Suppression of transcription termination by phage lambda

Learning from the Leaders: Gene Regulation by the Transcription Termination Factor Rho

The RNA helicase Rho triggers 20-30% of transcription termination events in bacteria. While Rho is associated with most transcription elongation complexes, it only promotes termination of a subset. Recent studies of individual Rho-dependent terminators located within the 5' leader regions of bacterial mRNAs have identified novel mechanisms that govern Rho target specificity and have revealed unanticipated physiological functions for Rho. In particular, the multistep nature of Rho-dependent termination enables regulatory input from determinants beyond the sequence of the Rho loading site, and allows a given Rho-dependent terminator to respond to multiple signals. Further, the unique position of Rho as a sensor of cellular translation has been exploited to regulate the transcription of genes required for protein synthesis, including those specifying Mg(2+) transporters.

Molecular cloning and high-level expression of human polymerase beta cDNA and comparison of the purified recombinant human and rat enzymes

The cDNA encoding the human polymerase beta from HeLa cells was PCR amplified and cloned, and its nucleotide sequence determined. The DNA sequence is identical to the polymerase beta cDNA sequence from Tera-2 cells. Three expression strategies were employed that were designed to maximize translation initiation of the polymerase beta mRNA in Escherichia coli and all yielded a high level of human polymerase beta. The recombinant protein was purified and its properties were compared with those of the recombinant rat enzyme. The domain structure and kinetic parameters (k(cat) and K(m)) were nearly identical. A mouse IgG monoclonal antibody to the rat enzyme (mAb-10S) was approximately 10-fold less reactive with the human enzyme than with the rat enzyme as determined by ELISA.

Translational repression by a transcriptional elongation factor

One of the classical positive regulators of gene expression is bacteriophage lambda N protein. N regulates the transcription of early phage genes by participating in the formation of a highly processive, terminator-resistant transcription complex and thereby stimulates the expression of genes lying downstream of transcriptional terminators. Also included in this antiterminating transcription complex are an RNA site (NUT) and host proteins (Nus). Here we demonstrate that N has an additional, hitherto unknown regulatory role, as a repressor of the translation of its own gene. N-dependent repression does not occur when NUT is deleted, demonstrating that N-mediated antitermination and translational repression both require the same cis-acting site in the RNA. In addition, we have identified one nut and several host mutations that eliminate antitermination and not translational repression, suggesting the independence of these two N-mediated mechanisms. Finally, the position of nutL with respect to the gene whose expression is repressed is important.

Structural analysis of ternary complexes of Escherichia coli RNA polymerase. Individual complexes halted along different transcription units have distinct and unexpected biochemical properties

Ternary complexes containing RNA polymerase, DNA and nascent RNA are intermediates in all RNA syntheses and are the targets of cellular factors that regulate RNA chain elongation and termination. Hence, elucidation of the structure and properties of these complexes is essential for understanding the catalytic and regulatory properties of the enzyme. We have described methods to prepare ternary complexes halted at defined positions along the DNA template, using specific dinucleotides to prime chain initiation along with limited subsets of the NTP substrates. Study of these static, halted complexes may provide information about the structure and properties of the transient elongation intermediates involved in transcription, although there is no necessary direct relationship between the two. Using specific halted complexes as precursors, we have walked the RNA polymerase along its template, producing defined ternary complexes at unique sites along two different transcription units. These complexes differ significantly from one another in many biochemical properties, in dramatic contrast to the properties expected from models that postulate a monotonous structure for elongation intermediates. These differences include variations in complex mobility during electrophoresis in non-denaturing polyacrylamide gels, in thermal stability and in stability to dissociation. Some halted complexes lose the ability to resume elongation when presented with the missing substrates. These "dead end" complexes must represent metastable structures in which elongation is blocked, and demonstrate clearly that not all halted complexes can be considered true intermediates in elongation. Other halted complexes rapidly cleave the nascent RNA seven nucleotides from the 3' terminus, in an unexpected and unusual biochemical reaction. These differences in properties among complexes bearing transcripts that differ by only one or a few nucleotides suggest that they have distinct structures. These differences must be due, at least in part, to differences in the template sequence and the length of the transcript. The results raise important questions as to the actual mechanism of transcription elongation, and suggest that it is a much more complex process than previously assumed.

