Nucleotide sequence of the rrnG ribosomal RNA promoter region of Escherichia coli

Uncovering a delicate balance between endonuclease RNase III and ribosomal protein S15 in E. coli ribosome assembly

The bacterial ribosomal protein S15 is located in the platform, a functional region of the 30S ribosomal subunit. While S15 is critical for in vitro formation of E. coli small subunits (SSUs), it is dispensable for in vivo biogenesis and growth. In this work, a novel synergistic interaction between rpsO, the gene that encodes S15, and rnc (the gene that encodes RNase III), was uncovered in E. coli. RNase III catalyzes processing of precursor ribosomal RNA (rRNA) transcripts and thus is involved in functional ribosome subunit maturation. Strains lacking S15 (ΔrpsO), RNase III (Δrnc) or both genes were examined to understand the relationship between these two factors and the impact of this double deletion on rRNA processing and SSU maturation. The double deletion of rpsO and rnc partially alleviates the observed cold sensitivity of ΔrpsO alone. A novel 16S rRNA precursor (17S∗ rRNA) that is detected in free 30S subunits of Δrnc is incorporated in 70S-like ribosomes in the double deletion. The stable accumulation of 17S∗ rRNA suggests that timing of processing events is closely coupled with SSU formation events in vivo. The double deletion has a suppressive effect on the cell elongation phenotype of ΔrpsO. The alteration of the phenotypes associated with S15 loss, due to the absence of RNase III, indicates that pre-rRNA processing and improvement of growth, relative to that observed for ΔrpsO, are connected. The characterization of the functional link between the two factors illustrates that there are redundancies and compensatory pathways for SSU maturation.

Strength and Regulation of Seven rRNA Promoters in Escherichia coli

The model prokaryote Escherichia coli contains seven copies of the rRNA operon in the genome. The presence of multiple rRNA operons is an advantage for increasing the level of ribosome, the key apparatus of translation, in response to environmental conditions. The complete sequence of E. coli genome, however, indicated the micro heterogeneity between seven rRNA operons, raising the possibility in functional heterogeneity and/or differential mode of expression. The aim of this research is to determine the strength and regulation of the promoter of each rRNA operon in E. coli. For this purpose, we used the double-fluorescent protein reporter pBRP system that was developed for accurate and precise determination of the promoter strength of protein-coding genes. For application of this promoter assay vector for measurement of the rRNA operon promoters devoid of the signal for translation, a synthetic SD sequence was added at the initiation codon of the reporter GFP gene, and then approximately 500 bp-sequence upstream each 16S rRNA was inserted in front of this SD sequence. Using this modified pGRS system, the promoter activity of each rrn operon was determined by measuring the rrn promoter-directed GFP and the reference promoter-directed RFP fluorescence, both encoded by a single and the same vector. Results indicated that: the promoter activity was the highest for the rrnE promoter under all growth conditions analyzed, including different growth phases of wild-type E. coli grown in various media; but the promoter strength of other six rrn promoters was various depending on the culture conditions. These findings altogether indicate that seven rRNA operons are different with respect to the regulation mode of expression, conferring an advantage to E. coli through a more fine-tuned control of ribosome formation in a wide range of environmental situations. Possible difference in the functional role of each rRNA operon is also discussed.

Characterization of a small cryptic plasmid from endophytic Pantoea agglomerans and its use in the construction of an expression vector

A circular cryptic plasmid named pPAGA (2,734 bp) was isolated from Pantoea agglomerans strain EGE6 (an endophytic bacterial isolate from eucalyptus). Sequence analysis revealed that the plasmid has a G+C content of 51% and contains four potential ORFs, 238(A), 250(B), 131(C), and 129(D) amino acids in length without homology to known proteins. The shuttle vector pLGM1 was constructed by combining the pPAGA plasmid with pGFPmut3.0 (which harbors a gene encoding green fluorescent protein, GFP), and the resulting construct was used to over-express GFP in E. coli and P. agglomerans cells. GFP production was used to monitor the colonization of strain EGE6gfp in various plant tissues by fluorescence microscopy. Analysis of EGE6gfp colonization showed that 14 days after inoculation, the strain occupied the inner tissue of Eucalyptus grandis roots, preferentially colonizing the xylem vessels of the host plants.

