Release of polarity in Escherichia coli by gene N of phage lambda: termination and antitermination of transcription

Roles of the leader-trailer helix and antitermination complex in biogenesis of the 30S ribosomal subunit

Ribosome biogenesis occurs co-transcriptionally and entails rRNA folding, ribosomal protein binding, rRNA processing, and rRNA modification. In most bacteria, the 16S, 23S and 5S rRNAs are co-transcribed, often with one or more tRNAs. Transcription involves a modified RNA polymerase, called the antitermination complex, which forms in response to cis-acting elements (boxB, boxA and boxC) in the nascent pre-rRNA. Sequences flanking the rRNAs are complementary and form long helices known as leader-trailer helices. Here, we employed an orthogonal translation system to interrogate the functional roles of these RNA elements in 30S subunit biogenesis in Escherichia coli. Mutations that disrupt the leader-trailer helix caused complete loss of translation activity, indicating that this helix is absolutely essential for active subunit formation in the cell. Mutations of boxA also reduced translation activity, but by only 2- to 3-fold, suggesting a smaller role for the antitermination complex. Similarly modest drops in activity were seen upon deletion of either or both of two leader helices, termed here hA and hB. Interestingly, subunits formed in the absence of these leader features exhibited defects in translational fidelity. These data suggest that the antitermination complex and precursor RNA elements help to ensure quality control during ribosome biogenesis.

Hybrid Vigor: Importance of Hybrid λ Phages in Early Insights in Molecular Biology

Laboratory-generated hybrids between phage λ and related phages played a seminal role in establishment of the λ model system, which, in turn, served to develop many of the foundational concepts of molecular biology, including gene structure and control. Important λ hybrids with phages 21 and 434 were the earliest of such phages. To understand the biology of these hybrids in full detail, we determined the complete genome sequences of phages 21 and 434. Although both genomes are canonical members of the λ-like phage family, they both carry unsuspected bacterial virulence gene types not previously described in this group of phages. In addition, we determined the sequences of the hybrid phages λ imm21, λ imm434, and λ h434 imm21. These sequences show that the replacements of λ DNA by nonhomologous segments of 21 or 434 DNA occurred through homologous recombination in adjacent sequences that are nearly identical in the parental phages. These five genome sequences correct a number of errors in published sequence fragments of the 21 and 434 genomes, and they point out nine nucleotide differences from Sanger's original λ sequence that are likely present in most extant λ strains in laboratory use today. We discuss the historical importance of these hybrid phages in the development of fundamental tenets of molecular biology and in some of the earliest gene cloning vectors. The 434 and 21 genomes reinforce the conclusion that the genomes of essentially all natural λ-like phages are mosaics of sequence modules from a pool of exchangeable segments.

Mycobacteriophage D29 induced association of Mycobacterial RNA polymerase with ancillary factors leads to increased transcriptional activity

Mycobacteriophage D29 infects species belonging to the genus Mycobacterium including the deadly pathogen Mycobacterium tuberculosis. D29 is a lytic phage, although, related to the lysogenic mycobacteriophage L5. This phage is unable to lysogenize in mycobacteria as it lacks the gene encoding the phage repressor. Infection by many mycobacteriophages cause various changes in the host that ultimately leads to inactivation of the latter. One of the host targets often modified in the process is RNA polymerase. During our investigations with phage D29 infected Mycobacterium smegmatis (Msm) we observed that the promoters from both phage, and to a lesser extent those of the host were found to be more active in cells that were exposed to D29, as compared to the unexposed. Further experiments indicate that the RNA polymerase purified from phage infected cells possessed higher affinity for promoters particularly those that were phage derived. Comparison of the purified RNA polymerase preparations from infected and uninfected cells showed that several ancillary transcription factors, Sigma factor F, Sigma factor H, CarD and RbpA are prominently associated with the RNA polymerase from infected cells. Based on our observations we conclude that the higher activity of RNA polymerase observed in D29 infected cells is due to its increased association with ancillary transcription factors.

A Tale of Good Fortune in the Era of DNA

Two strains of good fortune in my career were to stumble upon the Watson–Gilbert laboratory at Harvard when I entered graduate school in 1964, and to study gene regulation in bacteriophage λ when I was there. λ was almost entirely a genetic item a few years before, awaiting biochemical incarnation. Throughout my career I was a relentless consumer of the work of previous and current generations of λ geneticists. Empowered by this background, my laboratory made contributions in two areas. The first was regulation of early gene transcription in λ, the study of which began with the discovery of the Rho transcription termination factor, and the regulatory mechanism of transcription antitermination by the λ N protein, subjects of my thesis work. This was developed into a decades-long program during my career at Cornell, studying the mechanism of transcription termination and antitermination. The second area was the classic problem of prophage induction in response to cellular DNA damage, the study of which illuminated basic cellular processes to survive DNA damage.

