Effects of UV irradiation on the fate of 5-bromodeoxyuridine-substituted bacteriophage T4 DNA.

We have carried out a series of experiments designed to characterize the impact of UV irradiation (260 nm) on 5-bromodeoxyuridine-labeled (heavy) T4 bacteriophage, both before and after infection of Escherichia coli. In many respects, these effects differ greatly from those previously described for non-density-labeled (light) phage. Moreover, our results have led us to propose a model for a novel mechanism of host-mediated repair synthesis, in which excision of UV-damaged areas is followed by initiation of replication, strand displacement, and a considerable amount of DNA replication. UV irradiation of 5-bromodeoxyuridine-labeled phage results in single-stranded breaks in a linear, dose-dependent manner (1.3 to 1.5 breaks per genomic strand per lethal hit). This damage does not interfere with injection of the phage genome, but some of the UV-irradiated heavy phage DNA undergoes additional intracellular breakdown (also dose dependent). However, a minority (25%) of the injected parental DNA is protected, maintaining its preinjection size. This protected moiety is associated with a replicative complex of DNA and proteins, and is more efficiently replicated than is the parental DNA not so associated. Most of the progeny DNA is also found with the replicative complex. The 5-bromodeoxyuridine of heavy phage DNA is debrominated by UV irradiation, resulting in uracil which is removed by host uracil glycosylase. Unlike the simple gap-filling repair synthesis after infection with UV-irradiated light phage, the repair replication of UV-irradiated heavy phage is extensive as determined by density shift of the parental label in CsC1 gradients. The newly synthesized segments are covalently attached to the parental fragments. The repair replication takes place even in the presence of chloramphenicol, a protein synthesis inhibitor, suggesting it is host mediated. Furthermore, the extent of the repair replication is greater at higher doses of UV irradiation applied to the heavy phage. This abundant synthesis results ultimately in dispersion of the parental sequences as short stretches in the midst of long segments of newly synthesized progeny DNA. Together, the extensive replication and the resulting distribution pattern of parental sequences, without significant solubilization of parental label, are most consistent with a model of repair synthesis in which the leading strand displaces, rather than ligates to, the encountered 5' end.     

Continued Synthesis of Bacterial DNA After Infection by Bacteriophage T4

Early in infection by bacteriophage T4, before replication has commenced, one can detect the presence of newly synthesized DNA which cosediments with parental phage DNA on sucrose gradients. As shown earlier (R. E. Murray and C. K. Mathews, 1969), some of this represents covalent attachment of new material to parental phage DNA molecules. However, as shown herein, most of it is bacterial DNA, which is synthesized after infection and presumably degraded to T4 DNA-sized pieces. The small amount of phage-specific DNA synthesis which occurs is apparently a repair process, for its extent is greatly increased if the phage are irradiated with ultraviolet light prior to infection. Analysis by means of pulse labeling with [(3)H]thymidine and DNA-DNA hybridization shows that host DNA synthesis continues at a significant rate (40 to 80% of the preinfection rate) as late as 10 min after infection at 37 C. Very early in infection this is primarily replicative synthesis, but later a repair process predominates. Presumably this represents attempted repair of damage being inflicted on host DNA by phage-coded nucleases.     

Replication Process of the Parvovirus H-1 III. Factors Affecting H-1 RF DNA Synthesis

Replication of the single-stranded DNA parvovirus H-1 involves the synthesis of a double-stranded DNA replicative form (RF). In this study, the metabolism of RF DNA was examined in parasynchronous hamster embryo cells. The initiation of RF DNA replication was found to occur late in S phase, as was the synthesis of the DNA upon which subsequent viral hemagglutinin synthesis is dependent. Evidence is presented which indicates that initiation of RF replication requires proteins synthesized in late S phase, but that concomittant protein synthesis is not required for the continuation of RF replication. The data also suggest a requirement for viral protein(s) for progeny strand synthesis. Incorporation of 5-bromo-2'-deoxyuridine (BUdR) into viral DNA resulted in an "all-or-none" inhibition of viral hemagglutinin and viral antigen synthesis. BUdR inactivation of viral protein function was used to explore the time of synthesis of viral DNA serving as template for viral RNA synthesis and the effect of viral protein on RF replication and progeny strand synthesis. Results of this study suggest that parental RF DNA is synthesized shortly after infection, and that viral mRNA is transcribed from only a few copies of the viral genome in each cell. They also support the conclusion that viral protein is inhibitory to RF DNA replication. Density labeling of RF DNA with BUdR, allowing separation of viral strand DNA (V) from viral complementary strand (C), provided additional data in support of the above findings.     

