homologue of the regulatory protein L10 of the beta-operon of E. coil. However, we show that MvaL10 does not have a regulatory function.

Effects of Mg2+, K+, and H+ on an equilibrium between alternative conformations of an RNA pseudoknot

A complex pseudoknot structure surrounds the first ribosome initiation site in the Escherichia coli alpha mRNA and mediates its regulation by ribosomal protein S4. A 112 nt RNA fragment containing this pseudoknot exists in two conformations that are resolvable by gel electrophoresis below room temperature. Between 30 degrees C and 45 degrees C the conformers reach thermodynamic equilibrium on a time scale ranging from one hour to one minute, and the interconversion between conformers is linked to H+, K+ and Mg2+ concentrations. Mg2+ favors formation of the "fast" electrophoretic form: a single Mg2+ is bound in the rate-limiting step, followed by cooperative binding of approximately 1.7 additional ions. Binding of the latter ions provides most of the favorable free energy for the reaction. However, the "slow" form binds about the same number of Mg ions, albeit more weakly, so that saturating Mg2+ concentrations drive the equilibrium to only approximatley 70% fast form. A single H+ is taken up in the switch to the "slow" conformer, which has apparent pK approximately 5.9; low pH also stabilizes part of the pseudoknot structure melting at approximately 62 degrees C. Mg2+ and H+ appear to direct alpha mRNA folding by relatively small (10 to 100-fold) differences in their affinities for alternative conformers. K+ has very little effect on the conformational equilibrium, but at high concentrations accelerates interconversion between the conformers. The alpha mRNA conformational switch is similar in its slow kinetics, large activation energy, and Mg2+ dependence of the equilibrium constant to slow steps in the folding of tRNA, group I introns, and RNase P RNA tertiary structures, though it differs from these in the association of a single Mg2+ with the rate-limiting step.

A pseudoknot is required for efficient translational initiation and regulation of the Escherichia coli rpsO gene coding for ribosomal protein S15

Escherichia coli ribosomal protein S15 down regulates its own synthesis by binding to its mRNA in a region overlapping the ribosome binding site, called the translational operator. This binding stabilizes a pseudoknot structure that exists in equilibrium with two stem-loop structures. When synthesized in excess over 16S rRNA, S15 binds to its translational operator and traps the ribosome on its loading site in a transient state, preventing the formation of the active ternary (30S-mRNA-rRNA(f)Met) complex. This inhibition can be suppressed by 16S rRNA, which displaces S15 from the mRNA. An extensive mutational analysis showed that the pseudoknot is the structural element required for S15 recognition and in vivo translational control. Specific sequence determinants are located in limited regions of the structure formed by the pseudoknot. An unexpected result is that the pseudoknot can exist in a variety of topologically equivalent structures recognizable and shapable by S15. Based on footprinting experiments and computer graphic modelling, S15 shields the two stems of the pseudoknot, sitting in the major groove of the coaxial stack.

Messenger RNA recognition by fragments of ribosomal protein S4

Ribosomal protein S4 from Escherichia coli binds a large domain of 16 S ribosomal RNA and also a pseudoknot structure in the alpha operon mRNA, where it represses its own synthesis. No similarity between the two RNA binding sites has been detected. To find out whether separate protein regions are responsible for rRNA and mRNA recognition, proteins with N-terminal or C-terminal deletions have been overexpressed and purified. Protein-mRNA interactions were detected by (i) a nitrocellulose filter binding assay, (ii) inhibition of primer extension by reverse transcriptase, and (iii) a gel shift assay. Circular dichroism spectra were taken to determine whether the proteins adopted stable secondary structures. From these studies it is concluded that amino acids 48-104 make specific contacts with the mRNA, although residues 105-177 (out of 205) are required to observe the same toeprint pattern as full-length protein and may stabilize a specific portion of the mRNA structure. These results parallel ribosomal RNA binding properties of similar fragments (Conrad, R. C., and Craven, G. R. (1987) Nucleic Acids Res. 15, 10331-10343, and references therein). It appears that the same protein domain is responsible for both mRNA and rRNA binding activities.

