Defective particle assembly in wild type P2 bacteriophage and its correction by the lg mutation

The transcriptional switch of bacteriophage WPhi, a P2-related but heteroimmune coliphage

Phage WPhi is a member of the nonlambdoid P2 family of temperate phages. The DNA sequence of the whole early-control region and the int and attP region of phage WPhi has been determined. The phage integration site was located at 88.6 min of the Escherichia coli K-12 map, where a 47-nucleotide sequence was found to be identical in the host and phage genomes. The WPhi Int protein belongs to the Int family of site-specific recombinases, and it seems to have the same arm binding recognition sequence as P2 Int, but the core sequence differs. The transcriptional switch contains two face-to-face promoters, Pe and Pc, and two repressors, C and Cox, controlling Pe and Pc, respectively. The early Pe promoter was found to be much stronger than the Pc promoter. Furthermore, the Pe transcript was shown to interfere with Pc transcription. By site-directed mutagenesis, the binding site of the immunity repressor was located to two direct repeats spanning the Pe promoter. A point mutation in one or the other repeat does not affect repression by C, but when it is included in both, C has no effect on the Pe promoter. The Cox repressor efficiently blocks expression from the Pc promoter, but its DNA recognition sequence was not evident. Most members of the P2 family of phages are able to function as helpers for satellite phage P4, which lacks genes encoding structural proteins and packaging and lysis functions. In this work it is shown that P4 E, known to function as an antirepressor by binding to P2 C, also turns the transcriptional switch of WPhi from the lysogenic to the lytic mode. However, in contrast to P2 Cox, WPhi Cox is unable to activate the P4 Pll promoter.

The E protein of satellite phage P4 acts as an anti-repressor by binding to the C protein of helper phage P2

Temperate phage P2 has the capacity to function as a helper for the defective, unrelated, satellite phage P4. In the absence of a helper, P4 can either lysogenize its host or establish itself as a plasmid. For lytic growth, P4 requires the structural genes, packaging and lysis functions of the helper. P4 can get access to the late genes of prophage P2 by derepression, which is mediated by the P4 E protein. E has been hypothesized to function as an anti-repressor. To locate possible epitopes interacting with E, an epitope display library was screened against E, and the most frequent sequence found had some identities to a region within P2 C. Using the yeast two-hybrid system, a clear activation of a reporter gene was found, strongly supporting an interaction between E and C. The P2 C repressor is believed to act as a dimer, which is confirmed in this work using in vivo dimerization studies. The E protein was also found to form dimers in vivo. The E protein only affects dimerization of C marginally, but the presence of E enhances multimeric forms of C. Furthermore, binding of the C protein to its operator is inhibited by E in vitro, indicating that the anti-repressor function of E is mediated by the formation of multimeric complexes of E and C that interfere with the binding of C to its operator.

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.

Studies of bacteriophage P2 DNA replication: localization of the cleavage site of the A protein

Bacteriophage P2 replicates via a modified rolling circle-type of mechanism, where the P2 A protein acts as an initiator of the replication by inducing a single-stranded cut at the origin of replication (ori). The exact location of the cut induced by the A protein in vivo is determined in this report by: (i) restriction analysis; (ii) DNA sequence analysis; and (iii) primer extensions. It is located 89.2% from the left end of the P2 genome, which is within the coding part of the A gene, in a region devoid of secondary structures. The A gene has been cloned into an expression vector, and the A protein has been purified. The purified A protein does not bind to double-stranded ori containing DNA, but it cleaves single-stranded ori containing DNA, which indicates that a special DNA structure and/or protein is required to make the ori accessible for the A protein.

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.

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.

DNA sequences of the tail fiber genes of bacteriophage P2: evidence for horizontal transfer of tail fiber genes among unrelated bacteriophages

We have determined the DNA sequence of the bacteriophage P2 tail genes G and H, which code for polypeptides of 175 and 669 residues, respectively. Gene H probably codes for the distal part of the P2 tail fiber, since the deduced sequence of its product contains regions similar to tail fiber proteins from phages Mu, P1, lambda, K3, and T2. The similarities of the carboxy-terminal portions of the P2, Mu, ann P1 tail fiber proteins may explain the observation that these phages in general have the same host range. The P2 H gene product is similar to the products of both lambda open reading frame (ORF) 401 (stf, side tail fiber) and its downstream ORF, ORF 314. If 1 bp is inserted near the end of ORF 401, this reading frame becomes fused with ORF 314, creating an ORF that may represent the complete stf gene that encodes a 774-amino-acid-long side tail fiber protein. Thus, a frameshift mutation seems to be present in the common laboratory strain of lambda. Gene G of P2 probably codes for a protein required for assembly of the tail fibers of the virion. The entire G gene product is very similar to the products of genes U and U' of phage Mu; a region of these proteins is also found in the tail fiber assembly proteins of phages TuIa, TuIb, T4, and lambda. The similarities in the tail fiber genes of phages of different families provide evidence that illegitimate recombination occurs at previously unappreciated levels and that phages are taking advantage of the gene pool available to them to alter their host ranges under selective pressures.

