Cloning of a functional replication origin of phage G4 into the genome of phage M13.

A chimeric single-stranded DNA phage, M13Gori1, has been formed as a result of the in vitro insertion of a 2216 base-pair HaeII fragment of bacteriophage G4 replicative form DNA into the replicative form DNA of bacteriophage M13. The inserted G4 DNA carries the dnaG-dependent origin for G4 complementary strand synthesis. The cloned G4 origin functions both in vivo and in vitro in the conversion of M13Gori1 single-stranded viral DNA to the duplex replicative form by a rifampicin-resistant mechanism. Labelling of the 3′ terminus of the single discontinuity in M13Gori1 replicative form II molecules synthesized in crude extracts and subsequent restriction analysis indicate that M13Gori1 complementary strand synthesis can be initiated at either the RNA polymeraseprimed M13 origin or at the dnaG-primed G4 origin. The M13Gori1 complementary strand initiated at the G4 origin terminates in the vicinity of the G4 origin after progressing around the circular template and traversing the M13 origin region, indicating the absence of a specific nucleotide sequence in the M13 origin for termination of the newly formed complementary strand. The ability of this chimeric phage to utilize the cloned G4 origin in vivo even in the presence of the presumed M13 pilot protein (gene 3 protein) indicate that the nucleotide sequence of the replication origin is sufficient for recognizing the appropriate initiation enzymes. Since decapsidation of M13 is tightly coupled to replicative form formation, initiation at the G4 origin, located over 1000 nucleotides from the M13 complementary strand origin, indicates that widely separated nucleotide sequences contained in the filamentous virion can be exposed to the cell cytoplasm during eclipse.     

Adsorption protein of bacteriophage fl: solubilization in deoxycholate and localization in the fl virion.

A complex containing the minor coat protein or adsorptionprotein (A protein) of bacteriophage fl has been solubilized from the fl virion, using the detergent deoxycholate. This complex was resolved from the fl DNA and from the fl major coat protein, or B protein, by gel filtration in the presence of deoxycholate. The A protein complex migrated as a single band on sodium dodecyl sulfate-urea-polyacrylamide gels corresponding to a molecular weight of 60 000. Analysis of the amino acid composition and amino terminal residues of this preparation indicates that the preparation contains a 20% contamination of additional protein species. Antibody against purified fd A protein is cross-reactive with deoxycholate-purified fl A protein and with fl phage. Electron microscopic observation of negatively stained complexes of fl phage with this anti-fd A protein antibody and ferritin conjugated goat anti-rabbit IgG antibody revealed phages with ferritin particles at their termini or complexes of two or more phages joined together at one end by ferritin, indicating that the complex of A protein molecules is located at one end of the filamentous fl virion.     

Insertion of the Tn3 transposon into the genome of the single-stranded DNA phage M13.

The transposable genetic element Tn3, which carries an ampicillin (Ap) resistance determinant, has been translocated from a ColE1-Apr plasmid, RSF2124, to the genome of the filamentous single-stranded DNA phage M13. The site orientation of the inserted element has been determined for one such phage, M13::Tn3-15. The insertion is within the intergenic space separating genes 2 and 4 and containing both the viral strand and complementary strand origins. The lengths of both the filamentous phage and the duplex replicative form (RF) DNA are 1.7--1.8 times those of M13 phage and replicative form DNA. Both plaque formation and transduction of sensitive cells to ampicillin resistance by M13::Tn3-15 are sensitive to purified antibodies to the M13 major coat protein.     

A specific DNA orientation in the filamentous bacteriophage fd as probed by psoralen crosslinking and electron microscopy.

The molecular structure of the single-stranded fd DNA inside its filamentous virion has been stabilized by the photochemical reaction with a psoralen derivative and examined in the electron microscope. The results support the notion that the 6389 nucleotide-long DNA molecule is folded back on itself inside the 1 μm-long protein coat. At one end of the virion, there exists a DNA hairpin region 200±50 base-pairs long. This “end hairpin” is mapped on the fd genome to the site of the replication origin. The most stable in vitro hairpin of fd DNA has been mapped previously to this same site. This unique duplex region of fd DNA may play an important role in the formation of specific protein-DNA complexes which are crucial to stages of the fd life cycle: the adsorption of the phage to the bacteria, the initiation of replication of the single-stranded DNA, and the assembly of newly synthesized DNA strands into the filamentous virions.     