Regulation of human RPS14 transcription by intronic antisense RNAs and ribosomal protein S14

RNase protection studies reveal two stable RNAs (250 and 280 nucleotides) transcribed from the antisense strand of the human ribosomal protein gene RPS14's first intron. These transcripts, designated alpha-250 and alpha-280, map to overlapping segments of the intron's 5' sequence. Neither RNA encodes a polypeptide sequence, and both are expressed in all human cells and tissues examined. Although alpha-280 is detected among both the cells' nuclear and cytoplasmic RNAs, the great majority of alpha-250 is found in the cytoplasmic subcellular compartment. As judged by its resistance to high concentrations of alpha-amanitin, cell-free transcription of alpha-250 and alpha-280 appears to involve RNA polymerase I. Tissue culture transfection and cell-free transcription experiments demonstrate that alpha-250 and alpha-280 stimulate S14 mRNA transcription, whereas free ribosomal protein S14 inhibits it. Electrophoretic mobility shift experiments indicate specific binary molecular interactions between r-protein S14, its message and the antisense RNAs. In light of these data, we propose a model for fine regulation of human RPS14 transcription that involves RPS14 intron 1 antisense RNAs as positive effectors and S14 protein as a negative effector.

C/EBP is an immediate-early gene required for the consolidation of long-term facilitation in Aplysia

The consolidation of long-term memory requires protein and mRNA synthesis. A similar requirement has been demonstrated for learning-related synaptic plasticity in the gill-withdrawal reflex of Aplysia. The monosynaptic component of this reflex can be reconstituted in vitro, where it undergoes both short- and long-term increases in synaptic strength in response to serotonin (5-HT), a neurotransmitter released during behavioral sensitization, a simple form of learning. As with sensitization, the long-term synaptic modification is characterized by a brief consolidation period during which gene expression is required. We find that during this phase, the transcription factor Aplysia CCAAT enhancer-binding protein (ApC/EBP) is induced rapidly by 5-HT and by cAMP, even in the presence of protein synthesis inhibitors. Blocking the function of ApC/EBP blocks long-term facilitation selectively without affecting the short-term process. These data indicate that cAMP-inducible immediate-early genes have an essential role in the consolidation of stable long-term synaptic plasticity in Aplysia.

Post-transcriptional regulation of the str operon in Escherichia coli. Ribosomal protein S7 inhibits coupled translation of S7 but not its independent translation

The str operon of Escherichia coli consists of the genes for ribosomal proteins S12 (rpsL) and S7 (rpsG) and elongation factors G (fusA) and Tu (tufA). Previous studies have shown that S7 is a translational feedback repressor and inhibits the synthesis of itself and of elongation factor G. We have now shown that induction of S7 synthesis from the S7 gene fused to the arabinose promoter on a plasmid also leads to inhibition of the synthesis of S12 from the chromosomal S12 gene, and that this regulation takes place using the same target site as that used for distal gene regulation, i.e. S7 retroregulates S12. We have then demonstrated that S7 synthesis is mostly translationally coupled with the translation of the preceding S12 gene. Using a rpsG'-'lacZ fusion gene as a reporter for S7 synthesis, we found that abolishing S12 translation by a mutational alteration of the AUG start codon of the S12 gene leads to about tenfold reduction of S7 synthesis without significantly affecting its rate of transcription. Deletion of the proximal portion of the S12 gene or a premature termination of S12 translation by an amber mutation at the 26th codon also led to a large reduction of S7 synthesis. Unexpectedly, we have discovered that overproduction of S7 in trans from a plasmid leads to repression of the rpsG'-'lacZ fusion gene when the fusion gene is preceded by the intact S12 gene, but not when the S12 gene carried the above-mentioned mutations that abolish S12 translation. Thus, a novel feature of this regulatory system is that translation of S7 achieved by independent initiation is not inhibited by S7 in vivo, whereas translation of S7 achieved by translational coupling is sensitive to S7 repression. These observations also suggest that the coupled S7 translation is probably achieved by the use of ribosomal subunits employed for translation of the upstream S12 gene.