Characterization of the detachable Rho-dependent transcription terminator of the fimE gene in Escherichia coli K-12

The fim genetic switch in the chromosome of Escherichia coli K-12 is an invertible DNA element that harbors the promoter for transcription of the downstream fim structural genes and a transcription terminator that acts on the upstream fimE regulatory gene. Switches oriented appropriately for structural gene transcription also allow fimE mRNA to read through, whereas those in the opposite orientation terminate the fimE message. We show here that termination is Rho dependent and is suppressed in a rho mutant or by bicyclomycin treatment when fimE mRNA is expressed by the fimE gene, either from a multicopy recombinant plasmid or in its native chromosomal location. Two cis-acting elements within the central portion of the 314-bp invertible DNA switch were identified as contributors to Rho-dependent termination and dissected. These fim sequence elements show similarities to well-characterized Rho utilization (rut) sites and consist of a boxA motif and a C-rich and G-poor region of approximately 40 bp. Deletion of the boxA motif alone had only a subtle negative effect on Rho function. However, when this element was deleted in combination with the C-rich, G-poor region, Rho function was considerably decreased. Altering the C-to-G ratio in favor of G in this portion of the switch also strongly attenuated transcription termination. The implications of the existence of a fimE-specific Rho-dependent terminator within the invertible switch are discussed in the context of the fim regulatory circuit.

Effects of growth conditions on expression of mycobacterial murA and tyrS genes and contributions of their transcripts to precursor rRNA synthesis

All mycobacteria studied to date have an rRNA operon, designated rrnA, located downstream from a single copy of the murA gene, which encodes an enzyme (EC 2.5.1.7) important for peptidoglycan synthesis. The rrnA operon has a promoter, P1(A), located within the coding region of murA, near the 3' end. Samples of RNA were isolated from Mycobacterium tuberculosis at different stages of the growth cycle and from Mycobacterium smegmatis grown under different conditions. RNase protection assays were used to investigate transcripts of both murA and rrnA. Transcription of murA was found to continue into the 16S rRNA gene, as if murA and rrnA form a hybrid (protein coding-rRNA coding) operon. During the growth of M. tuberculosis, the hybrid operon contributed approximately 2% to total pre-rRNA. Analysis of M. smegmatis RNA revealed that the level of murA RNA depended on the growth rate and that the patterns of expression during the growth cycle were different for murA and rrnA. M. smegmatis has a second rRNA operon, rrnB, located downstream from a single copy of the tyrS gene, encoding tyrosyl-tRNA synthetase. Transcription of tyrS was found to continue into the 16S rRNA gene rrnB. The hybrid tyrS-rrnB operon contributed 0.2 to 0.6% to rrnB transcripts. The pattern of tyrS expression during the growth cycle matched the pattern of rrnB expression, reflecting the essential role of TyrS and rRNA in protein biosynthesis.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Degradative capacities and 16S rRNA-targeted whole-cell hybridization of sulfate-reducing bacteria in an anaerobic enrichment culture utilizing alkylbenzenes from crude oil

A mesophilic sulfate-reducing enrichment culture growing anaerobically on crude oil was used as a model system to study which nutritional types of sulfate-reducing bacteria may develop on original petroleum constituents in oil wells, tanks, and pipelines. Chemical analysis of oil hydrocarbons during growth revealed depletion of toluene and o-xylene within 1 month and of m-xylene, o-ethyltoluene, m-ethyltoluene, m-propyltoluene, and m-isopropyltoluene within approximately 2 months. In anaerobic counting series, the highest numbers of CFU (6 x 10(6) to 8 x 10(6) CFU ml-1) were obtained with toluene and benzoate. Almost the same numbers were obtained with lactate, a substrate often used for detection of the vibrio-shaped, incompletely oxidizing Desulfovibrio sp. In the present study, however, lactate yielded mostly colonies of oval to rod-shaped, completely oxidizing, sulfate-reducing bacteria which were able to grow slowly on toluene or crude oil. Desulfovibrio species were detected only at low numbers (3 x 10(5) CFU ml-1). In agreement with this finding, a fluorescently labeled, 16S rRNA-targeted oligonucleotide probe described in the literature as specific for members of the Desulfovibrionaceae (suggested family) hybridized only with a small portion (< 5%) of the cells in the enrichment culture. These results are consistent with the observation that known Desulfovibrio species do not utilize aromatic hydrocarbons, the predominant substrates in the enrichment culture. All known sulfate-reducing bacteria which utilize aromatic compounds belong to a separate branch, the Desulfobacteriaceae (suggested family). Most members of this family are complete oxidizers. For specific hybridization with members of this branch, the probe had to be modified by a nucleotide exchange. Indeed, this modified probe hybridized with more than 95% of the cells in the enrichment culture. The results show that completely oxidizing, alkylbenzene-utilizing sulfate-reducing bacteria rather than Desulfovibrio species have to be considered in attempts to understand the microbiology of sulfide production in oil wells, tanks, and pipelines when no electron donors other than the indigenous oil constituents are available.

