Gene organization and primary structure of a ribosomal RNA operon from Escherichia coli

Maturation of the 3' end of 5-S ribosomal RNA from Escherichia coli

The 3' ends of 5-S rRNA isolated from Escherichia coli cells were analyzed and identified after different durations of labeling with 32Pi, with and without blocking of protein synthesis. These experiments suggest that the 5-S rRNA starts as a species containing 126 nucleotides, three at each end, and that the extra nucleotides are removed from the 5' and 3' ends in parallel at comparable but different rates. Inhibition of protein synthesis with chloramphenicol blocks, in addition to the 5'-end maturation, the trimming of the extra nucleotides from the 3' end. The trimming of extra nucleotides from both ends of the 5-S rRNA is also affected by the structure of the molecular stalk of 5-S rRNA. A number of observations suggest that the trimmings from both ends are independent processes, which are carried out probably by different enzymes.

P1 plasmid replication: multiple functions of RepA protein at the origin

Replication functions of a bacteriophage P1 miniplasmid are carried on a 1.2-kilobase pair (kb) segment that can be subdivided into a 245-base pair (bp) replication origin and a 959-bp region that encodes a protein required for replication (RepA). The origin region contains five 19-bp direct repeats. By using primer extension and gene-fusion assays, we mapped the promoter of the repA gene within the repeated sequences and showed that the promoter is repressed by RepA. Regulation of RepA synthesis is apparently achieved by the binding of RepA to the repeat sequences. This regulation might be a key step in the replication-control circuit, as we found that overproduction of RepA (from a foreign promoter) inhibits replication. Thus, in addition to being an autoregulated activator of replication, the protein also can have a negative regulatory role.

Chloramphenicol-erythromycin resistance mutations in a 23S rRNA gene of Escherichia coli

Two chloramphenicol resistance mutations were isolated in an Escherichia coli rRNA operon (rrnH) located on a multicopy plasmid. Both mutations also confer resistance to 14-atom lactone ring macrolide antibiotics, but they do not confer resistance to 16-atom lactone ring macrolide antibiotics or other inhibitors of the large ribosomal subunit. Classic genetic and recombinant DNA methods were used to map the two mutations to 154-base-pair regions of the 23S RNA genes. DNA sequencing of these regions revealed that chloramphenicol-erythromycin resistance results from a guanine-to-adenine transition at position 2057 of the 23S RNA genes of both independently isolated mutants. These mutations affect a region of 23S RNA strongly implicated in peptidyl transfer and known to interact with a variety of peptidyl transferase inhibitors.

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.

A mutation in an Escherichia coli ribosomal RNA operon that blocks the production of precursor 23 S ribosomal RNA by RNase III in vivo and in vitro

We have isolated on a multicopy plasmid a mutant rrnB ribosomal RNA operon containing a 130 base-pair deletion immediately preceding the 23 S rRNA gene. The deletion shortens by just three base-pairs the 26 base-pair complementarity of the sequences that flank the 23 S rRNA gene, and which normally form an RNase III cleavage site in the rrnB primary transcript. Both in vivo and in vitro, cleavage at the altered RNase III site was almost completely abolished by the mutation. Our results therefore indicate that even a small perturbation of the double-stranded region normally recognized by RNase III strongly inhibits the action of the enzyme.

Escherichia coli 23S ribosomal RNA truncated at its 5' terminus

In a strain of E. coli deficient in RNase III (ABL1), 23S rRNA has been shown to be present in incompletely processed form with extra nucleotides at both the 5' and 3' ends (King et al., 1984, Proc. Natl. Acad. Sci. U.S. 81, 185-188). RNA molecules with four different termini at the 5' end are observed in vivo, and are all found in polysomes. The shortest of these ("C3") is four nucleotides shorter than the accepted mature terminus. In growing cells of both wild-type and mutant strains up to 10% of the 23S rRNA chains contain the 5' C3 terminus. In stationary phase cells, the proportion of C3 termini remains the same in the wild-type cells; but C3 becomes the dominant terminus in the mutant. Species C3 is also one of the 5' termini of 23S rRNA generated in vitro from larger precursors by the action of purified RNase III. We therefore suggest that some form of RNase III may still exist in the mutant; and since no cleavage is detectable at any other RNase III-specific site, the remaining enzyme would have a particular affinity for the C3 cleavage site, especially in stationary phase cells. We raise the question whether the C3 terminus has a special role in cellular metabolism.

