Regions of DNA involved in the stringent control of plasmid-encoded rRNA in vivo

Ribosomal protein S4 is a transcription factor with properties remarkably similar to NusA, a protein involved in both non-ribosomal and ribosomal RNA antitermination

Escherichia coli ribosomal RNA (rRNA) operons contain antitermination motifs necessary for forming terminator-resistant transcription complexes. In preliminary work, we isolated 'antiterminating' transcription complexes and identified four new proteins potentially involved in rRNA transcription antitermination: ribosomal (r-) proteins S4, L3, L4 and L13. We show here that these r-proteins and Nus factors lead to an 11-fold increase in terminator read-through in in vitro transcription reactions. A significant portion of the effect was a result of r-protein S4. We show that S4 acted as a general antitermination factor, with properties very similar to NusA. It retarded termination and increased read-through at Rho-dependent terminators, even in the absence of the rRNA antiterminator motif. High concentrations of NusG showed reduced antitermination by S4. Like rrn antitermination, S4 selectively antiterminated at Rho-dependent terminators. Lastly, S4 tightly bound RNA polymerase in vivo. Our results suggest that, like NusA, S4 is a general transcription antitermination factor that associates with RNA polymerase during normal transcription and is also involved in rRNA operon antitermination. A model for key r-proteins playing a regulatory role in rRNA synthesis is presented.

Functional determinants of the Escherichia coli fis promoter: roles of -35, -10, and transcription initiation regions in the response to stringent control and growth phase-dependent regulation

Escherichia coli Fis is a small DNA binding and bending protein that has been implicated in a variety of biological processes. A minimal promoter sequence consisting of 43 bp is sufficient to generate its characteristic growth phase-dependent expression pattern and is also subject to negative regulation by stringent control. However, information about the precise identification of nucleotides contributing to basal promoter activity and its regulation has been scant. In this work, 72 independent mutations were generated in the fis promoter (fis P) region from -108 to +78 using both random and site-directed PCR mutagenesis. beta-Galactosidase activities from mutant promoters fused to the (trp-lac)W200 fusion on a plasmid were used to conclusively identify the sequences TTTCAT and TAATAT as the -35 and -10 regions, respectively, which are optimally separated by 17 bp. We found that four consecutive substitutions within the GC-rich sequence just upstream of +1 and mutations in the -35 region, but not in the -10 region, significantly reduced the response to stringent control. Analysis of the effects of mutations on growth phase-dependent regulation showed that replacing the predominant transcription initiation nucleotide +1C with a preferred nucleotide (A or G) profoundly altered expression such that high levels of fis P mRNA were detected during late logarithmic and early stationary phases. A less dramatic effect was seen with improvements in the -10 and -35 consensus sequences. These results suggest that the acute growth phase-dependent regulation pattern observed with this promoter requires an inefficient transcription initiation process that is achieved with promoter sequences deviating from the -10 and -35 consensus sequences and, more importantly, a dependence upon the availability of the least favored transcription initiation nucleotide, CTP.

Mutational analysis of two highly conserved UGG sequences of 23 S rRNA from Escherichia coli

The 23 S-type rRNA contains two phylogenetically conserved UGG sequences, which have the potential to bind the universal CCA-3'-ends of tRNAs at the ribosomal peptidyltransferase center by base pairing. The first two positions, UG, of these sequences at the helix-loop 80 (U2249G2250) and helix-loop 90 (Psi2580G2581) and some related nucleotides were tested by site-directed mutagenesis for their involvement in ribosomal function, i.e. peptidyltransferase. The plasmid-derived mutated 23 S rRNA comprised about 50% of the total 23 S rRNA. None of the single mutations caused an assembly defect, and all 50 S subunits carrying an altered 23 S rRNA could freely exchange with the pools of 70S ribosomes and polysomes. The mutations at the helix-loop 80 region hardly affected bacterial growth. However, mutations at the helix 90 caused severe growth effects and severely impaired the in vitro protein synthesis, showing that this 23 S rRNA region is of high importance for ribosomal function.

rRNA transcription and growth rate-dependent regulation of ribosome synthesis in Escherichia coli

The synthesis of ribosomal RNA is the rate-limiting step in ribosome synthesis in bacteria. There are multiple mechanisms that determine the rate of rRNA synthesis. Ribosomal RNA promoter sequences have evolved for exceptional strength and for regulation in response to nutritional conditions and amino acid availability. Strength derives in part from an extended RNA polymerase (RNAP) recognition region involving at least two RNAP subunits, in part from activation by a transcription factor and in part from modification of the transcript by a system that prevents premature termination. Regulation derives from at least two mechanistically distinct systems, growth rate-dependent control and stringent control. The mechanisms contributing to rRNA transcription work together and compensate for one another when individual systems are rendered inoperative.