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.

An Escherichia coli cis-acting antiterminator sequence: the dnaG nut site

The Escherichia coli rpsU-dnaG-rpoD operon contains an internal transcription terminator T1 located in the intergenic region between the rpsU and dnaG genes (Smiley et al. 1982). By cloning T1 as a small 127 bp fragment into the terminator probe plasmid pDR720 between the trp operator promoter and the assayable galK gene, it was shown that T1 acts as a strong transcription terminator, comparable in strength to the 3' operon terminator T2. However, an operon sequence that occurs 5' to T1 within the coding region of the rpsU gene and which has homology with the lambda nut site, (Lupski et al. 1983) when placed 5' to T1 in the pDR720 plasmid construct, modifies transcription through T1 allowing expression of the galK gene. This sequence, called the dnaG nut site also modifies the termination activity of the external operon terminator T2. It is proposed that the dnaG nut site is a cis-acting element of an antitermination system in E. coli.

Transcriptional patterns for the thrS-infC-rplT operon of Escherichia coli

The genes coding for threonyl-tRNA synthetase (thrS), translation initiation factor 3 (infC) and ribosomal protein L20 (rplT) are clustered in the Escherichia coli genome. Previous studies had suggested the possibility that the expression of these genes is coupled. The transcriptional events in this operon have now been examined by S1 nuclease mapping and promoter fusion studies. The results indicate that infC-containing mRNAs are initiated from three separate promoters. Two of these are located in the protein-coding region of thrS and one, P12, is the major promoter at all growth rates tested. In addition, there is co-transcription of thrS and infC from the thrS promoter (PT). A single promoter for thrS has been mapped approx. 170 nucleotides upstream from its translation initiation site. Another promoter has been located within the infC-coding region. It is separated from the next downstream gene, rplT, by a transcription end point. However, termination at this region is only 50-70% efficient and transcripts starting at this promoter can read through into rplT. These findings demonstrate that the pattern of transcription in this operon is highly complex and the mRNA levels for each of the genes is determined by a variety of factors, including multiple promoters, co-transcription and readthrough of transcription termination signals.

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.

Rho-dependent transcription termination of a bacterial operon is antagonized by an extrachromosomal gene product

The psu gene product of "phasmid" (phage-plasmid) P4 acts as a transcription antitermination factor in trans and in cis, respectively, within the morphogenic operons of its P2 phage helper during lytic viral development and on P4 itself during the establishment stage of its alternative mode of propagation as a plasmid. Here we show that psu also antagonizes activity of the Escherichia coli transcription termination factor rho at the terminator of the trp operon. Such a finding provides to our knowledge the first direct evidence for antitermination activity at a known rho-dependent site by the psu gene product. It also reveals an example of an extrachromosomal gene product that acts on specific sites of three different genomes to regulate expression of unlinked families of genes.

Inefficient translation initiation causes premature transcription termination in the lacZ gene

Expression plasmids containing the E. coli lacZ coding region preceded by a set of different ribosome-binding sites and put under transcriptional control of the leftward promoter of phage lambda (PL) were used to study the synthesis of lacZ mRNA. In a normal host the steady state level of full-length lacZ mRNA varied 100-fold with the different synthesis levels of beta-galactosidase, whereas in a host expressing the antitermination protein N of phage lambda, all vectors synthesized the same amount of full-length lacZ mRNA, while maintaining the differences in beta-galactosidase expression. We present evidence for a causal relationship between the rate of ribosome loading and the continuation of transcription across the lacZ gene. We suggest that extended spacing between the RNA polymerase and the elongating ribosome causes transcriptional polarity by increasing the extent of premature termination. The conditional character of the termination event can best be explained by invoking termination factor Rho.

