Sense and antisense transcription of bacteriophage T4 gene 32. Processing and stability of the mRNAs

Transcriptional Organization of the Salmonella Typhimurium Phage P22 pid ORFan Locus

Many phage genes lack sequence similarity to any other open reading frame (ORF) in current databases. These enigmatic ORFan genes can have a tremendous impact on phage propagation and host interactions but often remain experimentally unexplored. We previously revealed a novel interaction between phage P22 and its Salmonella Typhimurium host, instigated by the ORFan gene pid (for phage P22 encoded instigator of dgo expression) and resulting in derepression of the host dgoRKAT operon. The pid gene is highly expressed in phage carrier cells that harbor a polarly located P22 episome that segregates asymmetrically among daughter cells. Here, we discovered that the pid locus is fitted with a weak promoter, has an exceptionally long 5′ untranslated region that is instructive for a secondary pid mRNA species, and has a 3′ Rho-independent termination loop that is responsible for stability of the pid transcript.

Global Transcriptional Analysis of Virus-Host Interactions between Phage ϕ29 and Bacillus subtilis

The study of phage-host relationships is essential to understanding the dynamic of microbial systems. Here, we analyze genome-wide interactions of Bacillus subtilis and its lytic phage ϕ29 during the early stage of infection. Simultaneous high-resolution analysis of virus and host transcriptomes by deep RNA sequencing allowed us to identify differentially expressed bacterial genes. Phage ϕ29 induces significant transcriptional changes in about 0.9% (38/4,242) and 1.8% (76/4,242) of the host protein-coding genes after 8 and 16 min of infection, respectively. Gene ontology enrichment analysis clustered upregulated genes into several functional categories, such as nucleic acid metabolism (including DNA replication) and protein metabolism (including translation). Surprisingly, most of the transcriptional repressed genes were involved in the utilization of specific carbon sources such as ribose and inositol, and many contained promoter binding-sites for the catabolite control protein A (CcpA). Another interesting finding is the presence of previously uncharacterized antisense transcripts complementary to the well-known phage ϕ29 messenger RNAs that adds an additional layer to the viral transcriptome complexity.

IMPORTANCE

The specific virus-host interactions that allow phages to redirect cellular machineries and energy resources to support the viral progeny production are poorly understood. This study provides, for the first time, an insight into the genome-wide transcriptional response of the Gram-positive model Bacillus subtilis to phage ϕ29 infection.

Towards Gene-Inhibition Therapy: A Review of Progress and Prospects in the Field of Antiviral Antisense Nucleic Acids and Ribozymes

Antisense RNA and its derivatives may provide the basis for highly selective gene inhibition therapies of virus infections. In this review, I concentrate on advances made in the study of antisense RNA and ribozymes during the last five years and their implications for the development of such therapies. It appears that antisense RNAs synthesized at realistic levels within the cell can be much more effective inhibitors than originally supposed. Looking at those experiments that enable comparisons to be made, it seems that inhibitory antisense RNAs are not those that are complementary to particular sites within mRNAs but those that are able to make stable duplexes with their targets, perhaps by virtue of their secondary structure and length. The inclusion of ribozyme sequences within antisense RNAs confers RNA-cleaving activity upon them in vitro and possibly in cells, thereby offering the possibility of markedly increasing their therapeutic potential. The varieties of natural ribozyme and their adaptation as artificial catalysts are reviewed. The implications of these developments for antiviral therapy are discussed.

55.1, a gene of unknown function of phage T4, impacts on Escherichia coli folate metabolism and blocks DNA repair by the NER