Post-transcriptional regulation of the str operon in Escherichia coli. Structural and mutational analysis of the target site for translational repressor S7

In the Escherichia coli str operon, translation of the S12 and S7 genes is largely coupled, and the translational repressor S7 inhibits S7 translation, which is coupled to that of S12, but does not inhibit independent translation of S7 by free ribosomes in the intracellular pool. We have studied the S12-S7 intercistronic region of mRNA by analyzing RNA synthesized in vitro using structure-specific nucleases and a chemical probe, dimethyl sulfate. Based on the results obtained, we have deduced a secondary structure model of the S12-S7 intercistronic region and identified nucleotide residues "protected" by S7. We then carried out site-directed mutagenesis to identify nucleotide residues important for S7 translation as well as for repression by S7. The results showed that two distinct regions are important for S7-mediated repression; one is the S7 binding region identified by the protection analysis and the second is the stem structure that sequesters the Shine-Dalgarno sequence for the S7 gene. Some of the base alterations in the first region abolished S7 binding and, as a consequence, abolished S7-mediated repression, without affecting the efficiency of S7 translation. Other mutations disrupting the stem structure in the second region abolished S7-mediated repression without significantly affecting the S7-mRNA interaction. We also found that certain mutations drastically decrease S7 translation achieved by translational coupling without affecting S7 translation achieved by independent initiation. These mutations are in base-paired regions and evidence was obtained to suggest that these base-paired structures are important for translational coupling. We suggest that some specific RNA structures in the intercistronic region play an active role in achieving translational coupling in this system, and that repression of S7 translation by S7 protein is due to disruption of such structures induced by binding of S7 protein to the target site, rendering translational coupling very inefficient, but leaving independent translation initiation unaffected.

Cloning and characterization of the RNA polymerase alpha-subunit operon of Chlamydia trachomatis

We have cloned the chlamydial operon that encodes the initiation factor IF1, the ribosomal proteins L36, S13, and S11, and the alpha subunit of RNA polymerase. The genes for S11 and alpha are closely linked in Escherichia coli, Bacillus subtilis, and plant chloroplast genomes, and this arrangement is conserved in Chlamydia spp. The S11 ribosomal protein gene potentially encodes a protein of 125 amino acids with 41 to 42% identity over its entire length to its E. coli and B. subtilis homologs; the gene encoding the alpha subunit specifies a protein of 322 amino acids with 25 to 30% identity over its entire length to its E. coli and B. subtilis homologs. In a T7-based expression system in E. coli, the chlamydial alpha gene directed the synthesis of a 36-kDa protein. Mapping of the chlamydial mRNA transcript by RNase protection studies and by a combination of reverse transcription and the polymerase chain reaction demonstrates that IF1, L36, S13, S11, and alpha are transcribed as a polycistronic transcript.

Allosteric mechanism for translational repression in the Escherichia coli alpha operon

The ribosomal protein S4 is a translational repressor that binds to a complex mRNA pseudoknot structure containing the ribosome binding site for the first gene of the alpha operon. Either 30S subunits or S4 protein bound to the mRNA causes Moloney murine leukemia virus reverse transcriptase to pause near the 3' terminus of the pseudoknot. There is no competition between subunits and S4 for mRNA binding. The kinetics of forming S4-30S-mRNA complexes are biphasic, and the fraction of mRNA molecules reacting more rapidly decreases as the temperature is increased from 30 degrees C to 40 degrees C. The complex cannot be detected with mRNA mutants that cannot be repressed. We have previously shown similar kinetic behavior for the formation of tRNA(fMet) initiation complexes with tRNA(fMet), 30S subunits, and mRNA, except that the fraction reacting rapidly increases when the temperature is increased over the same 30-40 degrees C range. Thus the two sets of experiments show that there are two forms of 30S-mRNA complexes that differ in their abilities to bind S4 and tRNA(fMet). The results support an allosteric model for translational repression in which S4 traps the mRNA in a conformation able to bind 30S subunits but unable to form an initiation complex with tRNA(fMet).

Messenger RNA secondary structure and translational coupling in the Escherichia coli operon encoding translation initiation factor IF3 and the ribosomal proteins, L35 and L20