Transposition studies of mini-Mu plasmids constructed from the chemically synthesized ends of bacteriophage Mu

We describe below the chemical synthesis of the right and left ends of bacteriophage Mu and characterize the activity of these synthetic ends in mini-Mu transposition. Mini-Mu plasmids were constructed which carry the synthetic Mu ends together with the Mu A and B genes under control of the bacteriophage lambda pL promoter. Derepression of pL leads to a high frequency of mini-Mu transposition (5.6 X 10(-2) which is dependent on the presence of the Mu ends and the Mu A and B proteins. Five deletion mutants in the Mu ends were tested in the mini-Mu transposition system and their effects on transposition are described.

Evidence that ribosomal protein S10 itself is a cellular component necessary for transcription antitermination by phage lambda N protein

Bacteriophage lambda N gene product acts to modify host RNA polymerase allowing the formation of a termination-resistant transcription apparatus. Previous studies have demonstrated that the nusE71 mutation that has altered the ribosomal protein S10 prevents N action in vivo. Using a coupled transcription-translation system, we demonstrate here that purified S10 protein as well as the 30S ribosomal subunit is sufficient to restore N activity in the nusE mutant extract, allowing antitermination of Rho-dependent and Rho-independent terminators. This provides direct biochemical evidence that the S10 protein itself is one of the cellular components necessary for the formation of an antitermination apparatus.

Autogenous regulation of transcription termination factor Rho

We present evidence that the transcription termination factor Rho is autogenously regulated in Escherichia coli. The steady-state level of Rho is increased approximately tenfold in rho mutant cells. In the rho+ revertants, the content of Rho is similar to the wild-type level. A rho-/rho+ merodiploid produces equimolar amounts of the mutant and the wild-type Rho polypeptides, both at a reduced level compared to the mutant. The steady-state level of rho messenger RNA is also increased in a rho mutant. A rho-galK transcriptional fusion produces at least tenfold more galactokinase in a rho- strain than in a rho+ strain. In vitro, in a coupled transcription-translation system, the synthesis of Rho protein is specifically inhibited by wild-type Rho but not by Rho15 mutant protein. Anti-Rho antibody specifically stimulates Rho synthesis in the rho+ extract but not in a rho- extract. We suggest that the autogenous regulation of Rho involves premature transcription termination within the rho gene. Regulation of Rho level may provide the cell a mechanism to modulate the expression of genes which are separated from their promoters by Rho-dependent termination signals.

A CII-responsive promoter within the Q gene of bacteriophage lambda

A site within the phage lambda Q gene shares homology with the CII-activated promoters, pE and pI, and is oriented in the direction opposite to that of Q gene transcription. A DNA fragment containing this site can serve as a template for CII-activated transcription in vitro. To ask if this presumptive CII control site functions as a CII-activated promoter in vivo, a restriction fragment containing this promoter has been cloned on a plasmid so that synthesis of beta-galactosidase will be under its control. When CII protein is supplied in trans from a compatible plasmid, this promoter, designated PaQ, is activated to produce beta-galactosidase. A promoter positioned within the Q gene which can be activated by CII protein to initiate transcription in an anti-sense direction should result in an interference with Q gene expression, enhancing CII regulation of late functions, and adding to the list of known CII controls on the lysogenic response.

Attenuation may regulate gene expression in animal viruses and cells

In eukaryotes, an abundant population of promoter-proximal RNA chains have been observed and studied, mainly in whole nuclear RNA, in denovirus type 2, and in SV40. On the basis of these results it has been suggested that a premature termination process resembling attenuation in prokaryotes occurs in eukaryotes. Moreover, these studies have shown that the adenosine analog 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) enhances premature termination, but its mode of action is not understood. The determination of the nucleotide sequences of SV40 and other viruses and cellular genes provide means for elucidating the nucleotide sequences involved in the attenuation mechanism. A model has recently been described in which attenuation and mRNA modulation in a feedback control system quantitatively regulate SV40 gene expression. The suggested mechanism described in this model opens up approaches to the investigation of attenuation and mRNA modulation as a possible mechanism whereby eukaryotes may regulate transcription in a variety of different circumstances.