Multiple and Specific Initiation of T4 DNA Replication

Partially replicated T4 DNA molecules (PRM) whose parental or progeny DNA was labeled with bromodeoxyuridine BUdR was analyzed by gradual shearing followed by CsCl banding of the sheared product. Analysis of PRM containing 18-mum replicated DNA showed that each replicated region was 3- to 6-mum long, indicating three to 6 replicative sites per molecule. Analysis of PRM containing 9-mum replicated DNA similarly indicated two to three replicated regions per molecule. DNA from the replicated regions of PRM containing 10-mum replicated DNA ("donor") was hybridized to DNA from mature phage ("recipient"), and the resulting hybrid was subjected to digestion with exonuclease I. The extent of protection of the recipient and more efficient self-annealing of progeny fragments from PRM indicated that the replicated regions represented 8 to 10 nonrandom locations of the genome. Possible significance of multiple sites for initiation of DNA replication is discussed.     

Partial replicas of UV-irradiated bacteriophage T4 genomes and their role in multiplicity reactivation.

A physicochemical study was made of the replication and transmission of UV-irradiated T4 genomes. The data presented in this paper justify the following conclusions. (i) For both low and high multiplicity of infection there was abundant replication from UV-irradiated parental templates. It exceeded by far the efficiency predicted by the hypothesis that a single lethal hit completely prevents replication of the killed phage DNA: i.e., some dead phage particles must replicate parts of thier DNA. (ii) Replication of the UV-irradiated DNA was repetitive as shown by density reversal experiments. (iii) Newly synthesized progeny DNA originating from UV-irradiated templates appeared as significantly shorter segments of the genomes than progeny DNA produced from non-UV-irradiated templates. A good correlation existed between the number of UV hits and the number of random cuts that would be needed to reduce replication fragments to the length observed. (iv) The contribution of UV-irradiated parental DNA among progeny phage in multiplicity reactivation was disposed in shorter subunits than was the DNA from unirradiated parental phage. It is important to emphasize that it was mainly in the form of replicative hybrid. These conclusions appear to justify excluding interparental recombination as a prerequisite for multiplicity reactivation. They lead directly to some form of partial replica hypothesis for multiplicity reactivation.     

DNA helicase requirements for DNA replication during bacteriophage T4 infection.

The lytic bacteriophage T4 uses multiple mechanisms to initiate the replication of its DNA. Initiation occurs predominantly at replication origins at early times of infection, but there is a switch to genetic recombination-dependent initiation at late times of infection. The T4 insertion-substitution system was used to create a deletion in the T4 dda gene, which encodes a 5'-3' DNA helicase that stimulates both DNA replication and recombination reactions in vitro. The deletion caused a delay in T4 DNA synthesis at early times of infection, suggesting that the Dda protein is involved in the initiation of origin-dependent DNA synthesis. However, DNA synthesis eventually reached nearly wild-type levels, and the final number of phages produced per bacterium was similar to that of the wild type. When the dda mutant phage also contained a mutation in T4 gene 59 (a gene normally required only for recombination-dependent DNA replication), essentially no DNA was synthesized. Recent in vitro studies have shown that the gene 59 protein loads a component of the primosome, the T4 gene 41 DNA helicase, onto DNA. A molecular model for replication initiation is presented that is based on our genetic data.     

Semiconservative DNA replication is initiated at a single site in recombination-deficient gene 32 mutants of bacteriophage T4.

We have investigated, by electron microscopy, replicative intermediate produced early after infection of Escherichia coli with two phage T4 gene 32 mutants (amA453 and tsG26) which replicate their parental DNA but are defective in secondary replications and in moderating the activities of recombination nucleases. Under conditions completely restrictive for progeny production, both of these mutant produced replicative intermediates, each containing a single internal loop. Both branches of these loops were double stranded; i.e., both leading and lagging strands were synthesized. The replicative intermediates of these mutants qualitatively and quantitatively resembled early replicating wild-type T4 chromosomes after solitary infection of E. coli. However, in contrast to intracellular wild-type T4 DNA isolated from multiple infection, the mutant DNAs showed neither multiple branches nor multiple tandem loops. These results demonstrate that a truncated gene 32 protein which consists of less than one-third of the wild-type T4 helix-destabilizing protein can facilitate the functions of T4 replication proteins, specifically those of T4 DNA polymerase and priming proteins. Our results also support the hypothesis that the generation of multiple tandem loops or branches in vegetative T4 DNA depends on recombination (Mosig et al., in B. Alberts, ed., Mechanistic Studies of DNA Replication and Genetic Recombination, p. 527-543, Academic Press, Inc., New York, 1980).     