Nucleotide sequence of the DNA packaging and capsid synthesis genes of bacteriophage P2

Overlapping DNA fragments containing the DNA packaging and capsid synthesis gene region of bacteriophage P2 were cloned and sequenced. In this report we present the complete nucleotide sequence of this 6550 bp region. Each of six open reading frames found in the interval was assigned to one of the essential genes (Q, P, O, N, M and L) by correlating genetic, physical and mutational data with DNA and protein sequence information. Polypeptides predicted were: a capsid completion protein, gpL; the major capsid precursor, gpN; the presumed capsid scaffolding protein; gpO; the ATPase and proposed endonuclease subunits of terminase, gpP and gpM, respectively; and a candidate for the portal protein, gpQ. These gene and protein sequences exhibited no homology to analogous genes or proteins of other bacteriophages. Expression of gene Q in E. coli from a plasmid caused production of a Mr 39,000 Da protein that restored Qam34 growth. This sequence analysis found only genes previously known from analysis of conditional-lethal mutations. No new capsid genes were found.

Morphopoietic switch mutations of bacteriophage P2

During the growth of bacteriophage P4, for which the genome of bacteriophage P2 is needed as helper, the decision whether to make large, P2 size, heads or small, P4 size, heads depends on the size-directing function of P4's sid gene and on P2's "sid responsiveness." P2 mutants (=P2 sir) impaired in their response to P4's sid function are readily obtainable as one class of P2 plaque formers selected on certain P4 cl plasmid lysogens. We describe nine P2 sir mutants of independent origin. For eight we could assign their sir mutation to P2 gene N, which encodes the major capsid protein. DNA sequencing indicated an open reading frame of 357 codons for gene N and showed these sir mutations to affect only four codons within a 38-codon segment in the middle of N. Seven mutations are missense mutations (three of them identical); one is a deletion of one codon. There seems to be a correlation between the phenotypic "strength" of the sir mutations and the type of amino acid replacement by missense mutations. Although the weakest mutation, sir7, could not yet be assigned to any P2 gene, it appears clear from this work that P2's N gene product is the major (or only) target of P4's Sid gene function.

Bacteriophage P2 ogr and P4 delta genes act independently and are essential for P4 multiplication

Satellite bacteriophage P4 requires the products of the late genes of a helper phage such as P2 for lytic growth. Expression of the P2 late genes is positively regulated by the P2 ogr gene in a process requiring P2 DNA replication. Transactivation of P2 late gene expression by P4 requires the P4 delta gene product and works even in the absence of P2 DNA replication. We have made null mutants of the P2 ogr and P4 delta genes. In the absence of the P4 delta gene product, P4 multiplication required both the P2 ogr protein and P2 DNA replication. In the absence of the P2 ogr gene product, P4 multiplication required the P4 delta protein. In complementation experiments, we found that the P2 ogr protein was made in the absence of P2 DNA replication but could not function unless P2 DNA replicated. We produced P4 delta protein from a plasmid and found that it complemented the null P4 delta and P2 ogr mutants.

A mutation of the transactivation gene of satellite bacteriophage P4 that suppresses the rpoA109 mutation of Escherichia coli

Satellite bacteriophage P4 requires the products of the late genes of a helper such as P2 in order to grow lytically. The Escherichia coli rpoA109 mutation, which alters the alpha subunit of RNA polymerase, prevents transcription of the late genes of bacteriophage P2. Suppressor mutations that define the P2 ogr gene overcome this block. We found that P4 lytic growth using a P2 ogr+ prophage helper was prevented by the rpoA109 mutation but that this block was overcome when the P2 helper carried the suppressor mutation in the ogr gene. Furthermore, we isolated and characterized four independent mutations in P4, called org, that suppress the E. coli rpoA109 mutation by allowing P4 lytic growth using a P2 ogr+ helper. DNA sequence analysis revealed that the four independent org mutations are identical and that they occur in the P4 delta gene, which codes for a factor that positively regulates the transcription of the P2 and P4 late genes. delta is predicted to code for a basic 166-amino-acid residue protein. Each 83-residue half of the predicted delta gene product is similar to the predicted 72-residue proteins encoded by the ogr gene of P2 and the B gene of phage 186.