Phage T4, the archetype of lytic bacterial viruses, needs only 62 genes to propagate under standard laboratory conditions. Interestingly, the T4 genome contains more than 100 putative genes of unknown function, with few detectable homologues in cellular genomes. To characterize this uncharted territory of genetic information, we have identified several T4 genes that prevent bacterial growth when expressed from plasmids under inducible conditions. Here, we report on the various phenotypes and molecular characterization of 55.1, one of the genes of unknown function. High-level expression from the arabinose-inducible P(BAD) promoter is toxic to the bacteria and delays the intracellular accumulation of phage without affecting the final burst size. Low-level expression from T4 promoter(s) renders bacteria highly sensitive to UV irradiation and hypersensitive to trimethoprim, an inhibitor of dihydrofolate reductase. The delay in intracellular phage accumulation requires UvsW, a T4 helicase that is also a suppressor of 55.1-induced toxicity and UV sensitivity. Genetic and biochemical experiments demonstrate that gp55.1 binds to FolD, a key enzyme of the folate metabolism and suppressor of 55.1. Finally, we show that gp55.1 prevents the repair of UV-induced DNA photoproducts by the nucleotide excision repair (NER) pathway through interaction with the UvrA and UvrB proteins.

Post-transcriptional control by bacteriophage T4: mRNA decay and inhibition of translation initiation

Over 50 years of biological research with bacteriophage T4 includes notable discoveries in post-transcriptional control, including the genetic code, mRNA, and tRNA; the very foundations of molecular biology. In this review we compile the past 10 - 15 year literature on RNA-protein interactions with T4 and some of its related phages, with particular focus on advances in mRNA decay and processing, and on translational repression. Binding of T4 proteins RegB, RegA, gp32 and gp43 to their cognate target RNAs has been characterized. For several of these, further study is needed for an atomic-level perspective, where resolved structures of RNA-protein complexes are awaiting investigation. Other features of post-transcriptional control are also summarized. These include: RNA structure at translation initiation regions that either inhibit or promote translation initiation; programmed translational bypassing, where T4 orchestrates ribosome bypass of a 50 nucleotide mRNA sequence; phage exclusion systems that involve T4-mediated activation of a latent endoribonuclease (PrrC) and cofactor-assisted activation of EF-Tu proteolysis (Gol-Lit); and potentially important findings on ADP-ribosylation (by Alt and Mod enzymes) of ribosome-associated proteins that might broadly impact protein synthesis in the infected cell. Many of these problems can continue to be addressed with T4, whereas the growing database of T4-related phage genome sequences provides new resources and potentially new phage-host systems to extend the work into a broader biological, evolutionary context.

Transcriptional control in the prereplicative phase of T4 development

Control of transcription is crucial for correct gene expression and orderly development. For many years, bacteriophage T4 has provided a simple model system to investigate mechanisms that regulate this process. Development of T4 requires the transcription of early, middle and late RNAs. Because T4 does not encode its own RNA polymerase, it must redirect the polymerase of its host, E. coli, to the correct class of genes at the correct time. T4 accomplishes this through the action of phage-encoded factors. Here I review recent studies investigating the transcription of T4 prereplicative genes, which are expressed as early and middle transcripts. Early RNAs are generated immediately after infection from T4 promoters that contain excellent recognition sequences for host polymerase. Consequently, the early promoters compete extremely well with host promoters for the available polymerase. T4 early promoter activity is further enhanced by the action of the T4 Alt protein, a component of the phage head that is injected into E. coli along with the phage DNA. Alt modifies Arg265 on one of the two α subunits of RNA polymerase. Although work with host promoters predicts that this modification should decrease promoter activity, transcription from some T4 early promoters increases when RNA polymerase is modified by Alt. Transcription of T4 middle genes begins about 1 minute after infection and proceeds by two pathways: 1) extension of early transcripts into downstream middle genes and 2) activation of T4 middle promoters through a process called sigma appropriation. In this activation, the T4 co-activator AsiA binds to Region 4 of σ⁷⁰, the specificity subunit of RNA polymerase. This binding dramatically remodels this portion of σ⁷⁰, which then allows the T4 activator MotA to also interact with σ⁷⁰. In addition, AsiA restructuring of σ⁷⁰ prevents Region 4 from forming its normal contacts with the -35 region of promoter DNA, which in turn allows MotA to interact with its DNA binding site, a MotA box, centered at the -30 region of middle promoter DNA. T4 sigma appropriation reveals how a specific domain within RNA polymerase can be remolded and then exploited to alter promoter specificity.