Feedback regulation of rRNA and tRNA synthesis and accumulation of free ribosomes after conditional expression of rRNA genes

We have constructed a conditional rRNA gene expression system by fusing a plasmid-encoded rrnB operon to the lambda PL promoter/operator. It was thereby possible to study the events that lead to the regulation of chromosomal rRNA and tRNA synthesis after overproduction of rRNA. rRNA induction resulted in a 2-fold increase in 30S and 50S free ribosomal subunits, whereas the polysome fraction was unaffected. Overproduction of rRNA and "free" ribosomes produced a large repression of rRNA and tRNA synthesis from chromosomal genes and a smaller increase in the concentration of guanosine tetraphosphate. These results lend support to the ribosome feedback regulation model: rRNA and tRNA operons are negatively regulated, either directly or through some intermediate, by free, nontranslating ribosomes.

Common structural features of the genes for two stable RNAs from Halobacterium halobium

The genes coding for the 5S rRNA and another stable RNA, termed 7S RNA, in Halobacterium halobium were isolated from a genomic library of this archaebacterium and their nucleotide sequences determined. Both genes are colinear with their transcripts (5S rRNA and 7S RNA), but 5S rRNA and possibly also 7S RNA isolated from other halobacteria carry additional nucleotides within the RNA transcript. Both genes are located in the G + C rich chromosomal fraction I of H. halobium. Comparison of the 3' non-coding regions of both genes shows a 20 bp sequence of high homology immediately at the 3' ends which is almost symmetrically flanked by two stem-loop structures, one being situated close to the 3' end but within the coding region and the other downstream of the common 20 bp sequence.

Transcriptional block caused by a negative supercoiling induced structural change in an alternating CG sequence

Using supercoiled plasmids containing a (CG)16 sequence downstream of a promoter, it is shown that purified E. coli RNA polymerase can transcribe through the sequence when it is in the B helical form. However, the polymerase together with its nascent transcript is blocked at the boundary of the CG sequence proximal to the promoter when the template is negatively supercoiled to flip the CG sequence to the left-handed Z-form. S1 nuclease mapping of in vivo transcripts from an E. coli gyrase temperature-sensitive mutant harboring the plasmids indicates that the bulk of the transcripts at either permissive or nonpermissive temperatures can proceed through the CG sequence, suggesting that the sequence is normally in the B helical form in vivo. The almost total blockage of transcription in vitro by the (CG)16 sequence in a highly negatively supercoiled DNA is not observed for a d(CA)21 X d(TG)21 insert.

"ATG vectors' for regulated high-level expression of cloned genes in Escherichia coli

A plasmid cloning vector system has been constructed that allows for the production of large quantities of foreign proteins or fragments thereof, in an unfused state. These vectors provide strong regulated trp-lac fusion promoters and the lacZ ribosome-binding site (RBS) followed by an ATG translation initiation codon at an appropriate distance from the RBS. The ATG codon is located within a unique NcoI restriction site (CCATGG). Digestion with NcoI exposes the ATG for fusion. Gene fragments lacking a prokaryotic RBS and/or ATG start codons can be inserted in several ways. Expression experiments using a truncated cI gene of bacteriophage lambda or a large portion of the coding region of the Herpes simplex virus type 1 glycoprotein D gene have been performed. The results of these studies show that the vectors are useful for the high-level expression of prokaryotic and eukaryotic genes in Escherichia coli.

Nucleotide sequence of the birA gene encoding the biotin operon repressor and biotin holoenzyme synthetase functions of Escherichia coli

A 2.2-kb region of DNA containing the birA gene of Escherichia coli has been sequenced. The birA gene sequence predicts a 35.3-kDal [321 amino acids (aa)] bifunctional protein containing biotin-operon-repressor and biotin-holoenzyme-synthetase activities. Mutations, generated by random insertion of XhoI linkers, defined the extent of the gene. Mutations affecting one or more of five discernable properties of birA [Barker, D. and Campbell, A., J. Bacteriol., 143 (1980) 789-800] were mapped. Three mutations that result in temperature-sensitive (ts) growth, birA85, birA215, and birA879 mapped in the N-terminal two-thirds of the protein. The birA352 mutation, which partially complements birA215 and birA879, maps in the N-terminal third of the protein. Finally, birA361 maps closest to the amino terminus.

Mapping of transcription terminators of bacteriophages phi X174 and G4 by sequence analysis

An algorithm to locate transcription terminators (V. Brendel and E. N. Trifonov, Nucleic Acids Res. 12:4411-4427, 1984) was applied to the genomes of bacteriophages phi x174 and G4. The proposed sites are similarly located in phiX and G4 and fit with transcript lengths previously observed in vivo and in vitro.