The RNA chain elongation rate of the lambda late mRNA is unaffected by high levels of ppGpp in the absence of amino acid starvation

In this study, the effects of high levels of guanosine tetraphosphate (ppGpp) on the decay and RNA chain elongation kinetics of the bacteriophage lambda late transcript in Escherichia coli were examined in the absence of amino acid starvation. The accumulation, mRNA decay kinetics, and RNA chain elongation rate of the lambda late mRNA were determined after heat induction of lambdacI857 lysogens in the presence of high levels of ppGpp induced from a RelAalpha fragment-overproducing plasmid. The accumulation kinetics and elongation rate determinations of the late mRNA were made at long times after induction to allow a new steady state of transcriptional activities under conditions of elevated intracellular levels of ppGpp. The results indicate no prolonged or significant effect on either mRNA decay or the RNA chain elongation rate of the late mRNA as a result of elevated ppGpp levels. Surprisingly, the RNA chain elongation rate determinations indicate an RNA polymerase processivity of approximately 90-100 nucleotides/s for the lambda late transcript despite the presence of high levels of ppGpp. The results are discussed in terms of various models for regulation of stable and messenger RNA synthesis in E. coli.

Control of rRNA transcription in Escherichia coli

The control of rRNA synthesis in response to both extra- and intracellular signals has been a subject of interest to microbial physiologists for nearly four decades, beginning with the observations that Salmonella typhimurium cells grown on rich medium are larger and contain more RNA than those grown on poor medium. This was followed shortly by the discovery of the stringent response in Escherichia coli, which has continued to be the organism of choice for the study of rRNA synthesis. In this review, we summarize four general areas of E. coli rRNA transcription control: stringent control, growth rate regulation, upstream activation, and anti-termination. We also cite similar mechanisms in other bacteria and eukaryotes. The separation of growth rate-dependent control of rRNA synthesis from stringent control continues to be a subject of controversy. One model holds that the nucleotide ppGpp is the key effector for both mechanisms, while another school holds that it is unlikely that ppGpp or any other single effector is solely responsible for growth rate-dependent control. Recent studies on activation of rRNA synthesis by cis-acting upstream sequences has led to the discovery of a new class of promoters that make contact with RNA polymerase at a third position, called the UP element, in addition to the well-known -10 and -35 regions. Lastly, clues as to the role of antitermination in rRNA operons have begun to appear. Transcription complexes modified at the antiterminator site appear to elongate faster and are resistant to the inhibitory effects of ppGpp during the stringent response.

Guanosine tetraphosphate as a global regulator of bacterial RNA synthesis: a model involving RNA polymerase pausing and queuing

A recently reported comparison of stable RNA (rRNA, tRNA) and mRNA synthesis rates in ppGpp-synthesizing and ppGpp-deficient (delta relA delta spoT) bacteria has suggested that ppGpp inhibits transcription initiation from stable RNA promoters, as well as synthesis of (bulk) mRNA. Inhibition of stable RNA synthesis occurs mainly during slow growth of bacteria when cytoplasmic levels of ppGpp are high. In contrast, inhibition of mRNA occurs mainly during fast growth when ppGpp levels are low, and it is associated with a partial inactivation of RNA polymerase. To explain these observations it has been proposed that ppGpp causes transcriptional pausing and queuing during the synthesis of mRNA. Polymerase queuing requires high rates of transcription initiation in addition to polymerase pausing, and therefore high concentrations of free RNA polymerase. These conditions are found in fast growing bacteria. Furthermore, the RNA polymerase queues lead to a promoter blocking when RNA polymerase molecules stack up from the pause site back to the (mRNA) promoter. This occurs most frequently at pause sites close to the promoter. Blocking of mRNA promoters diverts RNA polymerase to stable RNA promoters. In this manner ppGpp could indirectly stimulate synthesis of stable RNA at high growth rates. In the present work a mathematical analysis, based on the theory of queuing, is presented and applied to the global control of transcription in bacteria. This model predicts the in vivo distribution of RNA polymerase over stable RNA and mRNA genes for both ppGpp-synthesizing and ppGpp-deficient bacteria in response to different environmental conditions. It also shows how small changes in basal ppGpp concentrations can produce large changes in the rate of stable RNA synthesis.

