Translational coupling varying in efficiency between different pairs of genes in the central region of the atp operon of Escherichia coli

Translational coupling via termination-reinitiation in archaea and bacteria

The genomes of many prokaryotes contain substantial fractions of gene pairs with overlapping stop and start codons (ATGA or TGATG). A potential benefit of overlapping gene pairs is translational coupling. In 720 genomes of archaea and bacteria representing all major phyla, we identify substantial, albeit highly variable, fractions of co-directed overlapping gene pairs. Various patterns are observed for the utilization of the SD motif for de novo initiation at upstream genes versus reinitiation at overlapping gene pairs. We experimentally test the predicted coupling in 9 gene pairs from the archaeon Haloferax volcanii and 5 gene pairs from the bacterium Escherichia coli. In 13 of 14 cases, translation of both genes is strictly coupled. Mutational analysis of SD motifs located upstream of the downstream genes indicate that the contribution of the SD to translational coupling widely varies from gene to gene. The nearly universal, abundant occurrence of overlapping gene pairs suggests that tight translational coupling is widespread in archaea and bacteria.

Archaea and bacteria often have gene pairs with overlapping stop and start codons, suggesting translational coupling. Here, Huber et al. analyse overlapping gene pairs from 720 genomes, and validate translational coupling via termination-reinitiation for 14 gene pairs in Haloferax volcanii and Escherichia coli.

Reduced Protein Expression in a Virus Attenuated by Codon Deoptimization

A general means of viral attenuation involves the extensive recoding of synonymous codons in the viral genome. The mechanistic underpinnings of this approach remain unclear, however. Using quantitative proteomics and RNA sequencing, we explore the molecular basis of attenuation in a strain of bacteriophage T7 whose major capsid gene was engineered to carry 182 suboptimal codons. We do not detect transcriptional effects from recoding. Proteomic observations reveal that translation is halved for the recoded major capsid gene, and a more modest reduction applies to several coexpressed downstream genes. We observe no changes in protein abundances of other coexpressed genes that are encoded upstream. Viral burst size, like capsid protein abundance, is also decreased by half. Together, these observations suggest that, in this virus, reduced translation of an essential polycistronic transcript and diminished virion assembly form the molecular basis of attenuation.

Effects of Kasugamycin on the Translatome of Escherichia coli

It is long known that Kasugamycin inhibits translation of canonical transcripts containing a 5’-UTR with a Shine Dalgarno (SD) motif, but not that of leaderless transcripts. To gain a global overview of the influence of Kasugamycin on translation efficiencies, the changes of the translatome of Escherichia coli induced by a 10 minutes Kasugamycin treatment were quantified. The effect of Kasugamycin differed widely, 102 transcripts were at least twofold more sensitive to Kasugamycin than average, and 137 transcripts were at least twofold more resistant, and there was a more than 100-fold difference between the most resistant and the most sensitive transcript. The 5’-ends of 19 transcripts were determined from treated and untreated cultures, but Kasugamycin resistance did neither correlate with the presence or absence of a SD motif, nor with differences in 5’-UTR lengths or GC content. RNA Structure Logos were generated for the 102 Kasugamycin-sensitive and for the 137 resistant transcripts. For both groups a short Shine Dalgarno (SD) motif was retrieved, but no specific motifs associated with resistance or sensitivity could be found. Notably, this was also true for the region -3 to -1 upstream of the start codon and the presence of an extended SD motif, which had been proposed to result in Kasugamycin resistance. Comparison of the translatome results with the database RegulonDB showed that the transcript with the highest resistance was leaderless, but no further leaderless transcripts were among the resistant transcripts. Unexpectedly, it was found that translational coupling might be a novel feature that is associated with Kasugamycin resistance. Taken together, Kasugamycin has a profound effect on translational efficiencies of E. coli transcripts, but the mechanism of action is different than previously described.

