Bacteriophage P4 immunity controlled by small RNAs via transcription termination

Integrative structural analysis of Pseudomonas phage DEV reveals a genome ejection motor

DEV is an obligatory lytic Pseudomonas phage of the N4-like genus, recently reclassified as Schitoviridae. The DEV genome encodes 91 ORFs, including a 3398 amino acid virion-associated RNA polymerase (vRNAP). Here, we describe the complete architecture of DEV, determined using a combination of cryo-electron microscopy localized reconstruction, biochemical methods, and genetic knockouts. We built de novo structures of all capsid factors and tail components involved in host attachment. We demonstrate that DEV long tail fibers are essential for infection of Pseudomonas aeruginosa but dispensable for infecting mutants with a truncated lipopolysaccharide devoid of the O-antigen. We determine that DEV vRNAP is part of a three-gene operon conserved in 191 Schitoviridae genomes. We propose these three proteins are ejected into the host to form a genome ejection motor spanning the cell envelope. We posit that the design principles of the DEV ejection apparatus are conserved in all Schitoviridae.

Integrative structural analysis of Pseudomonas phage DEV reveals a genome ejection motor

DEV is an obligatory lytic Pseudomonas phage of the N4-like genus, recently reclassified as Schitoviridae. The DEV genome encodes 91 ORFs, including a 3,398 amino acid virion-associated RNA polymerase. Here, we describe the complete architecture of DEV, determined using a combination of cryo-electron microscopy localized reconstruction, biochemical methods, and genetic knockouts. We built de novo structures of all capsid factors and tail components involved in host attachment. We demonstrate that DEV long tail fibers are essential for infection of Pseudomonas aeruginosa and dispensable for infecting mutants with a truncated lipopolysaccharide devoid of the O-antigen. We identified DEV ejection proteins and, unexpectedly, found that the giant DEV RNA polymerase, the hallmark of the Schitoviridae family, is an ejection protein. We propose that DEV ejection proteins form a genome ejection motor across the host cell envelope and that these structural principles are conserved in all Schitoviridae.

Human PNPase causes RNA stabilization and accumulation of R-loops in the Escherichia coli model system

Polyribonucleotide phosphorylase (PNPase) is a phosphorolytic RNA exonuclease highly conserved throughout evolution. In Escherichia coli, PNPase controls complex phenotypic traits like biofilm formation and growth at low temperature. In human cells, PNPase is located in mitochondria, where it is implicated in the RNA import from the cytoplasm, the mitochondrial RNA degradation and the processing of R-loops, namely stable RNA-DNA hybrids displacing a DNA strand. In this work, we show that the human PNPase (hPNPase) expressed in E. coli causes oxidative stress, SOS response activation and R-loops accumulation. Hundreds of E. coli RNAs are stabilized in presence of hPNPase, whereas only few transcripts are destabilized. Moreover, phenotypic traits typical of E. coli strains lacking PNPase are strengthened in presence of the human enzyme. We discuss the hypothesis that hPNPase expressed in E. coli may bind, but not degrade, the RNA, in agreement with previous in vitro data showing that phosphate concentrations in the range of those found in the bacterial cytoplasm and, more relevant, in the mitochondria, inhibit its activity.

Pseudomonas aeruginosa mutants defective in glucose uptake have pleiotropic phenotype and altered virulence in non-mammal infection models

Pseudomonas spp. are endowed with a complex pathway for glucose uptake that relies on multiple transporters. In this work we report the construction and characterization of Pseudomonas aeruginosa single and multiple mutants with unmarked deletions of genes encoding outer membrane (OM) and inner membrane (IM) proteins involved in glucose uptake. We found that a triple ΔgltKGF ΔgntP ΔkguT mutant lacking all known IM transporters (named GUN for Glucose Uptake Null) is unable to grow on glucose as unique carbon source. More than 500 genes controlling both metabolic functions and virulence traits show differential expression in GUN relative to the parental strain. Consistent with transcriptomic data, the GUN mutant displays a pleiotropic phenotype. Notably, the genome-wide transcriptional profile and most phenotypic traits differ between the GUN mutant and the wild type strain irrespective of the presence of glucose, suggesting that the investigated genes may have additional roles besides glucose transport. Finally, mutants carrying single or multiple deletions in the glucose uptake genes showed attenuated virulence relative to the wild type strain in Galleria mellonella, but not in Caenorhabditis elegans infection model, supporting the notion that metabolic functions may deeply impact P. aeruginosa adaptation to specific environments found inside the host.

Replication and Maintenance of Linear Phage-Plasmid N15

The lambdoid phage N15 of Escherichia coli is very unusual among temperate phages in that its prophage is not integrated into the chromosome but is a linear plasmid molecule with covalently closed ends (telomeres). Upon infection, the phage DNA circularizes via cohesive ends, and then a special phage enzyme of the tyrosine recombinase family, protelomerase, cuts at another site and joins the ends, forming hairpin telomeres of the linear plasmid prophage. Replication of the N15 prophage is initiated at an internally located ori site and proceeds bidirectionally, resulting in the formation of duplicated telomeres. The N15 protelomerase cuts them, generating two linear plasmid molecules with hairpin telomeres. Stable inheritance of the plasmid prophage is ensured by a partitioning operon similar to the F factor sop operon. Unlike the F centromere, the N15 centromere consists of four inverted repeats dispersed in the genome. The multiplicity and dispersion of centromeres are required for efficient partitioning of a linear plasmid. The centromeres are located in the N15 genome regions involved in phage replication and control of lytic development, and binding of partition proteins at these sites regulates these processes. The family of N15-like linear phage-plasmids includes lambdoid phages ɸKO2 and pY54, as well as Myoviridae phages ΦHAP-1, VHML, VP882, Vp58.5, and vB_VpaM_MAR of marine gamma-proteobacteria. The genomes of these phages contain similar protelomerase genes, lysogeny control modules, and replication genes, suggesting that these phages may belong to a group diverged from a common ancestor.

Tet-Trap, a genetic approach to the identification of bacterial RNA thermometers: application to Pseudomonas aeruginosa

Modulation of mRNA translatability either by trans-acting factors (proteins or sRNAs) or by in cis-acting riboregulators is widespread in bacteria and controls relevant phenotypic traits. Unfortunately, global identification of post-transcriptionally regulated genes is complicated by poor structural and functional conservation of regulatory elements and by the limitations of proteomic approaches in protein quantification. We devised a genetic system for the identification of post-transcriptionally regulated genes and we applied this system to search for Pseudomonas aeruginosa RNA thermometers, a class of regulatory RNA that modulates gene translation in response to temperature changes. As P. aeruginosa is able to thrive in a broad range of environmental conditions, genes differentially expressed at 37 °C versus lower temperatures may be involved in infection and survival in the human host. We prepared a plasmid vector library with translational fusions of P. aeruginosa DNA fragments (PaDNA) inserted upstream of TIP2, a short peptide able to inactivate the Tet repressor (TetR) upon expression. The library was assayed in a streptomycin-resistant merodiploid rpsL(+)/rpsL31 Escherichia coli strain in which the dominant rpsL(+) allele, which confers streptomycin sensitivity, was repressed by TetR. PaDNA fragments conferring thermosensitive streptomycin resistance (i.e., expressing PaDNA-TIP2 fusions at 37°C, but not at 28°C) were sequenced. We identified four new putative thermosensors. Two of them were validated with conventional reporter systems in E. coli and P. aeruginosa. Interestingly, one regulates the expression of ptxS, a gene implicated in P. aeruginosa pathogenesis.