Evidence for a ppGpp-binding site on Escherichia coli RNA polymerase: proximity relationship with the rifampicin-binding domain

On amino acid starvation, Escherichia coli cells exhibit an adaptive facility termed the stringent response. This is characterized by the production of high levels of a regulatory nucleotide, ppGpp, and concomitant curtailment in rRNA synthesis. Various studies reported earlier indicated that RNA polymerase is the site of action of ppGpp although a direct demonstration of the interaction of ppGpp with E. coli RNA polymerase is still lacking. Here we report the labelling of ppGpp with a fluorescent probe, 1-aminonapthalene-5-sulphonate (AmNS), at the terminal phosphates. AmNS-ppGpp responded much like a ppGpp molecule in an in vitro total transcription assay at selective promoters. Fluorescence titration of the tryptophan emission of RNA polymerase by AmNS-ppGpp indicated a unique binding site in the absence of template DNA. Competition experiments showed that unlabelled ppGpp binds to the enzyme at the same site. Sigma factor seems to have no effect on this binding. The titration profile is also characterized by a single slope in the Scatchard analysis. The presence of GTP or GDP does not influence the binding of AmNS-ppGpp with RNA polymerase. Forster's distance measurement was carried out which placed AmNS-ppGpp 27 A away from the rifampicin-binding domain of RNA polymerase.

A physical map of the Myxococcus xanthus chromosome

A physical map of the 9.2-Mbp Myxococcus xanthus DK1622 chromosome at a resolution of 25 kbp was constructed by using a strategy that is applicable to virtually all microorganisms. Segments of the chromosome were used as hybridization probes to subdivide a yeast artificial chromosome (YAC) library into groups of linked clones. The clones were aligned by comparing their EcoRI restriction patterns. The groups of YAC clones ("contigs") were oriented and aligned with the genomic restriction map by means of common genetic and physical markers such as rare restriction sites and transposon insertions. Over 95% of the genome is represented by cloned DNA. Sixty genetic loci including > 100 genes, many of which play a role in fruiting body development, have been mapped in this way. Additional genes can now be located on the chromosome map by hybridization of their sequences to the ordered set of YAC chromosomes. The mapped genetic loci account for approximately 2% of the genome.

Growth rate-dependent control of the rrnB P1 core promoter in Escherichia coli

We have extended our previous studies of the DNA sequences required for growth rate-dependent control of rRNA transcription in Escherichia coli. Utilizing a reporter system suitable for evaluation of promoters with low activities, we have found that the core promoter region of rrnB P1 (-41 to +1 with respect to the transcription initiation site) is sufficient for growth rate-dependent control of transcription, both in the presence and in the absence of guanosine 3'-diphosphate 5'-diphosphate (ppGpp). The core promoter contains the -10 and -35 hexamers for recognition by the sigma 70 subunit of RNA polymerase but lacks the upstream (UP) element, which increases transcription by interacting with the alpha subunit of RNA polymerase. It also lacks the binding sites for the positive transcription factor FIS. Thus, the UP element, FIS, and ppGpp are not needed for growth rate-dependent regulation of rRNA transcription. In addition, we find that several core promoter mutations, including -10 and -35 hexamer substitutions, severely reduce rrnB P1 activity without affecting growth rate-dependent control. Thus, a high activity is not a determinant of growth rate regulation of rRNA transcription.