ATP Synthesis by Oxidative Phosphorylation

The F1F0-ATP synthase (EC 3.6.1.34) is a remarkable enzyme that functions as a rotary motor. It is found in the inner membranes of Escherichia coli and is responsible for the synthesis of ATP in response to an electrochemical proton gradient. Under some conditions, the enzyme functions reversibly and uses the energy of ATP hydrolysis to generate the gradient. The ATP synthase is composed of eight different polypeptide subunits in a stoichiometry of α3β3γδεab2c10. Traditionally they were divided into two physically separable units: an F1 that catalyzes ATP hydrolysis (α3β3γδε) and a membrane-bound F0 sector that transports protons (ab2c10). In terms of rotary function, the subunits can be divided into rotor subunits (γεc10) and stator subunits (α3β3δab2). The stator subunits include six nucleotide binding sites, three catalytic and three noncatalytic, formed primarily by the β and α subunits, respectively. The stator also includes a peripheral stalk composed of δ and b subunits, and part of the proton channel in subunit a. Among the rotor subunits, the c subunits form a ring in the membrane, and interact with subunit a to form the proton channel. Subunits γ and ε bind to the c-ring subunits, and also communicate with the catalytic sites through interactions with α and β subunits. The eight subunits are expressed from a single operon, and posttranscriptional processing and translational regulation ensure that the polypeptides are made at the proper stoichiometry. Recent studies, including those of other species, have elucidated many structural and rotary properties of this enzyme.

Hybrid rotors in F1Fo ATP synthases: subunit composition, distribution, and physiological significance

The c ring of the Na+ F1Fo ATP synthase from the anaerobic acetogenic bacterium Acetobacterium woodii is encoded by three different genes: atpE1, atpE2 and atpE3. Subunit c1 is similar to typical V-type c subunits and has four transmembrane helices with one ion binding site. Subunit c2 and c3 are identical at the amino acid level and are typical F-type c subunits with one ion binding site in two transmembrane helices. All three constitute a hybrid FoVo c ring, the first found in nature. To analyze whether other species may have similar hybrid rotors, we searched every genome sequence publicly available as of 23 February 2015 for F1Fo ATPase operons that have more than one gene encoding the c subunit. This revealed no other species that has three different c subunit encoding genes but twelve species that encode one Fo- and one Vo-type c subunit in one operon. Their c subunits have the conserved binding motif for Na+. The organisms are all anaerobic. The advantage of hybrid c rings for the organisms in their environments is discussed.

A predictive biophysical model of translational coupling to coordinate and control protein expression in bacterial operons

Natural and engineered genetic systems require the coordinated expression of proteins. In bacteria, translational coupling provides a genetically encoded mechanism to control expression level ratios within multi-cistronic operons. We have developed a sequence-to-function biophysical model of translational coupling to predict expression level ratios in natural operons and to design synthetic operons with desired expression level ratios. To quantitatively measure ribosome re-initiation rates, we designed and characterized 22 bi-cistronic operon variants with systematically modified intergenic distances and upstream translation rates. We then derived a thermodynamic free energy model to calculate de novo initiation rates as a result of ribosome-assisted unfolding of intergenic RNA structures. The complete biophysical model has only five free parameters, but was able to accurately predict downstream translation rates for 120 synthetic bi-cistronic and tri-cistronic operons with rationally designed intergenic regions and systematically increased upstream translation rates. The biophysical model also accurately predicted the translation rates of the nine protein atp operon, compared to ribosome profiling measurements. Altogether, the biophysical model quantitatively predicts how translational coupling controls protein expression levels in synthetic and natural bacterial operons, providing a deeper understanding of an important post-transcriptional regulatory mechanism and offering the ability to rationally engineer operons with desired behaviors.

SpyA is a membrane-bound ADP-ribosyltransferase of Streptococcus pyogenes which modifies a streptococcal peptide, SpyB

All sequenced genomes of Streptococcus pyogenes (Group A Streptococcus, GAS) encode a protein, SpyA, with homology to C3-like ADP-ribosyltransferase toxins. SpyA is a novel virulence factor which plays a role in pathogenesis in a mouse model of soft-tissue infection. In this study we demonstrate that SpyA is a surface-exposed membrane protein which is anchored to the streptococcal membrane by an N-terminal transmembrane sequence. We identified a small gene upstream of spyA, designated spyB, which encodes a peptide of 35 amino acids, and is co-transcribed with spyA. Expression of spyBA is strongly influenced by translational coupling: mutational inactivation of spyB translation completely abolishes translation of spyA. spyB expression increases with increasing cell density and reaches its maximum at late exponential growth phase. The SpyB N-terminus is predicted to fold into an amphipathic α-helix, a structural motif that targets a protein to the cytoplasmic membrane. Consistent with the prediction, we found that a SpyB fusion with peptide affinity tags is located in the streptococcal membrane. An ADP-ribosylation assay with recombinant SpyA demonstrated that SpyA modifies SpyB. Thus, our study suggests that ADP-ribosylation of SpyB may be an important function of SpyA.