Pirates of the Caudovirales

Molecular piracy is a biological phenomenon in which one replicon (the pirate) uses the structural proteins encoded by another replicon (the helper) to package its own genome and thus allow its propagation and spread. Such piracy is dependent on a complex web of interactions between the helper and the pirate that occur at several levels, from transcriptional control to macromolecular assembly. The best characterized examples of molecular piracy are from the E. coli P2/P4 system and the S. aureus SaPI pathogenicity island/helper system. In both of these cases, the pirate element is mobilized and packaged into phage-like transducing particles assembled from proteins supplied by a helper phage that belongs to the Caudovirales order of viruses (tailed, dsDNA bacteriophages). In this review we will summarize and compare the processes that are involved in molecular piracy in these two systems.

Genome-wide discovery of small RNAs in Mycobacterium tuberculosis

Only few small RNAs (sRNAs) have been characterized in Mycobacterium tuberculosis and their role in regulatory networks is still poorly understood. Here we report a genome-wide characterization of sRNAs in M. tuberculosis integrating experimental and computational analyses. Global RNA-seq analysis of exponentially growing cultures of M. tuberculosis H37Rv had previously identified 1373 sRNA species. In the present report we show that 258 (19%) of these were also identified by microarray expression. This set included 22 intergenic sRNAs, 84 sRNAs mapping within 5′/3′ UTRs, and 152 antisense sRNAs. Analysis of promoter and terminator consensus sequences identified sigma A promoter consensus sequences for 121 sRNAs (47%), terminator consensus motifs for 22 sRNAs (8.5%), and both motifs for 35 sRNAs (14%). Additionally, 20/23 candidates were visualized by Northern blot analysis and 5′ end mapping by primer extension confirmed the RNA-seq data. We also used a computational approach utilizing functional enrichment to identify the pathways targeted by sRNA regulation. We found that antisense sRNAs preferentially regulated transcription of membrane-bound proteins. Genes putatively regulated by novel cis-encoded sRNAs were enriched for two-component systems and for functional pathways involved in hydrogen transport on the membrane.

The RNA processing enzyme polynucleotide phosphorylase negatively controls biofilm formation by repressing poly-N-acetylglucosamine (PNAG) production in Escherichia coli C

Background

Transition from planktonic cells to biofilm is mediated by production of adhesion factors, such as extracellular polysaccharides (EPS), and modulated by complex regulatory networks that, in addition to controlling production of adhesion factors, redirect bacterial cell metabolism to the biofilm mode.

Results

Deletion of the pnp gene, encoding polynucleotide phosphorylase, an RNA processing enzyme and a component of the RNA degradosome, results in increased biofilm formation in Escherichia coli. This effect is particularly pronounced in the E. coli strain C-1a, in which deletion of the pnp gene leads to strong cell aggregation in liquid medium. Cell aggregation is dependent on the EPS poly-N-acetylglucosamine (PNAG), thus suggesting negative regulation of the PNAG biosynthetic operon pgaABCD by PNPase. Indeed, pgaABCD transcript levels are higher in the pnp mutant. Negative control of pgaABCD expression by PNPase takes place at mRNA stability level and involves the 5’-untranslated region of the pgaABCD transcript, which serves as a cis-element regulating pgaABCD transcript stability and translatability.

Conclusions

Our results demonstrate that PNPase is necessary to maintain bacterial cells in the planktonic mode through down-regulation of pgaABCD expression and PNAG production.

S1 ribosomal protein and the interplay between translation and mRNA decay

S1 is an ‘atypical’ ribosomal protein weakly associated with the 30S subunit that has been implicated in translation, transcription and control of RNA stability. S1 is thought to participate in translation initiation complex formation by assisting 30S positioning in the translation initiation region, but little is known about its role in other RNA transactions. In this work, we have analysed in vivo the effects of different intracellular S1 concentrations, from depletion to overexpression, on translation, decay and intracellular distribution of leadered and leaderless messenger RNAs (mRNAs). We show that the cspE mRNA, like the rpsO transcript, may be cleaved by RNase E at multiple sites, whereas the leaderless cspE transcript may also be degraded via an alternative pathway by an unknown endonuclease. Upon S1 overexpression, RNase E-dependent decay of both cspE and rpsO mRNAs is suppressed and these transcripts are stabilized, whereas cleavage of leaderless cspE mRNA by the unidentified endonuclease is not affected. Overall, our data suggest that ribosome-unbound S1 may inhibit translation and that part of the Escherichia coli ribosomes may actually lack S1.

Complex transcriptional organization regulates an Escherichia coli locus implicated in lipopolysaccharide biogenesis

The Escherichia coli yrbG-lptB locus (yrbG kdsD kdsC lptC lptA lptB) encodes genes for outer membrane biogenesis, namely, kdsC and kdsD for biosynthesis of the lipopolysaccharide inner core sugar Kdo, and lptA, lptB, and lptC for lipopolysaccharide transport to the outer membrane. Three promoters (yrbGp, kdsCp and the σ(E)-dependent lptAp) have been previously identified by genetic analysis. In this work, we show that transcription of this locus generates an array of overlapping mRNAs and we characterize the two intralocus promoter regions. In the kdsCp region, we identified three promoters (kdsCp1, kdsCp2, and kdsCp3) scattered within about 600 nt in the 3'-coding region of kdsD. The lptAp region is composed of two closely spaced promoters, lptAp1 and lptAp2. The former had been previously identified as a σ(E)-dependent promoter. Interestingly, lptAp1 is not activated by several stressful conditions that normally induce the σ(E)-dependent envelope stress response, whereas it seems to respond to conditions affecting lipopolysaccharide biogenesis, thus implying a specialized σ(E)-dependent LPS stress signaling pathway.

N15: the linear phage-plasmid

The lambdoid phage N15 of Escherichia coli is very unusual among temperate phages in that its prophage is not integrated into chromosome but is a linear plasmid molecule with covalently closed ends. Upon infection the phage DNA circularises via cohesive ends, then phage-encoded enzyme, protelomerase, cuts at an inverted repeat site and forms hairpin ends (telomeres) of the linear plasmid prophage. Replication of the N15 prophage is initiated at an internally located ori site and proceeds bidirectionally resulting in formation of duplicated telomeres. Then the N15 protelomerase cuts duplicated telomeres generating two linear plasmid molecules with hairpin telomeres. Stable inheritance of the plasmid prophage is ensured by partitioning operon similar to the F factor sop operon. Unlike F sop, the N15 centromere consists of four inverted repeats dispersed in the genome. The multiplicity and dispersion of centromeres are required for efficient partitioning of a linear plasmid. The centromeres are located in N15 genome regions involved in phage replication and control of lysogeny, and binding of partition proteins at these sites regulates these processes. Two N15-related lambdoid Siphoviridae phages, φKO2 in Klebsiella oxytoca and pY54 in Yersinia enterocolitica, also lysogenize their hosts as linear plasmids, as well as Myoviridae marine phages VP882 and VP58.5 in Vibrio parahaemolyticus and ΦHAP-1 in Halomonas aquamarina. The genomes of all these phages contain similar protelomerase genes, lysogeny modules and replication genes, as well as plasmid-partitioning genes, suggesting that these phages may belong to a group diverged from a common ancestor.