The Escherichia coli infC-rpmI-rplT operon encodes translation initiation factor IF3 and the ribosomal proteins, L35 and L20, respectively. The expression of the last cistron (rplT) has been shown to be negatively regulated at a post-transcriptional level by its own product, L20, which acts at an internal operator located within infC. The present work shows that L20 directly represses the expression of rpmI, and indirectly that of rplT, via translational coupling with rpmI. Deletions and an inversion of the coding region of rpmI, suggest an mRNA secondary structure forming between sequences within rpmI and the translation initiation site of rplT. To verify the existence of this structure, detailed analyses were performed using chemical and enzymatic probes. Also, mutants that uncoupled rplT expression from that of rpmI, were isolated. The mutations fall at positions that would base-pair in the secondary structure. Our model is that L20 binds to its operator within infC and represses the translation of rpmI. When the rpmI mRNA is not translated, it can base-pair with the ribosomal binding site of rplT, sequestering it, and abolishing rplT expression. If the rpmI mRNA is translated, i.e. covered by ribosomes, the inhibitory structure cannot form leaving the translation initiation site of rplT free for ribosomal binding and for full expression. Although translational coupling in ribosomal protein operons has been suspected to be due to the formation of secondary structures that sequester internal ribosomal binding sites, this is the first time that such a structure has been shown to exist.

Escherichia coli rpoA mutation which impairs transcription of positively regulated systems

The rpoA341 (phs) mutation of Escherichia coli results in decreased expression of several positively regulated operons and has been mapped to within or very near the rpoA gene encoding the alpha subunit of RNA polymerase. We have shown that plasmid-directed synthesis of the wild-type alpha subunit can complement the defective phenotypes associated with this mutation consistent with its proposed location within rpoA. This mutation was mapped by marker rescue to within a 182bp region near the 3' end of rpoA and was subsequently transferred to a plasmid by recombination in vivo. DNA sequence analysis revealed that the RpoA341 phenotype was the result of the substitution of lysine 271 by glutamate within the alpha polypeptide. We discuss this result in relation to our current understanding of the functional organization of the alpha subunit.

Cloning and analysis of the Bacillus subtilis rpsD gene, encoding ribosomal protein S4

The rpsD gene, encoding ribosomal protein S4, was isolated from Bacillus subtilis by hybridization with oligonucleotide probes derived from the S4 amino-terminal protein sequence. Sequence analysis of the cloned DNA indicated that rpsD is likely to be monocistronic, in contrast to Escherichia coli rpsD, which is located in the alpha operon and is the translational regulator for alpha operon ribosomal protein gene expression in E. coli. The cloned gene was shown to map at position 263 degrees on the B. subtilis chromosome, at the position to which mutations conferring alterations in the electrophoretic mobility of protein S4 were localized. A promoter was identified upstream of the rpsD coding sequence; initiation of transcription at this promoter would result in a transcript containing a leader region 180 bases in length. Immediately downstream of the rpsD coding region were two sequences resembling transcriptional terminators. An open reading frame homologous to tyrosyl-tRNA synthetase (tyrS) genes was identified downstream of rpsD but in the opposite orientation. The leader region of rpsD mRNA is predicted to have extensive secondary structure, resembling a region of B. subtilis 16S rRNA where S4 is likely to bind; similar mRNA features have been found to be important in ribosomal gene regulation in E. coli. These results provide the first steps toward analysis of the regulation of rpsD gene expression in B. subtilis.

Transcriptional organization of the S10, spc and alpha operons of Escherichia coli

We have investigated the transcription patterns at the inter-operon regions between the S10 and spc, and spc and alpha ribosomal protein operons of Escherichia coli. Newly synthesized transcripts were characterized by RNase T1 protection experiments, and accumulated transcripts were mapped with S1 nuclease. With both techniques we found that about 75% of the RNA polymerases transcribing the S10 operon terminated at the position of a typical rho-independent terminator. In contrast, most or all RNA polymerases transcribing the spc operon continued into the alpha operon. Nevertheless, we observed that about 30% of the transcripts of the alpha operon were initiated at the alpha operon promoter.

Translation initiation in Escherichia coli: old and new questions

We discuss the features of Escherichia coli mRNAs which determine where and how efficiently translation is initiated. We have shown that DNA fragments comprising 60-80 nucleotides that bracket the initiation codon of real genes generally promote translation when inserted within a foreign mRNA, while those not corresponding to an authentic gene start do not do so even if they include a Shine-Dalgarno-like element followed by AUG or GUG. Therefore, the information that pinpoints the correct start sites, while extending beyond the mere presence of these elements, remains essentially local. The possible nature of this information is discussed. Next, we point out that, in order to remain accessible, translational starts must escape long-range base-pairing within large mRNAs, and we argue that the tight coupling between translation and transcription plays an important role in achieving this. Finally, we discuss two intriguing situations in which the initiation frequency should be dependent upon the rate of translation elongation.

