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

Characterization of Regulatory Elements of L11 and L1 Operons in Thermophilic Bacteria and Archaea

Ribosomal protein L1 is a conserved two-domain protein that is involved in formation of the L1 stalk of the large ribosomal subunit. When there are no free binding sites available on the ribosomal 23S RNA, the protein binds to the specific site on the mRNA of its own operon (L11 operon in bacteria and L1 operon in archaea) preventing translation. Here we show that the regulatory properties of the r-protein L1 and its domain I are conserved in the thermophilic bacteria Thermus and Thermotoga and in the halophilic archaeon Haloarcula marismortui. At the same time the revealed features of the operon regulation in thermophilic bacteria suggest presence of two regulatory regions.

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.

In polycistronic Qbeta RNA, single-strandedness at one ribosome binding site directly affects translational initiations at a distal upstream cistron

In Qβ RNA, sequestering the coat gene ribosome binding site in a putatively strong hairpin stem structure eliminated synthesis of coat protein and activated protein synthesis from the much weaker maturation gene initiation site, located 1300 nucleotides upstream. As the stability of a hairpin stem comprising the coat gene Shine-Dalgarno site was incrementally increased, there was a corresponding increase in translation of maturation protein. The effect of the downstream coat gene ribosome binding sequence on maturation gene expression appeared to have occurred only in cis and did not require an AUG start codon or initiation of coat protein synthesis. In all cases, no structural reorganization was predicted to occur within Qβ RNA. Our results suggest that protein synthesis from a relatively weak translational initiation site is greatly influenced by the presence or absence of a stronger ribosome binding site located elsewhere on the same RNA molecule. The data are consistent with a mechanism in which multiple ribosome binding sites compete in cis for translational initiations as a means of regulating protein synthesis on a polycistronic messenger RNA.

Requirements for translation re-initiation in Escherichia coli: roles of initiator tRNA and initiation factors IF2 and IF3

Despite its importance in post-transcriptional regulation of polycistronic operons in Escherichia coli, little is known about the mechanism of translation re-initiation, which occurs when the same ribosome used to translate an upstream open reading frame (ORF) also translates a downstream ORF. To investigate translation re-initiation in Escherichia coli, we constructed a di-cistronic reporter in which a firefly luciferase gene was linked to a chloramphenicol acetyltransferase gene using a segment of the translationally coupled geneV–geneVII intercistronic region from M13 phage. With this reporter and mutant initiator tRNAs, we show that two of the unique properties of E. coli initiator tRNA – formylation of the amino acid attached to the tRNA and binding of the tRNA to the ribosomal P-site – are as important for re-initiation as for de novo initiation. Overexpression of IF2 or increasing the affinity of mutant initiator tRNA for IF2 enhanced re-initiation efficiency, suggesting that IF2 is required for efficient re-initiation. In contrast, overexpression of IF3 led to a marked decrease in re-initiation efficiency, suggesting that a 30S ribosome and not a 70S ribosome is used for translation re-initiation. Strikingly, overexpression of IF3 also blocked E. coli from acting as a host for propagation of M13 phage.

Limitation of ribosomal protein L11 availability in vivo affects translation termination

Historically referred to as "the GTPase center", the L11 binding region (L11BR) of Escherichia coli 23 S rRNA is a highly conserved structure that has been implicated in several essential functions during protein synthesis. Here, in vivo expression of an RNA fragment containing that structure was found to affect translation termination in a codon-specific manner. The cause of these effects appeared to be titration of ribosomal protein L11, since normal phenotypes could be restored by simultaneous overproduction of wild-type L11 but not mutant L11. Subsequently, altered termination phenotypes were produced when the availability of L11 was limited by overexpression of RNA antisense to L11 mRNA and, finally, by inactivation of the chromosomal L11 gene, and they too were reversible by simultaneous expression of cloned L11. Our results indicate that in the intact cell the L11BR is an integral functional unit important for translation termination and that the presence of L11 in ribosomes is required for UAG-dependent termination and is somewhat inhibitory of UGA-dependent termination.