The intD mobile genetic element from Dichelobacter nodosus, the causative agent of ovine footrot, is associated with the benign phenotype

The Gram-negative anaerobic pathogen Dichelobacter nodosus is the principal causative agent of footrot in sheep. The intA, intB and intC elements are mobile genetic elements which integrate into two tRNA genes downstream from csrA (formerly glpA) and pnpA in the D. nodosus chromosome. CsrA homologues act as global repressors of virulence in several bacterial pathogens, as does polynucleotide phosphorylase, the product of pnpA. We have proposed a model in which virulence in D. nodosus is controlled in part by the integration of genetic elements downstream from csrA and pnpA, altering the expression of these putative global regulators of virulence. We describe here a novel integrated genetic element, the intD element, which is 32kb in size and contains an integrase gene, intD, several genes related to genes on other integrated elements of D. nodosus, a type IV secretion system and a putative mobilisation region, suggesting that the intD element has a role in the transfer of other genetic elements. Most of the D. nodosus strains examined which contained the intD gene were benign, with intD integrated next to pnpA, supporting our previous observation that virulent strains of D. nodosus have the intA element next to pnpA.

Autogenous regulation of Escherichia coli polynucleotide phosphorylase expression revisited

The Escherichia coli polynucleotide phosphorylase (PNPase; encoded by pnp), a phosphorolytic exoribonuclease, posttranscriptionally regulates its own expression at the level of mRNA stability and translation. Its primary transcript is very efficiently processed by RNase III, an endonuclease that makes a staggered double-strand cleavage about in the middle of a long stem-loop in the 5'-untranslated region. The processed pnp mRNA is then rapidly degraded in a PNPase-dependent manner. Two non-mutually exclusive models have been proposed to explain PNPase autogenous regulation. The earlier one suggested that PNPase impedes translation of the RNase III-processed pnp mRNA, thus exposing the transcript to degradative pathways. More recently, this has been replaced by the current model, which maintains that PNPase would simply degrade the promoter proximal small RNA generated by the RNase III endonucleolytic cleavage, thus destroying the double-stranded structure at the 5' end that otherwise stabilizes the pnp mRNA. In our opinion, however, the first model was not completely ruled out. Moreover, the RNA decay pathway acting upon the pnp mRNA after disruption of the 5' double-stranded structure remained to be determined. Here we provide additional support to the current model and show that the RNase III-processed pnp mRNA devoid of the double-stranded structure at its 5' end is not translatable and is degraded by RNase E in a PNPase-independent manner. Thus, the role of PNPase in autoregulation is simply to remove, in concert with RNase III, the 5' fragment of the cleaved structure that both allows translation and prevents the RNase E-mediated PNPase-independent degradation of the pnp transcript.

Polynucleotide phosphorylase hinders mRNA degradation upon ribosomal protein S1 overexpression in Escherichia coli

The exoribonuclease polynucleotide phosphorylase (PNPase, encoded by pnp) is a major player in bacterial RNA decay. In Escherichia coli, PNPase expression is post-transcriptionally regulated at the level of mRNA stability. The primary transcript is very efficiently processed by the endonuclease RNase III at a specific site and the processed pnp mRNA is rapidly degraded in a PNPase-dependent manner. While investigating the PNPase autoregulation mechanism we found, by UV-cross-linking experiments, that the ribosomal protein S1 in crude extracts binds to the pnp-mRNA leader region. We assayed the potential role of S1 protein in pnp gene regulation by modulating S1 expression from depletion to overexpression. We found that S1 depletion led to a sharp decrease of the amount of pnp and other tested mRNAs, as detected by Northern blotting, whereas S1 overexpression caused a strong stabilization of pnp and the other transcripts. Surprisingly, mRNA stabilization depended on PNPase, as it was not observed in a pnp deletion strain. PNPase-dependent stabilization, however, was not detected by chemical decay assay of bulk mRNA. Overall, our data suggest that PNPase exonucleolytic activity may be modulated by the translation potential of the target mRNAs and that, upon ribosomal protein S1 overexpression, PNPase protects from degradation a set of full-length mRNAs. It thus appears that a single mRNA species may be differentially targeted to either decay or PNPase-dependent stabilization, thus preventing its depletion in conditions of fast turnover.

Isolation of the Bacteriophage DinoHI from Dichelobacter nodosus and its Interactions with other Integrated Genetic Elements

The Gram-negative anaerobic pathogen Dichelobacter nodosus carries several genetic elements that integrate into the chromosome. These include the intA, intB, intC and intD elements, which integrate adjacent to csrA and pnpA, two putative global regulators of virulence and the virulence-related locus, vrl, which integrates into ssrA. Treatment of D. nodosus strains with ultraviolet light resulted in the isolation of DinoHI, a member of the Siphoviridae and the first bacteriophage to be identified in D. nodosus. Part of the DinoHI genome containing the packaging site is found in all D. nodosus strains tested and is located at the end of the vrl, suggesting a role for DinoHI in the transfer of the vrl by transduction. Like the intB element, the DinoHI genome contains a copy of regA which has similarity to the repressors of lambdoid bacteriophages, suggesting that the maintenance of DinoHI and the intB element may be co-ordinately controlled.

Transcription-termination-mediated immunity and its prevention in bacteriophage SfV of Shigella flexneri

The temperate phage SfV encodes the genes responsible for the serotype conversion of Shigella flexneri strains from serotype Y to 5a. Bacteriophages often encode proteins that prevent subsequent infection by homologous phages; the mechanism by which this is accomplished is referred to as superinfection immunity. The serotype conversion mediated following lysogenization of SfV is one such mechanism. Another mechanism is the putative lambda-like CI protein within SfV. This study reports the characterization of a third superinfection mechanism, transcription termination, in SfV. The presence of a small immunity-mediating RNA molecule, called CI RNA, and its essential role in the establishment of immunity, is shown. The novel role of the gene orf77, located immediately downstream from the transcription termination region, in inhibiting the establishment of CI RNA-mediated immunity is also presented.

The antirepressor needed for induction of linear plasmid-prophage N15 belongs to the SOS regulon

The physiological conditions and molecular interactions that control phage production have been studied in only a few families of temperate phages. We investigated the mechanisms that regulate activation of lytic development in lysogens of coliphage N15, a prophage that is not integrated into the host chromosome but exists as a linear plasmid with covalently closed ends. We identified the N15 antirepressor gene, antC, and showed that its product binds to and acts against the main phage repressor, CB. LexA binds to and represses the promoter of antC. Mitomycin C-stimulated N15 induction required RecA-dependent autocleavage of LexA and expression of AntC protein. Thus, a cellular repressor whose activity is regulated by DNA damage controls N15 prophage induction.

