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.

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.

Recombinant bacterial cells as efficient biocatalysts for the production of nucleosides.

The preparation of nucleosides as well as their base-modified analogues using purified nucleoside phosphorylase enzymes or, more conveniently, using whole bacterial cells is described. The development of genetically modified strains of Escherichia coli, able to over-produce Uridine-phosphorylase and Purine-nucleoside-phosphorylase in the same cells, improves the specific biocatalytic activity and the consequent industrial scale approach.

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.

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.

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.

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.

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.

Characterization of the oriI and oriII origins of replication in phage-plasmid P4.

In the Escherichia coli phage-plasmid P4, two partially overlapping replicons with bipartite ori sites coexist. The essential components of the oriI replicon are the alpha and cnr genes and the ori1 and crr sites; the oriII replicon is composed of the alpha gene, with the internal ori2 site, and the crr region. The P4 alpha protein has primase and helicase activities and specifically binds type I iterons, present in ori1 and crr. Using a complementation test for plasmid replication, we demonstrated that the two replicons depend on both the primase and helicase activities of the alpha protein. Moreover, neither replicon requires the host DnaA, DnaG, and Rep functions. The bipartite origins of the two replicons share the crr site and differ for ori1 and ori2, respectively. By deletion mapping, we defined the minimal ori1 and ori2 regions sufficient for replication. The ori1 site was limited to a 123-bp region, which contains six type I iterons spaced regularly close to the helical periodicity, and a 35-bp AT-rich region. Deletion of one or more type I iterons inactivated oriI. Moreover, insertion of 6 or 10 bp within the ori1 region also abolished replication ability, suggesting that the relative arrangement of the iterons is relevant. The ori2 site was limited to a 36-bp P4 region that does not contain type I iterons. In vitro, the alpha protein did not bind ori2. Thus, the alpha protein appears to act differently at the two origins of replication.

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.

Multicenter trial on mother-to-infant transmission of GBV-C virus. The Lombardy Study Group on Vertical/Perinatal Hepatitis Viruses Transmission.

Evidence indicates that the GBV-C or hepatitis G virus can cause persistent infection in humans, but little is known on the importance of vertical transmission. To assess the risk of mother-to-infant transmission and the clinical outcome of infected babies, we investigated 175 anti-HCV positive mothers and followed-up their children for 3-33 months. GBV-C RNA was detected by RT-PCR and anti-E2 antibody was assayed by EIA. Thirty-four (19.4%) women were GBV-C RNA positive and transmission occurred to 21 (61.8%) babies; 20 (95.2%) acquired GBV-C alone, and one (4.8%) GBV-C and HCV. Maternal factors such as intravenous drug use, HIV coinfection, HCV-RNA positivity, and type of feeding were not correlated with GBV-C transmission. GBV-C RNA remained persistently positive in all infected babies but one baby who seroconverted to anti-E2. Seven (35%) babies with GBV-C alone developed marginally elevated ALT; the baby with HCV and GBV-C co-infection had the highest ALT peak value (664 IU/l). Seven of the 141 (5%) babies born to the GBV-C RNA negative mothers acquired HCV and six (85.7%) had abnormal ALT. The mean ALT peak value was significantly higher (P < 0.05) for babies with HCV than for those with GBV-C. None of the children with GBV-C or with HCV became icteric. GBV-C is frequently present in anti-HCV positive women. The infection is transmitted efficiently from mother to baby and rate of transmission is much higher than that for HCV. GBV-C can cause persistent infection in babies but usually without clear evidence of liver disease.

Cnr protein, the negative regulator of bacteriophage P4 replication, stimulates specific DNA binding of its initiator protein alpha.

Bacteriophage P4 DNA replication depends upon the phage-encoded alpha protein, which has DNA helicase and DNA primase activity and can specifically bind to the replication origin (ori) and to the cis replicating region (crr). The P4 Cnr protein functions as a negative regulator of P4 replication, and P4 does not replicate in cells that overexpress cnr. We searched for P4 mutants that suppressed this phenotype (Cnr resistant [alpha cr]). Eight independent mutants that grew in the presence of high levels of Cnr were obtained. None of these can establish the plasmid state. Each of these mutations lies in the DNA binding domain of gp alpha that occupies the C terminus of the protein. Five different sequence changes were found: T675M, G732V (three times), G732W (twice), L733V, and L737V. A TrxA-Cnr fusion protein does not bind DNA by itself but stimulates the ori and crr binding abilities of alpha protein in vitro. The alpha cr mutant proteins were still able to bind specifically to ori or crr, but specific DNA binding was less stimulated by the TrxA-Cnr protein. We present evidence that Cnr protein interacts with the gp alpha domain that binds specifically to DNA and that gp(alpha)cr mutations impair this interaction. We hypothesize that gp alpha-Cnr interaction is essential for the control of P4 DNA replication.

A Rho-dependent transcription termination site regulated by bacteriophage P4 RNA immunity factor.