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.

rRNA operon multiplicity in Escherichia coli and the physiological implications of rrn inactivation

Here we present evidence that only five of the seven rRNA operons present in Escherichia coli are necessary to support near-optimal growth on complex media. Seven rrn operons are necessary, however, for rapid adaptation to nutrient and temperature changes, suggesting it is the ability to adapt quickly to changing environmental conditions that has provided the selective pressure for the persistence of seven rrn operons in E. coli. We have also found that one consequence of rrn operon inactivation is a miscoordination of the concentrations of initiation factor IF3 and ribosomes.

Cloning and primary structure of the wide-spectrum amidase from Brevibacterium sp. R312: high homology to the amiE product from Pseudomonas aeruginosa

A Brevibacterium sp. R312 DNA fragment encoding the wide-spectrum amidase (EC 3.5.1.4) has been cloned and sequenced, using limited amino acid (aa) sequence information obtained from the purified enzyme. The deduced aa sequence showed more than 80% strict identity with the Pseudomonas aeruginosa aliphatic amidase, the product of the amiE gene, suggesting a horizontal transfer of the gene during evolution between Gram+ and Gram- bacteria.

ClpB proteins copurify with the anaerobic Escherichia coli reductase

Two proteins, called alpha and beta 3, copurify with the anaerobic ribonucleotide reductase from Escherichia coli (Eliasson et al. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 3314-3318). Both are now identified as products of the clpB gene that is presumed to code for a subunit of an ATP dependent protease. The tight associations suggest the possibility that the ClpB proteins are involved in the regulation of the anaerobic reductase.

ClpB is the Escherichia coli heat shock protein F84.1

ClpB is thought to be involved in proteolysis because of its sequence similarity to the ClpA subunit of the ClpA-ClpP protease. It has recently been shown that ClpP is a heat shock protein. Here we show that ClpB is the Escherichia coli heat shock protein F84.1. The F84.1 protein was overproduced in strains containing the clpB gene on a plasmid and was absent from two-dimensional gels from a clpB null mutation. Besides possessing a slower growth rate at 44 degrees C, the null mutant strain had a higher rate of death at 50 degrees C. We used reverse transcription of in vivo mRNA to show that the clpB gene was expressed from a sigma 32-specific promoter consensus sequence at both 37 and 42 degrees C. We noted that the clpB+ gene also caused the appearance of a second protein spot, F68.5, on two-dimensional gels. This spot was approximately 147 amino acids smaller than F84.1 and most probably is the result of a second translational start on the clpB mRNA. F68.5 can be observed on many published two-dimensional gels of heat-induced E. coli proteins, but the original catalog of 17 heat shock proteins did not include this spot.