Sequence analysis of a region from the early right operon in phage P22 including the replication genes 18 and 12

A comparison of a 3000-bp sequence of Salmonella phage P22, coding for gene c1 and the replication genes 18 and 12, with the analogous cII-O-P region of coliphage lambda permits the localization of transcriptional signals, an oop RNA species, and the origin of replication (ori) within gene 18. Gene c1 and the amino terminal region of gene 18 show homology to the respective lambda genes. In the ori domain of the replicator proteins the homology to phi 82 is most pronounced. Of two lambda:repP22 hybrids (lambda with replication genes of P22) analysed, one codes for a hybrid O/18 protein with 30 N-terminal amino acids coded for by lambda. Gene 12 is nonhomologous to its lambda counterpart (gene P), but closely related to dnaB of Escherichia coli. A ren gene is missing, whereas two open reading frames (ORFs) distal to gene 12 are almost identical to those in the lambda nin region. We try to account for the occurrence and location of highly conserved sequences among the lambdoid phages by assigning them a role in recombinational reassortment of functional units during the evolution of this phage family.

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.

Overexpression and sequence of the Escherichia coli cheY gene and biochemical activities of the CheY protein

We overexpressed the CheY protein by fusing the cheY gene to the tryptophan promoter from Serratia marcescens. Expression of the trp promoter-cheY fusion and subsequent purification of the protein resulted in the isolation of up to 20 mg of homogeneously pure CheY protein from 100 mg of the cytoplasmic supernatant fraction. Purification of the CheY protein was accomplished by exploiting the affinity of CheY protein to cibacron blue dye and molecular sieve chromatography. Preliminary biochemical characterization of the pure CheY protein revealed specific interactions with S-adenosylmethionine and cibacron blue dye. Additional kinetic analysis showed that CheY protein inhibits EcoRI methyltransferase. The amino acid composition of the CheY protein predicted by the DNA sequence of the cheY gene and the amino acid analysis of the CheY protein were in agreement, confirming the authenticity of the purified CheY protein.

Transcription antitermination in vitro by lambda N gene product: requirement for a phage nut site and the products of host nusA, nusB, and nusE genes

Employing specifically engineered plasmids in which the expression of E. coli galK cistron is regulated by transcription termination, we have analyzed the antitermination function of phage lambda N gene product in S30 extracts. Antitermination by N, dependent on its site of action, nutL, is defective in the extracts prepared from nusA, nusB, and nusE mutants. By complementation analysis, we demonstrate that none of the these nus mutations affects the synthesis of N or the other nus gene products to cause a defect in antitermination. Rather, these mutations have inactivated a set of specific host components, the Nus factors, which are essential for N activity. Curiously, an appreciable portion of N and Nus complementation activities of an S30 extract is ribosome-associated. The significance of this finding remains to be uncovered.

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.

Formation of termination-resistant transcription complex at phage lambda nut locus: effects of altered translation and a ribosomal mutation

Transcription antitermination by lambda N gene product is affected in a mutant Escherichia coli with altered ribosomal protein S10, caused by the nusE71 mutation. To study the role of translation in antitermination, we have fused the phage nutR locus, the site of action of N, with the lac regulatory region. We have monitored N action by measuring galactokinase, whose synthesis depends on suppression of terminators located between nutR and the galK cistron. We show that a deletion removing potential ribosome binding signals and AUG codons from the upstream region of nut site does not affect N action. Moreover, the lack of translation upstream of nutR does not overcome the antitermination defect caused by nusE mutation. When the upstream region is translated, however, N action is impaired if translation terminates 19 base pairs upstream of nutR . Termination of translation at further upstream sites, such as 23 or 97 base pairs upstream, does not interfere with N action. Our results suggest that the S10 ribosomal protein is required for N action without involving translation. These results also suggest that the nut site RNA itself plays an important role in the formation of a termination-resistant transcription complex.

