Properties of the A and A proteins of bacteriophage G4. The origin of G4 replicative-form DNA replication

The A and A proteins of the bacteriophage G4 have been purified. The proteins have been analysed for their enzymatic activities on single-stranded and double-stranded DNA. The A protein introduces a single-stranded break at a specific place in the G4 replicative form I DNA. This cleavage site has been localized between nucleotides 506 and 507 in the viral (+) strand. The A protein binds covalently to the 5' end of the cleavage site. The A protein initiates the replication of the viral (+) DNA [Borrias, et al. (1979) Virology, 31, 288-298]; the cleavage site therefore identifies the origin of replication. The A protein cleaves viral (+) strand DNA at many different sites and also binds covalently to the 5' ends of the nick sites. The properties of both proteins strongly resemble the properties of the A and A proteins of the related and much butter analysed phage phi X174. These results indicate that the G4 and phi X174A and A proteins have comparable functions and also that both phages initiate the replicative form DNA in a similar way.     

DNA synthesis in nucleotide-permeable Escherichia coli cells. VII. Conversion of phi chi-174 DNA to its replicative form

On incubation with deoxynucleoside triphosphates and rATP, ether-treated (nucleotide-permeable) cells convert the single-stranded DNA of adsorbed bacteriophage φX174 particles to the double-stranded replicative forms. The main final product is the doubly-closed replicative form, RFI; a minor product is the relaxed form II. Interruptions in the nascent complementary strand of the viral DNA result in pieces corresponding to 5 to 10% of the unit length of the viral DNA. Pieces of similar size were previously seen in studies of the replication synthesis of Escherichia, coli DNA in ether-treated cells. Since the conversion of the single-stranded φX174 DNA to replicative form is known to be mediated entirely by host factors, it is argued that the viral single strands are replicated by macromolecular factors involed in the replication of E. coli DNA and that this is the reason why new φX174 DNA appears in short pieces. Possible consequences of this interpretation for an understanding of duplex replication are discussed. The joining of the short pieces of complementary φX174 DNA is inhibited at low deoxynucleoside triphosphate concentration (1 μM) but not by nicotinamide mononucleotide, which inhibits the NAD-dependent DNA ligase and blocks the conversion of RFII to RFI in ether-treated cells. The results are discussed with respect to previous studies on cell-DNA synthesis (Geider, 1972). It is argued that there are two polynucleotide joining mechanisms, of which only one requires NAD-dependent ligase action.     

Effect of Chloramphenicol on the DNA Synthesis of Bacteriophage ϕX174

In bacteriophage ?X174 infection, the net synthesis of replicative form DNA ceased between 15 and 20 min after infection. When 30 μg of chloramphenicol/ml was added, net RF synthesis, however, continued beyond the normal time and level of turn-off. Experiments with ?X174 mutants unable to synthesize single-stranded DNA showed that a protein synthesis was required for the cessation of net RF synthesis and the protein was synthesized between 10 and 15 min after infection.     

Process of attachment of phi X174 parental DNA to the host cell membrane

The phi X174-DNA membrane complex was isolated from Escherichia coli infected with phi X174 am3 by isopycnic sucrose gradient centrifugation followed by zone electrophoresis. The phi X174 DNA-membrane complex banded at two positions, intermediate density membrane fraction and cytoplasmic membrane fraction, having bouyant densities of 1.195 and 1.150 g/ml, respectively. Immediately after infection with phi X147, replicating DNA was pulse-labeled and then the incorporated label was chased. The radioactivity initially recovered in the intermediate density membrane fraction migrated to the cytoplasmic membrane fraction. The DNAs from both complexes sedimented mainly at the position of parental replicative form I (RFI). The phi X174 DNA-membrane complex contained a speficic membrane-bound protein having a molecular weigth of 80,000 which is accumulated in the host DNA-membrane complex. These results suggest that when phi X174 DNA penetrated into cells in the early phase of infection, single-stranded circular DNA was converted to parental RFI at a wall/membrane adhesion region and migrated to the cytoplasmic membrane fraction, where the parental RF could serve as a template in the replication of progeny RF.     

DNA sequences which support activities of the bacteriophage phi X174 gene A protein