Level of rRNA, not tRNA, synthesis controls transcription of rRNA and tRNA operons in Escherichia coli

We have recently proposed a model for the negative feedback control of rRNA and tRNA synthesis in Escherichia coli by products of rRNA operons or their derivatives (e.g., nontranslating ribosomes) (S. Jinks-Robertson, R.L. Gourse, and M. Nomura, Cell 33:865-876, 1983). In this paper, we examined the following questions. (i) Are the spacer tRNAs carried within rRNA operons the products responsible for the regulation of rRNA and tRNA transcription? (ii) Are tRNAs capable of regulating their own syntheses? We measured tRNA accumulations in cells containing plasmids with intact or defective rRNA operons or with tRNA operons. From the results obtained, we conclude that neither the tRNAs encoded within rRNA operons nor the tRNAs encoded in non-rRNA operons are capable of controlling rRNA or tRNA transcription. Therefore, the products responsible for the initial step leading to rRNA and tRNA regulation are rRNAs (or their derivatives).

Expression of Herpes simplex virus type 1 glycoprotein C antigens in Escherichia coli

DNA fragments encoding structural information of the Herpes simplex virus type 1 (HSV-1) glycoprotein C (gC) gene were cloned into pUC plasmids [Vieira and Messing, Gene 19 (1982) 259-268]. None of the hybrid plasmids were able to direct the synthesis of significant amounts of gC related peptides. Several of the plasmid-bearing strains, however, exhibited inhibition characteristics which can be correlated with the presence on the plasmid of specific gC gene sequences. After insertion of gC DNA fragments into expression vector pMF2 between phage lambda repressor gene cI and lacZ, significant amounts of cI::gC::beta-galactosidase fusion proteins are synthesized. These tripartite fusion proteins are immunologically reactive with anti-HSV-1 antisera. The expression system based on pMF2 can be generally used to identify and express foreign antigens in Escherichia coli.

Chemical probing of conformation in large RNA molecules. Analysis of 16 S ribosomal RNA using diethylpyrocarbonate

Peattie & Gilbert (1980) have described an accurate and rapid gel method for assessing conformation of individual nucleotides in RNA, based on chemical modification of bases and aniline-induced strand scission. In order to extend this approach to analysis of large RNA molecules, we introduce the use of hybridization of modified RNA with DNA restriction fragments to generate RNA fragments of defined length. In principle, this permits chemical probing of conformation at any position of any RNA molecule for which a cloned DNA coding sequence is available. To illustrate the utility of this method, we use diethylpyrocarbonate to probe the reactivities of adenine residues in Escherichia coli 16 S rRNA under "native" (80 mM-potassium cacodylate (pH 7.0), 20 mM-MgCl2, 300 mM-KCl) and "quasi-secondary" (80 mM-potassium cacodylate (pH 7.0), 1 mM-EDTA) conditions. This study shows that: (1) there is generally good agreement between diethylpyrocarbonate reactivities of adenine residues in naked 16 S rRNA and a secondary structure model based on comparative sequence analysis; of 309 adenine residues probed under native conditions, only four strongly reactive residues are found in helices in the model. (2) Candidates for possible tertiary interactions are identified as adenine residues that are unpaired in the model and unreactive toward diethylpyrocarbonate under native conditions but reactive under quasi-secondary conditions. (3) An unexpectedly stable structure has been identified in the region between positions 109 and 279, where many adenine residues remain unreactive even at 90 degrees C in 80 mM-potassium cacodylate, 1 mM-EDTA. This may correspond to a structural "core" that is important for early events in ribosome assembly.

Regulation of ribosomal RNA promoters with a synthetic lac operator

A synthetic 21-base-pair long DNA fragment containing the central lac operator sequence has been inserted near the initiation point of the cloned Escherichia coli rrnB rRNA promoter P2 in the natural and reverse orientation. RNA synthesis is efficiently repressed in both orientations in lac Iq strains and is induced with isopropyl beta-D-thiogalactoside. When the rrnB promoter P1 is also present, upstream from P2 and the synthetic lac operator, repression of transcription is incomplete. The levels of transcription were measured in vivo, indirectly by the expression of a protein (chloramphenicol acetyltransferase), or directly by the expression of a stable RNA (E. coli 4.5S RNA) in a simple assay involving gel electrophoresis of unlabeled total RNA from E. coli. The rrnB promoter constructions can produce high levels of protein expression as well as high levels of expression of stable RNA.

Homology between the ribosomal DNA of Escherichia coli and mitochondrial DNA preparations of maize is principally to sequences other than mitochondrial rRNA genes

E. coli ribosomal DNA has been used to probe maize mitochondrial DNA. It hybridizes primarily with chloroplast ribosomal DNA sequences and with fungal and bacterial sequences which may contaminate the mtDNA preparations. It also hybridizes to the chloroplast 16S ribosomal RNA gene sequence present in the mitochondrial genome (1) as well as to the mitochondrial 18S ribosomal RNA gene sequence. Weak sequence homology was detected between E. coli rDNA and the mitochondrial 26S ribosomal RNA gene.