Homologous pairing and topological linkage of DNA molecules by combined action of E. coli recA protein and topoisomerase I

E. coil RecA protein and topolsomerase I, acting on superhelical DNA and circular single strands in the presence of ATP and Mg²⁺, topologically link single-stranded molecules to one another, and single-stranded molecules to duplex DNA. When super-helical DNA is relaxed by prior incubation with topoisomerase, it is a poor substrate for catenation. Extensive homology stimulates the catenation of circular single-stranded DNA and superhelical DNA, whereas little reaction occurs between these forms of the closely related DNAs of phages φX174 and G4, indicating that, in conjunction with topoisomerase I, RecA protein can discriminate perfect or nearly perfect homology from a high degree of relatedness. Circular single-stranded G4 DNA reacts with superhelical DNA of a chimeric phage, M13Goril, to form catenanes, at least half of which survive heating at 80°C following restriction cleavage in the M13 region, but few of which survive following restriction cleavage in the G4 region. Electron microscopic examination of catenated molecules cleaved in the M13 region reveals that in most cases the single-stranded G4 DNA is joined to the linear duplex M13(G4) DNA in the homologous G4 region. The junction frequently has the appearance of a D loop, with an extent equivalent to 100 or more bp. We conclude that a significant fraction of catenanes were hemicatenanes, in which the single-stranded circle was topologically linked, probably by multiple turns, to its complementary strand in the duplex DNA. These observations support the previous conclusion that RecA protein can pair a single strand with its complementary strand in duplex DNA in a side-by-side fashion without a free end in any of the three strands.     

In vivo methylation of replicating bacteriophage phi chi174 DNA

The pattern of DNA methylation during the infection of Escherichia coli C cells with bacteriophage φX174, has been studied. In vivo methylated DNA was isolated and analyzed using the following techniques: velocity sedimentation through neutral and alkaline sucrose gradients, isopycnic analysis, chromatography on benzoylated DBAE-cellulose columns and specific enzymatic digestion. All these analytical methods indicated that the DNA molecules that are methylated during the process of phage φX DNA replication are the replicating intermediates composed of a circular complementary strand and a viral strand larger than one genome length. It is concluded that methylation occurs on the nascent DNA strand of the replicating intermediates involved in the synthesis of progeny single-stranded DNA.     

Interference between M13 and oriM13 plasmids is mediated by a replication enhancer sequence near the viral strand origin

The origin of replication for the viral strand of bacteriophage M13 DNA is contained within a 507 base-pair intergenic region of the phage chromosome. The viral strand origin is defined as the specific site at which the M13 gene II protein nicks the duplex replicative form of M13 DNA to initiate rolling-circle synthesis of progeny viral DNA. Using in vitro techniques we have constructed deletion mutations in M13 DNA at the unique AvaI site which is located 45 nucleotides away on the 3' side of the gene II protein nicking site. This deletion analysis has identified a sequence near the viral strand origin that is required for efficient replication of the M13 genome. We refer to this part of the intergenic region as a "replication enhancer" sequence. We have also studied the function of this sequence in chimeric pBR322-M13 plasmids and found that plasmids carrying both the viral strand origin and the replication enhancer sequence interfere with M13 phage replication. Based upon these findings we propose a model for the mechanism of action of the replication enhancer sequence involving binding of the M13 gene II protein.     

Structure and function of the major tail protein of bacteriophage lambda: Mutants having small major tail protein molecules in their virion

Viable mutants of bacteriophage lambda having small major tail protein molecules in their virion have been isolated as pseudo-revertants of a defective prophage mutant (defK244) in gene V, which codes for the major tail protein. According to deletion mapping, the defK244 mutation is located near the translation terminal of gene V, whereas some mappable reversion mutations leading to small major tail protein molecules map upstream to defK244 but still downstream to all the amber mutations tested. This suggests (if not proves) that the removable part is located at or near the carboxyl terminal of the major tail protein. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis and buoyant density measurements of the mutant phage particles show that as much as one-third of the major tail protein molecule can be removed without losing its capacity to maintain the total shape and infectivity of the phage particles. In the three-dimensional structure of the tail the removable part of the molecule exists as a protrusion at the outer part of the tail tube according to electron microscopy and hydrodynamic calculations based on sedimentation velocity experiments.     

