Genetic interaction between the nip1 mutation and genes affecting integration and excision in phage P2

Dimerization of bacteriophage P2 integrase is not required for binding to its DNA target but for its biological activity

Coliphage P2 integrates into the host chromosome upon lysogenization via site-specific recombination mediated by the phage integrase (Int). P2 integrase belongs to the tyrosine family of recombinases. In this work, it is shown that P2 integrase forms dimers but not oligomers in the absence of its DNA target. Furthermore, the C-terminal end of the protein and amino acid (aa) E197 have been found to be involved in dimerization. Amino acid E197 is located in a conserved region of the tyrosine recombinases that has not previously been implicated in dimerization. The dimerization deficient mutants were unaffected in binding to its phage attachment site (attP) substrate, but had a reduced ability to complement an int-defective prophage.

The multifunctional bacteriophage P2 cox protein requires oligomerization for biological activity

The Cox protein of bacteriophage P2 is a multifunctional protein of 91 amino acids. It is directly involved in the site-specific recombination event leading to excision of P2 DNA out of the host chromosome. In this context, it functions as an architectural protein in the formation of the excisome. Cox is also a transcriptional repressor of the P2 Pc promoter, thereby ensuring lytic growth. Finally it promotes derepression of prophage P4, a nonrelated defective satellite phage, by activating the P4 P(LL) promoter that controls P4 DNA replication. In this case it binds upstream of the P(LL) promoter, which normally is activated by the P4 Delta protein. In this work we have analyzed the native form of the Cox protein in vivo, using a bacteriophage lambda cI-based oligomerization assay system, and in vitro, using gel filtration, cross-linking agents, and gel retardation assays. We found that P2 Cox has a strong oligomerization function in vivo as well as in vitro. The in vitro analysis indicates that its native form is a tetramer that can self-associate to octamers. Furthermore we show that oligomerization is necessary for the biological activity by characterizing different cox mutants and that oligomerization is mediated by the C-terminal region.

The Cox protein is a modulator of directionality in bacteriophage P2 site-specific recombination

The P2 Cox protein is known to repress the Pc promoter, which controls the expression of the P2 immunity repressor C. It has also been shown that Cox can activate the late promoter PLL of the unrelated phage P4. By this process, a P2 phage infecting a P4 lysogen is capable of inducing replication of the P4 genome, an example of viral transactivation. In this report, we present evidence that Cox is also directly involved in both prophage excision and phage integration. While purified Cox, in addition to P2 Int and Escherichia coli integration host factor, was required for attR x attL (excisive) recombination in vitro, it was inhibitory to attP x attB (integrative) recombination. The same amounts of Int and integration host factor which mediated optimal excisive recombination in vitro also mediated optimal integrative recombination. We quantified and compared the relative efficiencies of attB, attR, and attL in recombination with attP and discuss the functional implications of the results. DNase I protection experiments revealed an extended 70-bp Cox-protected region on the right arm of attP, centered at about +60 bp from the center of the core sequence. Gel shift assays suggest that there are two Cox binding sites within this region. Together, these data support the theory that in vivo, P2 can exert control over the direction of recombination by either expressing Int alone or Int and Cox together.

Characterization of the binding sites of two proteins involved in the bacteriophage P2 site-specific recombination system

Integration of the bacteriophage P2 genome into the Escherichia coli host chromosome occurs by site-specific recombination between the phage attP and E. coli attB sites. The phage-encoded 38-kDa protein, integrase, is known to be necessary for both phage integration as well as excision. In order to begin the molecular characterization of this recombination event, we have cloned the int gene and overproduced and partially purified the Int protein and an N-terminal truncated form of Int. Both the wild-type Int protein and the integration host factor (IHF) of E. coli were required to mediate integrative recombination in vitro between a supercoiled attP plasmid and a linear attB substrate. Footprint experiments revealed one Int-protected region on both of the attP arms, each containing direct repeats of the consensus sequence TGTGGACA. The common core sequences at attP and attB were also protected by Int from nuclease digestion, and these contained a different consensus sequence, AA T/A T/A C/A T/G CCC, arranged as inverted repeats at each core. A single IHF-protected site was located on the P (left) arm, placed between the core- and P arm-binding site for Int. Cooperative binding by Int and IHF to the attP region was demonstrated with band-shift assays and footprinting studies. Our data support the existence of two DNA-binding domains on Int, having unrelated sequence specificities. We propose that P2 Int, IHF, attP, and attB assemble in a higher-order complex, or intasome, prior to site-specific integrative recombination analogous to that formed during lambda integration.