Mapping and spacer identification of rRNA operons of Salmonella typhimurium

The rRNA operons of Salmonella typhimurium have been characterized with respect to their map position, orientation, and type of tRNA spacer. One of the seven rrn operons was found to be linked to pheA and another was found to be linked to aroE. This information, together with published information about the other five rrn operons, shows that S. typhimurium and Escherichia coli are essentially identical in terms of the number, the map position, and the orientation of all seven operons. S. typhimurium and E. coli were also similar in that four of the rrn spacer regions code for tRNAGlu2 and three code for tRNAAla1B. However, the two species differed in that rrnD coded for tRNAGlu2 and rrnB coded for tRNAAla1B in S. typhimurium. This is the opposite of the arrangement in E. coli. We have tabulated the coordinates of the BamHI and PstI sites flanking six of the S. typhimurium rrn genes and present revisions for the coordinates of some of the E. coli sites.

Antitermination of transcription from an Escherichia coli ribosomal RNA promoter

The Escherichia coli lac and ara promoters and rrnC ribosomal RNA promoter-leader region were fused to lacZYA. Transcription termination signals were introduced into the lac genes of these fusions by Tn9 and IS1 insertions. Measurement of lac enzymes from upstream and downstream of the insertions showed that termination signals resulting from these insertions are very efficient when transcription begins at lac or ara promoters but are very inefficient when transcription begins at the rrnC promoter-leader region. The rrnC promoter-leader region must, therefore, modify RNA polymerase to enable it to read through transcription termination signals.

Cotranscription and processing of 23S, 4.5S and 5S rRNA in chloroplasts from Zea mays

The termini of rRNA processing intermediates and of mature rRNA species encoded by the 3' terminal region of 23S rDNA, by 4.5S rDNA, by the 5' terminal region of 5S rDNA and by the 23S/4.5S/5S intergenic regions from Zea mays chloroplast DNA were determined by using total RNA isolated from maize chloroplasts and 32P-labelled rDNA restriction fragments of these regions for nuclease S1 and primer extension mapping. Several processing sites detectable by both 3' and 5' terminally labelled probes could be identified and correlated to the secondary structure for the 23S/4.5S intergenic region. The complete 4.5S/5S intergenic region can be reverse transcribed and a common processing site for maturation of 4.5S and 5S rRNA close to the 3' end of 4.5S rRNA was detected. It is therefore concluded that 23S, 4.5S and 5S rRNA are cotranscribed.

Synthesis and processing of 5 S rRNA from an rrnB minigene in a plasmid

A recombinant plasmid containing the promoters, terminators and only the intact 5 S rRNA gene of rrnB is expressed efficiently in Escherichia coli cells. In strains containing a thermolabile RNAase E (rne) full-length transcripts of the rrnB region from the plasmid and a partially processed intermediate product accumulate at non-permissive temperatures. Upon addition of chloramphenicol two additional plasmid-specific RNA molecules appear. They are shorter than the full-length transcripts. These species contain the 3'-end region of the full-length transcripts. Even though the 5' ends of these RNAs were most likely produced by degradative enzymes these 5' ends are not ragged. All these plasmid-specific RNAs are specific substrates for the two endonucleolytic RNA processing enzymes, RNAase E and RNAase III.

The relationship between base composition and codon usage in bacterial genes and its use for the simple and reliable identification of protein-coding sequences

Bacterial genes that code for proteins appear to possess a codon usage characteristic of their overall base composition. This results in different but predictable non-random distributions of nucleotides within codons, permitting the recognition of protein-coding sequences in a wide range of bacterial species. The nature of this distribution depends on the base composition of the coding sequence. The position-specific differences are especially conspicuous in genes of extreme G + C content, allowing the particularly reliable prediction of the reading frame and coding strand of experimentally determined DNA sequences. This finding has been exploited to identify the coding sequence of the viomycin phosphotransferase (vph) gene of Streptomyces vinaceus. An easily applied computer program ("Frame") has been written to carry out and display such analyses.

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.

Plasmid P1 replication: negative control by repeated DNA sequences

The incompatibility locus, incA, of the unit-copy plasmid P1 is contained within a fragment that is essentially a set of nine 19-base-pair repeats. One or more copies of the fragment destabilizes the plasmid when present in trans. Here we show that extra copies of incA interfere with plasmid DNA replication and that a deletion of most of incA increases plasmid copy number. Thus, incA is not essential for replication but is required for its control. When cloned in a high-copy-number vector, pieces of the incA fragment that each contain only three repeats destabilize P1 plasmids efficiently. This result makes it unlikely that incA specifies a regulatory product. Our in vivo results suggest that the repeating DNA sequence itself negatively controls replication by titrating a P1-determined protein, RepA, that is essential for replication. Consistent with this hypothesis is the observation that the RepA protein binds to the incA fragment in vitro.