Genetic studies on the beta subunit of Escherichia coli RNA polymerase. IV. Structure-function correlates

We have isolated a set of strains that synthesise 331 potential variants of E. coli DNA-dependent RNA polymerase making use of nonsense suppression of amber mutations in the beta structural gene; rpoB. Translational mapping, together with the effect of known amino acid substitutions, has allowed us to locate sites on the beta polypeptide involved in transcription termination, stringent response and resistance to the antibiotic rifampicin. In general, the C-terminal quarter appears to be less affected by such single amino acid exchanges than the rest of beta. These studies permit for the first time structure-function correlates for the beta subunit of RNA polymerase.

Nucleotide sequence of the regulatory region of the uvrD gene of Escherichia coli

We have sequenced the control region of the Escherichia coli uvrD gene and demonstrated the presence of a nucleotide sequence which is a perfect match for the consensus LexA protein binding site [Little and Mount, Cell 29 (1982) 11-22]. Upstream of this presumed LexA binding site is a promoter sequence, uvrD P1 which would be under LexA control while farther downstream is another possible promoter, uvrD P2, which would be independent of LexA control. Downstream of the LexA binding site is a potential transcription terminator in the form of a stem-loop structure followed by a series of T residues. On the basis of this sequence analysis, expression of the uvrD gene would be expected to increase after DNA damage or replication inhibition as part of the SOS response, as is reported in the preceding paper [Arthur and Eastlake, Gene 25 (1983) 309-316].

lambda mutation in the Escherichia coli rho gene that inhibits the N protein activity of phage lambda

Certain Escherichia coli rho mutations, exemplified by rho026, block the growth of phage lambda by interfering with phage gene expression. The phage gene N, whose product suppresses transcription termination, appears to be expressed normally in the mutants, and the functional stability of the N protein is not affected. Our data suggest that these rho mutations allow transcription to terminate despite the presence of N. Other E. coli mutants displaying a similar phenotype (Nus(-)) fail to propagate wild-type lambda but permit the growth of the lambda variant lambdanin5, which has undergone a deletion of the lambda terminator t(R2). The phenotype of the rho026 mutant differs: the growth of lambda is only marginally improved by the nin5 deletion. Interestingly, N activity at rho-independent terminators is not inhibited by the mutations, whereas its ability to suppress rho-dependent terminators is markedly reduced. The relevance of this specificity in terms of models of N action is discussed.

Escherichia coli nusB mutations that suppress nusA1 exhibit lambda N specificity

The bacteriophage lambda N protein regulates phage development by selectively suppressing transcription termination in its host, Escherichia coli. The E. coli nus mutants prevent N activity. To provide additional information on transcription termination, we have isolated pseudo-revertants of the nusA1 mutation that restore lambda N function. One series of pseudo-revertants lie in the E. coli nusB gene, whose product is normally required for lambda N activity. These mutations are N-specific: mutations that restore lambda N activity do not restore the activity of the analogous N protein of phage 21. Similarly, nusB mutations that restore phage 21 N function are deficient for lambda N function. Mapping of the two classes of mutation is consistent with their location in two distinct domains in the nusB protein. We discuss whether nusB is specific for N protein or for some other component of this regulation system, e.g. the phage site (nut) required for N action.