RNA processing and decay in bacteriophage T4

Bacteriophage T4 is the archetype of virulent phage. It has evolved very efficient strategies to subvert host functions to its benefit and to impose the expression of its genome. T4 utilizes a combination of host and phage-encoded RNases and factors to degrade its mRNAs in a stage-dependent manner. The host endonuclease RNase E is used throughout the phage development. The sequence-specific, T4-encoded RegB endoribonuclease functions in association with the ribosomal protein S1 to functionally inactivate early transcripts and expedite their degradation. T4 polynucleotide kinase plays a role in this process. Later, the viral factor Dmd protects middle and late mRNAs from degradation by the host RNase LS. T4 codes for a set of eight tRNAs and two small, stable RNA of unknown function that may contribute to phage virulence. Their maturation is assured by host enzymes, but one phage factor, Cef, is required for the biogenesis of some of them. The tRNA gene cluster also codes for a homing DNA endonuclease, SegB, responsible for spreading the tRNA genes to other T4-related phage.

The immense journey of bacteriophage T4--from d'Hérelle to Delbrück and then to Darwin and beyond

In spite of their importance, the genomics, diversity and evolution of phages and their impact on the biosphere have remained largely unexplored research domains in microbiology. Here, we report on some recent studies with the T4 phage superfamily that shed some new light on these topics.

Modular architecture of the T4 phage superfamily: a conserved core genome and a plastic periphery

Among the most numerous objects in the biosphere, phages show enormous diversity in morphology and genetic content. We have sequenced 7 T4-like phages and compared their genome architecture. All seven phages share a core genome with T4 that is interrupted by several hyperplastic regions (HPRs) where most of their divergence occurs. The core primarily includes homologues of essential T4 genes, such as the virion structure and DNA replication genes. In contrast, the HPRs contain mostly novel genes of unknown function and origin. A few of the HPR genes that can be assigned putative functions, such as a series of novel Internal Proteins, are implicated in phage adaptation to the host. Thus, the T4-like genome appears to be partitioned into discrete segments that fulfil different functions and behave differently in evolution. Such partitioning may be critical for these large and complex phages to maintain their flexibility, while simultaneously allowing them to conserve their highly successful virion design and mode of replication.

The diversity and evolution of the T4-type bacteriophages

Recent studies suggest that viruses are the most numerous entities in the biosphere; bacteriophages, the viruses that infect Eubacteria and Archaea, constitute a substantial fraction of this population. In spite of their ubiquity, the vast majority of phages in the environment have never been studied and nothing is known about them. For the last 10 years our research has focused on an extremely widespread group of phages, the T4-type. It has now become evident that phage T4 has a myriad of relatives in nature that differ significantly in their host range. The genomes of all these phages have homology to the T4 genes that determine virion morphology. Although phylogenetically related, these T4-type phages can be subdivided into four groups that are increasingly distant from T4: the T-evens, the pseudo T-evens, the schizo T-evens and the exo T-evens. Genomic comparisons between the various T4-type phages and T4 indicate that these genomes share homology not only for virion structural components but also for most of the essential genes involved in the T4 life cycle. This suggests that horizontal transmission of the genetic information may have played a less general role in the evolution of these phages than has been supposed. Nevertheless, we have identified several regions of the T4-type genome, such as the segment containing the tail fiber genes that exhibit evidence of extensive modular shuffling during evolution. The T4-type genomes appear to be a mosaic containing a large and fixed group of essential genes as well as highly variable set of non-essential genes. These non-essential genes are probably important for the adaptation of these phages to their particular life-style. Furthermore, swapping autonomous domains within the essential proteins may slightly modify their function(s) and contribute to the adaptive ability of the T4-type phage family. Regulatory sequences also display considerable evolutionary plasticity and this too may facilitate the adaptation of phage gene expression to new environments and stresses.

