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.     

Host- and Phage-Mediated Repair of Radiation Damage in Bacteriophage T4

T4+ exhibits increased ultraviolet sensitivity on derivatives of Escherichia coli K12 or B lacking deoxyribonucleic acid (DNA) polymerase I. However, the sensitivity of T4v is not affected by the absence of host DNA polymerase. T4x and T4y also show increased sensitivity on DNA polymerase-deficient strains, but to a lesser extent than observed with wild-type T4. When T4x or T4y, but not T4+, are plated on a double mutant lacking both DNA polymerase and the uvrA gene product, a partial suppression of the polymerase effect is observed. Host ligase appears to be able to suppress to some extent the T4y phenotype but has no effect on wild-type T4 or other T4 mutants. T4xv incubated in E. coli B or B(s-1) in the presence of chloramphenicol (50 mug/ml) shows increased resistance over directly plated irradiated phage. Increased survival under the same conditions was not observed with T4+ or other T4 mutants. The repair of X-ray-damaged T4 was investigated by examining survival curves of T4+, T4x, T4y, T4ts43, and T4ts30. The repair processes were further defined by observing the effects of plating irradiated phage on various hosts including strains lacking DNA polymerase I or polynucleotide ligase. Two classes of effects were observed. Firstly, the x and y gene products seem to be involved in a repair system utilizing host ligase. Secondly, in the absence of host DNA polymerase, phage sensitivity is increased in an unknown manner which is enhanced by the presence of host uvrA gene product.     

Enzymic in vitro repair and chemical nature of DNA chain breaks induced by incorporated phosphorus-32P decay.

In vitro repair of single strand breaks in T4 and phage DNA caused by 32p decay was studied. Zone centrifugation procedure showed that polynucleotide kinase, ligase enzyme system failed to repair 32P-damages. It was found that damaged DNA contained gaps and could be repaired by DNA-polymerase I, polynucleotide ligase treatment.     

Phage T4‐induced DNA breaks activate a tRNA repair‐defying anticodon nuclease

The natural role of the conserved bacterial anticodon nuclease (ACNase) RloC is not known, but traits that set it apart from the homologous phage T4‐excluding ACNase PrrC could provide relevant clues. PrrC is silenced by a genetically linked DNA restriction‐modification (RM) protein and turned on by a phage‐encoded DNA restriction inhibitor. In contrast, RloC is rarely linked to an RM protein, and its ACNase is regulated by an internal switch responsive to double‐stranded DNA breaks. Moreover, PrrC nicks the tRNA substrate, whereas RloC excises the wobble nucleotide. These distinctions suggested that (i) T4 and related phage that degrade their host DNA will activate RloC and (ii) the tRNA species consequently disrupted will not be restored by phage tRNA repair enzymes that counteract PrrC. Consistent with these predictions we show that Acinetobacter baylyi RloC expressed in Escherichia coli is activated by wild‐type phage T4 but not by a mutant impaired in host DNA degradation. Moreover, host and T4 tRNA species disrupted by the activated ACNase were not restored by T4's tRNA repair system. Nonetheless, T4's plating efficiency was inefficiently impaired by AbaRloC, presumably due to a decoy function of the phage encoded tRNA target, the absence of which exacerbated the restriction.     

Induction and repair of double- and single-strand DNA breaks in bacteriophage lambda superinfecting Escherichia coli

Induction and repair of double- and single-strand DNA breaks have been measured after decays of 125I and 3H incorporated into the DNA and after external irradiation with 4 MeV electrons. For the decay experiments, cells of wild type Escherichia coli K-12 were superinfected with bacteriophage lambda DNA labelled with 5'-(125I)iodo-2'-deoxyuridine or with (methyl-3H)thymidine and frozen in liquid nitrogen. Aliquots were thawed at intervals and lysed at neutral pH, and the phage DNA was assayed for double- and single-strand breakage by neutral sucrose gradient centrifugation. The gradients used allowed measurements of both kinds of breaks in the same gradient. Decays of 125I induced 0.39 single-strand breaks per double-strand break. No repair of either break type could be detected. Each 3H disintegration caused 0.20 single-strand breaks and very few double-strand breaks. The single-strand breaks were rapidly rejoined after the cells were thawed. For irradiation with 4 MeV electrons, cells of wild type E. coli K-12 were superinfected with phage lambda and suspended in growth medium. Irradiation induced 42 single-strand breaks per double-strand break. The rates of break induction were 6.75 x 10(-14) (double-strand breaks) and 2.82 x 10(-12) (single-strand breaks) per rad and per dalton. The single-strand breaks were rapidly repaired upon incubation whereas the double-strand breaks seemed to remain unrepaired. It is concluded that double-strand breaks in superinfecting bacteriophage lambda DNA are repaired to a very small extent, if at all.     