Mechanisms of Bacterial Transcription Termination

Bacterial transcription termination, described mostly for Escherichia coli, occurs in three recognized ways: intrinsic termination, an activity only of the core RNAP enzyme and transcript sequences that encode an RNA hairpin and terminal uridine-rich segment; termination by the enzyme Rho, an ATP-dependent RNA translocase that releases RNA by forcing uncharacterized structural changes in the elongating complex; and Mfd-dependent termination, the activity of an ATP-dependent DNA translocase that is thought to dissociate the elongation complex by exerting torque on a stalled RNAP. Intrinsic termination can be described in terms of the nucleic acid movements in the process, whereas the enzymatic mechanisms have been illuminated importantly by definitive structural and biochemical analysis of their activity.

Factor-dependent archaeal transcription termination

RNA polymerase activity is regulated by nascent RNA sequences, DNA template sequences, and conserved transcription factors. Transcription factors promoting initiation and elongation have been characterized in each domain, but transcription termination factors have been identified only in bacteria and eukarya. Here we describe euryarchaeal termination activity (Eta), the first archaeal termination factor capable of disrupting the transcription elongation complex (TEC), detail the rate of and requirements for Eta-mediated transcription termination, and describe a role for Eta in transcription termination in vivo. Eta-mediated transcription termination is energy-dependent, requires upstream DNA sequences, and disrupts TECs to release the nascent RNA to solution. Deletion of TK0566 (encoding Eta) is possible, but results in slow growth and renders cells sensitive to DNA damaging agents. Our results suggest that the mechanisms used by termination factors in archaea, eukarya, and bacteria to disrupt the TEC may be conserved, and that Eta stimulates release of stalled or arrested TECs.

Rho Protein: Roles and Mechanisms

At the end of the multistep transcription process, the elongating RNA polymerase (RNAP) is dislodged from the DNA template either at specific DNA sequences, called the terminators, or by a nascent RNA-dependent helicase, Rho. In Escherichia coli, about half of the transcription events are terminated by the Rho protein. Rho utilizes its RNA-dependent ATPase activities to translocate along the mRNA and eventually dislodges the RNAP via an unknown mechanism. The transcription elongation factor NusG facilitates this termination process by directly interacting with Rho. In this review, we discuss current models describing the mechanism of action of this hexameric transcription terminator, its regulation by different cis and trans factors, and the effects of the termination process on physiological processes in bacterial cells, particularly E. coli and Salmonella enterica Typhimurium.

Transcription Regulation in Archaea

The known diversity of metabolic strategies and physiological adaptations of archaeal species to extreme environments is extraordinary. Accurate and responsive mechanisms to ensure that gene expression patterns match the needs of the cell necessitate regulatory strategies that control the activities and output of the archaeal transcription apparatus. Archaea are reliant on a single RNA polymerase for all transcription, and many of the known regulatory mechanisms employed for archaeal transcription mimic strategies also employed for eukaryotic and bacterial species. Novel mechanisms of transcription regulation have become apparent by increasingly sophisticated in vivo and in vitro investigations of archaeal species. This review emphasizes recent progress in understanding archaeal transcription regulatory mechanisms and highlights insights gained from studies of the influence of archaeal chromatin on transcription.

Molecular Mechanisms of Transcription Initiation at gal Promoters and their Multi-Level Regulation by GalR, CRP and DNA Loop

Studying the regulation of transcription of the gal operon that encodes the amphibolic pathway of d-galactose metabolism in Escherichia coli discerned a plethora of principles that operate in prokaryotic gene regulatory processes. In this chapter, we have reviewed some of the more recent findings in gal that continues to reveal unexpected but important mechanistic details. Since the operon is transcribed from two overlapping promoters, P1 and P2, regulated by common regulatory factors, each genetic or biochemical experiment allowed simultaneous discernment of two promoters. Recent studies range from genetic, biochemical through biophysical experiments providing explanations at physiological, mechanistic and single molecule levels. The salient observations highlighted here are: the axiom of determining transcription start points, discovery of a new promoter element different from the known ones that influences promoter strength, occurrence of an intrinsic DNA sequence element that overrides the transcription elongation pause created by a DNA-bound protein roadblock, first observation of a DNA loop and determination its trajectory, and piggybacking proteins and delivering to their DNA target.