Inhibition of Bacteriophage φX174 DNA Replication in dnaB Mutants of Escherichia coli C

Bacteriophage phiX174 DNA replication was examined in temperature-sensitive dnaB mutants of Escherichia coli C to determine which stages require the participation of the product of this host gene. The conversion of the infecting phage single-stranded DNA to the double-stranded replicative form (parental RF synthesis) is completely inhibited at the nonpermissive temperature (41 C) in two of the three dnaB mutants tested. The efficiency of phage eclipse and of phage DNA penetration of these mutant host cells at 41 C is the same as that of the parent host strain. The defect is most likely in the synthesis of the complementary strand DNA. The semiconservative replication of the double-stranded replicative form DNA (RF replication) is inhibited in all three host mutants after shifting from 30 to 41 C. Late in infection, the rate of progeny single-stranded phage DNA synthesis increases following shifts from 30 to 41 C. Approximately the same amounts of phage DNA and of infectious phage particles are made following the shift to 41 C as in the control left at 30 C. The simplest interpretation of our data is that the product of the host dnaB gene is required for phiX174 parental RF synthesis and RF replication, but is not directly involved in phage single-stranded DNA synthesis once it has begun. The possible significance of the synthesis of parental RF DNA at 41 C in one of the three mutants is discussed.     

Control of the Replication Complex of Bacteriophage P22

A replication complex for the vegetative synthesis of the deoxyribonucleic acid (DNA) of the temperate phage P22 previously has been described. This complex is an association of parental phage DNA, most of the newly synthesized phage DNA made during pulses with (3)H-thymidine, and other cell constituents, and has a sedimentation rate in neutral sucrose gradients of at least 1,000S. The complex is one of the intermediates, intermediate I, in the synthesis and maturation of phage P22 DNA after infection or induction. Evidence supporting the replicative nature of intermediate I is presented. Phage replication is repressed in lysogenic bacteria. On superinfection of P22 lysogens with nonvirulent phage, little association of the input phage DNA with a rapidly sedimenting fraction is demonstrable. However, after induction with ultraviolet light, the superinfecting parental phage DNA quickly acquires the rapid sedimentation rate characteristic of intermediate I; phage DNA synthesis follows; and progeny phages are produced. Infection with a virulent mutant of P22 produces progeny phages in lysogens. Its DNA associates with intermediate I. In mixed infection with the virulent phage, replication of nonvirulent phage P22 is still repressed, even though the virulent replicates normally. The nonvirulent input DNA does not associate with intermediate I. The repressor of the lysogenic cell prevents replication by interfering with the physical association of template material with intermediate I. A phage function is required for association of phage template with the replication machinery.     

Inhibition of initiation of bacteriophage T4 DNA replication by perturbation of Escherichia coli host membrane composition.

3-Decynoyl-N-acetylcysteamine (3-decynoyl-NAC) is an analog which specifically causes the immediate cessation of the biosynthesis of unsaturated fatty acids in Escherichia coli, whereas the synthesis of saturated fatty acids is actually stimulated. As a result, the cell membrane accumulates saturated fatty acids in its phospholipid. Addition of the inhibitor at the time of infection of E. coli by T4 phage had no effect on normal phage replication and development, implying that the synthesis of unsaturated fatty acids per se has little effect on T4 DNA replication. However, if the integrity and composition of the bacterial membrane was grossly perturbed by first treating the cells with the inhibitor for 60 min before infection, the proper initiation and the attainment of a rapid rate of T4 DNA synthesis were not observed. Under these conditions, a full complement of T4 early proteins was synthesized. The membrane associability of the known DNA delay proteins induced by wild-type T4 phage in the treated cells resembled that expected of a culture of untreated cells infected with a DNA delay mutant. When any one of three DNA delay mutants was used to infect 3-decynoyl-NAC-treated cells, T4 DNA replication was aborted. These findings suggest that some kind of specific interactions among the initiation proteins defined by the DNA delay mutants and the bacterial membrane may be necessary to facilitate the normal initiation and rapid rate of T4 DNA replication. A model for the involvement of the three different initiation proteins and the subsequent attainment of rapid DNA synthesis is discussed.     

Accumulation of ColE1 early replicative intermediates catalyzed by extracts of Escherichia coli dnaG mutant strains.