Snapshot of the genome of the pseudo-T-even bacteriophage RB49

RB49 is a virulent bacteriophage that infects Escherichia coli. Its virion morphology is indistinguishable from the well-known T-even phage T4, but DNA hybridization indicated that it was phylogenetically distant from T4 and thus it was classified as a pseudo-T-even phage. To further characterize RB49, we randomly sequenced small fragments corresponding to about 20% of the approximately 170-kb genome. Most of these nucleotide sequences lacked sufficient homology to T4 to be detected in an NCBI BlastN analysis. However, when translated, about 70% of them encoded proteins with homology to T4 proteins. Among these sequences were the numerous components of the virion and the phage DNA replication apparatus. Mapping the RB49 genes revealed that many of them had the same relative order found in the T4 genome. The complete nucleotide sequence was determined for the two regions of RB49 genome that contain most of the genes involved in DNA replication. This sequencing revealed that RB49 has homologues of all the essential T4 replication genes, but, as expected, their sequences diverged considerably from their T4 homologues. Many of the nonessential T4 genes are absent from RB49 and have been replaced by unknown sequences. The intergenic sequences of RB49 are less conserved than the coding sequences, and in at least some cases, RB49 has evolved alternative regulatory strategies. For example, an analysis of transcription in RB49 revealed a simpler pattern of regulation than in T4, with only two, rather than three, classes of temporally controlled promoters. These results indicate that RB49 and T4 have diverged substantially from their last common ancestor. The different T4-type phages appear to contain a set of common genes that can be exploited differently, by means of plasticity in the regulatory sequences and the precise choice of a large group of facultative genes.

Messenger RNA stability and its role in control of gene expression in bacteria and phages

The stability of mRNA in prokaryotes depends on multiple factors and it has not yet been possible to describe the process of mRNA degradation in terms of a unique pathway. However, important advances have been made in the past 10 years with the characterization of the cis-acting RNA elements and the trans-acting cellular proteins that control mRNA decay. The trans-acting proteins are mainly four nucleases, two endo- (RNase E and RNase III) and two exonucleases (PNPase and RNase II), and poly(A) polymerase. RNase E and PNPase are found in a multienzyme complex called the degradosome. In addition to the host nucleases, phage T4 encodes a specific endonuclease called RegB. The cis-acting elements that protect mRNA from degradation are stable stem-loops at the 5' end of the transcript and terminators or REP sequences at their 3' end. The rate-limiting step in mRNA decay is usually an initial endonucleolytic cleavage that often occurs at the 5' extremity. This initial step is followed by directional 3' to 5' degradation by the two exonucleases. Several examples, reviewed here, indicate that mRNA degradation is an important step at which gene expression can be controlled. This regulation can be either global, as in the case of growth rate-dependent control, or specific, in response to changes in the environmental conditions.

The use of RNA probes for the analysis of gene expression

The monomeric bacteriophage RNA polymerases allow the synthesis of virtually any RNA molecule in unlimited quantity. In this protocol, we describe the preparation of plasmid and PCR-derived templates. A basic transcription protocol is provided with several optional modifications. The use of RNA probes in Northern blot hybridization and in RNase protection assays is described. The relative advantages and pitfalls of these two methods to quantitatively detect mRNA targets are discussed.

Gene organization and transcription of a late-expressed region of a Lactococcus lactis phage

The lactococcal phage bIL41 belongs to the small isometric-headed phages of the 936 quasi-species and is resistant to the abortive infection determined by abiB. A 10.2-kb segment from this phage, in which late transcription is initiated, has been sequenced. Thirteen open reading frames (ORFs) organized in one transcriptional unit have been identified. The location of two of them and the structural features of the proteins they code for are evocative of terminase subunits. Five other ORFs specify proteins which are highly homologous to structural proteins from the closely related phage F4-1. By comparing the phage bIL41 sequence with partial sequences available for four related phages, we were able to deduce a chimerical phage map covering the middle- and a large part of the late-expressed regions. Phages from this quasi-species differ by the insertion or deletion of either 1 to about 400 bp in noncoding regions or an entire ORF. Transcription was initiated 9 min after infection at a promoter with a -10 but no -35 consensus sequence. Synthesis of a phage activator protein was needed for initiation of transcription. A large 16-kb transcript covering all of the late-expressed region of the genome was synthesized. This transcript gave rise to smaller units. One of these units most probably resulted from a RNase E processing.