Autogenous regulation of Escherichia coli polynucleotide phosphorylase during cold acclimation by transcription termination and antitermination

Adaptation of Escherichia coli at low temperature implicates a drastic reprogramming of gene expression patterns. Mechanisms operating downstream of transcription initiation, such as control of transcription termination, mRNA stability and translatability, play a major role in controlling gene expression in the cold acclimation phase. It was previously shown that Rho-dependent transcription termination within pnp, the gene encoding polynucleotide phosphorylase (PNPase), was suppressed in pnp nonsense mutants, whereas it was restored by complementation with wild type allele. Using a tRNA gene as a reporter and the strong Rho-dependent transcription terminator t ( imm ) of bacteriophage P4 as a tester, here we show that specific sites in the 5'-untranslated region of pnp mRNA are required for PNPase-sensitive cold-induced suppression of Rho-dependent transcription termination. We suggest that suppression of Rho-dependent transcription termination within pnp and its restoration by PNPase is an autogenous regulatory circuit that modulates pnp expression during cold acclimation.

Bacteriophage P4 sut1: a mutation suppressing transcription termination

In the Escherichia coli satellite phage P4, transcription starting from PLE is prevalently controlled via premature termination at several termination sites. We identified a spontaneous mutation, P4 sut1 (suppression of termination), in the natural stop codon of P4 orf151 that, by elongating translation, suppresses transcription termination at the downstream t151 site. Both the translational and the transcriptional profile of P4 sut1 differed from those of P4 wild-type. First of all, P4 sut1 did not express Orf151, but a higher molecular mass protein, compatible with the 303 codon open reading frame generated by the fusion of orf151, cnr and the intervening 138 nt. Moreover, after infection of E. coli, the mutant expressed a very low amount of the 1.3 and 1.7 kb transcripts originating at PLE and PLL promoters, respectively, and terminating at the intracistronic t151 site, whereas correspondingly higher amounts of the 4.1 and 4.5 kb RNAs arising from the same promoters and covering the entire operon were detected. Thus the sut1 mutation converts a natural stop codon into a sense codon, suppresses a natural intracistronic termination site and leads to overexpression of the downstream cnr and α genes. This correlates with the inability of P4 sut1 to propagate in the plasmid state. By cloning different P4 DNA fragments, we mapped the t151 transcription termination site within the 7633–7361 region between orf151 and gene cnr. A potential stem–loop structure, resembling the structure of a Rho-independent termination site, was predicted by mfold sequence analysis at 7414–7385.

Genetic analysis of polynucleotide phosphorylase structure and functions

Polynucleotide phosphorylase (PNPase) is a phosphate-dependent 3' to 5' exonuclease widely diffused among bacteria and eukaryotes. The enzyme, a homotrimer, can also be found associated with the endonuclease RNase E and other proteins in a heteromultimeric complex, the RNA degradosome. PNPase negatively controls its own gene (pnp) expression by destabilizing pnp mRNA. A current model of autoregulation maintains that PNPase and a short duplex at the 5'-end of pnp mRNA are the only determinants of mRNA stability. During the cold acclimation phase autoregulation is transiently relieved and cellular pnp mRNA abundance increases significantly. Although PNPase has been extensively studied and widely employed in molecular biology for about 50 years, several aspects of structure-function relationships of such a complex protein are still elusive. In this work, we performed a systematic PCR mutagenesis of discrete pnp regions and screened the mutants for diverse phenotypic traits affected by PNPase. Overall our results support previous proposals that both first and second core domains are involved in the catalysis of the phosphorolytic reaction, and that both phosphorolytic activity and RNA binding are required for autogenous regulation and growth in the cold, and give new insights on PNPase structure-function relationships by implicating the alpha-helical domain in PNPase enzymatic activity.

Expression of phage P4 integrase is regulated negatively by both Int and Vis

Phage P4 int gene encodes the integrase responsible for phage integration into and excision from the Escherichia coli chromosome. Here, the data showing that P4 int expression is regulated in a complex manner at different levels are presented. First of all, the Pint promoter is regulated negatively by both Int and Vis, the P4 excisionase. The N-terminal portion of Int appears to be sufficient for such a negative autoregulation, suggesting that the Int N terminus is implicated in DNA binding. Second, full-length transcripts covering the entire int gene could be detected only upon P4 infection, whereas in P4 lysogens only short 5′-end covering transcripts were detectable. On the other hand, transcripts covering the 5′-end of int were also very abundant upon infection. It thus appears that premature transcription termination and/or mRNA degradation play a role in Int-negative regulation both on the basal prophage transcription and upon infection. Finally, comparison between Pint–lacZ transcriptional and translational fusions suggests that Vis regulates Int expression post-transcriptionally. The findings that Vis is also an RNA-binding protein and that Int may be translated from two different start codons have implications on possible regulation models of Int expression.

Non-essential KDO biosynthesis and new essential cell envelope biogenesis genes in the Escherichia coli yrbG–yhbG locus

In Escherichia coli and most Gram-negative bacteria, KDO (3-deoxy-D-manno-octulosonate), a component of the lipopolysaccharide inner core, is essential for outer membrane biogenesis and cell viability. Two recently identified genes involved in KDO biosynthesis, kdsD and kdsC, belong to the yrbG-yhbG locus where four additional ORFs (yrbG, yrbK, yhbN and yhbG) with unknown function are located. We have constructed six conditional expression mutants in which the arabinose-inducible araBp promoter is respectively located upstream of each gene of the locus. Complementation analysis of these mutants indicates that the locus is organized in at least three operons and that the three distal genes (yrbK, yhbN and yhbG) are essential for E. coli viability. Surprisingly, kdsD and kdsC (encoding a D-arabinose 5-phosphate isomerase and a KDO 8-phosphate phosphatase, respectively) were shown to be non-essential, indicating genetic redundancy for these two functions. A preliminary characterization of the arabinose-dependent mutants under permissive conditions and upon depletion revealed increased sensitivity to hydrophobic toxic chemicals, suggesting that the mutants have a defective outer membrane. These genes may thus be implicated in cell envelope integrity.

The Mycobacterium tuberculosis Rv2358-furB operon is induced by zinc

The Mycobacterium tuberculosis genome encodes two ferric uptake regulator homologues, furA and furB, the function of which is under investigation. Using Mycobacterium smegmatis as a model system, we investigated the transcriptional pattern of Rv(Ms)2358-furB genes. Transcripts covering the two genes could be identified by northern blotting and by reverse transcriptase PCR. The transcriptional start point was mapped at one base upstream of the Ms2358 start codon by the RACE technique. By cloning M. smegmatis and M. tuberculosis DNA regions upstream of a reporter gene, we demonstrated the presence of one promoter, located immediately upstream of the Rv(Ms)2358 gene. Promoter induction was tested on several cultures grown under different conditions of pH and temperature, and in the presence of different concentrations of metallic ions. The promoter was found to be specifically induced by zinc. The recombinant M. tuberculosis FurB protein typically contained two zinc ions per protein monomer. Complete removal of zinc could not be obtained, even with strong denaturation treatment. Our data are in favour of the hypothesis that Rv2358 and FurB are transcriptional regulators involved in zinc homeostasis.