To investigate the events occurring at the replication forks during DNA synthesis, we studied the replication of plasmid ColE1 DNA in vivo and in vitro, using strains of Escherichia coli carrying either the dnaG3(Ts) or dnaG308(Ts) mutation. Extracts of both mutant strains supported in vitro DNA synthesis, but the amount of [3H]TMP incorporated into DNA was always less for mutant extracts than for extracts of revertant strains, which were able to grow at 42 degrees C. Sucrose gradient analysis, Southern blot analysis, and electron microscopy showed that mutant extracts synthesize a large number of early replicative intermediates containing one or two (one on each template strand) fragments at the origin of replication and some completed molecules, either open circles or covalently closed circles. The revertant extracts synthesized more completed molecules although the fraction of templates used was about the same, 0.27 for mutant extracts and 0.21 for revertant extracts. Our results show that a mutation in dnaG causes a block in the synthesis of both leading and lagging strands after initiation, which results in the accumulation of early replicative intermediates. The average size of the newly replicated region in the early replicative intermediates is 730 bases as measured from electron micrographs of early replicative intermediates. We conclude that the DnaG protein functions in lagging strand synthesis and may be necessary for the continuation of leading strand synthesis as well.     

Inhibition of Bacteriophage ϕX174 Replicaiive-form DNA Replication by Rifampicin

?X174 DNA synthesis as well as phage production was inhibited by rifampicin when added in early phase of infection. Rifampicin did not inhibit the formation of parental duplex replicative-form, RF, and it inhibited the synthesis of progeny RF under conditions where protein synthesis was not necessary to be synthesized continuously. In addition, replication of parental RF into progeny RF was inhibited by rifampicin under conditions where a high concentration of chloramphenicol did not affect the replication. Consequently, it could be concluded that RNA synthesis other than that required for protein synthesis was necessary for both the initiation and continuation of RF replication.     

Mode of extension of the daughter strands in the replication of closed circular mitochondrial DNA in vitro.

1. The properties of nascent DNA in the replicative closed circular mitochondrial DNA were examined in the in vitro system of discontinuous replication, using newborn rat liver mitochondria containing endogeneous DNA templates and enzymes. 2. The nascent DNA associated with the closed circular DNA fraction was found to be of two types; one class consisted of the fragments, and the other of the higher molecular-weight DNAs. Data from pulse and chase experiments indicate that the fragments were initially synthesized and subsequently converted into both heavy and light strands of the higher molecular-weight DNAs in an asymmetrical mode. 3. DNA - DNA hybridization experiments revealed that half of the fragments at least were copies of complementary parts of the parental DNA. 4. Based on the present in vitro data, a tentative structure of the replicating region and its expansion are discussed.     

Deoxyribonucleic Acid Replication and Expression of Early and Late Bacteriophage Functions in Bacillus subtilis

The role of deoxyribonucleic acid (DNA) replication in the control of the synthesis of deoxycytidylate (dCMP) deaminase and lysozyme in Bacillus subtilis infected with bacteriophage 2C has been studied. These phage-induced enzymes are synthesized at different times during the latent period. It was shown by actinomycin inhibition that the formation of the late enzyme (lysozyme) required messenger ribonucleic acid (mRNA) synthesized de novo after the initiation of translation of mRNA which specifies the early function (dCMP deaminase). The inhibition of phage DNA synthesis by mitomycin C prevented the synthesis of lysozyme only when added before the onset of phage DNA replication, but it did not affect the synthesis or action of dCMP deaminase when added at any time during the latent period. Treatment of infected cells with mitomycin C after phage DNA synthesis had reached 8 to 10% of its maximal rate resulted in the production of normal amounts of lysozyme. These observations suggest that mRNA specifying early enzymes can be transcribed from parental (and probably also from progeny) DNA, whereas late functional messengers can be transcribed only after the formation of progeny DNA.     

Involvement of a Replicative DNA Helicase of Bacteriophage T4 in DNA Recombination

Bacteriophage T4 gene 41 encodes a replicative DNA helicase that is a subunit of the primosome which is essential for lagging-strand DNA synthesis. A mutation, rrh, was generated and selected in the helicase gene on the basis of limited DNA replication that ceases early. The survival of ultraviolet-irradiated phage and the frequency of genetic recombination are reduced by rrh. In addition, rrh diminishes the production of concatemeric DNA. These results strongly suggest that the gene 41 replicative helicase participates in DNA recombination.     

The role of template superhelicity in the initiation of bacteriophage lambda DNA replication.