mRNA degradation in Escherichia coli: a novel factor which impedes the exoribonucleolytic activity of PNPase at stem-loop structures

Stem-loop structures can protect upstream mRNA from degradation by impeding the processive activities of 3'-5' exoribonucleases. The ability of such structures to impede exonuclease activity in vitro is insufficient to account for the stability they can confer on mRNA in vivo. In this study we identify a factor from Escherichia coli which specifically impedes the processive activity of the 3'-5' exonuclease PNPase at stem-loop structures in vitro. This factor can, potentially, reconcile the apparent discrepancy between the ability of 3' stem-loop structures to stabilize upstream mRNA in vitro and in vivo. Its mechanism of action, and possible role in regulating mRNA degradation, is discussed.

The asiA gene product of bacteriophage T4 is required for middle mode RNA synthesis

The asiA gene of bacteriophage T4 encodes a 10-kDa peptide which binds strongly in vitro to the sigma 70 subunit of Escherichia coli RNA polymerase, thereby weakening sigma 70-core interactions and inhibiting sigma 70-dependent transcription. To assess the physiological role of this protein, we have introduced an amber mutation into the proximal portion of the asiA gene. On suppressor-deficient hosts, this mutant phage (amS22) produces minute plaques and exhibits a pronounced delay in phage production. During these mutant infections, T4 DNA synthesis is strongly delayed, suggesting that the AsiA protein plays an important role during the prereplicative period of phage T4 development. The kinetics of protein synthesis show clearly that while T4 early proteins are synthesized normally, those expressed primarily via the middle mode exhibit a marked inhibition. In fact, the pattern of protein synthesis after amS22 infection resembles greatly that seen after infection by amG1, an amber mutant in motA, a T4 gene whose product is known to control middle mode RNA synthesis. The amber mutations in the motA and asiA genes complement, both for phage growth and for normal kinetics of middle mode protein synthesis. Furthermore, primer extension analyses show that three different MotA-dependent T4 middle promoters are not recognized after infection by the asiA mutant phage. Thus, in conjunction with the MotA protein, the AsiA protein is required for transcription activation at T4 middle mode promoters.

Initiation of mRNA decay in Bacillus subtilis

Ribosome stalling in the leader region of ermC mRNA results in a 10-15-fold increase in ermC mRNA half-life in Bacillus subtilis. Fusion of the ermC 5' regulatory region to several B. subtilis coding sequences resulted in induced stability of the fusion RNAs, showing that the ermC 5' region acts as a general '5' stabilizer'. RNA products of an ermC-lacZ transcriptional fusion were inducibly stable in the complete absence of translation and included a small RNA that is likely to be a decay product arising by blockage of a 3'-to-5' exoribonuclease activity. Insertion of sequences that encode endonucleolytic cleavage sites into the ermC coding sequence resulted in cleavage products whose stability depended on the nature of their 5' and 3' ends. It can be concluded from this study that initiation of mRNA decay in B. subtilis generally occurs at or near the 5' terminus.

Specificity of Escherichia coli endoribonuclease RNase E: in vivo and in vitro analysis of mutants in a bacteriophage T4 mRNA processing site

Endoribonuclease RNase E has an important role in the processing and degradation of bacteriophage T4 and Escherichia coli mRNAs. We have undertaken a mutational analysis of the -71 RNase E processing site of T4 gene 32. A series of mutations were introduced into a synthetic T4 sequence cloned on a plasmid, and their effects on processing were analyzed in vivo. The same mutations were transferred into T4 by homologous recombination. In both the plasmid and the phage contexts the processing of the transcripts was similarly affected by the mutations. Partially purified RNase E has also been used to ascertain the effect of these mutations on RNase E processing in vitro. The hierarchy of the efficiency of processing of the various mutant transcripts was the same in vivo and in vitro. These results and an analysis of all of the known putative RNase E sites suggest a consensus sequence RAUUW (R = A or G; W = A or U) at the cleavage site. Modifications of the stem-loop structure downstream of the -71 site indicate that a secondary structure is required for RNase E processing. Processing by RNase E was apparently inhibited by sequences that sequester the site in secondary structure.