Structural and functional analysis of Escherichia coli ribosomes containing small deletions around position 1760 in the 23S ribosomal RNA

Three different small deletions were produced at a single Pvu 2 restriction site in E. coli 23S rDNA of plasmid pKK 3535 using exonuclease Bal 31. The deletions were located around position 1760 in 23S rRNA and were characterized by DNA sequencing as well as by direct fingerprinting and S1-mapping of the rRNA. Two of the mutant plasmids, Pvu 2-32 and Pvu 2-33, greatly reduced the growth rate of transformed cells while the third mutant, Pvu 2-14 grew as fast as cells containing the wild-type plasmid pKK 3535. All three mutant 23S rRNAs were incorporated into 50S-like particles and were even found in 70S ribosomes and polysomes in vivo. The conformation of mutant 23S rRNA in 50S subunits was probed with a double-strand specific RNase from cobra venom. These analyses revealed changes in the accessibility of cleavage sites near the deletions around position 1760 and in the area around position 800 in all three mutant rRNAs. We suggest, that an altered conformation of the rRNAs at the site of the deletion is responsible for the slow growth of cells containing mutant plasmids Pvu 2-32 and Pvu 2-33.

Oligonucleotide directed mutagenesis of Escherichia coli 5S ribosomal RNA: construction of mutant and structural analysis

The ribosomal 5S RNA gene from the rrnB operon of E. coli was mutagenised in vitro using a synthetic oligonucleotide hybridised to M13 ssDNA containing that gene. The oligonucleotide corresponded to the 5S RNA sequence positions 34 to 51 and changed the guanosine at position 41 to a cytidine. The DNA containing the desired mutation was identified by dot blot hybridisation and introduced back into the plasmid pKK 3535 which contains the total rrnB operon in pBR 322. Plasmid coded 5S rRNA was selectively labeled with 32p using a modified maxi-cell system, and the replacement of guanosine G41 by cytidine was confirmed by RNA sequencing. The growth of cells containing mutant 5S rRNA was not altered by the base change, and the 5S rRNA was processed and incorporated into 50S ribosomal subunits and 70S ribosomes. The structure of wildtype and mutant 5S rRNA was compared by chemical modification of accessible guanosines with kethoxal and limited enzymatic digestion using RNase T1 and nuclease S1. These results showed that the wildtype and mutant 5S rRNA do not differ significantly in their structure. Furthermore, the formation, interconversion and stability of the two 5S rRNA A- and B-conformers are unchanged.

Effects of site-directed mutations in the central domain of 16 S ribosomal RNA upon ribosomal protein binding, RNA processing and 30 S subunit assembly

Using a multicopy plasmid encoding the Escherichia coli rrnB ribosomal RNA operon and the techniques of in vitro site-directed mutagenesis, we have introduced several small alterations into the central domain of 16 S rRNA, which encompasses nucleotides 560 to 890. Four of the rRNAs studied contained deletions and one contained an insertion. The altered small ribosomal subunit rRNAs were used to investigate relationships among 16 S rRNA processing, protein-16 S rRNA interactions and assembly of the 30 S ribosomal subunit. Analysis of plasmid-coded transcripts from maxicells revealed that products from wild-type 16 S rRNA genes were fully processed and assembled into mature 30 S subunits. Under the same conditions, the processing and assembly of transcripts derived from the mutant plasmids were severely impaired. In some instances, the mutations completely blocked both processes, while in other cases rRNA maturation and ribosome assembly were retarded, but not eliminated completely. In all cases, the mutations led to the accumulation of the 17 S precursor to 16 S rRNA. The mutant 17 S rRNAs were purified and incubated with various combinations of E. coli ribosomal proteins S6, S8, S15 and S18, which are known to bind to the central domain of 16 S rRNA. Ribonuclease digestion of the resulting protein-17 S rRNA complexes and fractionation of the products permitted detection of three distinct protein-RNA fragment complexes which contained S8, S8 + S15, or S6 + S8 + S15 + S18. Whereas wild-type 17 S rRNA was able to form all three of these complexes, deletion of nucleotides 693 to 721 or 822 to 874 abolished the interaction of S6 and S18, and removal of nucleotides 659 to 718 prevented the binding of S6, S15 and S18. In contrast, elimination of residue 614, or the presence of a 16-base insertion between nucleotides 614 and 615, had no significant effect on the binding of any of the four proteins tested. Together, our results demonstrate that 16 S rRNA maturation and 30 S subunit assembly are tightly coupled, and show that, in at least some cases, defects in these processes can be correlated with the inability of particular ribosomal proteins to associate with altered rRNA molecules. Moreover, we have confirmed the essentiality of certain rRNA sequences for the formation and/or stabilization of these protein-rRNA interactions.(ABSTRACT TRUNCATED AT 400 WORDS)

Organization of ribosomal RNA genes in Mycoplasma capricolum

DNA segments carrying rRNA genes of Mycoplasma capricolum have been cloned and characterized by restriction endonuclease mapping, DNA-RNA hybridization and nucleotide sequencing. The M. capricolum genome has two sets of rRNA gene clusters, where the arrangement is in the order of (5')16S-23S-5S(3'). The spacer region between 16S and 23S rDNA is extremely rich in AT and does not carry any tRNA genes.

