Bacteriophage P4 DNA replication. Location of the P4 origin

DNA replication in phage P4: characterization of replicon II

The genetic element P4 propagates in its host Escherichia coli both as a satellite phage and as a plasmid. Two partially overlapping replicons coexist, namely replicon I and replicon II. The former is composed of two sites, ori1 and crr, and depends on P4 alpha gene product for replication. The P4 alpha protein has primase and helicase activities, and binds specifically to both ori1 and crr. Replicon II is composed of two sites, ori2 and crr, and its replication also depends on P4 alpha primase and helicase activities. In replicon II, the alpha protein binds only crr. Here we show that for replicon II the relative orientation of ori2 and crr is essential for replication to occur. Furthermore we delimit ori2 to a 22 bp region (6234-6255), internal to the alpha gene, sufficient for replicon II replication. We mutagenized this region and identified two mutants, which carry one and two base substitutions, respectively, that prevent replicon II replication. In electrophoretic mobility shift experiments of ori2, ori1, and crr DNA fragments with E. coli extracts, ori2 was not shifted, whereas both ori1 and crr were specifically bound, suggesting that other host protein(s), beside P4 alpha, are able to bind to these cis essential regions. Apparently, no binding to ori2 could be identified, thus suggesting that neither alpha nor other bacterial proteins specifically bind to 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.

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.

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.

Domain structure of phage P4 alpha protein deduced by mutational analysis

Bacteriophage P4 DNA replication depends on the product of the alpha gene, which has origin recognition ability, DNA helicase activity, and DNA primase activity. One temperature-sensitive and four amber mutations that eliminate DNA replication in vivo were sequenced and located in the alpha gene. Sequence analysis of the entire gene predicted a domain structure for the alpha polypeptide chain (777 amino acid residues, M(r) 84,900), with the N terminus providing the catalytic activity for the primase and the middle part providing that for the helicase/nucleoside triphosphatase. This model was confirmed experimentally in vivo and in vitro. In addition, the ori DNA recognition ability was found to be associated with the C-terminal third of the alpha polypeptide chain. The type A nucleotide-binding site is required for P4 replication in vivo, as shown for alpha mutations at G-506 and K-507. In the absence of an active DnaG protein, the primase function is also essential for P4 replication. Primase-null and helicase-null mutants retain the two remaining activities functionally in vitro and in vivo. The latter was demonstrated by trans complementation studies, indicating the assembly of active P4 replisomes by a primase-null and a helicase-null mutant.

Bacteriophage P4 DNA replication

Replication of satellite phage P4 of Escherichia coli is dependent on three phage-encoded elements: the origin (ori), a cis replication element (crr), and the product of the alpha gene, gp alpha. In P4 replication is origin-specific resulting in monomeric form I DNA. DNA synthesis requires chromosomally encoded proteins DNA polymerase III holoenzyme, SSB, DNA gyrase and probably topoisomerase I; host-encoded initiation and priming functions are dispensable. The alpha protein is multifunctional in P4 replication, combining three activities in a single polypeptide chain. First, the protein complexes specifically with type I repeats at ori and crr. Second, the helicase activity associated with gp alpha unwinds DNA with 3'--> 5' polarity. Third, the primase activity results in the synthesis of RNA primers. Defined sequence motifs in gp alpha correlate with the helicase and primase activities which are arranged in distinct, separable domains. Primase activity is associated with the N-terminal half of the protein, ori/crr binding with the C-terminal portion. A model for the initiation mechanism of P4 replication which resembles that of mammalian simian virus 40 is discussed.

The incN plasmid replicon: two pathways of DNA polymerase I-independent replication

The 2,053-bp broad-host-range incompatibility group N replicon of plasmid pCU1 has two components: a region of 1,200 bp that is sufficient for its replication in Escherichia coli PolA+ and PolA- hosts and a regulatory region called the group I iteron region that contains 13 39-bp iterons. Within the 1,200-bp region, there are three replication origins, two of which, called oriB and oriS, function in PolA+ and PolA- hosts and a third, called oriV, which functions only in PolA+ hosts. The region also specifies a protein called RepA. We now show that both oriB and oriS can function in a delta polA strain but that in such a strain, only oriB has an absolute requirement for RepA. oriS can function without RepA and polymerase I provided that the iteron region is deleted and that in this circumstance, it is the only origin, the usage of which is detected. The requirements for oriB usage can thus be distinguished from those for oriS usage. The oriB region can be recovered as a plasmid only if RepA is provided in trans. These complex features of this replicon are also shown to be shared by the IncN replicons of other antibiotic resistance plasmids. Functionally distinguishable origins in a small replicon may be a way of endowing such a replicon with a broad host range.