Conditional expression of RPA190, the gene encoding the largest subunit of yeast RNA polymerase I: effects of decreased rRNA synthesis on ribosomal protein synthesis

The synthesis of ribosomal proteins (r proteins) under the conditions of greatly reduced RNA synthesis were studied by using a strain of the yeast Saccharomyces cerevisiae in which the production of the largest subunit (RPA190) of RNA polymerase I was controlled by the galactose promoter. Although growth on galactose medium was normal, the strain was unable to sustain growth when shifted to glucose medium. This growth defect was shown to be due to a preferential decrease in RNA synthesis caused by deprivation of RNA polymerase I. Under these conditions, the accumulation of r proteins decreased to match the rRNA synthesis rate. When proteins were pulse-labeled for short periods, no or only a weak decrease was observed in the differential synthesis rate of several r proteins (L5, L39, L29 and/or L28, L27 and/or S21) relative to those of control cells synthesizing RPA190 from the normal promoter. Degradation of these r proteins synthesized in excess was observed during subsequent chase periods. Analysis of the amounts of mRNAs for L3 and L29 and their locations in polysomes also suggested that the synthesis of these proteins relative to other cellular proteins were comparable to those observed in control cells. However, Northern analysis of several r-protein mRNAs revealed that the unspliced precursor mRNA for r-protein L32 accumulated when rRNA synthesis rates were decreased. This result supports the feedback regulation model in which excess L32 protein inhibits the splicing of its own precursor mRNA, as proposed by previous workers (M. D. Dabeva, M. A. Post-Beittenmiller, and J. R. Warner, Proc. Natl. Acad. Sci. USA 83:5854-5857, 1986).

Conditional expression of RPA190, the gene encoding the largest subunit of yeast RNA polymerase I: effects of decreased rRNA synthesis on ribosomal protein synthesis

The synthesis of ribosomal proteins (r proteins) under the conditions of greatly reduced RNA synthesis were studied by using a strain of the yeast Saccharomyces cerevisiae in which the production of the largest subunit (RPA190) of RNA polymerase I was controlled by the galactose promoter. Although growth on galactose medium was normal, the strain was unable to sustain growth when shifted to glucose medium. This growth defect was shown to be due to a preferential decrease in RNA synthesis caused by deprivation of RNA polymerase I. Under these conditions, the accumulation of r proteins decreased to match the rRNA synthesis rate. When proteins were pulse-labeled for short periods, no or only a weak decrease was observed in the differential synthesis rate of several r proteins (L5, L39, L29 and/or L28, L27 and/or S21) relative to those of control cells synthesizing RPA190 from the normal promoter. Degradation of these r proteins synthesized in excess was observed during subsequent chase periods. Analysis of the amounts of mRNAs for L3 and L29 and their locations in polysomes also suggested that the synthesis of these proteins relative to other cellular proteins were comparable to those observed in control cells. However, Northern analysis of several r-protein mRNAs revealed that the unspliced precursor mRNA for r-protein L32 accumulated when rRNA synthesis rates were decreased. This result supports the feedback regulation model in which excess L32 protein inhibits the splicing of its own precursor mRNA, as proposed by previous workers (M. D. Dabeva, M. A. Post-Beittenmiller, and J. R. Warner, Proc. Natl. Acad. Sci. USA 83:5854-5857, 1986).

Cloning and analysis of the spc ribosomal protein operon of Bacillus subtilis: comparison with the spc operon of Escherichia coli

A segment of Bacillus subtilis chromosomal DNA homologous to the Escherichia coli spc ribosomal protein operon was isolated using cloned E. coli rplE (L5) DNA as a hybridization probe. DNA sequence analysis of the B. subtilis cloned DNA indicated a high degree of conservation of spc operon ribosomal protein genes between B. subtilis and E. coli. This fragment contains DNA homologous to the promoter-proximal region of the spc operon, including coding sequences for ribosomal proteins L14, L24, L5, S14, and part of S8; the organization of B. subtilis genes in this region is identical to that found in E. coli. A region homologous to the E. coli L16, L29 and S17 genes, the last genes of the S10 operon, was located upstream from the gene for L14, the first gene in the spc operon. Although the ribosomal protein coding sequences showed 40-60% amino acid identity with E. coli sequences, we failed to find sequences which would form a structure resembling the E. coli target site for the S8 translational repressor, located near the beginning of the L5 coding region in E. coli, in this region or elsewhere in the B. subtilis spc DNA.