Targeting of csgD by the small regulatory RNA RprA links stationary phase, biofilm formation and cell envelope stress in Escherichia coli

RprA is a small regulatory RNA known to weakly affect the translation of σ^S (RpoS) in Escherichia coli. Here we demonstrate that csgD, which encodes a stationary phase-induced biofilm regulator, as well as ydaM, which encodes a diguanylate cyclase involved in activating csgD transcription, are novel negatively controlled RprA targets. As shown by extensive mutational analysis, direct binding of RprA to the 5′-untranslated and translational initiation regions of csgD mRNA inhibits translation and reduces csgD mRNA levels. In the case of ydaM mRNA, RprA base-pairs directly downstream of the translational start codon. In a feedforward loop, RprA can thus downregulate > 30 YdaM/CsgD-activated genes including those for adhesive curli fimbriae. However, during early stationary phase, when csgD transcription is strongly activated, the synthesis of csgD mRNA exceeds that of RprA, which allows the accumulation of CsgD protein. This situation is reversed when csgD transcription is shut off – for instance, later in stationary phase or during biofilm formation – or by conditions that further activate RprA expression via the Rcs two-component system. Thus, antagonistic regulation of csgD and RprA at the mRNA level integrates cell envelope stress signals with global gene expression during stationary phase and biofilm formation.

Intracistronic transcriptional polarity enhances translational repression: a new role for Rho

Transcriptional polarity in Escherichia coli occurs when cryptic Rho-dependent transcription terminators become activated as a consequence of reduced translation. Whether this is due to an increased spacing between the RNA polymerase and the leading ribosome or to prior functional inactivation of a subpopulation of the mRNAs has been a matter of discussion. Transcriptional polarity results in decreased synthesis of inefficiently translated mRNAs and therefore in decreased expression of downstream genes in the same operon (intercistronic polarity). By analogy, expression of the gene in which the conditional termination occurs is also expected to decrease, but this has so far not been demonstrated experimentally. To study the relevance of this intracistronic polarity for expression regulation in vivo, the polarity-prone IacZ reporter gene was fused to a range of mutated ribosome binding sites, repressed to different degrees by local RNA structure. Quantitative analysis of protein and mRNA synthesis shows that polarity occurs on functionally active mRNA molecules and that it indeed affects expression of the cistron carrying the terminator, thus enhancing the effect of translational repression. These findings point to a novel regulatory function of transcriptional polarity, reminiscent of transcriptional attenuation but opposite in effect.

RNA polymerase elongation factors

The elongation phase of transcription by RNA polymerase is highly regulated and modulated. Both general and operon-specific elongation factors determine the local rate and extent of transcription to coordinate the appearance of transcript with its use as a messenger or functional ribonucleoprotein or regulatory element, as well as to provide operon-specific gene regulation.

In vivo dynamics of intracistronic transcriptional polarity

Transcriptional polarity occurs in Escherichia coli when cryptic Rho-dependent transcription terminators become activated as a consequence of reduced translation. Increased spacing between RNA polymerase and the leading ribosome allows the transcription termination factor Rho to bind to mRNA, migrate to the RNA polymerase, and induce termination. Transcriptional polarity results in decreased synthesis of inefficiently translated mRNAs and, therefore, in decreased expression not only of downstream genes in the same operon (intercistronic polarity) but also of the cistron in which termination occurs (intracistronic polarity). To quantitatively measure the effect of different levels of translation on intracistronic transcription termination, the polarity-prone lacZ reporter gene was fused to a range of mutated ribosome binding sites, repressed to different degrees by local RNA structure. The results show that polarity gradually increases with decreasing frequency of translational initiation, as expected. Closer analysis, with the help of a newly developed kinetic model, reveals that efficient intracistronic termination requires very low translational initiation frequencies. This finding is unexpected because Rho is a relatively small protein that binds rapidly to its RNA target, but it appears to be true also for other examples of transcriptional polarity reported in the literature. The conclusion must be that polarity is more complex than just an increased exposure of the Rho binding site as the spacing between the polymerase and the leading ribosome becomes larger. Biological consequences and possible mechanisms are discussed.

Polarity in archaeal operon transcription in Thermococcus kodakaraensis

An in vivo archaeal gene reporter system has been established based on TK1761, a gene that encodes a nonessential beta-glycosidase in Thermococcus kodakaraensis. Following the introduction of nonsense codons into promoter-proximal genes, polarity in operon expression in this archaeon has been established by both microarray hybridization assays and a reporter gene expression system.

Global analysis of host response to induction of a latent bacteriophage

BACKGROUND

The transition from viral latency to lytic growth involves complex interactions among host and viral factors, and the extent to which host physiology is buffered from the virus during induction of lysis is not known. A reasonable hypothesis is that the virus should be evolutionarily selected to ensure host health throughout induction to minimize its chance of reproductive failure. To address this question, we collected transcriptional profiles of Escherichia coli and bacteriophage lambda throughout lysogenic induction by UV light.

RESULTS

We observed a temporally coordinated program of phage gene expression, with distinct early, middle and late transcriptional classes. Our study confirmed known host-phage interactions of induction of the heat shock regulon, escape replication, and suppression of genes involved in cell division and initiation of replication. We identified 728 E. coli genes responsive to prophage induction, which included pleiotropic stress response pathways, the Arc and Cpx regulons, and global regulators crp and lrp. Several hundred genes involved in central metabolism, energy metabolism, translation and transport were down-regulated late in induction. Though statistically significant, most of the changes in these genes were mild, with only 140 genes showing greater than two-fold change.