Role of ribosome recycling factor (RRF) in translational coupling

RNA phage GA coat and lysis protein expression are translationally coupled through an overlapping termination and initiation codon UAAUG. Essential for this coupling are the proximity of the termination codon of the upstream coat gene to the initiation codon of the lysis gene (either a <3 nucleotide separation or physical closeness through a possible hairpin structure) but not the Shine-Dalgarno sequence. This suggests that the ribosomes completing the coat gene translation are exclusively responsible for translation of the lysis gene. Inactivation of ribosome recycling factor (RRF), which normally releases ribosomes at the termination codon, did not influence the expression of the reporter gene fused to the lysis gene. This suggests the possibility that RRF may not release ribosomes from the junction UAAUG. However, RRF is essential for correct ribosomal recognition of the AUG codon as the initiation site for the lysis gene.

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.

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.

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.

Mutational analysis of an inherently defective translation initiation site

In a reverse of many studies of translational initiation sites, we have explored the basis for the inactivity of an apparently defective initiation site. Gene VII of the filamentous phage f1 has a translational start site with highly unusual functional properties and a sequence dissimilar to a prokaryotic ribosome binding site. The VII site shows no activity in assays of independent initiation, even in a deletion series designed to remove potentially interfering RNA secondary structure. Activity from the VII site is only observed if the site is coupled to a source of translation immediately upstream, but its efficiency is low at a one-nucleotide spacing from the stop codon of the upstream cistron and extremely sensitive to the distance between the stop codon and the gene VII AUG. These and other atypical characteristics of coupling distinguish the VII site from most coupled initiation sites. To identify the pattern of nucleotide substitutions that give the VII site the capacity for independent initiation, a series of designed and random point mutations were introduced in the sequence. Improving the Shine-Dalgarno complementarity from GG to GGAG or GGAGG made activity detectable, but at only low levels. Random substitutions, each increasing activity above background by a small increment, were found at 16 positions throughout the region of ribosome contact. These substitutions lengthened the Shine-Dalgarno complementarity or changed the G and C residues present in the wild-type site to A or T. Significant activity was not observed unless a strong Shine-Dalgarno sequence and a number of the up-mutations were present together. The nature and distribution of the substitutions and their agreement with the known preferences for nucleotides in initiation sites provide evidence that the VII site's major defect is its primary sequence overall. It appears to lack the specialized sequence required to bind free 30 S ribosomes, and thus depends on the translational coupling process to give it limited activity.

Cloning, sequencing, expression, and functional studies of a 15,000-molecular-weight Haemophilus somnus antigen similar to Escherichia coli ribosomal protein S9

Haemophilus somnus is a gram-negative bacterium capable of causing a number of disease syndromes in cattle. This article describes the cloning and characterization of a gene coding for a 15,000-molecular-weight (15K) polypeptide which reacts strongly with antiserum against H. somnus. Analysis of plasmid-encoded polypeptides by polyacrylamide gel electrophoresis showed that the corresponding gene is the second in a transcriptional unit. The first gene codes for a protein with a molecular weight of approximately 17,000. Using antiserum against the two recombinant proteins, we could show that the natural proteins are predominantly present in purified ribosomes from H. somnus. The nucleotide sequence of both genes and flanking regions has been determined, and the deduced amino acid sequence of the two polypeptides was used to search for sequence homology in the GenBank data base. The 15K polypeptide showed 89% similarity to the Escherichia coli ribosomal protein S9, and the 17K polypeptide showed 94% similarity to the E. coli ribosomal protein L13. In E. coli, the corresponding genes constitute a bicistronic operon, with the same gene order as that found in H. somnus. A plasmid expressing the 15K protein was found to complement an E. coli rpsI mutation. When a frameshift mutation was introduced into the 15K protein gene, the resulting plasmid failed to complement this rpsI mutation, demonstrating functional homology between the 15K protein and S9 from E. coli. Downstream from the 15K protein gene is located another open reading frame, which could code for a polypeptide with a predicted molecular weight of 24,427. A protein with a similar molecular weight was detected in minicells containing the recombinant clone. This polypeptide is 69% similar to the stringent starvation protein (Ssp) of E. coli.