Bacteriophage P4 Vis protein is needed for prophage excision

Upon infection of its host Escherichia coli, satellite bacteriophage P4 can integrate its genome into the bacterial chromosome by Int-mediated site-specific recombination between the attP and the attB sites. The opposite event, excision, may either occur spontaneously or be induced by a superinfecting P2 helper phage. In this work, we demonstrate that the product of the P4 vis gene, a regulator of the P4 late promoters P(LL) and P(sid), is needed for prophage excision. This conclusion is supported by the following evidence: (i) P4 mutants carrying either a frameshift mutation or a deletion of the vis gene were unable to excise both spontaneously or upon P2 phage superinfection; (ii) expression of the Vis protein from a plasmid induced P4 prophage excision; (iii) excision depended on a functional integrase (Int) protein, thus suggesting that Vis is involved in the formation of the excision complex, rather than in the excision recombination event per se; (iv) Vis protein bound P4 DNA in the attP region at two distinct boxes (Box I and Box II), located between the int gene and the attP core region, and caused bending of the bound DNA. Furthermore, we mapped by primer extension the 5' end of the int transcript and found that ectopic expression of Vis reduced its signal intensity, suggesting that Vis is also involved in negative regulation of the int promoter.

Changes in Escherichia coli transcriptome during acclimatization at low temperature

Upon cold shock Escherichia coli transiently stops growing and adapts to the new temperature (acclimatization phase). The major physiological effects of cold temperature are a decrease in membrane fluidity and the stabilization of secondary structures of RNA and DNA, which may affect the efficiencies of translation, transcription, and replication. Specific proteins are transiently induced in the acclimatization phase. mRNA stabilization and increased translatability play a major role in this phenomenon. Polynucleotide phosphorylase (PNPase) is one of the cold-induced proteins and is essential for E. coli growth at low temperatures. We investigated the global changes in mRNA abundance during cold adaptation both in wild type E. coli MG1655 and in a PNPase-deficient mutant. We observed a twofold or greater variation in the relative mRNA abundance of 20 genes upon cold shock, notably the cold-inducible subset of csp genes and genes not previously associated with cold shock response, among these, the extracytoplasmic stress response regulators rpoE and rseA, and eight genes with unknown function. Interestingly, we found that PNPase both negatively and positively modulated the transcript abundance of some of these genes, thus suggesting a complex role of PNPase in controlling cold adaptation.

Polynucleotide phosphorylase-deficient mutants of Pseudomonas putida

In bacteria, polynucleotide phosphorylase (PNPase) is one of the main exonucleolytic activities involved in RNA turnover and is widely conserved. In spite of this, PNPase does not seem to be essential for growth if the organisms are not subjected to special conditions, such as low temperature. We identified the PNPase-encoding gene (pnp) of Pseudomonas putida and constructed deletion mutants that did not exhibit cold sensitivity. In addition, we found that the transcription pattern of pnp upon cold shock in P. putida was markedly different from that in Escherichia coli. It thus appears that pnp expression control and the physiological roles in the cold may be different in different bacterial species.

RNase E and polyadenyl polymerase I are involved in maturation of CI RNA, the P4 phage immunity factor

Bacteriophage P4 immunity is controlled by a small stable RNA (CI RNA) that derives from the processing of primary transcripts. In previous works, we observed that the endonuclease RNase P is required for the maturation of CI RNA 5'-end; moreover, we found that polynucleotide phosphorylase (PNPase), a 3' to 5' RNA-degrading enzyme, is required for efficient 5'-end processing of CI RNA, suggesting that 3'-end degradation of the primary transcript might be involved in the production of proper RNase P substrates. Here, we demonstrate that another Escherichia coli nuclease, RNase E, would appear to be involved in this process. We found that transcripts of the P4 immunity region are modified by the post-transcriptional addition of short poly(A) tails and heteropolymeric tails with prevalence of A residues. Most oligoadenylated transcripts encompass the whole cI locus and are thus compatible as intermediates in the CI RNA maturation pathway. On the contrary, in a polynucleotide phosphorylase (PNPase)-defective host, adenylation occurred most frequently within cI, implying that such transcripts are targeted for degradation. We did not find polyadenylation in a pcnB mutant, suggesting that the pcnB-encoded polyadenyl polymerase I (PAP I) is the only enzyme responsible for modification of P4 immunity transcripts. Maturation of CI RNA 5'-end in such a mutant was impaired, further supporting the idea that processing of the 3'-end of primary transcripts is an important step for efficient maturation of CI RNA by RNase P.

Characterization of the small antisense CI RNA that regulates bacteriophage P4 immunity

In the immune state bacteriophage P4 prevents expression of the replication functions by premature termination of transcription. A small RNA, the CI RNA, is the trans acting factor that regulates P4 immunity, by pairing to complementary target sequences and causing premature transcription termination. The CI RNA is matured by RNAse P and PNPase from the leader region of the same operon it regulates. In this work we better characterize this molecule. CI RNA copy number was determined to be around 500 molecules per lysogenic cell. By S(1) mapping we defined the 3'-end at 8423(+/-1); thus CI RNA is 79(+/-1) nt long. The minimum region for correct processing requires two bases upstream of the CI RNA 5'-end and the CCA sequence at the 3'-end. Computer analysis by FOLD RNA of CI RNA sequence predicts a cloverleaf-like structure formed by a double-stranded stalk, a minor and a major stem loop, and a single-stranded bulge. We analysed several cI mutations, which fall either in the single or double-stranded CI RNA regions. Base substitutions in the main loop and in the single-stranded bulge apparently did not change CI RNA structure, but affected its activity by altering the complementarity with the target sequences, whereas a mutation in the secondary stem had a disruptive effect on CI RNA secondary structure. The effects of this latter mutation were suppressed by a base substitution that restored the complementarity with the corresponding base in the stem. Base substitutions in the main stem caused only local alterations in the secondary structure of CI. However, when the substitutions concerned either G8501 or its complementary base at the bottom of the stem, CI RNA was not correctly processed.

Transcriptional regulation of furA and katG upon oxidative stress in Mycobacterium smegmatis

The DNA region upstream of katG in Mycobacterium smegmatis was cloned and sequenced. The furA gene, highly homologous to Mycobacterium tuberculosis furA, mapped in this region. The furA-katG organization appears to be conserved among several mycobacteria. The transcription pattern of furA and katG in M. smegmatis upon oxidative stress was analyzed by Northern blotting and primer extension. Although transcription of both furA and katG was induced upon oxidative stress, transcripts covering both genes could not be identified either by Northern blotting or by reverse transcriptase PCR. Specific transcripts and 5' ends were identified for furA and katG, respectively. By cloning M. smegmatis and M. tuberculosis DNA regions upstream of a reporter gene, we demonstrated the presence of two promoters, pfurA, located immediately upstream of the furA gene, and pkatG, located within the terminal part of the furA coding sequence. Transcription from pfurA was induced upon oxidative stress. A 23-bp sequence overlapping the pfurA -35 region is highly conserved among mycobacteria and streptomycetes and might be involved in controlling pfurA activity. Transcription from a cloned pkatG, lacking the upstream pfurA region, was not induced upon oxidative stress, suggesting a cis-acting regulatory role of this region.