Expression of ClpB, an analog of the ATP-dependent protease regulatory subunit in Escherichia coli, is controlled by a heat shock sigma factor (sigma 32)

Escherichia coli K-12 produces at least two ATP-dependent proteases, Lon (La) and Clp (Ti), the latter consisting of a regulatory subunit (ClpA) and a proteolytic subunit (ClpP). The gene clpB encoding an analog of ClpA had been found at 57 min on the E. coli chromosome. Cloning and examination of novel heat shock promoters led us to identify a major clpB promoter specifically controlled by a heat shock sigma factor, sigma 32 (the rpoH [= htpR] gene product). beta-Galactosidase synthesis from a PclpB-lacZ operon fusion was transiently induced upon temperature shift from 30 to 42 degrees C, and the induction depended on the rpoH function. Chromosomal clpB transcripts also increased upon temperature upshift and were totally absent in the rpoH deletion strain. In the in vitro transcription experiments, the clpB promoter was specifically recognized and transcribed by RNA polymerase-sigma 32. Nucleotide sequencing and determination of mRNA start sites permitted us to identify a major heat shock promoter located upstream of the clpB coding sequence. The results clearly indicate that clpB expression is under direct control of sigma 32. Since ClpP was recently shown to be a sigma 32-dependent heat shock protein, the present finding suggests the possibility that a potential ATP-dependent protease, ClpB-ClpP complex, plays an important role against thermal stress in E. coli.

Transcriptional termination sequence at the end of the Escherichia coli ribosomal RNA G operon: complex terminators and antitermination

We have examined the termination region sequence of the rrnG operon and have observed its properties in vivo using a fusion plasmid test system. Transcription of rrnG terminator fragments was also studied in vitro. We found that termination of rrnG transcription is a complex process controlled by a tandem Rho-independent and Rho-dependent terminator arrangement which we designate rrnG-tt'. Together, these two elements were 98% efficient at terminating transcription initiated at the rrnG-P2 promoter. When the two elements were separated, however, we found that the Rho-independent structure was only 59% efficient while the Rho-dependent fragment alone could account for total transcriptional termination of the tandem arrangement. The rrnG termination region was resistant to rrn antitermination and, therefore, possesses some means of stopping antiterminated transcription. The distal rrnG sequence contains several additional noteworthy features; the rrnGt' fragment contains a REP (repetitive extragenic palindromic) sequence and homology with a small unidentified reading frame following rrnE. This sequence is followed by witA, which is homologous to a citrate transport gene, citB. Finally, our sequence, obtained from plasmid pLC23-30, contains a Tn1000 insertion that is absent from the E. coli chromosome. This insertion lies 975 bp beyond the 5S gene and is not involved in the termination events examined in this study.

Exchange of spacer regions between rRNA operons in Escherichia coli

The Escherichia coli rRNA operons each have one of two types of spacer separating the 16S and 23S coding regions. The spacers of four operons encode tRNA(Glu2) and the other three encode both tRNA(Ile) and tRNA(Ala1B). We have prepared a series of mutants in which the spacer region of a particular rrn operon has been replaced by the opposite type. Included among these were a mutant retaining only a single copy of the tRNA(Glu2) spacer (at rrnG) and another retaining only a single copy of the tRNA(Ile)-tRNA(Ala1B) spacer (at rrnA). While both mutants grew more slowly than controls, the mutant deficient in tRNA(Glu2) spacers was more severely affected. At a frequency of 6 X 10(-5), these mutants phenotypically reverted to faster growing types by increasing the copy number of the deficient spacer. In most of these phenotypic revertants, the deficient spacer type appeared in a rrn operon which previously contained the surplus type, bringing the ratio of spacer types closer to normal. In a few cases, these spacer changes were accompanied by an inversion of the chromosomal material between the donor and recipient rrn operons. Two examples of inversion of one-half of the E. coli chromosome between rrnG and rrnH were observed. The correlation of spacer change with inversion indicated that, in these particular cases, the change was due to an intrachromatid gene conversion event accompanied by a reciprocal crossover rather than reciprocal exchange between sister chromatids.