The genes required for replication of the temperate bacteriophage P4, which are coded by the phage left operon, are expressed from a constitutive promoter (PLE). In the lysogenic state, repression of the P4 replication genes is achieved by premature transcription termination. The leader region of the left operon encodes all the genetic determinants required for prophage immunity, namely: (i) the P4 immunity factor, a short, stable RNA (CI RNA) that is generated by processing of the leader transcript; (ii) two specific target sequences that exhibit complementarity with the CI RNA. RNA-RNA interactions between the CI RNA and the target sites on the mRNA leader region are essential for transcription termination. To understand how transcription termination is elicited by the P4 immunity mechanism, it is relevant to identify the transcription termination site. This, however, could not be directly inferred from the 3'-end of the transcription products because of the extensive and complex processing and degradation of the leader RNA. In this work, by making use of a tRNA gene as a reporter, we identify the termination site of the immunity transcripts (timm). This is a Rho-dependent terminator located within the first translated gene of the left operon and is regulated by P4 immunity. Analysis of the P4 transcription pattern in Escherichia coli rho mutants suggests that termination at timm may also be important for the efficient processing of the CI RNA.

Identification of a phage-coded DNA-binding protein that regulates transcription from late promoters in bacteriophage P4.

The genetic element P4 can propagate as a temperate phage or as a multicopy plasmid in its host Escherichia coli. Late in the lytic cycle and in the plasmid condition, transcription of the P4 essential genes depends on the activation of the late promoters P(LL) and P(sid), which control the transcription of the left and right operons, respectively. Both P4 late promoters are positively regulated by the product of the P4 delta gene, which is transcribed from P(sid). We have identified a new P4 gene, vis, that appears to play a relevant role in P4 late transcription control. vis is the first gene downstream of P(LL) and codes for a basic 88 amino acid protein with a potential helix-turn-helix motif. Expression of the cloned vis gene suppresses all the phenotypic traits exhibited by P4 vir1, a mutant that carries a promoter-up mutation in the late promoter P(LL). By Northern hybridization analysis we showed that vis negatively regulates transcription from P(LL) and enhances transcription from P(sid). Thus, vis auto-regulates its expression by repressing its own promoter and enhancing transcription of delta, which is required for P(LL) activation. The vis gene was fused with the glutathione S-transferase gene and the GST-Vis fusion protein was partially purified. By gel retardation assays and DNA footprinting we demonstrated that GST-Vis binds to a 32 bp long region immediately downstream of P(LL). We also showed, by gel retardation, that GST-Vis binds to the P sid region. A sequence present in both P(LL) and P(sid) regions may represent the Vis binding consensus sequence. The dual role of Vis on the control of P4 late transcription may be required for a regulated expression of the replication functions when P4 propagates in the plasmid state.

Immunity specificity determinants in the P4-like retronphage phi R73.

Retronphage phi R73 exhibits extensive sequence homology to the satellite bacteriophage P4. Bacteriophage P4 superinfection immunity is elicited by a small RNA (CI RNA) that causes premature transcription termination within the operon coding for the P4 replication functions. This control is exerted via interaction of the CI RNA with two complementary target sites on the untranslated leader RNA of the replication operon. We found that phi R73 is endowed with a similar immunity system but is heteroimmune to P4. The heteroimmunity is due to six base differences in the CI RNA and to compensatory base substitutions in the target sequences. The sequence differences in the CI RNA are all located in single-stranded regions, which appear to play a predominant role in the interaction with the target sites. Analysis of phage carrying a hybrid immunity system indicates that, although two target sequences are required for the establishment of lysogeny, a single site is sufficient to make a phage sensitive to the prophage immunity.

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.

Immunity determinant of phage-plasmid P4 is a short processed RNA.

In the phage-plasmid P4, both lysogenic and lytic functions are coded by the same operon. Early after infection the whole operon is transcribed from the constitutive promoter PLE. In the lysogenic condition transcription from PLE terminates prematurely and only the immunity functions, which are proximal to the promoter, are thus expressed. Fragments of the P4 immunity region were cloned in an expression vector. A DNA fragment as short as 91 bp was sufficient, when transcribed, to express P4 immunity and to complement P4 immunity deficient mutants. This fragment, like prophage P4, produced a 69 nt long RNA (CI RNA). A shorter P4 fragment neither expressed immunity nor synthesized the CI RNA. Thus the CI RNA is the P4 trans-acting immunity factor. The 5' end of the CI RNA, mapped by primer extension, does not correspond to the transcription initiation point, thus suggesting that the CI RNA is produced by processing of the primary transcript. In an RNase P mutant host the processing of the 5' end and the production of a functional CI RNA were impaired. The requirement of RNase P for the correct processing of CI appears to be related to the predicted secondary structure of the precursor CI RNA. A region (seqB) within the CI RNA shows complementarity with two cis-acting sequences (seqA and seqC) required for P4 immunity, suggesting that transcription termination may be caused by pairing of the CI RNA with the complementary target sequences on the nascent transcript.

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.

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.