Cnr interferes with dimerization of the replication protein alpha in phage-plasmid P4

DNA replication of phage-plasmid P4 in its host Escherichia coli depends on its replication protein alpha. In the plasmid state, P4 copy number is controlled by the regulator protein Cnr (copy number regulation). Mutations in alpha (alpha(cr)) that prevent regulation by Cnr cause P4 over-replication and cell death. Using the two-hybrid system in Saccharomyces cerevisiae and a system based on lambda immunity in E.coli for in vivo detection of protein-protein interactions, we found that (i) alpha protein interacts with Cnr, whereas alpha(cr) proteins do not; (ii) both alpha-alpha and alpha(cr)-alpha(cr) interactions occur and the interaction domain is located within the C-terminal of alpha; (iii) Cnr-Cnr interaction also occurs. Using an in vivo competition assay, we found that Cnr interferes with both alpha-alpha and alpha(cr)-alpha(cr) dimerization. Our data suggest that Cnr and alpha interact in at least two ways, which may have different functional roles in P4 replication control.

The plasmid status of satellite bacteriophage P4

P4 is a natural phasmid (phage-plasmid) that exploits different modes of propagation in its host Escherichia coli. Extracellularly, P4 is a virion, with a tailed icosahedral head, which encapsidates the 11.6-kb-long double-stranded DNA genome. After infection of the E. coli host, P4 DNA can integrate into the bacterial chromosome and be maintained in a repressed state (lysogeny). Alternatively, P4 can replicate as a free DNA molecule; this leads to either the lytic cycle or the plasmid state, depending on the presence or absence of the genome of a helper phage P2 in the E. coli host. As a phage, P4 is thus a satellite of P2 phage, depending on the helper genes for all the morphogenetic functions, whereas for all its episomal functions (integration and immunity, multicopy plasmid replication) P4 is completely autonomous from the helper. Replication of P4 DNA depends on its alpha protein, a multifunctional polypeptide that exhibits primase and helicase activity and binds specifically the P4 origin. Replication starts from a unique point, ori1, and proceeds bidirectionally in a straight theta-type mode. P4 negatively regulates the plasmid copy number at several levels. An unusual mechanism of copy number control is based on protein-protein interaction: the P4-encoded Cnr protein interacts with the alpha gene product, inhibiting its replication potential. Furthermore, expression of the replication genes cnr and alpha is regulated in a complex way that involves modulation of promoter activity by positive and negative factors and multiple mechanisms of transcription elongation-termination control. Thus, the relatively small P4 genome encodes mostly regulatory functions, required for its propagation both as an episomal element and as a temperate satellite phage. Plasmids that, like P4, propagate horizontally via a specific transduction mechanism have also been found in the Archaea. The presence of P4-like prophages or cryptic prophages often associated with accessory bacterial functions attests to the contribution of satellite phages to bacterial evolution.

Antisense RNA-dependent transcription termination sites that modulate lysogenic development of satellite phage P4

In the lysogenic state, bacteriophage P4 prevents the expression of its own replication genes, which are encoded in the left operon, through premature transcription termination. The phage factor responsible for efficient termination is a small, untranslated RNA (CI RNA), which acts as an antisense RNA and controls transcription termination by pairing with two complementary sequences (seqA and seqC) located within the leader region of the left operon. A Rho-dependent termination site, timm, was previously shown to be involved in the control of P4 replication gene expression. In the present study, by making use of phage PhiR73 as a cloning vector and of suppressor tRNAGly as a reporter gene, we characterized two additional terminators, t1 and t4. Although transcription termination at neither site requires the Rho factor, only t1 has the typical structure of a Rho-independent terminator. t1 is located between the PLE promoter and the cI gene, whereas t4 is located between cI and timm. Efficient termination at t1 requires the CI RNA and the seqA target sequence; in vitro, the CI RNA enhanced termination at t1 in the absence of any bacterial factor. A P4 mutant, in which the t1 terminator has been deleted, can still lysogenize both Rho+ and Rho- strains and exhibits increased expression of CI RNA. These data indicate that t1 and the Rho-dependent timm terminators are not essential for lysogeny. t1 is involved in CI RNA autoregulation, whereas t4 appears to be the main terminator necessary to prevent expression of the lytic genes in the lysogenic state.

Transcriptional and post-transcriptional control of polynucleotide phosphorylase during cold acclimation in Escherichia coli

Polynucleotide phosphorylase (PNPase, polyribonucleotide nucleotidyltransferase, EC 2.7.7.8) is one of the cold shock-induced proteins in Escherichia coli and pnp, the gene encoding it, is essential for growth at low temperatures. We have analysed the expression of pnp upon cold shock and found a dramatic transient variation of pnp transcription profile: within the first hour after temperature downshift the amount of pnp transcripts detectable by Northern blotting increased more than 10-fold and new mRNA species that cover pnp and the downstream region, including the cold shock gene deaD, appeared; 2 h after temperature downshift the transcription profile reverted to a preshift-like pattern in a PNPase-independent manner. The higher amount of pnp transcripts appeared to be mainly due to an increased stability of the RNAs. The abundance of pnp transcripts was not paralleled by comparable variation of the protein: PNPase steadily increased about twofold during the first 3 h at low temperature, as determined both by Western blotting and enzymatic activity assay, suggesting that PNPase, unlike other known cold shock proteins, is not efficiently translated in the acclimation phase. In experiments aimed at assessing the role of PNPase in autogenous control during cold shock, we detected a Rho-dependent termination site within pnp. In the cold acclimation phase, termination at this site depended upon the presence of PNPase, suggesting that during cold shock pnp is autogenously regulated at the level of transcription elongation.

Genomic sequence and analysis of the atypical temperate bacteriophage N15

N15 is a temperate bacteriophage that forms stable lysogens in Escherichia coli. While its virion is morphologically very similar to phage lambda and its close relatives, it is unusual in that the prophage form replicates autonomously as a linear DNA molecule with closed hairpin telomeres. Here, we describe the genomic architecture of N15, and its global pattern of gene expression, which reveal that N15 contains several plasmid-derived genes that are expressed in N15 lysogens. The tel site, at which processing occurs to form the prophage ends is close to the center of the genome in a similar location to that occupied by the attachment site, attP, in lambda and its relatives and defines the boundary between the left and right arms. The left arm contains a long cluster of structural genes that are closely related to those of the lambda-like phages, but also includes homologs of umuD', which encodes a DNA polymerase accessory protein, and the plasmid partition genes, sopA and sopB. The right arm likewise contains a mixture of apparently phage- and plasmid-derived genes including genes encoding plasmid replication functions, a phage repressor, a transcription antitermination system, as well as phage host cell lysis genes and two putative DNA methylases. The unique structure of the N15 genome suggests that the large global population of bacteriophages may exhibit a much greater diversity of genomic architectures than was previously recognized.