CONCLUSION

Overall, we observe that prophage induction has a surprisingly low impact on host physiology. This study provides the first global dynamic picture of how host processes respond to lambda phage induction.

Global analysis of host response to induction of a latent bacteriophage

Background

The transition from viral latency to lytic growth involves complex interactions among host and viral factors, and the extent to which host physiology is buffered from the virus during induction of lysis is not known. A reasonable hypothesis is that the virus should be evolutionarily selected to ensure host health throughout induction to minimize its chance of reproductive failure. To address this question, we collected transcriptional profiles of Escherichia coli and bacteriophage lambda throughout lysogenic induction by UV light.

Results

We observed a temporally coordinated program of phage gene expression, with distinct early, middle and late transcriptional classes. Our study confirmed known host-phage interactions of induction of the heat shock regulon, escape replication, and suppression of genes involved in cell division and initiation of replication. We identified 728 E. coli genes responsive to prophage induction, which included pleiotropic stress response pathways, the Arc and Cpx regulons, and global regulators crp and lrp. Several hundred genes involved in central metabolism, energy metabolism, translation and transport were down-regulated late in induction. Though statistically significant, most of the changes in these genes were mild, with only 140 genes showing greater than two-fold change.

Conclusion

Overall, we observe that prophage induction has a surprisingly low impact on host physiology. This study provides the first global dynamic picture of how host processes respond to lambda phage induction.

The upstream-activating sequences of the sigma54 promoter Pu of Pseudomonas putida filter transcription readthrough from upstream genes

Although the m-xylene-responsive sigma54 promoter Pu of Pseudomonas putida mt-2, borne by the TOL plasmid pWWO, is one of the strongest known promoters in vivo, its base-line level in the absence of its aromatic inducer is below the limit of any detection procedure. This is unusual because regulatory networks (such as the one to which Pu belongs) can hardly escape the noise caused by intrinsic fluctuations in background transcription, including that transmitted from upstream promoters. This study provides genetic evidence that the upstream-activating sequences (UAS), which serve as the binding sites for the pWW0-encoded XylR protein (the m-xylene-responsive sigma54-dependent activator of Pu), isolate expression of the upper TOL genes from any adventitious transcriptional flow originating further upstream. An in vivo test system was developed in which different segments of the Pu promoter were examined for the inhibition of incoming transcription products from an upstream promoter in P. putida and Escherichia coli. Minimal transcription filter ability was located within a 105-bp fragment encompassing the UAS of Pu. Although S1 nuclease assays showed that the UAS prevented the buildup of downstream transcripts, the mechanism seems to diverge from a typical termination system. This was shown by the fact that the UAS did not halt transcription in vitro and that the filter effect could not be relieved by the anti-termination system of lambda phage. Because the Pu promoter lies adjacent to the edge of a transposon in pWW0, the preset transcriptional filter in the UAS may isolate the upper TOL operon from undue expression after random insertion of the mobile genetic element in a new replicon.

Effect of different conformations of galactose messenger RNA on gene expression and messenger half-life in vitro

From a DNA-directed cell-free system, functional gal mRNA is obtained which directs the cell-free synthesis of the three galactose enzymes of Escherichia coli. A substantial fraction of this gal mRNA has the properties of a polycistronic messenger. Exposure to elevated temperatures in the presence or absence of magnesium ion results in pronounced changes of the capacity of this mRNA to give rise to the synthesis of the three enzymes. Depending on the conditions of the pre-treatment, the absolute amounts as well as the ratio of the three gene products synthesized can be changed. The different forms of gal messenger so obtained also exhibit different susceptibilities towards functional inactivation during the enzyme synthesis reaction. As the changes in template activity are reversible, it is concluded that the different treatments cause reversible transitions between different conformations of the gal mRNA.

Little lambda, who made thee?

The study of the bacteriophage lambda has been critical to the discipline of molecular biology. It was the source of key discoveries in the mechanisms of, among other processes, gene regulation, recombination, and transcription initiation and termination. We trace here the events surrounding these findings and draw on the recollections of the participants. We show how a particular atmosphere of interactions among creative scientists yielded spectacular insights into how living things work.