Interrelated effects of DNA supercoiling, ppGpp, and low salt on melting within the Escherichia coli ribosomal RNA rrnB P1 promoter

The formation of complexes containing high levels of DNA melting at the ribosomal RNA rrnB P1 promoter in vitro is shown to be facilitated by DNA supercoiling or low salt. The effector nucleotide ppGpp is ineffective under these conditions. The loss of supercoils or addition of salt increases the effectiveness of ppGpp in inhibiting formation of these complexes. In vivo plasmid DNA supercoiling is shown to decrease during starvation protocols that also increase levels of ppGpp. The results suggest that ppGpp regulation may be affected by the state of DNA supercoiling in vivo.

Novel mutants of 23S RNA: characterization of functional properties

Single point mutations corresponding to the positions G2505 and G2583 have been constructed in the gene encoding E.coli 23S rRNA. These mutations were linked to the second mutation A1067 to T, known to confer resistance to thiostrepton (1). Mutant ribosomes were analyzed in vitro for their ability to direct poly(U) dependent translation, their missence error frequency and in addition their sensitivity to peptidyltransferase inhibitors. It was evident that the mutated ribosomes had an altered dependence on [Mg2+] and an increased sensitivity to chloramphenicol during poly(U) directed poly(Phe) synthesis. In a transpeptidation assay mutated ribosomes were as sensitive to chloramphenicol as wild-type ribosomes. However, the mutant ribosomes exhibited an increased sensitivity to lincomycin. An increase in translational accuracy was attributed to the mutations at the position 2583: accuracy increased in the order G less than A less than U less than C.

Mutations in E.coli 16s rRNA that enhance and decrease the activity of a suppressor tRNA

The in vivo expression of mutations constructed within helix 34 of 16S rRNA has been examined together with a nonsense tRNA suppressor for their action at stop codons. The data revealed two novel results: in contrast to previous findings, some of the rRNA mutations affected suppression at UAA and UAG nonsense codons. Secondly, both an increase and a decrease in the efficiency of the suppressor tRNA were induced by the mutations. This is the first report that rRNA mutations decreased the efficiency of a suppressor tRNA. The data are interpreted as there being competition between the two release factors (RF-1 and RF-2) for an overlapping domain and that helix 34 influences this interaction.

Ribosomes containing the C1054-deletion mutation in E. coli 16S rRNA act as suppressors at all three nonsense codons

It was established some time ago that the deletion of base C1054 in E. coli 16S rRNA specifically affects UGA-dependent termination of translation. Based on this observation, a model for the termination event was proposed in which the UGA nonsense codon on the mRNA base-pairs with a complementary motif in 'helix 34' of the 16S rRNA, thus potentially providing a recognition signal for the binding of the release factor. This model has been re-examined here and evidence is presented which demonstrates that ribosomes containing the C1054 delta mutation enhance the activity of suppressors of both UAG and UAA termination codons introduced into the host. The results do not support the nonsense codon-16S rRNA base pairing model, and rather imply a more general involvement of 'helix 34' in the translation termination reactions.

A single mutation in 16S rRNA that affects mRNA binding and translation-termination

A single base change in 16S rRNA (C726 to G) has previously been shown to have a dramatic effect on protein synthesis in E. coli (1). This paper more specifically details the effects of the mutation on mRNA binding and translation-termination. The in vitro technique of toeprinting (2) was used to demonstrate that 30S subunits containing the mutation 726G had an altered binding affinity for mRNA by comparison to the wild type. In addition, expression of the mutant ribosomes in vivo resulted in exclusive suppression of the UGA nonsense codon. This effect was supported by in vitro studies that showed the mutant ribosomes to have an altered binding affinity for Release Factor-2.

Guanosine 3'-diphosphate 5'-diphosphate is not required for growth rate-dependent control of rRNA synthesis in Escherichia coli