Regulation of icosahedral virion capsid size by the in vivo activity of a cloned gene product

Determination of icosahedral virion capsid size can be directly studied during helper-dependent lytic development of satellite P4 because the assembly pathway specified by the P2 helper virus is altered to yield smaller-sized capsids. Size determination (sid) mutations identify a P4-encoded function regulating this process. To determine whether the sid gene product is necessary and sufficient to redirect the assembly pathway, we (i) cloned the sid structural gene in a plasmid vector (pMA30) under the control of an inducible promoter and (ii) constructed a packaging substrate (pMA1), a P4 genome-sized plasmid containing only that region of P4, the cos site, necessary for encapsidation. Superinfection by P2 of a host carrying pMA30 under induced conditions resulted in a shift from large to small capsid production. P2 superinfection of a host carrying the cos plasmid pMA1 plus pMA30 under induced conditions yielded pMA1-transducing particles of P4 capsid size. These cloning-based analyses directly demonstrate that sid protein is the only P4 gene product required for small-capsid size determination. In the absence of the P2 O gene product no capsids of any size are assembled during solo infection by P2. Nevertheless, P2 Oam mutant superinfection of a host carrying pMA1 and pMA30 under induced conditions yielded small P4-sized transducing particles. We therefore propose that (i) the sid gene product competes with the O gene product to determine the assembly of small vs. large capsid sizes and (ii) both gene products probably function as temporary scaffolding proteins.

A phasmid shuttle vector for the cloning of complex operons in Salmonella

Phasmid (phage plasmid hybrid) P4 vir1 can be propagated in Escherichia coli as a helper-dependent lytic phage, as a plasmid, or as a prophage. On the basis of an understanding of these modes of propagation, derivatives of P4 have been constructed for use as cloning vectors. In this report we demonstrate that phasmid P4 (i) will propagate as a helper-dependent lytic phage and as a plasmid in Salmonella spp. and (ii) can be used as a high efficiency phage shuttle vector for the reversible transfer of cloned genes between Salmonella spp. and E. coli. For both E. coli and Salmonella spp., P4 phage-mediated gene transfer proved to be only 10-fold lower than plaquing efficiency. For the case of Salmonella spp., this frequency is ca. 10(4)-fold more efficient than is typically found for the transformation of DNA molecules. The usefulness of this cloning vector system for analyses of pathogenic virulence factors is demonstrated by the cloning and expression of both the P pilus adhesin operon and the hemolysin operon of uropathogenic E. coli.

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.

Organization and expression of the satellite bacteriophage P4 late gene cluster

The satellite bacteriophage P4 genes for capsid size determination (sid), transactivation (delta), and polarity suppression (psu) are cotranscribed at late times after infection from a single P4 late promoter (Psid) that lies to the left of the sid gene. While the -10 region of this promoter is similar to the consensus sequence for Escherichia coli RNA polymerase, the -35 region shares no homology with known classes of E. coli promoters. The -10 and -35 regions of Psid share no homology with the late gene promoters of helper phage P2. Nonetheless, P4 late transcription is stimulated by coinfecting P2, as well as by P2 prophage. This stimulation depends on the P2 encoded transcription factor ogr; transcription from Psid is stimulated following the induction of the P2 ogr gene carried on a plasmid. P4 late transcription in the absence of P2 requires the P4 delta product, which is partially homologous to the P2 ogr gene product. DNA sequence analysis shows that the psu gene codes for a protein of Mr = 21,314 that is unrelated to the antitermination gene products of the lambdoid phages.

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.

Phasmid P4: manipulation of plasmid copy number and induction from the integrated state

"Phasmid" P4 is unusual in that it is capable of (i) temperate, (ii) lytic, helper-dependent, and (iii) plasmid modes of propagation. In this report we characterize most of the known P4 genetic functions as to their essential or nonessential roles in the stable maintenance of plasmid P4 vir1 (pP4 vir1 (pP4 vir1). We also identify growth conditions that can be used to stably maintain pP4 vir1 at any one of several different copy number levels (n = 1 to 3, n = 10 to 15, or n = 30 to 40). Analyses of a temperature-sensitive alpha derivative of pP4 vir1 show that shifting the temperature from 37 to 42 degrees C allows this mutant to maintain an integrated copy of the plasmid, whereas replication of free copies is repressed because of the nonpermissive condition for their DNA synthesis. Conversely, a shift from 42 to 37 degrees C can be used to reinstate plasmid propagation. The utility of the inducible states of pP4 vir1 is discussed with respect to its attributes as a vector with the potential for cloning inserts of DNA up to 33,000 base pairs in a wide range of bacterial hosts.