The prepriming steps in the initiation of bacteriophage lambda DNA replication depend on the action of the lambda O and P proteins and on the DnaB helicase, single-stranded DNA binding protein (SSB), and DnaJ and DnaK heat shock proteins of the E. coli host. The binding of multiple copies of the lambda O protein to the phage replication origin (ori lambda) initiates the ordered assembly of a series of nucleoprotein structures that form at ori lambda prior to DNA unwinding, priming and DNA synthesis steps. Since the initiation of lambda DNA replication is known to occur only on supercoiled templates in vivo and in vitro, we examined how the early steps in lambda DNA replication are influenced by superhelical tension. All initiation complexes formed prior to helicase-mediated DNA-unwinding form with high efficiency on relaxed ori lambda DNA. Nonetheless, the DNA templates in these structures must be negatively supertwisted before they can be replicated. Once DNA helicase unwinding is initiated at ori lambda, however, later steps in lambda DNA replication proceed efficiently in the absence of superhelical tension. We conclude that supercoiling is required during the initiation of lambda DNA replication to facilitate entry of a DNA helicase, presumably the DnaB protein, between the DNA strands.     

Synthesis of bacteriophage phiC DNA in dna mutants of Esherichia coli.

Host dna functions involved in the replication of microvirid phage phiC DNA were investigated in vivo. Although growth of this phage was markedly inhibited even at 35-37 degrees C even in dna+ host, conversion of the infecting single-stranded DNA into the double-stranded parental replicative form (stage I synthesis) occurred normally at 43 degrees C in dna+, dnaA, dnaB, dnaC(D), and dnaE cells. In dnaG mutant, the stage I synthesis was severely inhibited at 43 degrees C but not at 30 degrees C. The stage I replication of phiC DNA was clearly thermosensitive in dnaZ cells incubated in nutrient broth. In Tris-casamino acids-glucose medium, however, the dnaZ mutant sufficiently supported synthesis of the parental replicative form. At 43 degrees C, synthesis of the progeny replicative form DNA (stage II replication) was significantly inhibited even in dna+ cells and was nearly completely blocked in dnaB or dnaC(D) mutant. At 37 degrees C, the stage II replication proceeded normally in dna+ bacteria.     

Bypass of a primase requirement for bacteriophage T4 DNA replication in vivo by a recombination enzyme, endonuclease VII.

A primase, the product of phage T4 gene 61, is required to initiate synthesis of Okazaki pieces and to allow bidirectional replication from several T4 origins. However, primase-defective T4 gene 61 mutants are viable. In these mutants, leading-strand DNA synthesis starts at the same time as in wild type infections, but, in contrast to wild type, initiation is unidirectional and the first replicative intermediates are large displacement loops. Rapid double-strand DNA replication occurs later after infection, generating multiple branched concatemers, which are cut and packaged into viable progeny particles, as in wild-type T4. Evidence is presented that this late double-strand DNA replication requires functional endonuclease VII (endo VII), the product of the T4 gene 49. We propose that endo VII can provide a backup mechanism when primase is defective, because it cuts recombinational junctions, generating 3' ends. These ends can prime DNA synthesis to copy the DNA strands that had been displaced during the initial origin-dependent replication. We explain the DNA-delay phenotype and the commonly observed temperature dependence of DNA replication in primase-deficient gene 61 mutants as a consequence of temperature-dependent translational control of gene 49 expression. In the presence or absence of functional primase endo VII is essential for correct packaging of DNA. The powerful selection that keeps the function of endo VII and expression of its gene at levels that are optimal for T4 development determines both the efficiency and the limitations of the bypass mechanism.     

PriA and phage T4 gp59: factors that promote DNA replication on forked DNA substrates microreview

The initiation of DNA synthesis on forked DNA templates is a vital process in the replication and maintenance of cellular chromosomes. Two proteins that promote replisome assembly on DNA forks have so far been identified. In phage T4 development the gene 59 protein (gp59) assembles replisomes at D-loops, the sites of homologous strand exchange. Bacterial PriA protein plays an analogous function, most probably restarting replication after replication fork arrest with the aid of homologous recombination proteins, and PriA is also required for phage Mu replication by transposition. Gp59 and PriA exhibit similar DNA fork binding activities, but PriA also has a 3' to 5' helicase activity that can promote duplex opening for replisome assembly. The helicase activity allows PriA's repertoire of templates to be more diverse than that of gp59. It may give PriA the versatility to restart DNA replication without recombination on arrested replication forks that lack appropriate duplex openings.