Efficient read-through of Tn9 and IS1 by RNA polymerase molecules that initiate at rRNA promoters

Impaired expression of certain prereplicative bacteriophage T4 genes explains impaired T4 DNA synthesis in Escherichia coli rho (nusD) mutants

The Escherichia coli rho 026 mutation that alters the transcription termination protein Rho prevents growth of wild-type bacteriophage T4. Among the consequences of this mutation are delayed and reduced T4 DNA replication. We show that these defects can be explained by defective synthesis of certain T4 replication-recombination proteins. Expression of T4 gene 41 (DNA helicase/primase) is drastically reduced, and expression of T4 genes 43 (DNA polymerase), 30 (DNA ligase), 46 (recombination nuclease), and probably 44 (DNA polymerase-associated ATPase) is reduced to a lesser extent. The compensating T4 mutation goF1 partially restores the synthesis of these proteins and, concomitantly, the synthesis of T4 DNA in the E. coli rho mutant. From analyzing DNA synthesis in wild-type and various multiply mutant T4 strains, we infer that defective or reduced synthesis of these proteins in rho 026-infected cells has several major effects on DNA replication. It impairs lagging-strand synthesis during the primary mode of DNA replication; it delays and depresses recombination-dependent (secondary mode) initiation; and it inhibits the use of tertiary origins. All three T4 genes whose expression is reduced in rho 026 cells and whose upstream sequences are known have a palindrome containing a CUUCGG sequence between the promoter(s) and ribosome-binding site. We speculate that these palindromes might be important for factor-dependent transcription termination-antitermination during normal T4 development. Our results are consistent with previous proposals that the altered Rho factor of rho 026 may cause excessive termination because the transcription complex does not interact normally with a T4 antiterminator encoded by the wild-type goF gene and that the T4 goF1 mutation restores this interaction.

Cloning and transcription analysis of the entire glycerol utilization (gylABX) operon of Streptomyces coelicolor A3(2) and identification of a closely associated transcription unit

The entire glycerol utilization (gylABX) operon of Streptomyces coelicolor A3(2) was cloned and its transcriptional organization and regulation was analyzed by Northern blotting, S1 nuclease mapping and transcriptional fusions. Transcription of the operon is glycerol-inducible and glucose-repressible; glyA (presumptively encoding glycerol kinase), gylB (encoding sn-glycerol-3-phosphate dehydrogenase) and gylX (a non-essential 1.1 kb sequence) are transcribed consecutively to give a 5.4 kb mRNA. Two alternative transcription termination or gyl mRNA processing sites are located within the operon; one (a discrete site) lies between gylB and gylX and the other (a heterogeneous site) positioned 3 kb into the operon, may correspond to the gylA-gylB intercistronic region. A 0.9 kb glycerol-inducible transcription unit is located immediately upstream of gylABX. Transcriptional fusion studies employing an attP site-deleted phage vector provided complementary evidence for the organization of the operon.

Expression of a tRNA gene in the context of the lacZ mRNA

Fusions of the gene for tyrosine suppressor tRNA, tyrT(Sup3), and the lacZ gene of Escherichia coli were constructed such that the tRNA gene could be expressed from either its own promoter or that of the lac operon. These chimeras, carried on phage M13 vectors, were tested for the expression of the tRNA in E. coli. The tRNA gene was expressed on the order of 10-fold more weakly from the lac promoter than from its own promoter. To examine whether pausing or premature termination of transcription played a role in determining the relative strength, the fusions were tested in a variety of genetic backgrounds and under different physiological conditions that uncouple transcription and translation. The expression of the tRNA was not enhanced in backgrounds in which polarity was weakened or under the other conditions tested, although a dependence on nusB function was observed when the tRNA was transcribed from the lac promoter. These results indicate that pausing or premature termination of transcription did not play a role in the weak expression of the gene fusions. The results further suggest that the transcription of the tyrT gene does not normally require relief from polarity as imposed by any of the known transcriptional termination systems, in contrast to the antitermination system thought to be involved in the expression of the rRNAs.

The sequence of the distal end of the E. coli ribosomal RNA rrnE operon indicates conserved features are shared by rrn operons

The 1440 nucleotides of the distal region of the E. coli ribosomal RNA operon found on the lambda aroE transducing phage has been sequenced. We show that the lambda aroE hybrid rrn operon ends after a solitary 5S RNA gene with rrnE distal sequence. A single terminator structure of dyad symmetry followed by a run of six T's have been identified and compared to other sequenced rrn terminator hairpins. Immediately adjacent to the hairpin is a region of interrupted but conserved sequence that is shared by rrnE, rrnB and rrnD. An open reading frame of 127 amino acids abuts the terminator structure. Another open reading frame of 147 amino acids is found on the opposite strand several hundred nucleotides downstream.

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.

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.

Inhibitory effect of high-level transcription of the bacteriophage lambda nutL region on transcription of rRNA in Escherichia coli

Transcription of the bacteriophage lambda nutL region from the PL promoter on a multicopy plasmid in Escherichia coli causes a reduction in growth rate and in transcription of rRNA relative both to total transcription and to transcription of tRNAs that are not encoded in rRNA operons. These observations support the hypothesis, previously based on nut site DNA sequence homology, that the phage lambda and rRNA antitermination systems are related.

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.

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.

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.

Five mutations in the promoter region of the araBAD operon of Escherichia coli B/r

Five mutations that result in reduced expression of the araBAD operon were cloned onto the plasmid pBR322. The position of each mutation was determined by DNA sequence analysis. Three of the mutations were located in the RNA polymerase binding site of the araBAD promoter. The first, ara-1016, was a one-base-pair deletion at position -35; the second, ara-1036, was a transversion at position -13; the third, ara-1027, was a nine-base-pair deletion from +5 to +13. S1 nuclease mapping showed that mutations ara-1016 and ara-1036 greatly reduced transcription and that mutation ara-1027 had little, if any, effect on transcription. Two other mutations resulted from the transposition of the insertion element, IS1, downstream from the transcriptional start site of the operon. Molecular mechanisms for all of the mutations are discussed.