The anti-immunity system of phage-plasmid N15: identification of the antirepressor gene and its control by a small processed RNA

N15 is a temperate virus of Escherichia coli related to lambdoid phages. However, unlike all other known phages, the N15 prophage is maintained as a low copy number linear DNA molecule with covalently closed ends. The primary immunity system at the immB locus is structurally and functionally comparable to that of lambdoid phages, and encodes the immunity repressor CB. We have characterized a second locus, immA, in which clear plaque mutations were mapped, and found that it encodes an anti-immunity system involved in the choice between the lytic and the lysogenic cycle. Three open reading frames at the immA locus encode an inhibitor of cell division (icd ), an antirepressor (antA) and a gene that may play an ancillary role in anti-immunity (antB ). These genes may be transcribed from two promoters: the upstream promoter Pa is repressed by the immunity repressor CB, whereas the downstream promoter Pb is constitutive. Full repression of the anti-immunity system is achieved by premature transcription termination elicited by a small RNA (CA RNA) produced by processing of the leader transcript of the anti-immunity operon. The N15 anti-immunity system is structurally and functionally similar to the anti-immunity system of bacteriophage P1 and to the immunity system of satellite phage P4.

Translation of two nested genes in bacteriophage P4 controls immunity-specific transcription termination

In phage P4, transcription of the left operon may occur from both the constitutive PLE promoter and the regulated PLL promoter, about 400 nucleotides upstream of PLE. A strong Rho-dependent termination site, timm, is located downstream of both promoters. When P4 immunity is expressed, transcription starting at PLE is efficiently terminated at timm, whereas transcription from PLL is immunity insensitive and reads through timm. We report the identification of two nested genes, kil and eta, located in the P4 left operon. The P4 kil gene, which encodes a 65-amino-acid polypeptide, is the first translated gene downstream of the PLE promoter, and its expression is controlled by P4 immunity. Overexpression of kil causes cell killing. This gene is the terminal part of a longer open reading frame, eta, which begins upstream of PLE. The eta gene is expressed when transcription starts from the PLL promoter. Three likely start codons predict a size between 197 and 199 amino acids for the Eta gene product. Both kil and eta overlap the timm site. By cloning kil upstream of a tRNA reporter gene, we demonstrated that translation of the kil region prevents premature transcription termination at timm. This suggests that P4 immunity might negatively control kil translation, thus enabling transcription termination at timm. Transcription starting from PL proceeds through timm. Mutations that create nonsense codons in eta caused premature termination of transcription starting from PLL. Suppression of the nonsense mutation restored transcription readthrough at timm. Thus, termination of transcription from PLL is prevented by translation of eta.

Identification of two replicons in phage-plasmid P4

DNA replication of phage-plasmid P4 proceeds bidirectionally from the ori1 site (previously named ori), but requires a second cis-acting region, crr. Replication depends on the product of the P4 alpha gene, a protein with primase and helicase activity, that binds both ori1 and crr. A negative regulator of P4 DNA replication, the Cnr protein, is required for copy number control of plasmid P4. Using a plasmid complementation test for replication, we found that two replicons, both dependent on the alpha gene product, coexist in P4. The first replicon is made by the cnr and alpha genes and the ori1 and crr sites. The second is limited to the alpha and crr region. Thus, in the absence of the ori1 region, replication can initiate at a different site. By deletion mapping, a cis-acting region, ori2, essential for replication of the alpha-crr replicon was mapped within a 270-bp fragment in the first half of the alpha gene. The ori2 site was found to be dispensable in a replicon that contains ori1. A construct that besides crr and alpha carries also the cnr gene was unable to replicate, suggesting that Cnr not only controls replication from ori1, but also silences ori2.

Derepression of prophage P2 by satellite phage P4: cloning of the P4 epsilon gene and identification of its product

Escherichia coli phage P4 lacks all of the genetic information necessary for capsid, tail, and lysis functions. P4 is therefore dependent on a helper phage, such as P2, for lytic propagation. During P4 superinfection of a P2 lysogen, the P2 prophage is derepressed by the action of the P4-encoded epsilon gene. We have cloned the epsilon gene and identified the 10-kDa E protein. The epsilon gene product is the only P4 protein required to derepress prophage P2, which leads to in situ P2 DNA replication. A two-plasmid derepression assay system has been developed to examine the derepression activity of E. The reporter plasmid contains the two face-to-face promoters, Pe and Pc, involved in the lysis-lysogeny transcriptional switch of phage P2 and the immunity repressor C. The Pe promoter is coupled to a cat reporter gene. In the construct, the C repressor is transcribed from the Pc promoter and represses the Pe promoter, which mimics the in situ-repressed P2 prophage. The E protein is supplied in trans from a compatible plasmid in which the epsilon gene is under the control of the T7 promoter. We show here that in the two-plasmid assay system, induction of the E protein derepresses the Pe promoter. The ash9 mutation, which is located upstream of the epsilon gene, enhances the E-mediated derepression of the Pe promoter. The purified E protein shows no specific DNA binding activity, and the implications of this are discussed.

Control of transcription termination in prokaryotes

A growing number of genetic systems have been shown to be controlled at the level of premature termination of transcription. Genes in this class contain transcription termination signals in the region upstream of the coding sequence. The activity of these regulatory termination signals is controlled through a variety of mechanisms. These include modification of RNA polymerase to a terminator-resistant, or terminator-prone form, and alterations in the structure of the nascent transcript, to determine whether the stem-loop structure of an intrinsic terminator or an alternate antiterminator is formed. Structural alterations in the transcript can be controlled by the kinetics of translation of the RNA, by binding of specific regulatory proteins, and by mRNA-tRNA interactions. This review describes a number of variations on the termination control theme that have been uncovered in prokaryotes.

Polynucleotide phosphorylase of Escherichia coli is required for the establishment of bacteriophage P4 immunity

Bacteriophage P4's superinfection immunity mechanism is unique among those of other known bacteriophages in several respects: (i) the P4 immunity factor is not a protein but a short, stable RNA (CI RNA); (ii) in the prophage the expression of the replication operon is prevented by premature transcription termination rather than by repression of transcription initiation; (iii) transcription termination is controlled via RNA-RNA interactions between the CI RNA and two complementary target sequences on the nascent transcript; and (iv) the CI RNA is produced by processing of the same transcript it controls. It was thought that several host-encoded factors may participate in the molecular events required for P4 immunity expression, i.e., RNA processing, RNA-RNA interactions, and transcription termination. To identify such factors we searched for Escherichia coli mutations that affect P4 lysogenization. One such mutation, bfl-1, severely reduced P4's lysogenization frequency and delayed both the disappearance of the long transcripts that cover the entire replication operon and the appearance of the CI RNA. By physical mapping and genetic analysis we show that bfl-1 is allelic to pnp, which codes for polynucleotide phosphorylase, a 3'-to-5' exonucleolytic enzyme. A previously isolated pnp null mutant (pnp-7) exhibited a phenotype similar to that of bfl-1. These results indicate that the polynucleotide phosphorylase of E. coli is involved with the maturation pathway of bacteriophage P4's RNA immunity factor.