rRNA synthesis in Escherichia coli is subject to at least two regulation systems, growth rate-dependent control and stringent control. The inverse correlation between rRNA synthesis rates and guanosine 3'-diphosphate 5'-diphosphate (ppGpp) levels under various physiological conditions has led to the supposition that ppGpp is the mediator of both control mechanisms by inhibiting transcription from rrn P1 promoters. Recently, relA- spoT- strains have been constructed in which both ppGpp synthesis pathways most likely have been removed (M. Cashel, personal communication). We have confirmed that such strains produce no detectable ppGpp and therefore offer a direct means for testing the involvement of ppGpp in the regulation of rRNA synthesis in vivo. Stringent control was determined by measurement of rRNA synthesis after amino acid starvation, while growth rate control was determined by measurement of rRNA synthesis under different nutritional conditions. As expected, the relA- spoT- strain is relaxed for stringent control. However, growth rate-dependent regulation is unimpaired. These results indicate that growth rate regulation can occur in the absence of ppGpp and imply that ppGpp is not the mediator, or at least is not the sole mediator, of growth rate-dependent control. Therefore, growth rate-dependent control and stringent control may utilize different mechanisms for regulating stable RNA synthesis.

Coupling of DNA replication to growth rate in Escherichia coli: a possible role for guanosine tetraphosphate

Two promoters for the Escherichia coli operon that contains the four genes dnaA, dnaN, recF, and gyrB were found to be growth rate regulated and under stringent control. Transcript abundance relative to total RNA increased with the growth rate. Changes in transcription from the dnaAp1 and dnaAp2 promoters that were induced by amino acid starvation and chloramphenicol and were relA dependent were correlated with the stringent response. The abundance of these transcripts per total RNA also decreased in spoT mutants as the severity of the mutation increased (guanosine 5'-diphosphate 3'-diphosphate [ppGpp] basal levels increased). Because expression of these promoters appears to be inhibited by ppGpp, it is proposed that one mechanism for coupling DNA replication to the growth rate of bacteria is through ppGpp synthesis at the ribosome.

Visualization and quantitative analysis of complex formation between E. coli RNA polymerase and an rRNA promoter in vitro

We have established conditions that stabilize the interaction between RNA polymerase and the rrnB P1 promoter in vitro. The requirements for quantitative complex formation are unusual for E. coli promoters: (1) The inclusion of a competitor is required to allow visualization of a specific footprint. (2) Low salt concentrations are necessary since complex formation is salt sensitive. (3) The addition of the initiating nucleotides ATP and CTP, resulting in a low rate of dinucleotide production, is required in order to prevent dissociation of the complexes. The complex has been examined using DNAase I footprinting and filter binding assays. It is characterized by a region protected from DNAase I cleavage that extends slightly upstream of the region protected by RNA polymerase in most E. coli promoters. We find that only one mole of active RNA polymerase is required per mole of promoter DNA in order to detect filter-bound complexes. Under the conditions measured, the rate of association of RNA polymerase with rrnB P1 is as rapid as, or more rapid than, that reported for any other E. coli or bacteriophage promoter.

An Escherichia coli gene in search of a function

The rrnB gene of Escherichia coli is preceded by an open reading frame, which is cotranscribed with rrnB both in vivo and in vitro. It has earlier been shown that a 289 amino acid protein corresponding to this gene is actually synthesized in E. coli. In this paper we show that: (1.) The transcription of this gene diminishes the stringent response of the P1 promoter of the linked rrnB gene, but this is a cis effect and is not mediated by the protein product of the gene. (2.) The functional integrity of this gene seems to be essential, because efforts to replace it by a plasmid-coded copy mutagenized by Tn5 completely failed. (3.) The protein product of this gene was strongly overproduced by a recombinant plasmid, exploiting the principle of "translational coupling". This overproduction did not change the phenotype of the host cell significantly. The protein was purified to apparent electrophoretic homogeneity.

A single base change in the Shine-Dalgarno region of 16S rRNA of Escherichia coli affects translation of many proteins

A single base mutation was constructed at position 1538 of Escherichia coli 16S rRNA, changing a cytidine to a uridine. This position is in the Shine-Dalgarno region, thought to be involved in base-pairing to mRNA during initiation of protein synthesis. The mutation was constructed by using a synthetic oligodeoxynucleotide that differs in sequence by one base from the wild-type sequence of 16S rRNA. This oligonucleotide was used as a primer on single-stranded DNA of phage M13, into which was cloned a specific region of DNA encoding 16S rRNA. The mutation is lethal when expressed from the normal promoters of rRNA operons, P1 and P2, in a high-copy-number plasmid. Expression can be repressed by a temperature-sensitive repressor, cI857, in combination with the bacteriophage lambda PL promoter. Induction of transcription by temperature shift yields mutant 16S rRNA that is processed and assembled into functional ribosomal subunits. The presence of mutant ribosomes retards cell growth and dramatically alters incorporation of [35S]methionine into a large proportion of the cellular proteins. The change in level of synthesis of individual proteins correlates with the change in base-pairing between mutant rRNA and the Shine-Dalgarno region of the mRNA.