The global regulator RNase III modulates translation repression by the transcription elongation factor N

Efficient expression of most bacteriophage lambda early genes depends upon the formation of an antiterminating transcription complex to overcome transcription terminators in the early operons, p(L) and p(R). Formation of this complex requires the phage-encoded protein N, the first gene product expressed from the p(L) operon. The N leader RNA contains, in this order: the NUTL site, an RNase III-sensitive hairpin and the N ribosome-binding site. N bound to NUTL RNA is part of both the antitermination complex and an autoregulatory complex that represses the translation of the N gene. In this study, we show that cleavage of the N leader by RNase III does not inhibit antitermination but prevents N-mediated translation repression of N gene expression. In fact, by preventing N autoregulation, RNase III activates N gene translation at least 200-fold. N-mediated translation repression is extremely sensitive to growth rate, reflecting the growth rate regulation of RNase III expression itself. Given N protein's critical role in lambda development, the level of RNase III activity therefore serves as an important sensor of physiological conditions for the bacteriophage.

Simultaneous gain and loss of functions caused by a single amino acid substitution in the beta subunit of Escherichia coli RNA polymerase: suppression of nusA and rho mutations and conditional lethality

Transcript elongation and termination in Escherichia coli is modulated, in part, by the nusA gene product, an acidic protein that interacts not only with RNA polymerase itself but also with ancillary factors, namely the host termination protein Rho and phage lambda antitermination protein, N. The E. coli nusA1 mutant fails to support lambda development due to a specific defect in N-mediated antitermination. Certain rifampicin-resistant (rifR) variants of the nusA1 host support lambda growth. We report here the isolation and pleiotropic properties of one such rifR mutant, ts8, resulting from a single amino acid substitution mutation in rpoB, the structural gene for polymerase beta subunit. ts8 is a recessive lethal mutation that blocks cell growth at 42 degrees. Pulse-labeling and analysis of newly synthesized proteins indicate that the mutant cell is proficient in RNA synthesis at high temperature. Apparently, ts8 causes a loss of some specialized function of RNA polymerase without a gross defect in general transcription activities. ts8 is an allele-specific suppressor of nusA1. It does not suppress nusAsal, nusB5 and nusE71 mutations nor does it bypass the requirement for a functional N gene and the nut site for antitermination and lambda growth. A mutation in the N gene, punA1, that restores lambda growth in the nusA1 mutant host but not in the nusAsal host, compensates for the nusAsal allele in the ts8 mutant. This combined effect of two allele-specific suppressors suggests that they enhance some aspect of polymerase-NusA-N interaction and function. ts8 suppresses the rho15 mutation, but not the rho112 mutation, indicating that it might render RNA polymerase susceptible to the action of a defective Rho protein. Marker rescue analysis has localized ts8 to a 910-bp internal segment of rpoB that encodes the Rif domain. By amplification, cloning and sequencing of this segment of the mutant chromosome we have determined that ts8 contains Phe in place of Ser522, caused by a C to T transition. By gene conversion, we have established that the simultaneous gain and loss of three functions of polymerase is caused by this single amino acid substitution. Clearly, a site in the beta subunit critical for the functioning of both termination and antitermination factors is altered by ts8. The alteration, we imagine, might make this site on polymerase receptive to some factors but repulsive to others.

The nut site of bacteriophage lambda is made of RNA and is bound by transcription antitermination factors on the surface of RNA polymerase

The boxA and boxB components of the lambda nut site are important for transcriptional antitermination by the phage N protein. We show here that boxA and boxB RNA in N-modified transcription complexes are inaccessible to ribonucleases and have altered sensitivity to dimethylsulfate. N and NusA suffice to weakly protect boxB, independently of boxA and other factors. However, efficient protection of the entire nut site from ribonucleases requires boxA and boxB, N, NusA, NusB, S10, and NusG. Mutations in RNA polymerase, which inhibit antitermination by N in vivo, disallow protection of the nut site during transcription in vitro; therefore, the surface of RNA polymerase must coordinate the formation of complexes containing the antitermination factors and nut site RNA.

Molecular analysis of the recombination junctions of lambda bio transducing phages

To examine the mechanism of recombination involved in the formation of specialized transducing phage during the induction of bacteriophage lambda, we have determined the nucleotide sequences of the recombination junctions of lambda bio phages. The results indicate that abnormal excision takes place at many sites on both bacterial and phage genomes and that the recombination sites have short regions of homology (5-14 bp). Some of the sequences of the recombination sites were similar to the consensus sequences of DNA gyrase-cleavage sites and repetitive extragenic palindromic (REP) sequences. These results showed that abnormal excision is a type of illegitimate recombination. The possible involvement of DNA gyrase in this recombination is discussed.