Countertranscript-driven attenuation system of the pAM beta 1 repE gene

The plasmid-encoded RepE protein is absolutely essential and rate-limiting for replication of the promiscuous plasmid pAM beta 1 originating from Enterococcus faecalis. We previously showed that the rep gene is transcribed from a promoter that is negatively regulated (approximately 10-fold reduction) by the CopF repressor. In this report, we show that this transcription is decreased a further approximately 10-times by a countertranscript-driven transcriptional attenuation system. Extensive mutagenesis revealed that this system operates by a mechanism similar to that previously described for the unrelated repC gene of plasmid pT181.

Multiple regulatory mechanisms controlling phage-plasmid P4 propagation

Bacteriophage P4 autonomous replication may result in the lytic cycle or in plasmid maintenance, depending, respectively, on the presence or absence of the helper phage P2 genome in the Escherichia coli host cell. Alternatively, P4 may lysogenize the bacterial host and be maintained in an immune-integrated condition. A key step in the choice between the lytic/plasmid vs. the lysogenic condition is the regulation of P4 alpha operon. This operon may be transcribed from two promoters, PLE and PLL, and encodes both immunity (promoter proximal) and replication (promoter distal) functions. PLE is a constitutive promoter and transcription of the downstream replication genes is regulated by transcription termination. The trans-acting immunity factor that controls premature transcription termination is a short RNA encoded in the PLE proximal part of the operon. Expression of the replication functions in the lytic/plasmid condition is achieved by activation of the PLL promoter. Transcription from PLL is insensitive to the termination mechanism that acts on transcription starting from PLE.PLL is also negatively regulated by P4 orf88, the first gene downstream of PLL. An additional control on P4 DNA replication is exerted by the P4 cnr gene product.

Control of transcription termination by an RNA factor in bacteriophage P4 immunity: identification of the target sites

Prophage P4 immunity is elicited by a short, 69-nucleotide RNA (CI RNA) coded for within the untranslated leader region of the same operon it controls. CI RNA causes termination of transcription that starts at the promoter PLE and prevents the expression of the distal part of the operon that codes for P4 replication functions (alpha operon). In this work, we identify two sequences in the untranslated leader region of the alpha operon, seqA and seqC, that are the targets of the P4 immunity factor. seqA and seqC exhibit complementarity to a sequence internal to the CI RNA (seqB). Mutations in either seqA or seqC that alter its complementarity to seqB abolished or reduced P4 lysogenization proficiency and delayed the shutoff of the long transcripts originating from PLE that cover the entire operon. Both seqA and seqC single mutants were still sensitive to P4 prophage immunity, whereas P4 seqA seqC double mutants showed a virulent phenotype. Thus, both functional sites are necessary to establish immunity upon infection, whereas a single site appears to be sufficient to prevent lytic gene expression when immunity is established. A mutation in seqB that restored complementarity to both seqA and seqC mutations also restored premature termination of PLE transcripts, thus suggesting an important role for RNA-RNA interactions between seqB and seqA or seqC in P4 immunity.

A new gene of bacteriophage P4 that controls DNA replication

Bacteriophage P4 replication may result in either a lytic cycle or plasmid maintenance, depending on the presence or absence, respectively, of helper phase P2 genome. Bacteriophage P4 DNA replication depends on the product of gene alpha, which has origin recognition, primase, and helicase activities. An open reading frame with the coding capacity for a protein of 106 amino acids (orf106) is located upstream of the alpha gene. Genes orf106 and alpha are transcriptionally coregulated. Three amber mutations and an internal deletion (del51) were introduced into orf106. All of the amber mutations exhibited a polar effect on transcription of the downstream alpha gene. The P4 del51 mutant was slightly defective in lytic growth and could not be propagated in the plasmid state. In this latter condition, P4 DNA overreplication was observed. Overexpression of Orf106 severely inhibited P4 DNA replication, preventing P4 lytic growth and plasmid maintenance. The inhibitory effect of Orf106 on P4 replication was not observed when both orf106 and alpha were overexpressed. We suggest that orf106 is involved in P4 replication and that a balanced expression of orf106 relative to alpha may be necessary for proper P4 DNA replication. In particular, orf106 appears to be essential for the control of P4 genome replication in the plasmid state. We propose that orf106 be named cnr, for copy number regulation.

Division inhibition gene dicF of Escherichia coli reveals a widespread group of prophage sequences in bacterial genomes

The genomes of various eubacteria were analyzed by Southern blot hybridization to detect sequences related to the segment of the defective lambdoid prophage Kim which encodes DicF RNA, an antisense inhibitor of cell division gene ftsZ in Escherichia coli K-12. Among the homologous sequences found, one fragment from E. coli B, similar to a piece of Rac prophage, and two fragments from Shigella flexneri were cloned and sequenced. dicF-like elements similar to transcriptional terminators were found in each sequence, but unlike dicF these had no effect on division in E. coli K-12. Like dicF, these sequences are flanked by secondary structures which form potential sites for RNase III recognition. Coding sequences located upstream from the dicF-like feature in E. coli B are related to gene sieB of bacteriophage lambda, while sequences downstream of the S. flexneri elements are similar to the immunity region of satellite bacteriophage P4. Under hybridization conditions in which only strong sequence homologies were detected in E. coli B and S. flexneri, the genomes of a large variety of microorganisms, including some gram-positive bacteria, hybridized to the dicF probe. Our results suggest that dicF and its flanking regions are markers of a widespread family of prophage-like elements of different origins.

PcnB is required for the rapid degradation of RNAI, the antisense RNA that controls the copy number of ColE1-related plasmids

The replication of ColE1-related plasmids is controlled by an unstable antisense RNA, RNAI, which can interfere with the successful processing of the RNAII primer of replication. We show here that a host protein, PcnB, supports replication by promoting the decay of RNAI. In bacterial strains deleted for PcnB a stable, active form of RNAI, RNAI*, which appears to be identical to the product of 5'-end processing by RNAase E, accumulates. This leads to a reduction in plasmid copy number. We show, using a GST-PcnB fusion protein, that PcnB does not interfere with RNAI/RNAII binding in vitro. The fusion protein, like PcnB, has polyadenylating activity and is able to polyadenylate RNAI (and also another antisense RNA, CopA) in vitro.

Genetic analysis of the immunity region of phage-plasmid P4

In the prophage P4, expression of the early genes is prevented by premature termination of transcription from the constitutive promoter PLE. In order to identify the region coding for the immunity determinant, we cloned several fragments of P4 DNA and tested their ability to confer immunity to P4 superinfection. A 357 bp long fragment (P4 8418-8774) is sufficient to confer immunity to an infecting P4 phage and to complement the immunity-defective P4 cl405 mutant, both in the presence and in the absence of the helper phage P2. The immunity region covers PLE and the cl locus. We were unable to obtain evidence of translation of the region, thus we suggest that P4 immunity is not elicited by a protein but by a transcript (or transcripts) encoded by the region downstream of the promoter PLE. The promoter PLE appears to be necessary for the expression of P4 immunity: fragments in which the PLE region is deleted did not complement P4 cl405 for lysogenization, although they still interfered with P4 growth. Two complementary sequences downstream of PLE (seqA and seqB) at the 5' and 3' ends of the immunity region play an essential role in the control of P4 immunity.