Antitermination of characterized transcriptional terminators by the Escherichia coli rrnG leader region

We have used a plasmid antitermination test system to examine the response of an Escherichia coli rRNA operon antiterminator to transcription through Rho-dependent and Rho-independent terminator-containing fragments. We also monitored transcription through multiple copies of a terminator to explore the mechanism of rrn antitermination. Four principal observations were made about antitermination and transcriptional terminators. (1) The rrn antiterminator mediated efficient transcription through Rho-dependent terminators. (2) Under the influence of the rrn antiterminator, RNA polymerase transcribed through two and three copies of the Rho-dependent 16 S----terminator with nearly the same efficiency as through one. (3) The antiterminator had less effect on fragments containing Rho-independent terminators; the rpoC t fragment and three fragments derived from the rrnB terminator region stopped antiterminated transcription. Four other Rho-independent terminator fragments were weakly antiterminated in our test system. (4) Surprisingly, the strength of these terminator fragments was not strongly related to properties such as the -delta G or number of trailing uridine residues of their canonical Rho-independent structures, but appears to be related to additional downstream terminators. We have drawn the following conclusions from these experiments. First, that ribosomal antitermination primarily reverses Rho-dependent termination by modifying the RNA polymerase elongation complex. Transcription through a 1700 nucleotide, multiple terminator sequence showed that the antiterminator caused persistent changes in the transcription process. Second, that fragments derived from the Rho-independent rrnB and rpoBC terminator regions can effectively stop antiterminated transcription. Third, that efficient in vivo termination may often involve regions with complex multiple terminators.

Conservation of the regulatory subunit for the Clp ATP-dependent protease in prokaryotes and eukaryotes

Bacteria, tomatoes, and trypanosomes all contain genes for a large protein with extensive homology to the regulatory subunit, ClpA, of the ATP-dependent protease of Escherichia coli, Clp. All members of the family have between 756 and 926 amino acids and contain two large regions, of 233 and 192 amino acids, each containing consensus sequences for nucleotide binding. Within these regions there is at least 85% similarity between the most distant members of the family. The high degree of similarity among the ClpA-like proteins suggests that Clp-like proteases are likely to be important participants in energy-dependent proteolysis in prokaryotic and eukaryotic cells.

Identification and genetic mapping of proteins encoded in the fimbrial subunit gene region of Bacteroides nodosus

The fimbriae produced by the anaerobic bacterium Bacteroides nodosus are important in the pathogenesis of ovine foot rot. Studies on other microorganisms have shown that the genes coding for the production and assembly of fimbriae are often clustered. By the use of maxicells, transposon mutagenesis and expression vectors, we have identified several genes which are located in the fimbrial subunit gene region. Antiserum was prepared against one of the proteins (88 kDa) which we were able to overproduce in Escherichia coli. In Western blots, these antibodies reacted with an 88 kDa protein located in the B. nodosus cell membrane. However, they did not react with the putative basal protein which is found in fimbrial preparations. We concluded that in B. nodosus the genes involved in fimbrial assembly are not all localised to one small region of the genome. In addition, our studies showed that although the fimbrial subunits are not assembled into intact fimbriae, an N-terminal sequence is processed in E. coli.

Ribosomal RNA operon anti-termination. Function of leader and spacer region box B-box A sequences and their conservation in diverse micro-organisms

All Escherichia coli rrn operons show a common motif in which anti-terminator box B-box A sequences occur twice, first in the leader and again in the 16 S-23 S spacer. In this study we have analyzed several aspects of rrn anti-termination by leader and spacer anti-terminator sequences. Using DNA synthesis and a plasmid test system, we incorporated random changes into the leader anti-terminator region and examined these mutations for their ability to read through a strong terminator. We also examined anti-termination by synthetic box A and by rrn spacer region sequences. Information derived from these experiments was used to search the rrn sequences of other micro-organisms for possible anti-termination features. Our principal conclusions were that: (1) box A was sufficient for terminator readthrough; (2) we could show no positive requirement for box B in our test system; (3) many of the negative anti-terminator mutations caused a promoter up-effect in the absence of a terminator; (4) the search of rrn operons from other micro-organisms revealed that anti-terminator-like box B-box A sequences exist in leader and spacer regions of both eubacteria and archaebacteria. The frequent occurrence of this pattern suggested that the E. coli rrn anti-termination motif is widespread in nature and has been conserved in microbial evolution.