Assembly of transcription elongation complexes containing the N protein of phage lambda and the Escherichia coli elongation factors NusA, NusB, NusG, and S10

The transcription antitermination protein, N, of bacteriophage lambda; the Escherichia coli elongation factors NusA, NusB, ribosomal protein S10, and NusG; and a DNA template containing a lambda nut (N-ututilization) site are necessary and sufficient for the highly cooperative formation in vitro of stable transcription complexes containing all five elongation factors. Mutations in the nut site, NusA, or the beta-subunit of RNA polymerase (RNAP) that impair antitermination in vivo also abolish the assembly of a stable complex containing the antitermination factors in vitro. The effects of RNAP mutations on assembly imply that the antitermination factors assemble on the surface of RNAP. We have shown previously that NusA binds directly to transcribing RNAP (Ka approximately 10(7) M-1); Ka = association constant and we show here that S10 also binds directly and specifically to RNAP with an apparent Ka of 10(6) M-1. These observations led to a model for the ordered assembly of the N-modified transcription complex.

Overexpression of N antitermination proteins of bacteriophages lambda, 21, and P22: loss of N protein specificity

The N protein of bacteriophage lambda (N lambda) modifies Escherichia coli RNA polymerase in such a way that it transcribes through termination signals, a process called antitermination. N antitermination normally occurs only if the template contains a specific utilization or nut site upstream of the terminators and only in the presence of host-encoded Nus proteins. The lambda-related phages 21 and P22 produce N analogs, N21 and N22, but these require different nut sites and show a different pattern of functional interaction with one of the Nus factors, NusA, according to whether this protein is of E. coli or Salmonella origin (NusAEc or NusASal). We report the overproduction of N lambda, N21, or N22, each of which was induced by isopropyl-beta-D-thiogalactopyranoside at 37 degrees C from its cloned position downstream from ptac on a high-expression plasmid, each in a host that provided NusAEc or NusASal. Overproduction of each of these N proteins resulted in relaxed specificity for nut, which was shown by the ability to complement N mutants of heterologous phages; NusA specificity was determined by the N type that was present in these complementation tests. We also observed that excess N was able to suppress transcriptional polarity in the particular case of cloned 'trpA, the last gene of the tryptophan operon, although there was no effect on polarity within chromosomal trpE. Such polarity is attributed to the presence of cryptic intragenic terminators that become exposed in the absence of translation. Because there is no known nut site cis to 'trpA, we suggest that the 'trpA segment itself fortuitously contains a nut sequence that is able to function with excess N of any of the types tested and with either NusAEc or NusASal. We also found that excess N of any specificity, or even inactive N with missense mutation, could cause an increase in the level of NusAEc or NusASal, possibly because interaction between N and NusA, but independent of nut, whether functional or not, interferes with the autoregulation of NusA synthesis. These observations highlight the importance of protein concentration for the specificity of interactions both with other proteins and with nucleic acids. They also indicate that the interaction between N and NusA requires nut participation both for specificity and functionality.

Bacteriophage Mu late promoters: four late transcripts initiate near a conserved sequence

Late transcription of bacteriophage Mu, which results in the expression of phage morphogenetic functions, is dependent on Mu C protein. Earlier experiments indicated that Mu late RNAs originate from four promoters, including the previously characterized mom promoter. S1 nuclease protection experiments were used to map RNA 5' ends in the three new regions. Transcripts were initiated at these points only in the presence of C and were synthesized in a rightward direction on the Mu genome. Amber mutant marker rescue analysis of plasmid clones and limited DNA sequencing demonstrated that these new promoters are located between C and lys, upstream of I, and upstream of P within the N gene. A comparison of the promoter sequences upstream from the four RNA 5' ends yielded two conserved sequences: the first (tA . . cT, where capital and lowercase letters indicate 100 and 75% base conservation, respectively), at approximately -10, shares some similarity with the consensus Escherichia coli sigma 70 -10 region, while the second (ccATAAc CcCPuG/Cac, where Pu indicates a purine), in the -35 region, bears no resemblance to the E. coli -35 consensus. We propose that these conserved Mu late promoter consensus sequences are important for C-dependent promoter activity. Plasmids containing transcription fusions of these late promoters to lacZ exhibited C-dependent beta-galactosidase synthesis in vivo, and C was the only Mu product needed for this transactivation. As expected, the late promoter-lacZ fusions were activated only at late times after induction of a Mu prophage. The C-dependent activation of lacZ fusions containing only a few bases of the 5' end of Mu late RNA and the presence of altered promoter sequences imply that C acts at the level of transcription initiation.

NusA protein is necessary and sufficient in vitro for phage lambda N gene product to suppress a rho-independent terminator placed downstream of nutL

Transcription antitermination by phage lambda N protein is reproduced in vitro solely with purified components. We have placed a strong rho-independent terminator, lambda tR', in the PL operon about 200 base pairs downstream from the N-recognition site, nutL, and have monitored terminated and run-off transcripts produced by single-round transcription of linear plasmids. In the presence of NusA, one of several host factors implicated in antitermination, N is found to virtually abolish termination at tR'. N is unable to suppress termination if the terminator is preceded by a defective nut site. Thus, during transcription through the nut site, N and NusA can modify RNA polymerase to a termination-resistant form in the absence of any other accessory factor.