Antibiotic-induced ribosomal assembly defects result from changes in the synthesis of ribosomal proteins

Inhibitors of protein synthesis cause defects in the assembly of ribosomal subunits. In response to treatment with the antibiotics erythromycin or chloramphenicol, precursors of both large and small ribosomal subunits accumulate. We have used a pulse-labelling approach to demonstrate that the accumulating subribosomal particles maturate into functional 70S ribosomes. The protein content of the precursor particles is heterogeneous and does not correspond with known assembly intermediates. Mass spectrometry indicates that production of ribosomal proteins in the presence of the antibiotics correlates with the amounts of the individual ribosomal proteins within the precursor particles. Thus, treatment of cells with chloramphenicol or erythromycin leads to an unbalanced synthesis of ribosomal proteins, providing the explanation for formation of assembly-defective particles. The operons for ribosomal proteins show a characteristic pattern of antibiotic inhibition where synthesis of the first proteins is inhibited weakly but gradually increases for the subsequent proteins in the operon. This phenomenon most likely reflects translational coupling and allows us to identify other putative coupled non-ribosomal operons in the Escherichia coli chromosome.

Control of functional mRNA stability in bacteria: multiple mechanisms of nucleolytic and non-nucleolytic inactivation

Messenger RNA in bacteria may be inactivated by several parallel mechanisms acting independently on different target sites. For any species of mRNA the overall rate of inactivation is determined by the sum of the contributions from the different mechanisms. Transcripts may be inactivated directly by endonucleolytic attack or by processive nucleolytic degradation, which may proceed in the 3'-5' direction and probably also in the 5'-3' direction. Moreover, the functional lifetime of many mRNAs may be determined by processes that are not nucleolytic, such as the binding of translational repressors or the formation of secondary structures which prevent initiation of translation. These non-nucleolytic processes may also determine the chemical stability as chemical degradation frequently appears to be closely coupled to functional inactivation. The relative importance of the different mechanisms in the inactivation of bulk cellular mRNA, as well as the general prospects for engineering of stable mRNAs are discussed.

Genetics of acid adaptation in oral streptococci

A growing body of information has provided insights into the mechanisms by which the oral streptococci maintain their niches in the human mouth. In at least one case, Streptococcus mutans, the organism apparently uses a panel of proteins to survive in acidic conditions while it promotes the formation of dental caries. Oral streptococci, which are not as inherently resistant to acidification, use protective schemes to ameliorate acidic plaque pH values. Existing information clearly shows that while the streptococci are highly related, very different strategies have evolved for them to take advantage of their particular location in the oral cavity. The picture that emerges is that the acid-adaptive regulatory mechanisms of the oral streptococci differ markedly from those used by Gram-negative bacteria. What future research must determine is the extent and complexity of the acid-adaptive systems in these organisms and how they permit the organisms to maintain themselves in the face of a low-pH environment and the microbial competition present in their respective niches.

Adaptation of oral streptococci to low pH

The strategies employed by oral streptococci to resist the inimical influences of acidification reflect the diverse and dynamic niches of the human mouth. All of the oral streptococci are capable of rapid degradation of sugar to acidic end-products. As a result, the pH value of their immediate environment can plummet to levels where glycolysis and growth cease. At this point, the approaches for survival in acid separate the organisms. Streptococcus mutans, for example, relies on its F-ATPase, to protect itself from acidification by pumping protons out of the cells. S. salivarius responds by degrading urea to ammonia and S. sanguis produces ammonia by arginolysis. The mechanisms by which these organisms regulate their particular escape route are now being explored experimentally. The picture that emerges is that the acid-adaptive regulatory mechanisms of the oral streptococci differ markedly from those employed by Gram-negative bacteria. What remains to be elucidated are the breadth of the acid-response systems in these organisms and how they permit the microbes to sustain themselves in the face of low pH and the bacterial competition present in their respective niches. In this article, we summarize reports concerning the means by which oral streptococci either utilize acidification to subdue their competitors or protect themselves until pH values return to a more favorable level.