Nucleotide sequence of the rrnB 16S ribosomal RNA gene from Mycoplasma capricolum

The nucleotide sequences of the rrnB 16S ribosomal RNA gene and its 5'-and 3'-flanking regions from Mycoplasma capricolum have been determined. The coding sequence is 1521 base pairs long, being 21 base pairs shorter than that of the Escherichia coli 16S rRNA gene. The 16S rRNA sequence of M. capricolum reveals 74% and 76% identify with that of E. coli and Anacystis nidulans, respectively. The secondary structure model constructed from the M. capricolum 16S rRNA gene sequence resembles that proposed for E. coli 16S rRNA. A large stem structure can be constructed between the 5'- and 3'-flanking sequences of the 16S rRNA gene. The flanking regions are extremely rich in AT.

Promotion, termination, and anti-termination in the rpsU-dnaG-rpoD macromolecular synthesis operon of E. coli K-12

The regulatory regions for the rpsU-dnaG-rpoD macromolecular synthesis operon have been fused to a structural gene whose product is readily assayed (the Cmr structural gene coding for chloramphenicol acetyl transferase, CAT). The promoters (P1, P2, P3, Pa, Pb, Phs) for the macromolecular synthesis operon have different strengths as shown by their relative abilities to drive expression of the CAT gene. Promoter occlusion by P1 can be demonstrated within this operon. Regions 5kb upstream have a profound effect on operon gene expression. There is a thermoinducible promoter located within the dnaG structural gene. One of the macromolecular synthesis operon promoters is under lexA control. Although the operon structure allows coordinate expression of rpsU, dnaG and rpoD these additional features suggest that expression of individual genes can be independently regulated in response to altered growth conditions.

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.

Antibiotic resistance mutations in 16S and 23S ribosomal RNA genes of Escherichia coli

Recombinant DNA and classic genetic procedures were used to map a spectinomycin resistance mutation to a 121 base pair region of a 16S RNA gene and a macrolide-lincosamide-streptogramin type B resistance mutation to a 32 base pair region of a 23S RNA gene. DNA sequence analysis of these regions revealed that spectinomycin resistance results from a C/G to T/A transition at position 1192 of a 16S RNA gene. Resistance to macrolide, lincosamide and streptogramin type B antibiotics results from an A/T to T/A transversion at position 2058 of a 23S RNA gene. The alteration in 16S RNA is in a sequence that can participate in alternate base pairing arrangements that have been proposed to be involved in the translocation process. The alteration in 23S RNA identifies sequences important to peptidyl transfer.

A computer algorithm for testing potential prokaryotic terminators

The nucleotide sequences of 30 factor-independent terminators of transcription with RNA polymerase from E. coli have been compiled and analyzed. The standard features - a stretch of thymine residues and a preceding dyad symmetry - are shared by most sequences, but there are striking exceptions which indicate that these features alone are not sufficient to describe these sites. In two thirds of the sequences the 3'-half of the dyad symmetry contains the pentanucleotide CGGG (G/C) or a close derivative; about one third have TCTG or a close derivative just downstream of the termination point. The TCTG -box might be implied in termination of stringently controlled operons of E. coli. An algorithm to locate terminators in templates of known nucleotide sequence has been constructed on the basis of correlation to the distribution of dinucleotides along the aligned signal sequences. The algorithm has been tested on natural sequences of a total length of about 11,500 N. It finds all known independent terminators and only a few other sites, including some of the rho-dependent and putative terminators.

Point mutations in the middle of 16S ribosomal RNA of E. coli produced by deletion loop mutagenesis

Using the plasmid pKK3535 , which contains the rrnB operon of Escherichia coli in pBR322, a deletion mutation was constructed which lacks bases 822 to 874 in the middle of the 16S ribosomal RNA. This results in an "amputation" of a very distinct stem and loop structure in the RNA. By forming a heteroduplex between the deletion plasmid and the original pKK3535 and by modifying the single-stranded deletion loops with bisulfite, we produced plasmids containing one or two base changes at positions 839, 840, 841, 867 or 876. The clustering of the mutations near the top of the stem, and the inability to get base changes at other positions, suggests that single alterations at particular positions severely affect the formation of a functional ribosome. The ability to recover mutations at these positions is not determined by the secondary structure of the DNA during bisulfite mutagenesis. Restriction enzyme analysis of 12 revertants from a slow growing mutant (altered at positions 839 and 876) shows that they did not compensate for the mutation by re-establishing the original wild type sequence.