The DNA sequence of 30 nucleotides which surrounds the origin of viral strand DNA replication is highly conserved amongst the icosahedral single-stranded DNA bacteriophages. The A gene of these phages encodes a protein which is required for initiation and termination of viral strand DNA synthesis and acts as a nicking-closing activity specifically within this 30-nucleotide sequence. A system of purified Escherichia coli host proteins and phi X174 gene A protein has been developed which specifically replicates in vitro the viral strand of phi X174 from RF (replicative form) I template DNA and yields single-stranded circular DNA products (RF leads to SS(c) DNA replication system). Recombinant plasmids carrying inserts derived from phage phi X174 or G4 DNA which range in length from 49 to 1175 base pairs and contain the 30-nucleotide conserved sequence have been shown to support phi X A protein-dependent DNA synthesis in vitro in this replication system. We report here that insertion of the 30-nucleotide sequence alone into pBR322 allows the resulting recombinant plasmids to support phi X A protein-dependent in vitro DNA synthesis as efficiently as phi X174 template DNA in the RF leads to SS(c) replication system. The 30-nucleotide sequence functions as a fully wild type DNA replication origin as determined by the rate of DNA synthesis and the structure of resulting DNA products. Furthermore, the DNA sequence requirements for nicking of RF I DNA by the phi X A protein and for supporting replication origin function have been partially separated. Homology to positions 1, 29, and 30 of the 30-nucleotide conserved sequence are not required for cleavage of RF I DNA by the A protein; homology to position 1 but not 29 or 30 is required for efficient DNA replication.     

Viral DNA-synthesizing intermediate complex isolated during assembly of bacteriophage phi X174.

A DNA protein complex that is a precursor of mature phi X174 phage was isolated. The complex sedimented with an S value of 50 in a sucrose gradient and contained phage DNA consisting of a replicative form molecule with an extended tail of single-stranded viral DNA. The viral-strand DNA ranged from one to two genomes in length. Proteins coded on the phi X174 genome as well as the host genome were associated with the viral DNA in the 50S precursor complex. Our results indicated that both viral DNA synthesis and cleavage of the growing viral-strand DNA occurred in the 50S complex.     

The mechanism of replication of phi X174 single-stranded DNA. II. The role of viral proteins

We have studied the replication of φX174 DNA in Escherichia coli infected with various amber mutants (cistrons I to VII) of φX. Previous research showing that some of these mutants are able to form replicative form (RF) DNA but are unable to produce net amounts of viral progeny single-stranded DNA has been confirmed and extended. Evidence is presented that a defect in any one of four viral cistrons prevents the asymmetric replication of the RF to produce progeny viral DNA. At least four virus-coded proteins, three of which are part of the mature virion, must be present before single-stranded DNA synthesis can even be initiated; the possibility that single-stranded DNA is made and then degraded or converted to RF is eliminated. Mutants in one cistron (II) do permit the asymmetric replication of RF at late times, but the displaced viral strand is incorporated into a defective particle and subsequently may be partially degraded. Both RFI (superhelix) and RFII are present in roughly comparable amounts throughout the normal latent period in infections with wild-type phage or any of the phage mutants.     

The rep mutation. VI. Purification and properties of the Escherichia coli rep protein, DNA helicase III.

The protein product of the rep gene of Escherichia coli is required for the replication of certain bacteriophage genomes (phi X174, fd, P2) and for the normal replication of E. coli DNA. We have used a specialized transducing phage, lambda p rep+, which complements the defect of rep mutants, to identify the rep protein. The rep protein has been purified from cells infected with lambda p rep+ phage; it has a molecular weight of about 70 000 and appears similar to the protein found in normal cells. Stimulation of phi X174 replicative form DNA synthesis in vitro was observed when highly purified rep protein was supplied to a cell extract derived from phi X-infected E. coli rep cells and supplemented with replicative form DNA. The purified protein has a single-stranded DNA-dependent ATPase activity and is capable of sensitizing duplex DNA to nucleases specific for single-stranded DNA. For this reason we propose the enzyme be called DNA helicase III. We infer that the rep protein uses the energy of hydrolysis of ATP to separate the strands of duplex DNA; the E. coli DNA binding protein need not be present. The rep3 mutant appeared to make a limited amount of active rep protein.     

Novel replicative properties of a capsid mutant of bacteriophage phi chi 174.

A capsid mutant of bacteriophage phi chi 174 demonstrates altered requirements for the conversion of viral single-stranded DNA to double-stranded replicative form DNA. In the presence of puromycin at 42 C, wild-type phi chi 174 is unable to complete this replicative event, whereas phi chi ahb is able to do so. Furthermore, in contrast to wild-type phi chi 174, formation of phi chi ahb parental replicative form DNA is sensitive to rifampin under certain experimental conditions. These data suggest that the mutant capsid proteins of phi chi ahb influence the biosynthesis of phi chi ahb complementary strand DNA.     