S4-16 S ribosomal RNA complex. Binding constant measurements and specific recognition of a 460-nucleotide region

The region of the Escherichia coli 16 S ribosomal RNA recognized by the ribosomal protein S4 has been defined by assaying a set of 13 16 S rRNA fragments for S4 binding. The fragments were prepared by transcription in vitro, and binding constants were measured in three ways: retention of labeled RNA fragments on nitrocellulose filters by S4; co-sedimentation of labeled S4 with RNA fragments in sucrose gradients; and the distribution of labeled S4 between two RNAs of different sizes in a sucrose gradient. All three methods gave similar relative binding strengths for a variety of 16 S rRNA and non-specific (23 S rRNA) sequences, with the exception of two of the largest 16 S rRNA fragments; these gave smaller association constants in the filter retention assay than in the other methods. We found that specific complexes of S4 with these larger RNAs do not bind well to filters, leaving non-specific complexes to dominate the assay. Specific complexes with RNAs less than or equal to 891 nucleotides were retained efficiently by S4 on filters, and gave reliable binding constants. All 16 S rRNA fragments containing nucleotides 39 to 500 bound S4 with the same affinity as intact 16 S rRNA, while all fragments with endpoints within 39 to 500 bound at least tenfold more weakly. This sequence must be able to fold independently of the rest of the rRNA. Comparison of this minimal 462-nucleotide S4 binding site with S4 footprinting results suggests that S4 binding might alter the conformations of RNA neighboring the 39 to 500 region in the intact 16 S rRNA. Specific S4-rRNA binding is not sensitive to KCl concentration, but a more normal salt dependence is seen in K2SO4 (delta logK/delta log[K+] approximately -3.3). This duplicates the behavior of the specific S4-alpha mRNA translational repression complex, arguing that S4 recognizes both the mRNA and rRNA substrates by the same mechanism. Mg2+ is not required to form the specific rRNA complex, at least under conditions which stabilize RNA structure (0.35 M-KCl, 5 degrees C).

Translational coupling in the threonine operon of Escherichia coli K-12

In an attempt to express the two distal genes of the Escherichia coli threonine operon, the majority of the first gene in the operon, thrA, was removed and a series of transcriptional fusions were constructed placing the thrB and thrC genes downstream of either the trp or hybrid tac promoter. Analysis of the proteins produced by cells containing these fusions revealed that although the distal gene, thrC, was efficiently expressed, the proximal gene, thrB, was not expressed at a detectable level. A translational fusion was constructed which fused the cat gene in phase to the last 800 base pairs of thrA followed by thrB and thrC. Cells containing this fusion produced high levels of both the thrB and thrC gene products, showing that translation of thrB requires translation through thrA; thus, thrA and thrB are translationally coupled. In addition, it was found that a sequence between 220 and 57 base pairs before the start of thrB was necessary to allow translational coupling to occur.

Unusual mRNA pseudoknot structure is recognized by a protein translational repressor

Translation of ribosomal proteins in the alpha operon of E. coli is repressed by one of the encoded proteins, S4; it specifically recognizes an RNA fragment containing the translational initiation site for the first gene in the operon. RNA structure mapping experiments have suggested a pseudoknot structure for the S4 binding site: the loop of a hairpin is base paired to sequences downstream of the hairpin. Here, we systematically test this proposed structure by measuring S4 binding to an extensive set of site-directed mutations that create compensatory base pair changes in potential helices. The pseudoknot folding is confirmed, and two additional, unexpected interactions within the pseudoknot are also detected. The overall structure is an unusual "double pseudoknot" linking a hairpin upstream of the ribosome binding site with sequences 2-10 codons downstream of the initiation codon. Stabilization of this structure by S4 could account for translational repression.