Proton ATPases in bacteria: comparison to Escherichia coli F1F0 as the prototype

The F1F0 ATP synthase complex of Escherichia coli functions reversibly in coupling proton translocation to ATP synthesis or hydrolysis. The structural organization and subunit composition corresponds to that seen in many other bacteria, i.e. a membrane extrinsic F1 sector with five subunits in an alpha 3 beta 3 gamma delta epsilon stoichiometry, and a membrane-traversing F0 sector with three subunits in an a1b2c12 stoichiometry. The structure of much of the F1 sector is known from a X-ray diffraction model. During function, The gamma subunit is known to rotate within a hexameric ring of alternating alpha and beta subunits to promote sequential substrate binding and product release from catalytic sites on the three beta subunits. Proton transport through F0 must be coupled to this rotation. Subunit c folds in the membrane as a hairpin to two alpha helices to generate the proton-binding site in F0. Its structure was determined by NMR, and the structure of the c oligomer was deduced by cross-linking experiments and molecular mechanics calculations. The implications of the oligomeric structure of subunit c will be considered and related to the H+/ATP pumping ratio, P/O ratios and the cation-binding site in other types of F0. The possible limits of the structure in changing the ion-binding specificity, stoichiometry and routes of proton entrance/exit to the binding site will be considered.

Posttranscriptional control of gene expression in yeast

Studies of the budding yeast Saccharomyces cerevisiae have greatly advanced our understanding of the posttranscriptional steps of eukaryotic gene expression. Given the wide range of experimental tools applicable to S. cerevisiae and the recent determination of its complete genomic sequence, many of the key challenges of the posttranscriptional control field can be tackled particularly effectively by using this organism. This article reviews the current knowledge of the cellular components and mechanisms related to translation and mRNA decay, with the emphasis on the molecular basis for rate control and gene regulation. Recent progress in characterizing translation factors and their protein-protein and RNA-protein interactions has been rapid. Against the background of a growing body of structural information, the review discusses the thermodynamic and kinetic principles that govern the translation process. As in prokaryotic systems, translational initiation is a key point of control. Modulation of the activities of translational initiation factors imposes global regulation in the cell, while structural features of particular 5' untranslated regions, such as upstream open reading frames and effector binding sites, allow for gene-specific regulation. Recent data have revealed many new details of the molecular mechanisms involved while providing insight into the functional overlaps and molecular networking that are apparently a key feature of evolving cellular systems. An overall picture of the mechanisms governing mRNA decay has only very recently begun to develop. The latest work has revealed new information about the mRNA decay pathways, the components of the mRNA degradation machinery, and the way in which these might relate to the translation apparatus. Overall, major challenges still to be addressed include the task of relating principles of posttranscriptional control to cellular compartmentalization and polysome structure and the role of molecular channelling in these highly complex expression systems.

Translation limits synthesis of an assembly-initiating coat protein of filamentous phage IKe

Translation is shown to be downregulated sharply between genes V and VII of IKe, a filamentous bacteriophage classed with the Ff group (phages f1, M13, and fd) but having only 55% DNA sequence identity to it. Genes V and VII encode the following proteins which are used in very different amounts: pV, used to coat the large number of viral DNA molecules prior to assembly, and pVII, used to serve as a cap with pIX in 3 to 5 copies on the end of the phage particle that emerges first from Escherichia coli. The genes are immediately adjacent to each other and are represented in the same amounts on the Ff and IKe mRNAs. Ff gene VII has an initiation site that lacks detectable intrinsic activity yet through coupling is translated at a level 10-fold lower than that of upstream gene V. The experiments reported reveal that by contrast, the IKe gene VII initiation site had detectable activity but was coupled only marginally to upstream translation. The IKe gene V and VII initiation sites both showed higher activities than the Ff sites, but the drop in translation at the IKe V-VII junction was unexpectedly severe, approximately 75-fold. As a result, gene VII is translated at similarly low levels in IKe- and Ff-infected hosts, suggesting that selection to limit its expression has occurred.