The ABC-primosome. A novel priming system employing dnaA, dnaB, dnaC, and primase on a hairpin containing a dnaA box sequence

A priming mechanism requiring dnaA, dnaB, and dnaC proteins operates on a single-stranded DNA coated with single-stranded DNA-binding protein. This novel priming, referred to as "ABC-priming," requires a specific hairpin structure whose stem carries a dnaA protein recognition sequence (dnaA box). In conjunction with primase and DNA polymerase III holoenzyme, ABC-priming can efficiently convert single-stranded DNA into the duplex replicative form. dnaA protein specifically recognizes and binds the single-stranded hairpin and permits the loading of dnaB protein to form a prepriming protein complex containing dnaA and dnaB proteins which can be physically isolated. ABC-priming can replace phi X174 type priming on the lagging strand template of pBR322 in vitro, suggesting a possible function of ABC-priming for the lagging strand synthesis and duplex unwinding. Similar to the phi X174 type priming, a mobile nature of ABC-priming was indicated by helicase activity in the presence of ATP of a prepriming protein complex formed at the hairpin. The implications of this novel priming in initiation of replication at the chromosomal origin, oriC, and in its contribution to the replication fork are discussed.     

Rolling-circle replication of UV-irradiated duplex DNA in the phi X174 replicative-form----single-strand replication system in vitro.

Cloning of the phi X174 viral origin of replication into phage M13mp8 produced an M13-phi X174 chimera, the DNA of which directed efficient replicative-form----single-strand rolling-circle replication in vitro. This replication assay was performed with purified phi X174-encoded gene A protein, Escherichia coli rep helicase, single-stranded DNA-binding protein, and DNA polymerase III holoenzyme. The nicking of replicative-form I (RFI) DNA by gene A protein was essentially unaffected by the presence of UV lesions in the DNA. However, unwinding of UV-irradiated DNA by the rep helicase was inhibited twofold as compared with unwinding of the unirradiated substrate. UV irradiation of the substrate DNA caused a strong inhibition in its ability to direct DNA synthesis. However, even DNA preparations that contained as many as 10 photodimers per molecule still supported the synthesis of progeny full-length single-stranded DNA. The appearance of full-length radiolabeled products implied at least two full rounds of replication, since the first round released the unlabeled plus viral strand of the duplex DNA. Pretreatment of the UV-irradiated DNA substrate with purified pyrimidine dimer endonuclease from Micrococcus luteus, which converted photodimer-containing supercoiled RFI DNA into relaxed, nicked RFII DNA and thus prevented its replication, reduced DNA synthesis by 70%. Analysis of radiolabeled replication products by agarose gel electrophoresis followed by autoradiography revealed that this decrease was due to a reduction in the synthesis of progeny full-length single-stranded DNA. This implies that 70 to 80% of the full-length DNA products produced in this system were synthesized on molecules that carried photodimers. Thus, similarly to its activity on UV-irradiated single-stranded DNA, DNA polymerase III holenzyme can bypass pyrimidine photodimers in the more complex replicative form --->single-strand replication, which involves, in addition to the polymerizing activity, the unwinding of the duplex by the rep helicase and the participation of a more complex multiprotein replisome.     

Replication of Bacteriophage φX174 DNA in a Temperature-Sensitive dnaE Mutant of Escherichia coli C

Bacteriophage phiX174 cannot grow in a temperature-sensitive dnaE (DNA polymerase III) mutant of Escherichia coli C at the nonpermissive temperature. The inability to grow is the result of inhibition of virus DNA synthesis. The synthesis of the parental replicative form is unaffected, but the replication of the replicative form and the synthesis of the single-stranded virus DNA are inhibited.     

Replication of bacteriophage G13 DNA in dna mutants of Escherichia coli.

Host functions required for replication of microvirid phage G13 DNA were investigated in vivo, using thermosensitive dna mutants of Escherichia coli. In dna+ bacteria, conversion of viral single-stranded DNA into double-stranded replicative form (stage I synthesis) was resistant to 150 microgram/ml of chloramphenicol or 200 microgram/ml of rifampicin. Although multiplication of G13 phage was severely inhibited at 42--43 degrees C even in dna+ host, considerable amount of parental replicative form was synthesized at 43 degrees C in dna+, dnaA or dnaE bacteria. In dnaB and dnaG mutants, however, synthesis of parental replicative form was severely inhibited at the restrictive temperature. Interestingly enough, stage I replication of G13 DNA was, unlike that of phiX174, dependent on host dnaC(D) function. Moreover, the stage I synthesis of G13 DNA in dnaZ was thermosensitive in nutrient broth but not in Tris/casamino acids/glucose medium. In contrast with the stage I replication, synthesis of G13 progeny replicative form was remarkably thermosensitive even in dna+ or dnA cells.     

Identification of the Block in the Intracellular Replication of Single-Stranded DNA of Photodynamically Inactivated Bacteriophage φX174

(32)P-labeled single-stranded DNA phage phiX174 was photodynamically inactivated by irradiation in air with visible light in the presence of the acridine dye, proflavine sulfate. The inactivated phages could adsorb to the host cells but failed to lyse them. Formation of intracellular mature phages was almost completely inhibited. Photodynamic lesions in phiX174 DNA caused intracellular formation of defective double-stranded replicative form molecules which ultimately reverted to the single-stranded configuration.     