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.

Phage P4 DNA replication in vitro

Phage P4 DNA is replicated in cell-free extracts of Escherichia coli in the presence of partially purified P4 alpha protein [Krevolin and Calendar (1985), J. Mol. Biol. 182, 507-517]. Using a modified in vitro replication assay, we have further characterized this process. Analysis by agarose gel electrophoresis and autoradiography of in vitro replicated molecules demonstrates that the system yields supercoiled monomeric DNA as the main product. Electron microscopic analysis of in vitro generated intermediates indicates that DNA synthesis initiates in vitro mainly at ori, the origin of replication used in vivo. Replication proceeds from this origin bidirectionally, resulting in theta-type molecules. In contrast to the in vivo situation, no extensive single-stranded regions were found in these intermediates. The initiation proteins of the host, DnaB and DnaG, and the chaperones DnaJ and DnaK are not required for P4 replication, because polyclonal antibodies against those polypeptides do not inhibit the process. The reaction is inhibited by antibodies against the SSB protein, and by ara-CTP, a specific inhibitor of DNA polymerase III holoenzyme. Consistent with previous reports, P4 in vitro replication is independent of transcription by host RNA polymerase. Novobiocin, a DNA gyrase inhibitor, strongly inhibits P4 DNA synthesis, indicating that form I DNA is the required substrate.

Mechanisms of genome propagation and helper exploitation by satellite phage P4

Temperate coliphage P2 and satellite phage P4 have icosahedral capsids and contractile tails with side tail fibers. Because P4 requires all the capsid, tail, and lysis genes (late genes) of P2, the genomes of these phages are in constant communication during P4 development. The P4 genome (11,624 bp) and the P2 genome (33.8 kb) share homologous cos sites of 55 bp which are essential for generating 19-bp cohesive ends but are otherwise dissimilar. P4 turns on the expression of helper phage late genes by two mechanisms: derepression of P2 prophage and transactivation of P2 late-gene promoters. P4 also exploits the morphopoietic pathway of P2 by controlling the capsid size to fit its smaller genome. The P4 sid gene product is responsible for capsid size determination, and the P2 capsid gene product, gpN, is used to build both sizes. The P2 capsid contains 420 capsid protein subunits, and P4 contains 240 subunits. The size reduction appears to involve a major change of the whole hexamer complex. The P4 particles are less stable to heat inactivation, unless their capsids are coated with a P4-encoded decoration protein (the psu gene product). P4 uses a small RNA molecule as its immunity factor. Expression of P4 replication functions is prevented by premature transcription termination effected by this small RNA molecule, which contains a sequence that is complementary to a sequence in the transcript that it terminates.

Association of a retroelement with a P4-like cryptic prophage (retronphage phi R73) integrated into the selenocystyl tRNA gene of Escherichia coli

A new multicopy single-stranded DNA (msDNA-Ec73) was found in a clinical strain of Escherichia coli. Retron-Ec73, consisting of an msDNA-coding region and the gene for reverse transcriptase (RT), was found to be a part of a 12.7-kb foreign DNA fragment flanked by 29-bp direct repeats and integrated into the gene for selenocystyl-tRNA (selC) at 82 min on the E. coli chromosome. Except for the 2.4-kb retron region, the integrated DNA fragment showed remarkable homology to most of the bacteriophage P4 genome. Among the phage genes found in this element, however, the integrase gene had very low identity (40%) to P4 integrase, indicating that the cryptic prophage associated with the retroelement has its own unique site-specific integrase different from P4 integrase. Recently, we have shown that P2 phage can act as a helper to excise the cryptic prophage and to package its genome into an infectious virion. The newly formed phage (retronphage phi R73) can also lysogenize a new host strain, reintegrating its genome into the selC gene and enabling the newly formed lysogen to produce msDNA-Ec73 (S. Inouye, M. G. Sunshine, E. W. Six, and M. Inouye, Science 252:969-971, 1991).