Mechanism of coordinated synthesis of the antagonistic regulatory proteins NifL and NifA of Klebsiella pneumoniae

The nifLA operon of Klebsiella pneumoniae codes for the two antagonistic regulatory proteins which control expression of all other nitrogen fixation genes. NifA is a transcriptional activator, and NifL inhibits NifA. The importance of a correct NifL-NifA stoichiometry for efficient regulation of nitrogen fixation genes has been investigated by constructing a strain with an altered nifL-nifA gene dosage ratio, resulting from the integration of an extra copy of nifA. Results showed that a balanced synthesis of both gene products is essential for correct regulation. Effects of mutations provoking translation termination of nifL upstream or downstream of its natural stop codon, combined with overproduction of both proteins when the genes are transcribed and translated from signals of the phi10 gene of the phage T7, showed that, in addition to the previously reported transcriptional polarity, there is translational coupling between nifL and nifA. In spite of the apparently efficient ribosome binding site of nifA, its rate of independent translation is very low. This is due to a secondary structure masking the Shine-Dalgarno sequence of nifA, which could be melted by ribosomes translating nifL. Mutational analysis confirmed the functional significance of the secondary structure in preventing independent translation of nifA. Translational coupling between the two cistrons is proposed as an efficient mechanism to prevent production of an excess of NifA, which would affect the normal regulation of nitrogen fixation genes.

The promoter-proximal, unstable IB region of the atp mRNA of Escherichia coli: an independently degraded region that can act as a destabilizing element

Differential expression of the genes in the Escherichia coli atp (unc) operon is achieved via control of the translational initiation, translational coupling and mRNA stability of the respective genes. The atpIB region of the polycistronic mRNA is less stable than the remaining seven genes. We have investigated the functional half-lives of the atp genes in reconstructed versions of the operon. In order to be able to do this reliably, we have readdressed the interpretation of the complex functional inactivation data obtained by means of transcriptional inhibition using rifampicin. Our results indicate the usable information to be gleaned from this commonly applied technique, while identifying the potential errors in their quantitative interpretation. We estimate that the functional half-life of atpB is slightly over one-half that of atpE and the other atp genes, while atpI is at least two times less stable than atpB. The instability of the atpI mRNA was also demonstrated by its rapid fragmentation. Relocation of atpIB to a position in the promoter-distal region of the operon between atpG and atpD did not change the inactivation rate of atpB. However, it did destabilize the atpG mRNA. Examination of the physical degradation of atpI mRNA shows particularly rapid cleavage in this gene, thus explaining the destabilization effect. The atpIB segment is therefore an autonomously unstable region that can act as a destabilizing element for upstream-located genes in a polycistronic environment.

Hybrid Fo complexes of the ATP synthases of spinach chloroplasts and Escherichia coli. Immunoprecipitation and mutant analyses

Hybrid Fo complexes of the ATP synthases of spinach chloroplast (CFo) and Escherichia coli (EFo) were investigated. Immunoprecipitations with polyclonal antibodies against the different Fo subunits clearly revealed that hybrid Fo complexes derived from CFo subunit III and EFo subunits a and b were formed in vivo. In addition, the ATPase activities of the hybrid ATP synthase, measured in everted cytoplasmic membranes of an atpE mutant strain transformed with the atpH gene coding for CFo III, were comparable to activities obtained for the same mutant strain complemented with the atpE gene (EFo c). Nevertheless, CFo III was not able to replace EFo c functionally, since the strain containing the hybrid ATP synthase was not able to grow on succinate. In order to investigate the reason for this lack of function, hybrid proteolipids of CFo III and EFo c were constructed. Only a chimaeric protein comprising the seven N-terminal amino acid residues from CFo III and the remaining part of EFo c was able to replace wild-type EFo c, whereas hybrid proteins with 13 and 33 N-terminal amino acids of CFo III were not functional. The results suggested that a network of interactions between the subunits essential for proton translocation and/or coupling of the F1 part exists, which was optimized for each species during evolution, although the overall structure of FoF1 complexes has been conserved.

Effects of deletions in the uncA-uncG intergenic regions on expression of uncG, the gene for the gamma subunit of the Escherichia coli F1Fo-ATPase

The gamma subunit of the E. coli F1Fo-ATPase is coded for by uncG. This gene is poorly expressed compared to uncA (alpha subunit), which precedes uncG in the unc operon. The genes are separated by a 50-nucleotide intergenic region. We examined the effects of a set of deletions in this region on the relative expression of uncA'-'lacZ and uncG'-'lacZ translational fusion genes located either in the chromosomal unc operon or at the chromosomal lambda att site. The gene for the alpha subunit was expressed 3-6-times better than the gene for the gamma subunit, depending upon chromosomal location. Deletion analysis revealed that the uncA-uncG intergenic region significantly affects expression of uncG, but the Shine-Dalgarno region is not absolutely required for expression of uncG. Different deletions resulted in either increased or decreased expression of uncG.