Propagation of satellite phage P4 as a plasmid

Satellite phage P4 has two known options for propagation. In its lytic cycle, its regulatory functions can act in trans to alter the actions of a helper virus (P2), which then provides necessary gene products, including capsid proteins. P4 also can be propagated in the absence of a helper as a prophage, with distinct sites for integration within the Escherichia coli chromosome. We determined that a single spontaneous mutation (vir1) of phage P4 allows a third mode of propagation: as a plasmid (along with continued integration into the host chromosome). Hence, the P4 regulatory element is capable of (i) temperate; (ii) lytic, helper-dependent; and (iii) plasmid modes of development. These findings emphasize the close relationship between defective viruses and plasmids.

Knotted DNA from bacteriophage capsids

The majority of the DNA prepared from tailless capsids of bacteriophage P2 by the phenol extraction procedure consists of monomeric rings that have their cohesive ends joined. Electron microscopic and ultracentrifugal studies indicate that these molecules have a complex structure that is topologically knotted; they have a more compact appearance and a higher sedimentation coefficient when compared with regular nicked P2 DNA rings. Linearization of these rings by thermal dissociation or repair of the cohesive ends by DNA polymerase I in the presence of all four deoxynucleoside triphosphates gives molecules that are indistinguishable from normal P2 DNA that has been similarly treated. The knotted nature of the majority of P2 head DNA is further supported by analyzing the products when these molecules are treated with ligase and the ligase-treated molecules are subsequently nicked randomly with DNase I. The data are consistent with the notion that, if such a molecule is first converted to a form that contains only one single-chain scission per molecule, strand separation gives a linear strand and a highly knotted single-stranded ring. The results suggest that the DNA packaged in tailless P2 capsids is arranged in a way that leads to the formation of a complex knot when the ends join. In an intact phage particle, the anchoring of one terminus of the DNA to the head-proximal end of the tail [Chattoraj, D. K. & Inman, R. B. (1974) J. Mol. Biol. 87, 11-22] presumably diminishes or prevents this kind of joining. The novel knotted DNA can be used to assay type II DNA topoisomerases that break and rejoin DNA in a double-stranded fashion.

Recombinant P4 bacteriophages propagate as viable lytic phages or as autonomous plasmids in Klebsiella pneumoniae

We demonstrate the use of bacteriophage P4 as a molecular cloning vector in Klebsiella pneumoniae. A hybrid P4 phage, constructed in vitro, that contains a K. pneumoniae hisDG DNA fragment can be propagated either as a lytic viable specialized transducing phage or as an autonomous, self-replicating plasmid. Hybrid P4 genomes existing as plasmids can be readily converted into non-defective P4-hybrid phage particles by superinfection with helper phage P2. Infection of a K. pneumoniae hisD non-P2 lysogen with P4-hisD hybrid phage results in approximately 90% of the infected cells becoming stably transduced to HisD+. Because P4 interferes with P2 growth, high titre stocks of P4 hybrid phages are relatively free (less than or equal to 10(-6) of P2 contamination. The hisG gene product was detected in ultraviolet light irradiated host cells infected by the P4-hisDG hybrid phage. A mutant of P4 (P4sid1) that directs the packaging of P4 DNA into P2 sized capsids should permit the construction of hybrid phages carrying 26 kilobase inserts.

Recombination in bacteriophage P2: recA dependent enhancement by ultraviolet irradiation and by transfection with mixed DNA dimers

Bacteriophage P2 is known for its exceptionally low rate of spontaneous (non-integrative) recombination, which however may be stimulated by ultraviolet irradiation of the phage. We show here that ligated dimers, made in vitro from mixtures of DNAs of two P2 mutants, upon transfection of lysozyme-spheroplasts give origin to recombinants at high frequency. While spontaneous P2 recombination occurs independently of the main recombination pathway of the bacteria, P2 recombinant formation following either ultraviolet irradiation or transfection with DNA dimers requires at least some element of such a pathway, since it is absent or greatly reduced in recA- bacteria or spheroplasts. It would seen that, in the course of its lytic development, P2 deploys a mechanism that inhibits the main recombination pathway of the host cell, or assumes DNA configurations refractory to it.

Tandem pentuplication of a DNA segment in a derivative of bacteriophage P2: its use in the study of the mechanism of DNA annealing

From a tandem duplication mutant of phage P2, triplication, quadruplication and pentuplication forms were derived. They were recognized by decreased virion heat stability resulting from the increase in DNA content, and were confirmed by electron microscope heteroduplex mapping. These forms of partially repeated DNA are quite stable in P2 because of the low level of recombination typical of this phage. Under conditions normally employed for full DNA renaturation, these high order repeat chromosomes gave often incomplete renaturation over the repeated segments. Based on current models for DNA renaturation, several predictions were made and tested. The results, although not quantitatively exhaustive, indicated that base pairing proceeding from a nucleation site was sufficiently slow to allow a second nucleation to occur with a fair probability over a length of a few thousand base pairs.