Loss of the spacer loop sequence from the rrnB operon in the Escherichia coli K-12 subline that bears the relA1 mutation

A polymorphism affecting the spacer region of the rrnB rRNA operon is described. Strains from a major Escherichia coli K-12 subbranch are missing a 106-nucleotide portion of the rrnB 16S-to-23S spacer, and a 20-nucleotide sequence is found in its place. We have called this mutant operon rrnB2. The rrnB2 spacer was most probably derived from either rrnC or rrnE. This alteration of rrnB may have occurred by a recombinational exchange or by gene conversion. In the genealogy of E. coli K-12 strains, the appearance of rrnB2 is associated with the spontaneous occurrence of the first relaxed mutation, but attempts to show a selective relationship between the two mutational events have had negative results. The sequences of the rrnG and rrnC 16S-to-23S spacers have also been determined and their comparisons to the other rrn operons encoding tRNAGlu2 are presented.

In vivo translation of a region within the rrnB 16S rRNA gene of Escherichia coli

In this study we show that a segment of the Escherichia coli rrnB 16S gene can be translated in vivo. Other laboratories have previously reported that there are internal transcription and translation signals and open reading frames within the E. coli rrnB rRNA operon. Their studies revealed a translation start signal followed by a 252-base-pair open reading frame (ORF16) within the 16S gene and detected a promoter (p16) in the same general region by using in vitro RNA polymerase binding and transcription initiation assays. By using plasmid gene fusions of ORF16 to lacZ we showed that an ORF16'-'beta-galactosidase fusion protein was made in vivo. Transcripts encoding the fusion protein were expressed either from the rrnB p1p2 control region or from a hybrid trp-lac promoter (tacP), but the amount of expression was considerably less than for a lacZ control plasmid. We used fusions to the cat gene to show that p16 is one-half as active as lacP. Deletions were used to show that p16 is located within ORF16 and thus cannot promote a transcript encoding the ORF16 peptide. A comparison of sequences from different organisms shows that ORF16 and p16 lie in a highly conserved region of the procaryotic 16S RNA structure. The first 20 amino acids of ORF16 are conserved in most eubacterial and plant organellar sequences, and promoter activity has been detected in this region of the Caulobacter crescentus sequence by other workers.

Separation and analysis of the RNA polymerase binding sites of a complex Bacillus subtilis promoter

The Bacillus subtilis veg promotor site was shown to be composed of two neighboring RNA polymerase binding sites, only one of which ("Site I") produces a transcript. The relationship between these sites has been investigated following insertion of ten base pairs of DNA between the sites and subsequent cloning of each site independent of the other, and deletion of DNA sequences upstream from the productive site. The effect of DNA insertion was to permit transcription initiation from the previously nonproductive Site II, in either the presence or absence of Site I. This could be attributed to insertion of a purine residue seven base pairs downstream from the Pribnow box of Site II. Transcription from Site I was slightly increased in the presence of Site II in cis, but was still efficient in the absence of Site II, indicating that there is no absolute dependence on Site II for in vitro transcription from Site I.

Terminators of transcription with RNA polymerase from Escherichia coli: what they look like and how to find them

We present here a compilation of prokaryotic transcription terminator sequences (ref. 1-152). The compilation includes 49 independent terminators, 52 speculated independent terminators, 27 sites shown to function in vivo, and some 20 proven or speculated rho-dependent terminators. In addition to the well-known features of independent terminators (dyad symmetry and T-run), two consensus are found: CGGG(C/G) upstream and TCTG downstream of the termination point. A subset of the collection of sequence has been used to construct a computer algorithm to locate independent terminators by sequence analysis.

Unbalanced rRNA gene dosage and its effects on rRNA and ribosomal-protein synthesis

The synthesis of rRNA was unbalanced by the introduction of plasmids containing rRNA operons with large internal deletions. Significant unbalanced synthesis was achieved only when the deletions affected both 16S and 23S RNA genes or when the deletions affected the 23S RNA gene alone. Although large imbalances in rRNA synthesis resulted from deletions affecting 16S and 23S RNA genes or only 23S RNA genes, excess 16S RNA and defective rRNA species were rapidly degraded. Large imbalances in the synthesis of regions of rRNA did not result in significantly unbalanced synthesis of ribosomal proteins. It therefore is probable that excess intact 16S RNA is degraded because ribosomal proteins are not available for packaging the RNA into ribosomes. Defective RNA species also may be degraded for this reason or because proper ribosome assembly is prevented by the defects in RNA structure. We propose two possible explanations for the finding that unbalanced overproduction of binding sites for feedback ribosomal protein does not result in significant unbalanced translational feedback depression of ribosomal protein mRNAs.