New regulatory features of the promoters of an Escherichia coli rRNA gene

Recombinant plasmids were constructed by fusing either promoter p1 or p2 or both promoters of the rrnB gene of Escherichia coli to a DNA fragment coding for the N-terminal alpha-peptide of beta-galactosidase. These plasmids contained various lengths of the 5'-leader region of rRNA as the 5'-terminal end of the alpha-peptide messenger. In some cases the entire 5'-terminal rRNA-coding sequence was removed, and alpha-peptide synthesis was governed by rac promoters formed by fusion of rrnBp2 and lac promoters. By measuring the level of alpha peptide, conclusions could be drawn about the activities of the promoters under various physiological conditions. It was found that the rate of transcription starting from promoter p1 or p2 might vary more than 10-fold during the growth cycle, showing a sharp maximum during outgrowth from the stationary phase into exponential growth or during nutritional shift-up. The target sequence of this regulation was localized to the leader region of the rrnB gene.

DNA determinants of rRNA synthesis in E. coli: growth rate dependent regulation, feedback inhibition, upstream activation, antitermination

We have examined the DNA regions required for rRNA synthesis in E. coli using promoter-lacZ and lambda PL-rrnB operon fusions. Sequences between -51 and -20 with respect to the P1 promoter transcription initiation site contain the critical information for growth rate dependent control. The region essential for growth rate regulation is the same as that necessary for feedback inhibition. A separate upstream region, between -51 and -88, increases rRNA transcription at least 15-fold and appears to have an abnormal conformation. The box A sequence downstream of promoter P2, but not DNA between P2 and box A, is required for efficient rRNA chain elongation. These results indicate that neither upstream activation nor antitermination determines growth rate dependence. Rather, growth rate regulation takes place at the target site for the negative feedback system, the P1 promoter itself. We propose that negative feedback regulation is responsible for the growth rate dependence of rRNA synthesis in E. coli.

Promoter selectivity of E. coli RNA polymerase: analysis of the promoter system of convergently-transcribed dnaQ-rnh genes

Promoter properties were analyzed for the convergently-overlapped E. coli genes coding for the DNA polymerase III epsilon subunit (dnaQ) and the ribonuclease H (rnh). The rates of open complex formation for a single promoter of the rnh gene and two tandem promoters of the dnaQ gene were constant whether they are located on a single DNA fragment or separated into individual fragments. The relative expression levels of these three promoters, as measured using an in vitro mixed transcription system, varied differentially depending on the concentration of RNA polymerase. At low enzyme concentrations, the downstream promoter (P2) of the dnaQ gene was utilized preferentially, but the upstream promoter (P1) was utilized as well when the enzyme concentration was increased. This indicates different physiological roles between the two dnaQ promoters. The level of rnh transcription was as low as that of dnaQ-1 RNA synthesis but the rnh promoter was utilized as well as the dnaQ P2 promoter when it was separated from the dnaQ promoters. This implies a promoter interference between the convergently transcribed genes.

Defective antitermination of rRNA transcription and derepression of rRNA and tRNA synthesis in the nusB5 mutant of Escherichia coli

The nusB5 mutant of Escherichia coli was originally selected for reduced ability to support the antitermination of transcription that is mediated by the gene N product of bacteriophage lambda. By analyzing pulse-labeled RNA with an RNA.DNA filter hybridization technique, we have shown that, in the nusB5 mutant, the ratio of promoter-proximal rRNA transcripts to promoter-distal transcripts is increased at least by a factor of 1.6; that is, in the absence of the functional nusB gene product, premature transcription termination takes place within rRNA operons. These results demonstrate that rRNA transcription in E. coli utilizes an antitermination mechanism that has at least one factor in common with the phage lambda system, the nusB gene product. We have also observed that the transcription initiation frequency at rRNA promoters is increased in the nusB5 strain and that this strain accumulates 30S and 50S ribosomal subunits at approximately the same rate as the parent. Thus, it appears that E. coli compensates for premature termination of rRNA transcription by derepressing rRNA operon expression. The increase in rRNA promoter activity in the nusB5 mutant is accompanied by a parallel derepression of synthesis of tRNAs that are not encoded by rRNA operons. These results are consistent with a model for negative feedback regulation of rRNA and tRNA synthesis by products of rRNA operons.