Preparation and characterization of form V DNA, the duplex DNA resulting from association of complementary, circular single-stranded DNA.

Complementary circular single strands of plasmid PβG or bacteriophage PM2 DNA but not of single-stranded φX174 DNA associate under hybridisation conditions, giving rise to a two-stranded complex. This DNA, which we call form V, has well-defined physico-chemical properties. It sediments as a sharp peak in neutral sucrose gradients; its electrophoretic mobility in agarose gels is between that of covalently closed (form I) and denatured DNA. In the electron microscope form V appears as highly folded duplex molecules indistinguishable from form I. However, increasing concentrations of ethidium bromide which lead to relaxation and recoiling of form I DNA have no comparable effect upon form V. At 260 nm form V PβG DNA has a hypochromicity of 18.6%, as compared to 23.4% in the case of PβG form II DNA and 10.5% in the case of single-stranded φX174 DNA. The thermal melting of form V is non-cooperative with gradual increase in absorbance similar to that of single-stranded DNA. The circular dichroism spectrum of form V DNA differs from that of form I, circular nicked (form II) and single-stranded φX174 DNA in that it shows a negative band at 295 nm and a shift for the main positive band from 273 to 266 nm. We propose that form V consists of right-handed Watson-Crick type double-helices which are compensated by an equal number of left-handed duplex turns and negative supercoils. Wo cannot decide whether left-handed duplex turns are stabilised by base-stacking and hydrogen bonding, as for example in the models described by Rodley et al. (1976) or Sasisekharan &; Pattabiraman (1976), or whether they are merely compensatory turns without inherent stability.     

Isolation of specific ribosome binding sites from single-stranded DNA.

The ability of Escherichia coli ribosomes to protect small specific regions of single-stranded bacteriophage DNA from digestion by pancreatic DNAase has been investigated. A procedure is described by which ribosome-protected fragments can be isolated from the DNA of bacteriophage f1 and φX174. Size determination by polyacrylamide gel electrophoresis or thin layer homochromatography together with fingerprinting analysis following chemical depurination or digestion with E. coli endonuclease IV were employed to show that these fragments represent a small specific portion of these DNAs. The protection reaction is largely dependent upon components necessary for ribosome binding to mRNA, including GTP, formylmethionyl-tRNA, and initiation factors. Thus, ribosomal binding to DNA mimics the ribosome-mRNA interaction. Furthermore, the regions in f1 and φX174 DNA which are protected differ in sequence from each other.When E. coli endonuclease IV is substituted for pancreatic DNAase in the ribosome protection reaction, a fragment of φX174 DNA is obtained about 150 bases in length which contains all of the pyrimidine tracts in the shorter 50-base fragment obtained with pancreatic DNAase, and a number of additional polypyrimidines.Double-stranded DNAs such as φX174 replicative form do not bind at all to ribosomes in their native state. Heat denaturation of such double-stranded DNAs allows ribosome binding. Protection of the same specific regions as those protected in single-stranded φX174 DNA was observed. A similar specific protection was observed following heat denaturation and ribosome binding with DNA from polyoma virus.     

Reaction of poliovirus RNAs with antibodies to double-stranded RNA demonstrated by an immunochemical binding assay.

An immunochemical binding assay was used to investigate the reactivity of radioactively labeled viral RNAs from poliovirus-infected cells with antibodies to the synthetic double-stranded RNA, poly(I)-poly(C). A RNase-free antibody-containing serum fraction was employed. Poliovirus replicative form reacted with the antibodies to poly(I)-poly(C) as well as or better than poly(I)-poly(C). Poliovirus replicative intermediate reacted with the antibodies to a greater extent than poliovirus single-stranded RNA, but both were less reactive than replicative form. The use of the immunochemical binding assay with sucrose-gradient fractions demonstrated that for both poliovirus single-stranded RNA and replicative form the peak of reactivity with the antibodies was coincident with the peak of radioactive material precipitated by trichloroacetic acid. The proportion of replicative intermediate that reacted with the antibody increased in sucrose-gradient fractions containing the more slowly sedimenting RI RNA.     

Mechanism of Replication of φX174 Single-Stranded DNA IX. Requirement for the Escherichia coli dnaG Protein

Escherichia coli NY73, possessing a temperature-sensitive mutation in the dnaG locus, was rendered sensitive to bacteriophage phiX174 by P1 transduction. phiX174 reproduces in this strain at 30 C but not at 40 C. All three stages of phiX174 replication, parental replicative form (RF) synthesis, RF replication, and progeny single-stranded DNA synthesis, are thermolabile in this mutant. Competition-annealing data show that both plus- and minus-strand synthesis are equally inhibited after shift up to 40 C during RF replication. We conclude that the dnaG gene product is required for the synthesis of both strands of phiX RF during RF replication and of the complementary strand and viral progeny strands during stages I and III, respectively.     

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA.

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.