IncN plasmid replicon. A deletion and subcloning analysis

A DNA segment of approximately 2000 base-pairs bounded by restriction enzyme sites for PvuII and containing the minimal replicon of an N group plasmid was characterized. A natural derivative of this miniplasmid was found to have undergone a deletion within one of two tandem iteron families, the group I iterons. Further analysis showed that all plasmid-determined functions essential for stable maintenance in Escherichia coli were localized to a contiguous region of DNA of 1019 nucleotides that excludes entirely these iterons. However, the loss of these iterons led to an increase in plasmid copy number. This indicates that members of the group I iteron-family have a role in determining plasmid copy number perhaps by titrating a plasmid-specified trans-acting product. The 2000 base-pair segment contains six open reading frames of 40 or more amino acid residues. The essential segment contains a 368 nucleotide region that must be present in cis and within which there are three "GATC" sequences and a putative Escherichia coli DnaA protein-binding sequence (dnaA box). An interesting feature is that the cis-acting region is present entirely within a presumptive rep gene. The essential segment contains four open reading frames, only one of which has an Escherichia coli canonical ribosome-binding site. The 2000 base-pair miniplasmid has two separable regions determining N group plasmid incompatibility.

Integration of satellite bacteriophage P4 in Escherichia coli. DNA sequences of the phage and host regions involved in site-specific recombination

We determined the DNA sequences of regions essential for bacteriophage P4 integration. A 20 base-pair core sequence in both phage (P4attP) and host (P4attB) attachment regions contains the recombination site. In P4attP this sequence is flanked by five repeated sequences. A 1.3 x 10(3) base open reading frame codes for P4 integrase. Two possible promoters are upstream from P4int. One would be recognized by Escherichia coli RNA polymerase and may be repressed by integrase protein. The second would be recognized by RNA polymerase modified after infection by a P4 helper phage, P2. The P4attB core sequence is the 3' end of a leucine tRNA gene. Downstream from this tRNA in E. coli K-12 is a region homologous to P4int that may be part of a cryptic prophage.

Bacteriophage P4 DNA replication. Nucleotide sequence of the P4 replication gene and the cis replication region

A 3100 base piece of DNA from the 11,500 base genome of bacteriophage P4 was analyzed for its nucleotide sequence. This segment of DNA contains two open reading frames of 106 and 777 amino acid residues; the latter of which is the coding sequence for the Mr 84,841 alpha protein, which is necessary for P4 DNA replication and is thought to act as a P4-specific DNA primase. A region of about 300 base-pairs localized just beyond the alpha gene and about 4500 bases from the origin of replication (ori), was defined as the locus for P4's cis replication region (crr). This region is required for replication both in vivo and in vitro, and consists of two directly repeated sequences of 120 base-pairs that match one another at 98 positions. These directly repeated sequences are separated by 60 base-pairs, which are not necessary for replication. Each repeat in crr contains three copies of the octamer TGTTCACC that is found six times in ori. Either of the 120 base-pair repeat sequences in crr is sufficient for replication, and the entire crr can function in an inverted orientation. crr is also active at a distance of 1800 bases from the P4 origin of replication.

The replication of bacteriophage P4 DNA in vitro. Partial purification of the P4 alpha gene product

A soluble enzyme system has been prepared from a phage P4-infected Escherichia coli strain that supports the replication of exogenous, supercoiled P4 DNA. This DNA synthesis in vitro depends upon the four deoxyribonucleotides and ATP, but is enhanced about four- to fivefold by the presence of other ribonucleotides. E. coli DNA polymerase III holoenzyme, the E. coli single-strand DNA binding protein, and the partially purified P4 alpha gene product are required for replication in vitro. Rifamycin does not inhibit P4 replication in vitro. Since the P4 alpha gene codes for a rifamycin-resistant RNA polymerase (Barrett et al., 1983), and since P4 DNA replication is independent of the host primase (Bowden et al., 1975), we believe the alpha gene product is functioning as a P4-specific DNA primase.