Hybrid 5 S ribosomal RNA encoded by a multicopy plasmid is incorporated into ribosomes of Escherichia coli

The recombinant plasmid pJR3 delta contains a tandem pair of promoters from rrnA followed by a hybrid 5 S rRNA gene, derived from the two 5 S rRNA genes of the rrnD transcription unit, and a terminator. Escherichia coli cells transformed with this plasmid produce 2-3-times more 5 S rRNA compared to untransformed cells. The growth of cells containing this plasmid is not affected significantly. Although the sequence and the secondary structure of the plasmid-specific 5 S rRNA differ from those of its counterparts (e.g., from 5 S rRNA species encoded by chromosomal genes), it is processed properly and is incorporated into ribosomes.

Transcription of a gene cluster coding for two aminoacyl-tRNA synthetases and an initiation factor in Escherichia coli

The alpha and beta subunits of phenylalanyl-tRNA synthetase are encoded by the pheS and pheT genes, respectively. These genes are clustered closely together with the genes for threonyl-tRNA synthetase (thrS) and translation initiation factor IF3 (infC); the gene order is thrS infC pheS pheT. We have used two methods to study the transcription pattern within this cluster. The first was the in vitro transcription of DNA restriction fragments with purified RNA polymerase, followed by fractionation of the RNA products by polyacrylamide gel electrophoresis. The second method was the mapping of promoters by means of the "abortive initiation" reaction of McClure and co-workers. This procedure consists of the incubation of RNA polymerase with DNA restriction fragments plus one nucleoside monophosphate and one [alpha-32P]nucleoside triphosphate; the polymerase synthesizes dinucleotide products of known sequence at promoter sites in the DNA. We found that transcription initiated at an internal site within infC (designated P1), and at two promoter sites between infC and pheS (designated P2 and P3). Transcription terminated at two sites about 200 nucleotides apart, located just before pheS. The initiation and termination signals were arranged so as to yield a nested set of overlapping transcripts. At the P1 promoter, transcription initiated with G-C, at P2 with A-C and sometimes A-G, and at P3 with G-U. Promoter activity was also found in a 3000-base interval that includes the start of the thrS gene; eight or nine transcripts (not mapped in detail) were observed, which started with at least four different dinucleotides. All major initiation sites in the gene cluster represented purine starts, although some pyrimidine initiation was observed in trace amounts. No promoter activity was found between pheS and pheT with either of the two techniques; this observation supports the conclusion that these genes are co-transcribed. No evidence was found for any promoter between the termination sites and the beginning of the pheS gene. It is suggested that one of the terminators is an attenuation site controlling the extension of transcription into pheS and pheT. Attenuation may explain the observed regulation of phenylalanyl-tRNA synthetase by the amino acid supply.

Toxicity of an overproduced foreign gene product in Escherichia coli and its use in plasmid vectors for the selection of transcription terminators

A rat insulin gene which was fused to Escherichia coli signals for the initiation of translation could not be retained when expressed from the strong rrnB ribosomal RNA promoters or an induced trp/lac (= tac) hybrid promoter. When the latter promoter was repressed by transformation into a lac-repressor-overproducing strain, the insulin gene fragment could be retained. Upon induction of the promoter with isopropyl-beta-D-galactosidase the growth rate of the cells was reduced, and in most cases the cells subsequently lysed. Deletion of the translational initiation signals, changing the reading frame, or insertion of an efficient transcription terminator between the promoter and the rat insulin gene each permitted retention of the fragment. The first two observations indicate that overproduction of the specific polypeptide, and not of the RNA, is detrimental to the cell. The third finding has been exploited for the testing and selection of transcription terminators. The rpoC terminator, which is located distal to the rplJL /rpoBC operon, has been shown to terminate transcripts from the rrnB promoters. It was also shown that the putative rrnB terminators, T1 and T2, each function separately in vivo.

Plasmid vectors for the selection of promoters

Vectors were constructed which contain promoterless genes for chloramphenicol (cam) or tetracycline (tet) resistance, as promoter-probe plasmids. Escherichia coli cells harboring these plasmids are sensitive to cam or tet but resistant to ampicillin. In plasmids pKK231 -1 and pKK232 -8 the gene for cam acetyltransferase (CAT) and in pKK175 -6 the gene for tet resistance are flanked by efficient transcription terminators, preventing transcription from other pBR322 promoters into the antibiotic resistance region. In one of the vectors, pKK232 -8, translational stop codons were introduced in all three reading frames upstream from the initiation codon of the cat gene. If a DNA fragment containing a promoter is inserted into one of the cloning sites upstream from the antibiotic genes, cells carrying such plasmids acquire resistance to cam or tet. Using these vectors two restriction fragments that contain promoters were identified. One of these fragments contains sequences upstream from an unidentified gene ( ORFII ) located distal to the rrnB rRNA operon of E. coli.