Cotranscription of two genes necessary for ribosomal protein L11 methylation (prmA) and pantothenate transport (panF) in Escherichia coli K-12

Genetic complementation and enzyme assays have shown that the DNA region between panF, which encodes pantothenate permease, and orf1, the first gene of the fis operon, encodes prmA, the genetic determinant for the ribosomal protein L11 methyltransferase. Sequencing of this region identified one long open reading frame that encodes a protein of 31,830 Da and corresponds to the prmA gene. We found, both in vivo and in vitro, that prmA is expressed from promoters located upstream of panF and thus that the panF and prmA genes constitute a bifunctional operon. We located the major 3' end of prmA transcripts 90 nucleotides downstream of the stop codon of prmA in the DNA region upstream of the fis operon, a region implicated in the control of the expression of the fis operon. Although no promoter activity was detected immediately upstream of prmA, S1 mapping detected 5' ends of mRNA in this region, implying that some mRNA processing occurs within the bicistronic panF-prmA mRNA.

Characterization of the cobalamin (vitamin B12) biosynthetic genes of Salmonella typhimurium

Salmonella typhimurium synthesizes cobalamin (vitamin B12) de novo under anaerobic conditions. Of the 30 cobalamin synthetic genes, 25 are clustered in one operon, cob, and are arranged in three groups, each group encoding enzymes for a biochemically distinct portion of the biosynthetic pathway. We have determined the DNA sequence for the promoter region and the proximal 17.1 kb of the cob operon. This sequence includes 20 translationally coupled genes that encode the enzymes involved in parts I and III of the cobalamin biosynthetic pathway. A comparison of these genes with the cobalamin synthetic genes from Pseudomonas denitrificans allows assignment of likely functions to 12 of the 20 sequenced Salmonella genes. Three additional Salmonella genes encode proteins likely to be involved in the transport of cobalt, a component of vitamin B12. However, not all Salmonella and Pseudomonas cobalamin synthetic genes have apparent homologs in the other species. These differences suggest that the cobalamin biosynthetic pathways differ between the two organisms. The evolution of these genes and their chromosomal positions is discussed.

Regulation of the Escherichia coli uncH gene by mRNA secondary structure and translational coupling

The uncH gene is one of the most poorly-expressed genes of the proton-translocating ATPase (unc) operon of Escherichia coli. We constructed in-frame lacZ fusions to uncH and used site-directed mutagenesis to decrease the stability of the putative mRNA secondary structure in the Shine and Dalgarno region for this gene. These mutations significantly increased the expression of uncH. We also used the unc-lac fusions to show that the insertion of stop codons and a frameshift mutation in uncF, the gene preceding uncH, caused a 10-fold reduction in uncH expression. Hybridization of total cellular RNA with a lacZ-specific probe indicated that transcriptional polarity could not account for the observed decrease in gene expression. These results demonstrate that uncH expression is controlled by mRNA sequences around the translational initiation region, and is translationally coupled to uncF, even in cases where the putative mRNA secondary structure is weakened or eliminated.

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.

Interdependence of translation, transcription and mRNA degradation in the lacZ gene

We have constructed a collection of Escherichia coli strains which differ by point mutations in the ribosome binding site (RBS) that drives the translation of the lacZ gene. These mutations affect the Shine-Dalgarno sequence or the initiation codon, or create secondary structures that sequester these elements, and result in a 200-fold variation in beta-galactosidase expression. Surprisingly, these variations of expression are paralleled by nearly equivalent changes in the lacZ mRNA level. The ratio of the beta-galactosidase expression to the mRNA level reflects the average spacing between translating ribosomes: hence, paradoxically, mutations that affect translation initiation do not correspondingly change this spacing. Further analysis of the mRNA level variations shows that they originate from two independent mechanisms. When beta-galactosidase expression exceeds a threshold corresponding roughly to one translation event per transcript, the variations in the efficiency of translation initiation affect largely the chemical and functional lifetimes of the mRNA. We further show that the rate-limiting step in the chemical decay process is an RNase E-dependent cleavage, which is outcompeted by translation initiation. Below this expression threshold, the mRNA lifetime levels out and strain-to-strain variations in mRNA level arise solely from polarity effects. We suggest that, in this activity range, most mRNA molecules that escape polarity are crossed by a single ribosome, and hence are identical from the viewpoint of degradation. Altogether, the tight couplings between translation initiation on one hand, polarity and/or mRNA degradation on the other, result in translation initiation events being closely spaced in time even from inefficient RBS, at the expense of the mRNA level. Finally, we evocate the possible beneficial consequences of a coupling between translation, transcription and mRNA degradation, for the management of cellular resources.