Replication origin of the Bacillus subtilis chromosome determined by hybridization of the first-replicating DNA with cloned fragments from the replication origin region of the chromosome

The replication origin (ori) on the Bacillus subtilis genome was determined by the hybridization between the first-replicating DNA region and the cloned fragments from the ori region. The first-replicating DNA region was labeled specifically by [³H]thymidine in the presence of an inhibitor for DNA polymerase during a synchronous initiation of the chromosomal replication by germinating spores starved for thymine, and isolated by a sucrose density gradient centrifugation. Most of the labeled DNA molecules are small in size (up to 1000 bases long). The 45-kb ori region was cloned first in a λ Charon vector and then subcloned in pBR vectors. Restriction fragments from these cloned DNAs were purified by electrophoresis in agarose gels.

Only one region within the 45-kb ori region shows strong hybridization with the first-replicating DNA. Restriction fragments from this region were cloned in a phage M13 vector and separated into complementary strands. Hybridization of the labeled DNA with these cloned single-stranded fragments revealed that one site of the ori is located in each strand and they are some 2-kb apart from each other. Replication starts from these sites and proceeds inwards to pass each other.     

A bacterial gene, fip, required for filamentous bacteriophage fl assembly.

An Escherichia coli mutant which does not support the growth of filamentous bacteriophage fl allows phage fl DNA synthesis and gene expression in mutant cells, but progeny particles are not assembled. The mutant cells have no other obvious phenotype. On the basis of experiments with phage containing nonlethal gene I mutations and with mutant fl selected for the ability to grow on mutant bacteria, we propose an interaction between the morphogenetic function encoded by gene I of the phage and the bacterial function altered in this mutant. The bacterial mutation defines a new gene, fip (for filamentous phage production), located near 84.2 min on the E coli chromosome.     

Mike, a chimeric filamentous phage designed for the separate production of either DNA strand of pKUN vector plasmids by F+ cells

To enable the separate production of either DNA strand of recombinant pKUN plasmids [Peeters et al., Gene 41 (1986) 39-46] by conjugation-deficient F+ cells a chimeric Ff/IKe filamentous phage, Mike, has been constructed. Its genome contains the functions required for asymmetric DNA replication from the N-plasmid specific filamentous phage IKe, and the functions required for host cell penetration, single-stranded DNA accumulation, phage assembly, and secretion from the F-plasmid specific filamentous phage Ff (i.e. M13, fl, or fd).     

Construction of a microphage variant of filamentous bacteriophage.

The intergenic region in the genome of the Ff class of filamentous phage (comprising strains fl, fd and M13) genome constitutes 8% of the viral genome, and has essential functions in DNA replication and phage morphogenesis. The functional domains of this region may be inserted into separate sites of a plasmid to function independently. Here, we demonstrate the construction of a plasmid containing, sequentially, the origin of (+)-strand synthesis, the packaging signal and a terminator of (+)-strand synthesis. When host cells harboring this plasmid (pLS7) are infected with helper phage they produce a microphage particle containing all the structural elements of the mature, native phage. The microphage is 65 A in diameter and about 500 A long. It contains a 221-base single-stranded circle of DNA coated by about 95 copies of the major coat protein (gene 8 protein).     

Holliday junction affinity of the base excision repair factor Endo III contributes to cholera toxin phage integration

Toxigenic conversion of Vibrio cholerae bacteria results from the integration of a filamentous phage, CTXϕ. Integration is driven by the bacterial Xer recombinases, which catalyse the exchange of a single pair of strands between the phage single-stranded DNA and the host double-stranded DNA genomes; replication is thought to convert the resulting pseudo-Holliday junction (HJ) intermediate into the final recombination product. The natural tendency of the Xer recombinases to recycle HJ intermediates back into substrate should thwart this integration strategy, which prompted a search for additional co-factors aiding directionality of the process. Here, we show that Endo III, a ubiquitous base excision repair enzyme, facilitates CTXϕ-integration in vivo. In vitro, we show that it prevents futile Xer recombination cycles by impeding new rounds of strand exchanges once the pseudo-HJ is formed. We further demonstrate that this activity relies on the unexpected ability of Endo III to bind to HJs even in the absence of the recombinases. These results explain how tandem copies of the phage genome can be created, which is crucial for subsequent virion production.     