Protective Surface Antigen P69 of Bordetella pertussis: Its Characterization and Very High Level Expression in Escherichia coli

The surface antigen, P69 of Bordetella pertussis, an N-terminal fragment of the precursor protein, P93, is likely to be an important component of future subunit vaccines against whooping cough. We have expressed several defined N-terminal fragments of P93 in E. coli and compared their electrophoretic mobilities with that of purified P69 from B. pertussis. These experiments show that P69 is considerably smaller than the 69 kD originally estimated from its gel mobility and is probably 60.4 kD in size. Our initial plasmids expressed only very low levels of this antigen. We diagnosed the limiting factor to be a poor ribosome binding site (RBS) by demonstrating a large stimulation of expression on a two-cistron plasmid. The limitation of expression could be completely overcome by only two base changes close to the initiation codon, resulting in a further increase in expression of P69 at levels to 30-40% total cell protein. Although the protein accumulated as insoluble inclusion bodies, it could be solubilized by guanidinium chloride.

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.

Translated translational operator in Escherichia coli. Auto-regulation in the infC-rpmI-rplT operon

The genes coding for translation initiation factor IF3 (infC) and for the ribosomal proteins L35 (rpmI) and L20 (rplT) are transcribed in that order from a promoter in front of infC. The last two cistrons of the operon (rpmI and rplT) can be transcribed from a weak secondary promoter situated within the first cistron (infC). Previous experiments have shown that the expression of infC, the first cistron of the operon, is negatively autoregulated at the translational level and that the abnormal AUU initiation codon of infC is responsible for the control. We show that the expression of the last cistron (rplT) is also autoregulated at the posttranscriptional level. The L20 concentration regulates the level of rplT expression by acting in trans at a site located within the first cistron (infC) and thus different from that at which IF3 is known to act. This regulatory site, several hundred nucleotides upstream from the target gene (rplT), was identified through deletions, insertions and a point mutation. Thus, the expression of the operon is controlled in trans by the products of two different cistrons acting at two different sites. The localization within an open reading frame (infC) of a regulatory site acting in cis on the translation of a downstream gene (rplT) is new and was unforeseen since ribosomes translating through the regulatory site might be expected to impair either the binding of L20 or the mRNA secondary structure change caused by the binding. The possible competition between translation of the regions acting in cis and the regulation of the expression of the target gene is discussed.

The use of two-cistron constructions in improving the expression of a heterologous gene in E. coli

Many heterologous genes when cloned into bacterial expression vectors are poorly expressed because of an inefficient ribosome binding site (RBS). We have constructed a plasmid which expresses human gamma-interferon (gamma-IF), where the level of expression is limited by the RBS. Expression was increased by placing the gamma-IF sequence immediately downstream of a small translated sequence. The production of gamma-IF was dependent upon the efficiency of translation of this upstream cistron and could be increased to very high levels. The same upstream cistron would greatly improve the expression of gamma-IF in a plasmid where the RBS was very poor due to inhibitory secondary structure at the 5' end of its mRNA. However, it would not improve the efficiency of a poor RBS containing a weak Shine-Dalgarno sequence. The general utility of the two-cistron expression strategy to diagnose a weak RBS is discussed.

Heat-inducible translational coupling in Bacillus subtilis

Bacillus subtilis plasmid pGR71 is a promoter-probe shuttle vector derived from pUB110. The expression of the cat gene on pGR71 in B. subtilis requires the insertion of a Bacillus promoter and a ribosomal binding site (RBS) into the HindIII cloning site immediately upstream from the cat gene. A recombinant plasmid of pGR71, named pGR71-369, was obtained by a spontaneous deletion of a fragment containing most of the inserted HindIII fragment and the replication origin necessary for multiplication in Escherichia coli. The expression of the cat gene in B. subtilis cells carrying this plasmid was inducible by heat. Nucleotide sequence analysis of the upstream region of the cat gene, deletion analysis, and dot blot hybridization analysis of mRNA in various conditions revealed that the cat gene was expressed by heat-inducible translational coupling and that the regulatory region of heat inducibility was present in the upstream region of the cat gene.