A convenient method for locating sets of related short sequences in DNA sequences of any length

In investigating sequence variants in a family of highly repeated rat DNA, we needed to search the consensus sequence of the repeat unit of this family for short sequences which would become, with one base change, recognition sites for various restriction endonucleases. To do this, we have designed a pair of programs to search DNA sequences of any length for sets of related short sequences, allowing user-specified mismatches in the short sequence. Since putative regulatory regions are generally short sequences, these programs are also useful for locating all possible versions of such sequences in any given DNA. We describe the programs, and present results of searches using the programs.

RNase III cleavage is obligate for maturation but not for function of Escherichia coli pre-23S rRNA

RNase III makes the initial cleavages that excise Escherichia coli precursor 16S and 23S rRNA from a single large primary transcript. In mutants deficient in RNase III, no species cleaved by RNase III are detected and the processing of 23S rRNA precursors to form mature 23S rRNA fails entirely. Instead, 50S ribosomes are formed with rRNAs up to several hundred nucleotides longer than mature 23S rRNA. Unexpectedly, these aberrant subunits function well enough to participate in protein synthesis and permit cell growth. Consistent with the inference that RNase III cleavages are absolutely required for 23S rRNA maturation, when 50S ribosomes from a strain deficient in RNase III were incubated with a ribosome-free extract from a RNase III+ strain, rRNA species processed by RNase III and species with normal mature 23S rRNA termini were produced.

Crystallization of a ribonuclease-resistant fragment of Escherichia coli 5 S ribosomal RNA and its complex with protein L25

A ribonuclease-resistant fragment of Escherichia coli 5 S ribosomal RNA has been crystallized. The space group is P6(1)22 or P6(5)22, with a = 59.5 A and C = 268 A. The crystals contain one molecule per asymmetric unit, and show diffraction to 4.0 A resolution. Also, a complex of this fragment with L25 ribosomal protein has been crystallized in the same space group, but with a = 119 A, c = 250 A and four molecules per asymmetric unit.

Detailed analysis of the higher-order structure of 16S-like ribosomal ribonucleic acids

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Vectors bearing a hybrid trp-lac promoter useful for regulated expression of cloned genes in Escherichia coli

A strong promoter has been cloned on a series of plasmid vectors that facilitate the expression of cloned genes. This promoter, named tac [first described by DeBoer et al. (in Rodriguez, R.L. and Chamberlin, M.J. (Eds.),Promoters, Structure and Function. Praeger, New York, 1982, pp. pp. 462-481)] contains the -10 region of the lacUV5 promoter and the -35 region of the trp promoter. Our vectors contain various cloning sites followed by transcription termination signals. In addition, we describe plasmids that facilitate the conversion of the lac promoter to the stronger tac promoter. Thus, preexisting gene fusions using the lac or the lacUV5 promoter can be readily converted to tac promoter gene fusions without changing the ribosome-binding site (RBS). The tac promoter is repressed in lacIQ strains and can be induced by isopropylthio-beta-D-galactoside (IPTG). Studies of expression of the cI repressor of bacteriophage lambda show that the tac promoter is at least five times more efficient than the lacUV5 promoter. Under optimal conditions lambda repressor constitutes up to 30% of the total cellular protein.

The complete nucleotide sequence of a 23S rRNA gene from a blue-green alga, Anacystis nidulans

The complete nucleotide sequence of a 23S rRNA gene from a blue-green alga, Anacystis nidulans, has been determined. This nucleotide sequence has 78% and 68% homologies with those of the tobacco chloroplast and Escherichia coli 23S rRNA genes, respectively. The 3'-terminal region of the A. nidulans 23S rRNA gene has strong homology with the chloroplast 4.5S rRNA.

Structure and organization of rRNA operons in the region of the replication origin of the Bacillus subtilis chromosome

Structure and organization of two complete ribosomal RNA (rRNA) gene sets, rrnO and rrnA, were determined for the first time in Bacillus subtilis. They are located at the region of the replication origin of the chromosome. Each set constitutes a single operon of: two tandem promoters - leader sequence - 16S rRNA gene - Ile-tRNA gene - Ala-tRNA gene - 23S rRNA gene - 5S rRNA gene - termination signal. The first promoter (P1) of rrnO differs from that of rrnA in sequence and function. P1 of rrnO was used very little for transcription either in vivo or in vitro while P1 was predominantly used in rrnA. A putative transcript of the entire operon was determined and constructed into a secondary structure. Analysis of in vivo transcripts by S1 mapping revealed primary processing sites at the loop and stem structure of 16S rRNA in rrnO and rrnA. A unique sequence in the leader region of rrnO can be formed into a highly complexed secondary structure and affects processing of mature 16S rRNA. The sequences of the two spacer tRNA genes are highly conserved between B. subtilis and Escherichia coli.