Aberrant regulation of synthesis and degradation of viral proteins in coliphage lambda-infected UV-irradiated cells and in minicells

The patterns of bacteriophage lambda proteins synthesized in UV-irradiated Escherichia coli cells and in anucleate minicells are significantly different; both systems exhibit aberrations of regulation in lambda gene expression. In unirradiated cells or cells irradiated with low UV doses (less than 600 J/m2), regulation of lambda protein synthesis is controlled by the regulatory proteins CI, N, CII, CIII, Cro, and Q. As the UV dose increases, activation of transcription of the cI, rexA, and int genes by CII and CIII proteins fails to occur and early protein synthesis, normally inhibited by the action of Cro, continues. After high UV doses (greater than 2,000 J/m2), late lambda protein synthesis does not occur. Progression through the sequence of regulatory steps in lambda gene expression is slower in infected minicells. In minicells, there is no detectable cII- and cIII-dependent synthesis of CI, RexA, or Int proteins and inhibition of early protein synthesis by Cro activity is always incomplete. The synthesis of early b region proteins is not subject to control by CI, N, or Cro proteins, and evidence is presented suggesting that, in minicells, transcription of the early b region is initiated at a promoter(s) within the b region. Proteolytic cleavage of the regulatory proteins O and N and of the capsid proteins C, B, and Nu3 is much reduced in infected minicells. Exposure of minicells to very high UV doses before infection does not completely inhibit late lambda protein synthesis.

Translation initiation of bacteriophage lambda gene cII requires integration host factor

Escherichia coli integration host factor (IHF), a DNA-binding protein, positively regulates expression of the lambda cII gene. Purified IHF stimulates cII protein synthesis in vitro, suggesting a direct role for host factor in cII expression. Further evidence for a direct role for IHF was obtained with operon and gene fusions between cII and lacZ or cII and galE. Analysis of these fusions in vivo demonstrated that IHF is essential for the initiation of cII translation. Replacement of the entire cII coding sequence with lacZ yielded a gene fusion which was still IHF dependent. However, a cII-galE fusion carrying a hybrid ribosome binding region expressed galE in IHF mutants. These results indicate that sequences which make cII translation IHF dependent lie between the ribosome binding region and the initiating codon of cII. Failure to translate cII activates a transcription terminator located within cII and results in polar effects on downstream transcription. This polarity is suppressed by the lambda N antitermination function. When cloned into another context, the terminator is active in both wild-type and IHF mutant strains. The amino terminus of cII is located near an IHF binding site in a region with considerable dyad symmetry. The role of IHF in cII translation may be to prevent formation of an RNA-RNA duplex that sequesters the ribosome binding site of cII. The binding of IHF might influence RNA structure by altering the rate of the dissociation of RNA from the DNA template.

Genetic and DNA mapping of the late regulation and lysis genes of Salmonella bacteriophage P22 and coliphage lambda

Genetic and DNA heteroduplex analyses of lambda imm22 hybrid phages were used to compare the Salmonella bacteriophage P22 and coliphage lambda genes which control late gene regulation and lysis. Homologous DNA sequences were correlated with P22 gene 23 and lambda gene Q (late gene regulation) and with P22 gene 13 and lambda gene S (lysis control). Nonhomologous DNA sequences were correlated with P22 gene 19 and lambda gene R (lysozyme and endolysin) and with the region encoding the P22 alpha and lambda 6S transcripts.

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.

Efficient modification of E. coli RNA polymerase in vitro by the N gene transcription antitermination protein of bacteriophage lambda

The N gene protein of bacteriophage lambda prevents termination of transcription by E. coli RNA polymerase. We describe here the conditions of a cell-free reaction system in which pure N stimulates net transcription up to tenfold and therefore nearly stoichiometrically modifies transcribing RNA polymerase molecules. The reaction contains micrococcal nuclease-treated S100 extract derived from E. coli and a plasmid template DNA containing the lambda early promoter PL, the N utilization site nutL, and the Rho-dependent terminator tL1. Stimulation by N in this system is specific and biologically relevant since it is absent with vector pBR322 DNA and with extracts derived from E. coli strains bearing the nusA1 and nusE71 mutations known to block N function in vivo. We use the system to provide further evidence that ribosomes are not necessary for N function and to demonstrate the direct involvement in N function of the NusA protein of E. coli.