DNA sequence analysis of five genes; tnsA, B, C, D and E, required for Tn7 transposition

A region of DNA sequence of the bacterial transposon Tn7, which is required for transposition, has been determined. This DNA sequence completes an 8351 base pair (bp) region containing five long open reading frames (ORF's) that correspond to the genetically defined genes, tnsA, B, C, D and E, required for Tn7 transposition. All of the ORF's are oriented in the same direction, ie. inward from the element's right end. The genes are in a very compact arrangement with the presumed initiation codons never more than two bases beyond the preceding termination codon. Domains with similarity to the helix-turn-helix genre of Cro-like, sequence specific DNA binding sites occur within the deduced amino acid (a.a.) sequence of the TnsA, TnsB, TnsD and TnsE proteins. Translation of the tnsC ORF reveals strong homology to a consensus sequence for nucleotide binding sites as well as a region of similarity to a transcriptional activator (MalT). No striking a.a. sequence similarity to other DNA recombinases is observed. The possible roles of these proteins in Tn7 transposition is discussed in light of the analysis presented.

Translational reinitiation in the presence and absence of a Shine and Dalgarno sequence

The process of translational reinitiation in Escherichia coli was studied in a two cistron system where expression of the downstream reporter gene was dependent on translation of an upstream reading frame. The dependence was almost absolute. Upstream translation increased expression of the downstream gene by two to three orders of magnitude. This large difference allowed us to quantitate restarts in a meaningful manner. In the absence of a Shine and Dalgarno (SD) region reinitiation occurred but its efficiency was about 10% of that found in the SD carrying counterpart. We discuss three ways by which translational coupling between neighboring cistrons can be enforced.

Translation of phage f1 gene VII occurs from an inherently defective initiation site made functional by coupling

Expression of the filamentous phage f1 gene VII is shown to be translationally coupled to that of the upstream gene V. Fusions of the gene VII initiation site to the lacZ coding region were used to determine that initiation at the VII site is completely dependent on the process of translation having proceeded up to a stop codon immediately upstream from the VII site. Coupled expression from the VII site was found to be inefficient, proportional to the level of upstream translation, and very sensitive to the distance from the functional upstream stop codon. Independent expression from the VII site was not observed, even in a deletion series designed to remove potentially masking RNA structure. On the basis of the VII site's dissimilarity to ribosome binding site sequences and its properties overall, we suggest that it inherently lacks the features required for independent recognition by ribosomes, and acquires the ability to initiate synthesis of gene VII protein by virtue of the coupling process.

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.

SecA protein autogenously represses its own translation during normal protein secretion in Escherichia coli

The Escherichia coli secA gene, whose expression is responsive to the protein secretion status of the cell, is the second gene in an operon. We found that both the basal and induced levels of SecA biosynthesis are dependent on prior translation of the upstream gene, gene X, and identified two large gene X-secA transcripts. The 10-fold derepression of secA expression by protein export defects was at the translational level since no further increases in gene X or secA mRNA levels were detected during this period, and a secA-lacZ protein fusion but not an operon fusion was appropriately derepressed. Furthermore, overexpression of the SecA protein severely reduced expression of only the secA-lacZ protein fusion, indicating that SecA autogenously represses its own translation.

What constitutes the signal for the initiation of protein synthesis on Escherichia coli mRNAs?

Small DNA fragments (60 to 80 nucleotides), randomly obtained from a collection of 14 catabolic, biosynthetic or regulatory Escherichia coli genes, have been shot-gun cloned in place of the lacZ ribosome binding site. A total of 47 recombinants showing substantial beta-galactosidase synthesis (at least 1/30th of the wild-type) were isolated, and their newly acquired translational starts were characterized. Of these, 46 were found to carry a ribosome binding site from one of the original genes, and only one, a non-natural start. Moreover, 12 out of the 14 natural starts were found. The two that were not found are the only ones lacking a Shine-Dalgarno element. So, real starts are generally active in the lac mRNA, whereas the many sites (approx. 100 in this gene collection) that carry a Shine-Dalgarno element followed by AUG or GUG but are located in intra- or intergenic regions, or on non-transcribed strands, are inactive. I conclude that: (1) these "false" starts, being strongly discriminated against in the lac message, are presumably also inactive in their original mRNAs; (2) the discriminating information, being portable from one mRNA to another, must be contained within a small DNA region surrounding the starts. Indeed, I further show that it generally lies within a sequence of about 35 nucleotides bracketing real starts; and (3) this information must have a larger effect on initiation than the exact structure of the mRNA, because the discrimination persists despite a complete change of this structure. Previous statistical analysis has shown that real starts differ from false starts in having a non-random sequence composition from nucleotides -20 to +15 with respect to the start. To uncover whether these biases constitute the discriminating information or simply reflect coding constraints, translational starts were randomly searched in eukaryotic, largely non-coding, DNA. These "eukaryotic" starts all have an in-phase AUG or GUG, preceded by a typical Shine-Dalgarno sequence; outside these elements, the initiator region is strikingly rich in A, and poor in C. These biases match those found around real starts, demonstrating that they are indeed part of the initiation signal. Finally, I describe a simple procedure for introducing any DNA fragment in place of the lac operator site on the E. coli chromosome.