Evidence that pheV, a gene for tRNAPhe of E. coli is transcribed from tandem promoters

A DNA fragment of 487 bp containing a gene for tRNAPhe has been sequenced. Although the tRNAPhe sequence is identical to that of pheU (which maps at 94.5 min) the surrounding sequences are quite different. This sequence is thus that of a second gene for tRNAPhe (which we shall call pheV). In vitro transcription experiments and S1 mapping in vivo show the existence of two promoters separated by about 60 nucleotides. The second transcript starts only 3 nucleotides 5' from the tRNAPhe structural sequence. A DNA sequence characteristic of a rho-independent terminator is located 30 nucleotides 3' of the end of the structural gene and is shown to function efficiently in vitro.

In vivo transcription from deletion mutations introduced near Escherichia coli ribosomal RNA promoter P2

In order to characterize the tandem rrnB promoters transcribing one of the ribosomal RNA operons in E. coli we subcloned the basic promoter unit. This 185 bp fragment extends from -64 to +121 counted from the transcription start site of upstream promoter P1. The start site of downstream promoter P2 is also included in the promoter cartridge. S1 mapping experiments show that both promoters on this fragment are active in vivo. BAL-31 deletion mutations generated at the start site for promoter P2 were also tested by S1 mapping. Transcription from P2 remained active in all cases with the exception of one construction which lacks the -10 region. This demonstrates that the sequences downstream from the -10 region of P2 are not essential for basic promoter function.

Conserved features of coordinately regulated E. coli promoters

E. coli promoters which are coordinately regulated in response to amino acid limitation contain conserved nucleotide sequences immediately 3' to -10 region. These sequences contain predominantly either GC or AT residues depending on whether the response is respectively negative or positive. Certain classes of promoters also contain conserved sequences upstream of the primary promoter. In tRNA genes these sequences could act as a secondary polymerase binding site.

Carbon starvation and growth rate-dependent regulation of the Escherichia coli ribosomal RNA promoters: differential control of dual promoters

We studied the effects of carbon starvation and of varying the growth rate on the activity of each of the two tandem ribosomal RNA promoters from the rrnA operon of Escherichia coli. The cellular abundance of plasmid-encoded transcripts arising at promoters P1 and P2 and terminating at the ribosomal RNA terminator in promoter-terminator fusions, together with transcript turnover rates, was used to estimate promoter activities. The rate of synthesis of the P1-promoted transcript was found to increase exponentially with growth rate and predominate at fast growth rates. The activity of the downstream promoter (P2) changed only slightly at different growth rates. Upon carbon starvation, little or no activity of the upstream promoter was detectable, while P2 activity persisted. We interpret this to mean that the dual promoters are differentially regulated so as to have separate adaptive and maintenance functions. This model simplifies most features of rRNA regulation known in E. coli.

Differential stringent control of the tandem E. coli ribosomal RNA promoters from the rrnA operon expressed in vivo in multicopy plasmids

The tandem P1, P2 promoter region of the rrnA ribosomal operon has been fused to the t1, t2 terminator region of the rrnB operon in pBR322 plasmid derivatives. This deletes most internal RNA structural elements ordinarily processed out of ribosomal operon transcripts. In vivo as well as in vitro transcripts arising from both promoters terminate predominantly in the t1 terminator region about 40 base pairs beyond the mature rrnB 5S RNA gene. Stringent control of the P1 and P2 promoted transcripts has been assessed in vivo. In these plasmid fusions, the upstream (P1) promoter activity was subject to stringent control, while the downstream (P2) promoter activity was inhibited by amino acid starvation in both stringent and relaxed hosts. A plasmid with an additional deletion of the P2 region also showed stringent regulation of the P1 promoter.