Antitermination by both the promoter and the leader regions of an Escherichia coli ribosomal RNA operon

RNA polymerase initiating at Escherichia coli ribosomal RNA promoter-leader regions can efficiently read through factor rho-dependent termination signals. Dissection of the promoter-leader region reveals that the ability to read through termination signals is conferred independently by both promoter and leader regions. Events in the leader also affect the transcription rate of structural genes downstream of the leader. When cells are grown in rich medium, the rrnC leader reduces transcription by a factor of approximately 4 when downstream of the rrnC promoters and by a factor of 2 when downstream of the lac promoter.

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.

Antitermination of E. coli rRNA transcription is caused by a control region segment containing lambda nut-like sequences

We have localized the antitermination system involved in E. coli ribosomal RNA transcription and compared it with antitermination in the lamboid bacteriophages. In vivo experiments with gene-fusion plasmids were used to examine the ability of specific areas of the rrnG control region to convert an ordinary transcription complex into antitermination transcription complex. A 67 bp restriction fragment immediately following the rrnG P2 promoter decreased transcription termination about 50%. This fragment contains box A-, box B-, and box C-like sequences similar to those in lambda nut loci. It also caused transcripts from lac and hybrid trp-lac promoters to read through a transcription terminator. Translation through the 67 bp segment or reversal of its orientation resulted in complete loss of antitermination activity. We conclude that the E. coli ribosomal RNA operons possess an antitermination system similar to that used by the bacteriophage lambda.

Evidence for antitermination in Escherichia coli RRNA transcription

The stable RNA operons of Escherichia coli do not exhibit polarity, even though they make an RNA product that is not translated. By contrast, most E. coli operons that specify proteins exhibit polarity if their translation is interrupted. The transcriptional component of this polarity depends on the action of Rho protein on the exposed mRNA, which results in premature transcription termination. Here we examine how a stable RNA operon (rrnG) transcript is protected from the Rho protein-mediated polarity response. We compared transcription from the ara and the rrnG promoters through a 16S DNA segment. In each case, the promoter-16S sequences were joined to a trp-lac fusion, and lacZ mRNA was examined in rho+ and rho-115 strains. We found significant Rho protein-dependent termination of transcripts from the ara promoter but little or no Rho protein effect on transcription from the rrnG promoter. We concluded that the transcript of the 16S ribosomal DNA segment does contain Rho protein-dependent transcription terminators, but there is an antitermination system in the rrnG control region that allows it to transcribe through those terminators.

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.

DNA sequence of the tandem ribosomal RNA promoter for B. subtilis operon rrnB

A new ribosomal RNA operon designated rrnB has been identified by screening a Charon 4a library of cloned B. subtilis sequences. Clones containing the promoter region of this operon are unstable in E. coli unless a special vector possessing a transcriptional terminator is used. DNA sequence data suggests that this operon contains two tandem putative promotor regions not unlike those found in E. coli. There are 92 base pairs separating the two "-10 regions" of the promotors. The second is 180 bp upstream from the start site for mature 16S RNA. A potential 29 base pair stem structure necessary for processing of the mature 16S RNA sequence can also be predicted from this analysis.

Cloning of the promoters of an Escherichia coli rRNA gene. New experimental system to study the regulation of rRNA transcription

The promoters of the rrnB gene of Escherichia coli have been cloned on a multicopy, pBR322-derived plasmid by deleting most of the structural part of rrnB and fusing the terminators of the gene immediately to the promoters. Several further deletions were constructed to vary the promoter-terminator distance, destroy or damage selectively any of the promoters or terminators, and vary the distance between the two pairs of P1 P2 and P3 P4 promoters. All these transcription signals were shown to function on the plasmids in vitro and in vivo. The truncated in vivo transcription products initiated at the P1 and P2 promoters of the recombinant plasmids were found to be stable, and the accumulated transcripts could be easily distinguished from the chromosome-coded rRNA. This provides a convenient experimental system to study the regulation of rRNA biosynthesis.

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.