Plasmid vectors for selecting IS1-promoted deletions in cloned DNA: sequence analysis of the omega interposon

We have constructed two plasmid vectors which allow selection for in vivo deletions within cloned DNA fragments. The plasmids are derivatives of pBR322 which carry the Escherichia coli rpsL (strA) gene, known to confer a dominant streptomycin (Sm)-sensitivity phenotype to the host cell, and a copy of the IS1 transposable element. Sm-resistant strains that harbor these plasmids display sensitivity to Sm. Spontaneous IS1-promoted deletions across the rpsL gene can be isolated simply by selection for Sm resistance. Hence, nested sets of deletions of a cloned DNA can be obtained and sequenced with an IS1-specific primer. Using this approach, we have determined the complete nucleotide sequence of the omega interposon [Prentki and Krisch, Gene 29 (1984) 303-313].

Gene 32 transcription and mRNA processing in T4-related bacteriophages

We have analysed transcription and mRNA processing for the gene 32 region of five phages related to T4. Two different organizations of gene 32 proximal promoters were found. In T4 and M1, middle- and late-mode promoters are separated by 50 nucleotides and located within an upstream open reading frame. In T2, K3, Ac3, and Ox2, the 626bp T4 sequence that includes these promoters is replaced by a 59bp sequence containing overlapping middle and late promoters. The RNase E-dependent processing of the g32 mRNAs is conserved in all of the phages. The processing site immediately upstream of g32 in T4 and M1 has been replaced in the other phages by a different sequence that is also cleaved by RNase E. The remarkable conservation of these regulatory features, despite the sequence divergences, suggests that they play an important role in the control of gene expression.

Decay of mRNA encoding ribosomal protein S15 of Escherichia coli is initiated by an RNase E-dependent endonucleolytic cleavage that removes the 3' stabilizing stem and loop structure

The transcripts of the rpsO-pnp operon of Escherichia coli, coding for ribosomal protein S15 and polynucleotide phosphorylase, are processed at four sites in the 249 nucleotides of the intercistronic region. The initial processing step in the decay of the pnp mRNA is made by RNase III, which cuts at two sites upstream from the pnp gene. The other two cleavages are dependent on the wild-type allele of the rne gene, which encodes the endonucleolytic enzyme RNase E. The cuts are made 37 nucleotides apart at the base of the stem-loop structure of the rho-independent attenuator located downstream from rpsO. The cleavage downstream from the attenuator generates an rpsO mRNA.nearly identical with the monocistronic attenuated transcript, while the cleavage upstream from the transcription attenuator gives rise to an rpsO mesage lacking the terminal 3' hairpin structure. The rapid degradation of the processed mRNA in an rne+ strain, compared to the slow degradation of the transcript that accumulates in an rne- strain, suggests that RNase E initiates the decay of the rpsO message by removing the stabilizing stem-loop at the 3' end of the RNA.

RNase E, an endoribonuclease, has a general role in the chemical decay of Escherichia coli mRNA: evidence that rne and ams are the same genetic locus

Escherichia coli RNase E is known to process RNA precursors at specific sites. We show that this endoribonuclease has a general role in E. coli mRNA turnover and affects the stability of specific transcripts. The effect of the rne mutation on functional stability of mRNA was much less pronounced than that on chemical stability, although the expression of some genes was affected. The E. coli ams (altered mRNA stability) mutation was found to have phenotypes indistinguishable from those of the rne mutation, affecting both 9S RNA and T4 gene 32 mRNA processing. The rne and ams mutations were both complemented by the same 3.7 kb fragment of E. coli DNA and are probably allelic. RNase E is the first endoribonuclease identified as having a general role in the chemical decay of E. coli mRNA.