Genetic Expression in Heterozygous Replicative Form Molecules of phiX174

Heterozygous replicative form molecules of bacteriophage X174 deoxyribonucleic acid (DNA) have been constructed in vitro. These are composed of viral strands extracted from purified preparations of phage bearing ts mutations and complementary strands of either half length or full length synthesized with purified DNA polymerase, in vitro, on DNA from am3 phage. In infections with such heterozygous DNA, involving mutations in each of four different cistrons, phage with the genotype of the complementary strand comprised 1 to 20% of the total phage produced by a spheroplast population. From single-burst analysis of the progeny from DNA heterozygous in one cistron (B), it appears that those phage with the genotype of the complementary strand arise as major components in a small proportion of the infected cells rather than comprising a minor component in most cells. The implications of such a pattern of expression are discussed with respect to mechanisms of phage DNA synthesis.     

DNA sequence analysis of the defective interfering particles of bacteriophage f1.

Restriction mapping and nucleotide sequence analysis of several defective, interfering particles of bacteriophage f1 are described. These particles contain the nucleotide sequences corresponding to the carboxyl terminus of gene IV and the amino-terminus of gene II and the intergenic space between them. Tandem duplication of a portion of this intergenic space generates defective particles with novel nucleotide sequences not found in wild-type f1. This duplication is shown to contain the origin of complementary strand synthesis. Our results suggest that the duplication occurs at the site of gene II protein action, i.e. the origin of viral strand synthesis. A model is presented for the generation of these duplications in defective particles.     

Nucleotide sequence of the genome of the filamentous bacteriophage I2-2: Module evolution of the filamentous phage genome

Summary The nucleotide sequence of the circular single-stranded genome of the filamentous Escherichia coli phage I2-2 has been determined and compared with those of the filamentous E. coli phages Ff(M13, fl, or fd) and IKe. The I2-2 DNA sequence comprises 6744 nucleotides; 139 nucleotides less than that of the N- and I2-plasmid-specific phage IKe, and 337 (336) nucleotides more than that of the F-plasmid-specific phage Ff. Nucleotide sequence comparisons have indicated that I2-2, IKe, and Ff have a similar genetic organization, and that the genomes of I2-2 and IKe are evolutionarily more closely related than those of I2-2 and Ff. The studies have further demonstrated that the I2-2 genome is a composite replicon, composed of only two-thirds of the ancestral genome of IKe. Only a contiguous I2-2 DNA sequence of 4615 nucleotides encompassing not only the coat protein and phage assembly genes, but also the signal required for efficient phage morphogenesis, was found to be significantly homologous to sequences in the genomes of IKe and Ff. No homology was observed between the consecutive DNA sequence that contains the origins for viral and complementary strand replication and the replication genes. Although other explanations cannot be ruled out, our data strongly suggest that the ancestor filamentous phage genome of phages I2-2 and IKe has exchanged its replication module during evolution with that of another replicon, e.g., a plasmid that also replicates via the so-called rolling circle mechanism. Offprint requests to: R.N.H. Konings     

New vectors for peptide display on the surface of filamentous bacteriophage

We have modified the genome of the filamentous bacteriophage fd and also constructed a number of new vectors for the purpose of displaying peptides on the surface of the virion. These vectors facilitate the directional cloning of DNA encoding a peptide of interest at or near the N terminus of the major coat protein, the product of the bacteriophage gene VIII, and the construction of hybrid capsids in which the modified coat protein is interspersed with wild-type coat protein subunits.     

Viral SPP1 DNA is infectious in naturally competent Bacillus subtilis cells: inter- and intramolecular recombination pathways

A proteolyzed bacteriophage (phage) might release its DNA into the environment. Here, we define the recombination functions required to resurrect an infective lytic phage from inactive environmental viral DNA in naturally competent Bacillus subtilis cells. Using phage SPP1 DNA, a model that accounts for the obtained data is proposed (i) the DNA uptake apparatus takes up environmental SPP1 DNA, fragments it, and incorporates into the cytosol different linear single-stranded (ss) DNA molecules shorter than genome-length; (ii) the SsbA-DprA mediator loads RecA onto any fragmented linear SPP1 ssDNA, but negative modulators (RecX and RecU) promote a net RecA disassembly from these ssDNAs not homologous to the host genome; (iii) single strand annealing (SSA) proteins, DprA and RecO, anneal the SsbA- or SsbB-coated complementary strands, yielding tailed SPP1 duplex intermediates; (iv) RecA polymerized on these tailed intermediates invades a homologous region in another incomplete molecule, and in concert with RecD2 helicase, reconstitutes a complete linear phage genome with redundant regions at the ends of the molecule; and (v) DprA, RecO or viral G35P SSA, may catalyze the annealing of these terminally redundant regions, alone or with the help of an exonuclease, to produce a circular unit-length duplex viral genome ready to initiate replication.