Gene encoding the alpha core subunit of Bacillus subtilis RNA polymerase is cotranscribed with the genes for initiation factor 1 and ribosomal proteins B, S13, S11, and L17

We describe the genetic and transcriptional organization of the promoter-distal portion of the Bacillus subtilis alpha operon. By DNA sequence analysis of the region surrounding rpoA, the gene for the alpha core subunit of RNA polymerase, we identified six open reading frames by the similarity of their products to their counterparts in the Escherichia coli transcriptional and translational apparatus. Gene order in this region, given by gene product, was IF1-B-S13-S11-alpha-L17. Gene order in E. coli is similar but not identical: SecY-B-S13-S11-S4-alpha-L17. The B. subtilis alpha region differed most strikingly from E. coli in the presence of IF1 and the absence of ribosomal protein S4, which is the translational regulator of the E. coli alpha operon. In place of the gene for S4, B. subtilis had a 177-base-pair intercistronic region containing two possible promoter sequences. However, experiments with S1 mapping of in vivo transcripts, gene disruptions in the alpha region, and a single-copy transcriptional fusion vector all suggested that these possible promoters were largely inactive during logarithmic growth, that the major promoter for the alpha operon lay upstream from the region cloned, and that the genes in the IF1 to L17 interval were cotranscribed. Thus, the transcriptional organization of the region resembles that of E. coli, wherein the alpha operon is transcribed primarily from the upstream spc promoter, but the absence of the S4 gene suggests that the translational regulation of the region may differ more fundamentally.

Translational coupling of the two proximal genes in the S10 ribosomal protein operon of Escherichia coli

We have examined the translational coupling between the first two genes in the S10 ribosomal protein operon. We isolated mutations blocking the translation of the first gene of the operon, coding for S10, and monitored their effects on translation of the downstream gene, coding for L3. All of the mutations inhibiting S10 synthesis also affected the synthesis of L3. However, these experiments were complicated by decreased mRNA synthesis resulting from transcription polarity, which we could only partially eliminate by using a rho-100 strain. To completely eliminate the problem of transcription polarity and obtain a more accurate measurement of the coupling, we replaced the natural S10 promoter with a promoter used by the bacteriophage T7 RNA polymerase. As expected, the T7 RNA polymerase was not subject to transcription polarity. Using this system, we were able to show that a complete abolishment of S10 translation resulted in an 80% inhibition of L3 synthesis. Other experiments show that the synthesis of L3 goes up as a function of increasing S10 synthesis, but the translational coupling does not assure strictly proportional output from the two genes.

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.

Translational regulation of the spc operon in Escherichia coli. Identification and structural analysis of the target site for S8 repressor protein

The spc ribosomal protein operon of Escherichia coli is feedback-regulated by ribosomal protein S8, a translational repressor. We have analyzed the region of the spc mRNA that is responsible for this regulation. First, we have established that the S8 target site on the mRNA is near the translation start site of the third gene encoding ribosomal protein L5 in the operon. This was done by constructing hybrid plasmids carrying spc operon ribosomal protein genes under lac transcriptional control, as well as their deletion derivatives, and carrying out both in vivo and in vitro protein synthesis experiments. Next, the secondary structure of this region was studied by analyzing 5' end-labeled RNA synthesized from the phage SP6 promoter using structure-specific nucleases. A secondary structure model consistent with the results was deduced with the aid of a computer prediction of RNA folding. In addition, we cloned and sequenced the corresponding region from Salmonella typhimurium, Proteus vulgaris and Serratia marcescens and found five "compensating" substitutions that support some of the deduced helical structures of mRNA. None of the base changes was inconsistent with the deduced secondary structure model. Finally, site-directed mutagenesis experiments have identified bases important for regulation, including two base-paired sites representing each of two helical regions. This has led to the conclusion that some specific nucleotide residues located between these two helical regions are directly involved in S8 recognition, and that the function of the two helical regions is to maintain the proper orientation of these nucleotide residues. Comparison of the structure of the S8 target site on the spc mRNA with the known S8 binding site on rRNA has revealed a striking similarity in both primary and secondary structures. In particular, primary sequences of rRNA conserved among distantly related bacterial species in this region is found to be identical with the sequences at the corresponding positions in mRNA. These results suggest that the same structural features of the S8 repressor protein are involved in the interaction with both 16 S rRNA and the mRNA target site.