Escherichia coli RNase E has a role in the decay of bacteriophage T4 mRNA

Bacteriophage T4 mRNAs are markedly stabilized, both chemically and functionally, in an Escherichia coli strain deficient in the RNA-processing endonuclease RNase E. The functional stability of total T4 messages increased 6-fold; we were unable to detect a T4 message whose functional stability was not increased. There was a 4-fold increase in the chemical stability of total T4 RNA. The degree of chemical stabilization of six specific T4 mRNAs examined varied from a maximum of 28-fold to a minimum of 1.5-fold. In the RNase E-deficient strain, several minutes delay and a slower rate of progeny production led to a reduction in final phage yield of approximately 50%. Although the effect of the rne temperature-sensitive mutation could be indirect, the simplest interpretation of our results is that RNase E acts directly in the degradation of many T4 mRNAs.

Mechanism of erythromycin-induced ermC mRNA stability in Bacillus subtilis

In Bacillus subtilis, the ermC gene encodes an mRNA that is unusually stable (40-min half-life) in the presence of erythromycin, an inducer of ermC gene expression. A requirement for this induced mRNA stability is a ribosome stalled in the ermC leader region. This property of ermC mRNA was used to study the decay of mRNA in B. subtilis. Using constructs in which the ribosome stall site was internal rather than at the 5' end of the message, we show that ribosome stalling provides stability to sequences downstream but not upstream of the ribosome stall site. Our results indicate that ermC mRNA is degraded by a ribonucleolytic activity that begins at the 5' end and degrades the message in a 5'-to-3' direction.

Transcription and messenger RNA processing upstream of bacteriophage T4 gene 32

Bacteriophage T4 gene 32 lies at the 3' end of a complex transcription unit which includes genes 33, 59, and several open reading frames. In the course of an infection, four major transcripts are synthesized from this unit: two overlapping polycistronic transcripts about 3800 and 2800 nucleotides in length, and two monocistronic gene 32 transcripts about 1150 and 1100 nucleotides in length. These transcripts are made at different times in infection and the polycistronic transcripts have segmental differences in stability. Messenger RNA processing yields a 1025 nucleotide monocistronic gene 32 transcript, and a 135 nucleotide transcript containing part of the gene 59 coding sequence. Processing depends on Escherichia coli encoded ribonuclease E. This pattern of transcription and processing leads to the synthesis of gene 32 mRNA throughout infection, whereas transcripts encoding the upstream genes are present only early in infection. The 3800 nucleotide polycistronic transcript initiates at a promoter that does not require T4 encoded factors for activity. However, full-length synthesis of this transcript depends on the T4 mot gene product. The region upstream of gene 32 also contains four E. coli-like promoters that are active on chimeric plasmids in uninfected cells, but inactive in bacteriophage T4. The location of these cryptic T4 promoters is intriguing in that they lie near the 5' ends of open reading frame B, gene 59 and gene 32. They could play a role in phage development under particular conditions of growth or in bacterial hosts other than those examined here.

Analysis of the promoters and transcripts involved in IS10 anti-sense RNA control

Genetic analysis of eleven mutations affecting the IS10 promoters, pIN and pOUT, involved in anti-sense RNA control of transposase gene expression, and characterization of the transcripts, reveal that: (i) The transposase message (RNA-IN) and the anti-sense RNA (RNA-OUT) have been unambiguously identified in vivo. (ii) Five mutations affect pIN activity, and establish that pIN is the only IS10 promoter transcribing the tnp gene, and the only such IS10 promoter that responds to DNA-adenine methylation. (iii) Six mutations alter pOUT activity, and establish that pOUT is the only IS10 promoter specifying the anti-sense RNA-OUT. (iv) The latter, however, need not be so: heterologous promoters, if properly positioned, can also specify active anti-sense RNAs. (v) These heterologously promoted anti-sense RNAs are processed to species closely resembling native RNA-OUT.