Structure and function of the Salmonella typhimurium and Escherichia coli K-12 histidine operons

We have determined the complete nucleotide sequence of the histidine operons of Escherichia coli and of Salmonella typhimurium. This structural information enabled us to investigate the expression and organization of the histidine operon. The proteins coded by each of the putative histidine cistrons were identified by subcloning appropriate DNA fragments and by analyzing the polypeptides synthesized in minicells. A structural comparison of the gene products was performed. The histidine messenger RNA molecules produced in vivo and the internal transcription initiation sites were identified by Northern blot analysis and S1 nuclease mapping. A comparative analysis of the different transcriptional and translational control elements within the two operons reveals a remarkable preservation for most of them except for the intercistronic region between the first (hisG) and second (hisD) structural genes and for the rho-independent terminator of transcription at the end of the operon. Overall, the operon structure is very compact and its expression appears to be regulated at several levels.

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.

Translational coupling between the ilvD and ilvA genes of Escherichia coli

The hypothesis that translation of the ilvD and ilvA genes of Escherichia coli may be linked has been examined in strains in which lacZ-ilvD protein fusions are translated in all three reading frames with respect to ilvD. In these strains, the nucleotide sequence was altered to obtain premature termination of ilvD translation, and in one strain translation termination of ilvD DNA occurred two bases downstream of the ilvA initiation codon. In the wild-type strain, the ilvD translation termination site was located two bases upstream of the ilvA start codon. In each of the mutant strains, expression of ilvA, as determined by the level of threonine deaminase activity, was strikingly lower than in the wild-type strain. The data suggest that expression of ilvD and ilvA is translationally coupled. By inserting a promoterless cat gene downstream of ilvA, it was shown that the differences in enzyme activity were not the result of differences in the amount of ilvA mRNA produced.

Cloning and DNA sequence determination of the L11 ribosomal protein operon of Serratia marcescens and Proteus vulgaris: translational feedback regulation of the Escherichia coli L11 operon by heterologous L1 proteins

In Escherichia coli the genes encoding ribosomal proteins L11 (rplK) and L1 (rplA) are contained in a single operon and their expression is translationally regulated by L1. We have cloned the homologous genes from two other enterobacteria, Serratia marcescens and Proteus vulgaris, and determined nucleotide sequences. The genes are organized in a similar way to that found in E. coli. Conservation of nucleotide and amino acid sequences relative to E. coli in the protein coding regions are 89.2% and 94.7% for S. marcescens, and 80.9% and 88.6% for P. vulgaris. Nucleotide sequences of L11 mRNA leader regions were strongly conserved for the primary as well as the secondary structures in the L1 target site. We have also constructed plasmids carrying E. coli L11 and either P. vulgaris or S. marcescens L1 genes fused to the lac promoter, with or without the E. coli leader containing the L1 target site. Induction of transcription of the operons possessing the E. coli mRNA leader did not lead to overproduction of L11, indicating translational regulation of the chimeric operon as well as the chromosomal operon by the plasmid encoded L1. Repression of the chromosomal L11 operon was directly demonstrated upon induction of the chimeric operons without the leader, which also lack the L11 initiation signal but have a mutation allowing L1 translation.(ABSTRACT TRUNCATED AT 250 WORDS)