Genetic analysis of the DNA recognition sequence of the P2 Cox protein

The Cox protein of temperate Escherichia coli phage P2 is involved in three important biological processes: (i) excision of the integrated prophage genome (G. Lindahl and M. Sunshine, Virology 49:180-187, 1972), (ii) transcriptional repression of the P2 Pc promoter, which controls the expression of the immunity repressor C and the integrase (S. Saha, E. Haggård-Ljungquist, and K. Nordström, EMBO J. 6:3191-3199, 1987), and (iii) transcriptional activation of the late PII promoter of the unrelated satellite phage P4 (S. Saha, E. Haggård-Ljungquist, and K. Nordström, Proc. Natl. Acad. Sci. USA 86:3973-3977, 1989). A comparison of the DNA regions protected by Cox from DNaseI degradation has revealed a presumptive Cox recognition sequence (Saha et al., Proc. Natl. Acad. Sci. USA). The binding region of Cox in the P2 Pc promoter contains three presumptive recognition sequences, "Cox boxes," located in tandem. P2 vir3 and P2 vir24 are virulent deletion mutants unable to plate on Cox-producing strains, most likely because the deletions locate the new early promoters too close to the Cox-binding region (Saha et al., EMBO J.). In this report, spontaneous P2 vir3 and vir24 mutants, no longer sensitive to repression by the Cox protein, have been isolated. These mutants plate with equal efficiency on strains with or without a Cox-producing plasmid, and they have been named cor for cox resistance. Three types are recognized; the four P2 vir3 cor mutants have a 1-base deletion in the first Cox box, while the P2 vir24 cor mutants were of two types; four have a base substitution in the first Cox box, and one has a base substitution in the second Cox box. The effect of the Cox protein on the mutated P2 vir3 and vir24 promoters was analyzed in vivo by using fusions to a promoterless cat (chloramphenicol acetyltransferase) gene. The activities of the P2 vir3 and vir24 early promoters, as opposed to the wild-type early Pe promoter, are drastically reduced by the Cox protein, and the cor mutation renders them as resistant to Cox as the wild-type Pe promoter. Thus, at least the first two Cox boxes are essential for binding of the Cox protein.

Integration host factor is necessary for lysogenization of Escherichia coli by bacteriophage P2

Whether infection by bacteriophage P2 results in lysogenization of the host or vegetative growth of the phage depends upon a race between transcription from the repressor promoter Pc and the early promoter Pe; transcription from these promoters is mutually exclusive, since the Pc repressor Cox is formed from the Pe transcript and the Pe repressor C from the Pc transcript. The involvement of integration host factor (IHF) in the lysogenization of Escherichia coli K12 by P2 was tested by comparing wild-type and IHF-deficient (himA and himD) mutants. No lysogenic clones were formed following infection of the mutant bacteria. A switch plasmid that contains Pc-C-cat and Pe-cox-kan was used to test the choice for expression of Pc versus Pe. In the wild-type K12 bacteria, 20% of the clones expressed Pe transcription and 80% Pc transcription, whereas all transformed IHF-defective clones expressed transcription from Pe only. The effects of IHF on the in vivo expression of the Pe and Pc promoters were only marginal. The IHF protein was found to bind upstream of the Pe promoter, where a potential ihf sequence is located.

Control of prophage integration and excision in bacteriophage P2: nucleotide sequences of the int gene and att sites

Integration of bacteriophage P2 into the Escherichia coli host genome involves recombination between two specific attachment sites, attP and attB, one on the phage and the other on the host genome, respectively. The reaction is controlled by the product of the phage int gene, a basic polypeptide of about 37 kDa [Ljungquist and Bertani, Mol. Gen. Genet. 192 (1983) 87-94]. The int gene appears to be expressed differently by an infecting phage, as opposed to a prophage [Bertani, Proc. Natl. Acad. Sci. USA 65 (1970) 331-336]. A 1200-bp region of P2 DNA containing the int gene and attP, the prophage hybrid ends attL and attR, and one bacterial attachment site, the preferred site locI from E. coli strain C, have all been sequenced. An open reading frame coding for a polypeptide of 337 amino acids corresponds to the int gene. The gene has no obvious promoter sequence preceding it. The int gene transcript seems to continue past the attP site downstream from it, suggesting a possible explanation for the previously observed difference in integration and excision. A comparison of the four attachment sites reveals a common 'core' sequence of 27 bp: 5'-AAAAAATAAGCCCGTGTAAGGGAGATT-3'. The P2 nip1 mutation, which increases prophage excision [Calendar et al., Virology 47 (1972) 68-75], was found to lie within the int gene itself. The P2 saf variant, which has altered site preference [Six, Virology 29 (1966) 106-125], has a bp substitution within the core sequence. Three deletion/substitution mutants, vir22, vir94 and del3, also have altered core sequences.