A nuclease that cuts specifically in the ribosome binding site of some T4 mRNAs

We have identified a nucleolytic activity in Escherichia coli infected by bacteriophage T4 that introduces cuts in the ribosome binding site of at least two T4 mRNAs. Cutting takes place specifically in the GGAG sequences that are complementary to the 3' end of 16S rRNA (Shine-Dalgarno sequence). The nature of this nucleolytic cut has been investigated by reverse transcriptase mapping, anti-mRNA mapping, utilization of the vaccinia virus guanylyltransferase, and labeling by polynucleotide kinase. We have compared the sequences of target mRNAs with an mRNA of similar sequence but that is not a substrate for the nuclease. This allowed us to narrow down the possibilities for sequence elements that determine nuclease recognition. We hypothesize that this nuclease plays a physiological role in the inhibition of expression of a class of phage proteins.

Autogenous regulatory site on the bacteriophage T4 gene 32 messenger RNA

We have identified the binding site on the bacteriophage T4 gene 32 mRNA responsible for autogenous translational regulation. We demonstrate that this site is largely unstructured and overlaps the initiation codon of gene 32 as previously predicted. Co-operative binding of gene 32 protein to this site specifically blocks the formation of 30 S-tRNA(fMet)-gene 32 mRNA ternary complexes and initiation of translation. The translational operator is bound co-operatively by gene 32 protein and this binding is facilitated by a nucleation site far upstream from the initiation codon. A similar unstructured mRNA lacking this nucleation site is also bound co-operatively, but only at concentrations of gene 32 protein higher than those needed to repress binding of ribosomes to the gene 32 mRNA. Some sequence-specific interactions may also influence this binding. Comparison of the bacteriophage T2, T4 and T6 gene 32 operator sequences leads us to propose that the nucleation site is a pseudoknot.

A bacteriophage T4 expression cassette that functions efficiently in a wide range of gram-negative bacteria

We have constructed a derivative of the broad-host-range vector RSF1010. This plasmid, p alpha omega, contains an expression cassette derived from bacteriophage T4 gene 32, into which we have inserted the coding sequence for the xylE enzyme (C2,3O) of the TOL plasmid pWWO. The composite plasmid, p alpha xylE omega, was transferred by conjugal mobilisation into a variety of Gram-negative bacteria (Agrobacter, Paracoccus, Erwinia, Pseudomonas, Rhizobium and Xanthomonas). High levels of C2,3O activity were found in almost all of the extracts. Polyacrylamide gel electrophoresis of these extracts revealed a prominent protein band at 35 kDa whose identity as the C2,3O gene product was confirmed by immunoblotting. We have mapped the 5' ends of the gene 32/xylE hybrid transcripts. In all of the Gram-negative bacteria, the proximal P2 promoter is the most efficient promoter in the cassette. In most of the strains a weaker and more distal promoter activity (Pl) was also detected. In both uninfected and phage-infected Escherichia coli cells, the transcript produced from this promoter is processed at a specific site upstream from the gene 32 start codon. The same processing occurred in all the bacterial species examined. The decay of the hybrid xylE transcript has been analyzed in E. coli and Erwinia, and in both strains this mRNA was among the most stable.

Molecular analysis and regulation of the glnA gene of the gram-positive anaerobe Clostridium acetobutylicum

The nucleotide sequence of a 2.0-kilobase DNA segment containing the Clostridium acetobutylicum glnA gene was determined. The upstream region of the glnA gene contained two putative extended promoter consensus sequences (p1 and p2), characteristic of gram-positive bacteria. A third putative extended gram-positive promoter consensus sequence (p3), oriented towards the glnA gene, was detected downstream of the structural gene. The sequences containing the proposed promoter regions p1 and p2 or p3 were shown to have promoter activity by subcloning into promoter probe vectors. The complete amino acid sequence (444 residues) of the C. acetobutylicum glutamine synthetase (GS) was deduced, and comparisons were made with the reported amino acid sequences of GS from other organisms. To determine whether the putative promoter p3 and a downstream region with an extensive stretch of inverted repeat sequences were involved in regulation of C. acetobutylicum glnA gene expression by nitrogen in Escherichia coli, deletion plasmids were constructed lacking p3 and various downstream sequences. Deletion of the putative promoter p3 and downstream inverted repeat sequences affected the regulation of GS and reduced the levels of GS approximately fivefold under nitrogen-limiting conditions but did not affect the repression of GS levels in cells grown under nitrogen-excess conditions.