In the Escherichia coli lacZ gene the spacing between the translating ribosomes is insensitive to the efficiency of translation initiation

We have constructed a series of 44 Escherichia coli strains in which the chromosomal region corresponding to the Ribosome Binding Site (RBS) of the lacZ gene, has been replaced by small DNA fragments harboring either RBSs from other genes, or artificial RBSs. The beta-galactosidase expression from these strains ranges from 1 to 130 per cent of that of the parental strain. Using this collection, we demonstrate here that strain-to-strain variations in expression are paralleled by nearly equivalent variations in lacZ mRNA content. We propose that, in this system, polarity and mRNA stability are tightly coupled to translation initiation, so that changes in RBS efficiency are detected mainly as changes in mRNA concentration rather than in the spacing between translating ribosomes. In addition, we show that the mRNA sequence immediately downstream from the initiator codon influences per se the lifetime of the lacZ mRNA. We discuss the mechanism of the interdependence between translation, transcription and degradation in this gene, and speculate about the general role of this interdependence in determining the expression of bacterial genes.

The relation between translation and mRNA degradation in the lacZ gene

The technique of gene fusion, in which the gene of interest, severed from its 3' end, is in-phase fused to a reporter gene--usually lacZ--is widely used to study translational regulation in Escherichia coli. Implicit in these approaches is the assumption that the activity of the ribosome binding site (RBS) fused in-phase with lacZ, does not per se modify the steady-state level of the lacZ mRNA. Herein, we have tested this hypothesis, using a model system in which the RBS of the lamB gene is fused to lacZ. Several point mutations affecting translation initiation have been formerly characterized in this RBS, and we used Northern blots to study their effect upon the lacZ mRNA pattern. Two series of constructs were assayed: in the first one, a 51-bp fragment centered around the lamB initiator codon, was inserted in front of lacZ within the natural lactose operon, whereas in the second the lacZ gene was fused to the genuine malK-lamB operon just downstream from the lamB RBS. We observed that in the first series, the concentration and average molecular weight of the lacZ mRNA dropped sharply as the efficiency of the RBS decreased. This apparently arose from a decreased stability of the message, since the mRNA patterns are equalized when the endonuclease RNase E is inactivated. We suggest that in this case the rate limiting step in the decay process is an RNase E cleavage that is outcompeted by translation.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection and localization of the i protein in Escherichia coli cells using antibodies

Using antibodies raised against the purified i protein, the expression of the chromosomal uncI gene was demonstrated. The i protein was identified as a component of the cytoplasmic membrane and shown to be present in preparations of Fo or F1Fo. The protein is not associated with the F1 moiety.

Differential gene expression from the Escherichia coli atp operon mediated by segmental differences in mRNA stability

The atp operon of Escherichia coli directs synthesis rates of protein subunits that are well matched to the requirements of assembly of the membrane-bound H(+)-ATPase (alpha 3 beta 3 gamma 1 delta 1 epsilon 1a1b2c10-15). Segmental differences in mRNA stability are shown to contribute to the differential control of atp gene expression. The first two genes of the operon, atpl and atpB, are rapidly inactivated at the mRNA level. The remaining seven genes are more stable. It has previously been established that the translational efficiencies of the atp genes vary greatly. Thus differential expression from this operon is achieved via post-transcriptional control exerted at two levels. Neither enhancement of translational efficiency nor insertion of repetitive extragenic palindromic (REP) sequences into the atplB intercistronic region stabilized atpl. We discuss the implications of these results in terms of the pathway of mRNA degradation and of the role of mRNA stability in the control of gene expression.