Feedback regulation of the spc operon in Escherichia coli: translational coupling and mRNA processing

The spc operon of Escherichia coli encodes 10 ribosomal proteins in the order L14, L24, L5, S14, S8, L6, L18, S5, L30, and L15. This operon is feedback regulated by S8, which binds near the translation start site of L5 and inhibits translation of L5 directly and that of the distal genes indirectly. We constructed plasmids carrying a major portion of the spc operon genes under lac transcriptional control. The plasmids carried a point mutation in the S8 target site which abolished regulation and resulted in overproduction of plasmid-encoded ribosomal proteins upon induction. We showed that alteration of the AUG start codon of L5 to UAG decreased the synthesis rates of plasmid-encoded distal proteins, as well as L5, by approximately 20-fold, with a much smaller (if any) effect on mRNA synthesis rates, indicating coupling of the distal cistrons' translation with the translation of L5. This conclusion was also supported by experiments in which S8 was overproduced in trans. In this case, there was a threefold reduction in the synthesis rates of chromosome-encoded L5 and the distal spc operon proteins, but no decrease in the mRNA synthesis rate. These observations also suggest that transcription from ribosomal protein promoters may be special, perhaps able to overcome transcription termination signals. We also analyzed the state of ribosomal protein mRNA after overproduction of S8 in these experiments and found that repression of ribosomal protein synthesis was accompanied by stimulation of processing (and degradation) of spc operon mRNA. The possible role of mRNA degradation in tightening the regulation is discussed.

Noncoordinate translation-level regulation of ribosomal and nonribosomal protein genes in the Escherichia coli trmD operon

The trmD operon of Escherichia coli contains the genes for the ribosomal protein S16, a 21-kilodalton polypeptide of unknown function, the tRNA(1-methylguanosine)methyltransferase, and the ribosomal protein L19, in that order. As reported elsewhere, the operon is transcribed as a single polycistronic mRNA species, and there is no significant difference in the steady-state amounts of different parts of the mRNA (A.S. Byström, A. von Gabain, and G.R. Björk, submitted for publication). Furthermore, accumulation of all parts of the transcript is altered in a stringently controlled manner upon starvation for valyl-tRNA. Here we show that the rate of synthesis of the trmD operon proteins increased with increasing growth rate and that the amount in steady state, at a specific growth rate (k = 1.0), of the tRNA(1-methylguanosine)methyltransferase was 260 molecules per gene copy, which is about 40 times lower than the amount of the two ribosomal proteins, whereas the 21-kilodalton protein was synthesized to the amount of about 850 molecules per gene copy. The lower steady-state amount of the two nonribosomal proteins was not due to a higher turnover rate. Synthesis of the 21-kilodalton and TrmD proteins responded differently from that of the two ribosomal proteins during conditions which provoked amino acid starvation, although accumulation of the entire mRNA molecule responds similarly to the rate of synthesis of the two ribosomal proteins. We conclude that the observed differential and noncoordinate expression is achieved by regulation at the level of mRNA translation.

S4-alpha mRNA translation repression complex. I. Thermodynamics of formation

Expression of the four ribosomal proteins from the Escherichia coli alpha operon (S4, S11, S13, and L17) is regulated at the level of translation by the binding of S4 to the alpha mRNA. Using a filter binding assay and alpha mRNA sequences prepared by in-vitro transcription, previous work located the S4 target site within the approximately 100-base leader sequence. We have extended this work to include fragments of the alpha leader with six different 5' end points and four different 3' end points. A core region between bases 23 and 69 (numbering from the first nucleotide of the E. coli transcript) binds S4 with an affinity of approximately 2 microM-1. Regions of weak interactions are located in the 22 nucleotides 5' and the 70 nucleotides 3' to this core; they increase the S4 affinity to approximately 13 microM-1. Studies of S4-alpha mRNA binding under different conditions have revealed the following. (1) Specific and non-specific binding show the same dependence on K+ concentration, with delta log+ K/delta log [K+] approximately 4 in most potassium salts. With KCl and KBr, much weaker salt dependence of specific complex formation is observed suggesting that the protein responds to the correct RNA substrate by binding halide anions. (2) Increasing the MgCl2 concentration between 1 and 4 mM enhances binding by a factor of 4, with no further effects up to 20 mM. About five Mg2+ are taken up by the complex with an average binding constant of approximately 600 M-1 each. Renaturation of the RNA in the presence of MgCl2 is also required to obtain full binding. These effects are seen only with alpha mRNA extending beyond the initiation codon; S4 binding to the alpha leader sequence itself is insensitive to Mg2+. (3) The association kinetics are fast and probably diffusion controlled. (4) Formation of the complex is entirely entropy driven.