Activation of prophage P4 by the P2 Cox protein and the sites of action of the Cox protein on the two phage genomes

Phage P2 induces the unrelated prophage P4. In this paper we show that this is due to the activation of the P4 late promoter PII by the P2 Cox protein. This is in contrast to the effects of Cox on P2, for which it is known from previous work that it acts as a repressor of the promoter Pc, which is responsible for expression of the immunity repressor C. The activator role of Cox was revealed by its effect on replication of P4 DNA and on the formation of chloramphenicol acetyltransferase when a promoterless cat gene was inserted downstream of the P4 PII promoter. DNase I protection studies revealed that the Cox protein binds to the repressor promoter Pc of phage P2 and to the promoter PII of phage P4. In the latter case the Cox protein binds upstream of the -35 region, in analogy to several other activators of promoters. A weak binding was found in the promoters Pe of phage P2 and Ple of phage P4. The Cox protein is a case of viral transactivation of the replication genes of one phage by a control protein of the other. However, the effects of the Cox protein are totally different in the two phages, repressive in one case and activating in the other.

DNA sequences of bacteriophage P2 early genes cox and B and their regulatory sites

Part of the early operon of the temperate phage P2 of Escherichia coli, including genes cox (involved in prophage excision) and B (required for phage specific DNA synthesis), was sequenced. The results are consistent with an early promoter spanning the repressor binding sites, a leader sequence of about 80 bases which overlaps the leader sequence of the repressor gene for about 30 bases, and coordinate transcription of genes cox and B with a termination signal after the B gene. In addition, the data provide amino acid sequences for the Cox and B proteins of 91 and 166 residues, respectively and reveal a hitherto undetected coding sequence between genes cox and B that has the potential to produce a very basic polypeptide of 56 residues. Slight structural similarities between the P2 Cox protein and the analogous Xis protein of phage lambda were noted and the P2 B gene product was compared with proteins that interact with the DnaB protein of E. coli.

Immunity repressor of bacteriophage P2. Identification and DNA-binding activity

The product of gene C of the temperate bacteriophage P2, the immunity repressor, can be detected as a unique band eluting from phosphocellulose columns at 0.12 M-potassium phosphate when differentially labelled with a radioactive amino acid: the band is absent when phages that either have lost gene C through deletion or carry a suppressor-sensitive mutation in the gene are used. The repressor in its monomeric form is about 11,000 in molecular weight. At near physiological salt concentrations, the form predominantly recovered is the dimer. In filter-binding assays, the partially purified repressor binds wild-type P2 DNA strongly. It does not bind DNA of P2 vir94, a deletion that removes all the genetic elements involved in the regulation of lysogeny; it also does not bind, or binds inefficiently, DNA of P2 vir3, a mutation in the operator that controls the early replicative functions of P2. At the concentrations employed, the dimer is the active form in binding. The P2 repressor clearly differs in several features from the well-studied immunity repressor of bacteriophage lambda.

Properties and products of the cloned int gene of bacteriophage P2

Fragments of DNA of the temperate phage P2, generated by treatment with the restriction enzyme PstI, have been cloned into the plasmid pBR322. One such fragment, which has its endpoints within phage genes T and C, carries the structural P2 int gene as well as its promoter and the phage att site. When introduced into a suitable bacterial host, the cloned fragment mediates the integration and excision of int- mutants of P2 and recombination within the phage att site in mixed infection. All these activities are independent of the orientation of the fragment within the plasmid. When introduced into minicells, the fragment produces, in addition to the products of genes D and U, a protein of 35-37,000 daltons identified as the int protein. A study of the map location of two amber int mutants, together with the sizes of the polypeptides they produce, indicates that the P2 int gene is transcribed from right to left on the P2 map, i.e. starting near gene C and proceeding toward att.