Control of phage P22 tail protein expression by transcription termination

The structural gene for Salmonella bacteriophage P22 tail protein, gene 9, is separated from the remainder of the P22 late operon genes by the immI region. Early transcription of immI gene ant, which is immediately promoter proximal to gene 9, occurs in the same direction as late gene transcription but does not enter gene 9 coding sequences (Susskind & Youderian, 1982). We have cloned gene 9 and surrounding sequences into pBR322 and subsequently positioned lac UV5 promoters at varying distances before the start of gene 9 by DNA manipulations in vitro. Using an in vitro phage assembly assay to measure in vivo expression of tail protein from these plasmids and in vitro transcription reactions to measure transcriptional template activity of DNA fragments isolated from these plasmids, we have identified a region of DNA between gene ant and gene 9 that behaves as a transcription termination signal. The DNA sequence of this region shows hyphenated dyad symmetry followed by a run of seven thymine residues on the coding strand. This sequence can be drawn in a potential stem-and-loop secondary structure similar to known rho-independent transcription termination signal sequences. We discuss the role of this transcriptional terminator sequence in gene 9 expression and the early to late transcriptional switch in the P22 infection cycle.

A cluster of leftward, rho-dependent t'J terminators in the J gene of coliphage lambda

While searching for the N-unresponsive terminator described by Honigman (Gene 13 (1981) 299-309), a 1680-bp DNA fragment from within gene J of bacteriophage lambda was cloned into plasmid pD12 between promoter p'R and the galK gene. In vitro transcription of this plasmid and S1 mapping assays, together with nucleotide sequencing, demonstrated that this DNA fragment contains a cluster of at least four in rho+ Escherichia coli hosts and only 30% in rho- hosts at at 30 degrees C. At the elevated temperature of 42 degrees C, the rho-dependent termination component of the t'J cluster becomes somewhat leaky, with the readthrough increasing by about twofold. The t'J terminators appear to be less responsive to nutR- and N-mediated antitermination (efficiency of 84-87%) than tL3, which responds to the same antitermination function with an efficiency of 97%. The relationship between the t'J cluster and the same antitermination function with an efficiency of 97%. The relationship between the t'J cluster and the highly N-unresponsive leftward termination signal tJ, which is also located within the J gene region (Gottesman et al., J. Mol. Biol. 140 (1980) 57-75; Honigman, Gene 13 (1981) 299-309), is unknown.

Regulation of the rpsU-dnaG-rpoD macromolecular synthesis operon and the initiation of DNA replication in Escherichia coli K-12

We have fused the E. coli dnaG 5' regulatory region to the TcR structural gene in the promoter probe plasmids pPV33 and pKK175-6 to demonstrate that a promoter activity is located on a 250 bp SacII-HindIII restriction fragment and that a transcription terminator, previously reported by nucleotide sequence (Smiley et al. 1982) to immediately precede the dnaG gene, acts as such in vivo. We have determined the complete nucleotide sequence of this controlling region and report: 1) tandem promoters on the same SacII-HindIII restriction fragment which promotes tet expression in the gene fusion experiments, 2) an open reading frame between these promoters and the dnaG gene which is the rpsU (ribosomal protein S21) gene, 3) a sequence homologous to the lambda nut site, 4) a possible LexA protein binding site on one of the dnaG promoters. This places the order on the E. coli genetic map at 66 min in the clockwise direction as rpsU-dnaG-rpoD which are all contained in a single macromolecular synthesis operon. We postulate a model for regulation of the initiation of DNA replication based on antitermination of the rpsU-dnaG-rpoD operon.

Analysis of nutR: a region of phage lambda required for antitermination of transcription

The N gene product of coliphage lambda acts with host factors (Nus) through sites (nut) to render subsequent downstream transcription resistant to a variety of termination signals. These sites, nutR and nutL, are downstream, respectively, from the early promoters PR and PL. Thus a complicated set of molecular interactions are likely to occur at the nut sites. We have selected mutations in the nutR region that reduce the effectiveness of pN in altering transcription initiating at the PR promoter. DNA sequence analysis of three independently selected mutations revealed, in each case, a deletion of a single base pair in the cro gene. Consideration of the effect of such mutations on the extension of translation of cro message into the adjacent downstream nut region led to the identification of a consensus sequence CGCTCT(T)TAA that appears to play a role in the recognition of a host factor, possibly the NusA protein.