Internal promoter in the ilvGEDA transcription unit of Escherichia coli K-12

Segments of the ilvGEDA transcription unit have been cloned into the promoter tester plasmid pMC81. This vector contains cloning sites situated upstream of the lacZ gene coding for beta-galactosidase. Using this method we have quantitatively evaluated in vivo (i) the activity of previously described promoter, pG, preceding ilvG; (ii) the relative activity of pE promoter, previously postulated to be located between ilvG and ilvE; and (iii) the effect of the frameshift site present in the wild-type ilvG gene by comparison with mutant derivatives lacking this frameshift site. Isogenic derivatives of strain MC1000 were constructed by transduction with phage P1 grown on rho-120, delta(ilvGEDA), delta(ilvED), and ilvA538 hosts. The potential effects of these alleles that were previously postulated to affect ilvGEDA expression were assessed in vivo by monitoring beta-galactosidase production directed by ilv DNA fragments. Cloned ilv segments were also tested for activity in vitro with a DNA-directed coupled transcription and translation system. The production in vitro of ilv-directed ilv gene expression and beta-galactosidase expression with ara-ilv-lac fusions paralleled the in vivo activity.

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.

nusB: a protein factor necessary for transcription antitermination in vitro by phage lambda N gene product

We demonstrate that the protein product of the Escherichia coli nusB gene is essential for transcription antitermination in vitro by phage lambda N gene product. We recently have described a convenient biochemical assay for N protein activity in the S30-coupled transcription translation system and demonstrated that N action requires the 69-kDa L factor (nusA), the product of E. coli nusA gene. Using a complementation assay for the restoration of N activity specifically in the nusB mutant extract, we have purified the nusB complementing activity. This activity is due to a 15-kDa polypeptide that is overproduced in E. coli containing multiple copies of the nusB gene. We find that nusA and nusB are required for N activity to suppress a rho-dependent as well as a rho-independent terminator. The requirement for nusB protein in antitermination could not be overcome by an excess of nusA or N protein, nor could an excess of nusB overcome the requirements for nusA in antitermination. Our results suggest that the formation of an antitermination apparatus by N requires nusA and nusB proteins in equimolar amounts.

Application of phage lambda technology to Salmonella typhimurium. Construction of a lambda-sensitive Salmonella strain

We have previously constructed a novel strain of S. typhimurium carrying the E. coli lamB gene and shown that this strain adsorbs phage lambda and, for example, can be used for transposon mutagenesis with lambda vectors. In this study, we show that this strain can support the lytic growth of phage lambda nin derivatives, but not growth of wild-type lambda. However, lysogenization with lambda nin does not occur. Using this strain as starting material we took the construction one step further by introducing the E. coli nusA gene in a multicopy plasmid to this strain. We could show that this new Salmonella derivative can support both the lytic and lysogenic mode of growth of several different lambda derivatives. Using the same approach it should be possible to construct lambda-sensitive derivatives of other enteric bacteria thus rendering them more amenable to in vivo genetic manipulation.

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.

Autoregulation of the rho gene of Escherichia coli K-12

It has previously been proposed, based on indirect evidence, that the Rho protein may control the expression of the rho gene. Using an in vitro system for the transcription and translation of the rho gene cloned into plasmid pBR322, we tested this hypothesis directly by monitoring the effect in vitro of excess or limiting Rho protein. The addition of purified Rho protein suppresses Rho synthesis in vitro. The addition of antibody to Rho specifically stimulates Rho synthesis in vitro. The stimulation of Rho factor synthesis by antibody to Rho is reversed by Rho protein. Rho factor purified from a strain with a mutationally altered rho gene (rho-115) does not suppress Rho synthesis in vitro. These results provide convincing evidence that the rho gene is subject to autoregulation.

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.

Tn5 carries a streptomycin resistance determinant downstream from the kanamycin resistance gene

In Rhizobium meliloti, Tn5 conferred resistance not only to kanamycin but to streptomycin, as well, in Escherichia coli, however only to kanamycin. Using in vitro recombinant DNA techniques, it was shown that the streptomycin resistance determinant was located downstream from the kanamycin resistance gene in the unique central region of Tn5. Expression of various cloned fragments of Tn5 suggested that both kanamycin and streptomycin resistance genes were transcribed from the same promoter. E. coli mutants allowing the expression of streptomycin resistance from Tn5 were isolated. The differential expression of the streptomycin resistance gene provides a simple selection/counterselection criterion, using only streptomycin in transfer experiments of Tn5 between E. coli and R. meliloti.

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.

Regulation of the F conjugation genes studied by hybridization and tra-lacZ fusion

Hybridization experiments and tra-lacZ fusions were used to obtain further insight into the complex series of control systems that affect F conjugation. We confirmed that the regular IncF FinOP control system represses transcription of traJ, and found that the traJ product is required for transcription of traM as well as of the traY-Z operon. The chromosomal sfrA gene product may be required to prevent premature termination of traJ transcription, while the sfrB gene product prevents premature termination at two sites within the traY-Z operon. The FinQ inhibition system determined by several IncI plasmids caused termination at three different sites in the operon, and that of JR66a at one further site. JR66a and R485 strongly inhibit F transfer, but have weak, or no (respectively) effects on transcription: they may inhibit function of one or more transfer gene products.