In vitro activation of bacteriophage P2 late gene expression by extracts from phage P4-infected cells

We have used a cell-free, DNA-dependent protein-synthesizing system to study the stimulation of phage P2 late gene expression by satellite phage P4. An activity is present in extracts prepared from P4-infected cells, which, when added to the in vitro system with P2 DNA template, stimulates the synthesis of a number of P2 proteins. These stimulated proteins include the major P2 capsid protein (N gene product) and a major component of the P2 phage tail (FII gene product). Extracts prepared from P4-infected cells are also able to stimulate the synthesis from P4 DNA of two low-molecular-weight proteins (18,500 and 17,000 Mr). The stimulating activity has no effect on the synthesis of proteins from lambda plac5 template. Extracts prepared from cells infected with P4 alpha amber mutants lack this stimulating activity.

Bacteriophage P2 late promoters. Transcription initiation sites for two late mRNAs

Divergent transcription of two of the bacteriophage P2 late mRNAs, encoding genes QP and ONMLKRS, is initiated from opposite strands of the DNA in a region near the left end of the P2 genome. The first gene in each of these transcription units (P and O) has been located in the nucleotide sequence by amino-terminal sequence analysis of the P gene product and by DNA sequence determination of the single nucleotide changes in two O amber mutants. The 5' ends of the P and O gene mRNAs are separated by 109 nucleotide pairs in the DNA template. The locations of these 5' termini were determined by protection of end-labeled restriction fragments in RNA-DNA hybrids from digestion with nuclease S1. Sequence analysis of mRNA that had been labeled at the 5' end with [alpha-32P]GTP and guanylyl transferase confirmed that these termini resulted from initiation of transcription. The DNA sequences preceding the O and P transcription starts have poor homologies to the bacterial promoter consensus sequences at -10 and -35, consistent with the apparent requirement for phage-encoded proteins in the regulation of P2 late gene expression. The O and P promoter regions also have no detectable homology to each other in the -10 or -35 regions, and are unusually G + C-rich. There are, however, blocks of sequence homology within the transcribed region of each of these two late operons near the 5' end. Satellite phage P4 induces P2 late gene expression without the usual requirement for P2 DNA replication. The 5' ends of the P2 P and O gene transcripts are the same during P4 "transactivation" as during normal P2 late gene expression. Thus the regulation of P2 late gene expression by P4 does not involve a change in the site for initiation of transcription.

The transient inability of the conjugating female cell to host 186 infection explains the absence of zygotic induction for 186

In an Hfr(186) X F- cross, the 186 prophage on the incoming male chromosome is not induced, despite the fact that prophage 186 can be induced by other means (W. H. Woods and J.B. Egan, J Virol. 14:1349-1356, 1974). We show here that the conjugating female is temporarily inhibitory to infection by 186, and this delay, we postulate, enables cI repression to be reestablished before the female cell recovers its 186 sensitivity.

Further physical characterization of deletion and substitution mutants affecting the control of lysogeny in bacteriophage P2

A deletion of phage P2, del6 (L.E. Bertani, 1980), thought to remove the structural gene int, and a deletion/substitution, vir94, thought to remove genes int, C and cox, were mapped by electron microscopy, using the heteroduplex technique. Four independent deletion/substitution mutations, all affecting the regulatory region of P2, were compared in all possible combinations with the same technique: two showed sequence homology in their substitution DNA. The results confirm the model proposed for the origin of these mutants, analogous to that for the origin of transducing variants in phage lambda, but suggest in first approximation that the exchange between the P2 DNA and the chromosome of the host bacterium may occur at several different bacterial sites. A map of the regulatory region of P2, based on all data available from the study of deletions and insertions, is presented.

Cloning of the immunity repressor determinant of bacteriophage P2 in the pBR322 plasmid

Through in vitro recombination of DNA restriction fragments, we have constructed a plasmid, which expressed in vivo the immunity repressor gene (C) of bacteriophage P2. A bacterial strain carrying such a plasmid showed a high level of P2 specific immunity. It was lysogenized normally by an infecting P2, but the frequency of spontaneous phage production was reduced about 10(4) fold as compared to a normal P2 lysogen. Satellite phage P4, known to derepress P2 lysogens, was unable to derepress the plasmid-carrying lysogenic strain so to allow growth of coinfecting P2. Phage P4 multiplied on the plasmid-carrying, P2-lysogenic strain, but due to a prolonged latent period failed to form plaques on this strain.