Injection of Ultraviolet-Damage-Specific Enzyme by T4 Bacteriophage

When UV-irradiated T4 bacteriophage (v(+)) infects in the presence of chloramphenicol, the phage DNA rapidly acquires single-stranded breaks proportional to the dose of UV. In contrast, when UV-irradiated T4 v(1) (radiation sensitive mutant) infects under identical conditions, the phage DNA remains integral. A series of coinfections with v(+) and v(1) phage (UV-v(1) + majority non-UV-v(+) and UV-v(+) and majority non-UV-v(1)) show that the enzyme responsible for breakage is injected by the phage. It is also demonstrated that the v(1) phage injects an inactive enzyme that delays breakage by the v(+) enzyme and interferes with subsequent repair. The cross of v(+) and v(1) phage produces mixed progeny that contain both active and inactive enzyme in a single capsid. The possible function of this breaking enzyme, necessitating injection of multiple copies, is considered.     

Photosensitizing effect of 8-methoxypsoralen on bacteriophage cd

Mutagenesis in extracellular phage sd by 8-metoxypsoralen (8-MOP) and longwave (lambda greater than 310 nm) UV-irradiation has been established. The kinetics of lethal and mutagenic effects of 8-MOP+light was studied. The efficiency of mutagenesis on the first linear part of mutation curve was 0.3% per the lethal hit which is 2 times lower than that of shortwave (lambda=254 nm) UV-irradiation. The maximum yield of mutants makes up 1%, after which the mutation curve is maintained. It has been established that the main (may be the only) contribution into mutagenesis is made by monoadducts, whereas the lethal effect is conditioned by diadducts (cross-links). The comparison of the efficiency of mutagenic effects of 8-MOP+light with mutagenic effects of other kinds of irradiations was carried out. The possibility of repair of damaged 8-MOP+light phage sd DNA by transfection of Escherichia coli C (uvr+) and Cs (uvr-) lysozyme spheroplasts has been established. The repair mechanism of photodamage in intact phage sd induced with 8-MOP+light was also investigated using the method of two-step irradiation. It has been shown that 65% of photodamages are repaired in E. coli SK cells in the M9 medium, i. e. under cellular metabolism. The recovery of phage sd is completely inhibited in phosphate buffer. Unlike chloramphenicol (150 microgram/ml), 1% caffeine blocks the phage recovery only by 30%. The participation of phage sd determining enzymes in its intracellular recovery from 8-MOP+light damages is assumed.     

Repair of depurinated DNA with enzymes from rat liver chromatin.

DNA from T7 phage containing AP (apurinic/apyrimidinic) sites was repaired by the successive actions of three chromatin enzymes [AP endodeoxyribonuclease, DNAase IV (5'----3'-exodeoxyribonuclease) and DNA polymerase-beta] prepared from rat liver and T4-phage DNA ligase. Since DNA ligase is also found in rat liver chromatin, all the activities used for the successful repair in vitro are thus present in the chromatin of a eukaryotic cell. Our results show, in particular, that the chromatin DNAase IV is capable of excising the AP site from the DNA strand nicked by the chromatin AP endodeoxyribonuclease. We did not try to combine all the enzymes, since competition between some of them might have prevented the repair; we have, for instance, shown that DNA ligase can seal the incision 5' to the AP site made by the AP endodeoxyribonuclease. Changes in chromatin structure during repair might perhaps prevent this competition when nuclear DNA is repaired in the living cell.     

In vitro repair of UV-or X-irradiated bacteriophage T4 DNA by extract from blue-green alga Anacystis nidulans

The cell-free extract from blue-green alga Anacystis nidulans contains enzymatic activities which repair in vitro transforming DNA of bacteriophage T4 damaged by UV light or X-rays. The repair effect of the extract was observed with double-stranded irradiated DNA but not with denatured irradiated DNA. The level of restoration of the transforming activity depends on the protein concentration in the reaction mixture and on the dose of irradiation. A fraction of DNA lesions induced by X-rays is repaired by a NAD-dependent polynucleotide ligase present in the extract. The repair of UV-induced lesions is the most efficient in the presence of magnesium ions, NAD, ATP and the four deoxynucleoside triphosphates. The results indicate that the repair of UV-irradiated DNA is performed with the participation of DNA polymerase and polynucleotide ligase which function in the cell-free extract of the algae on the background of a low deoxyribonuclease activity.Abbreviations UV ultraviolet - TA transforming activity - PN-ligase polynucleotide ligase - NAD nicotinamide adenine dinucleotide - dNTP deoxynucleoside triphosphates - dATP, dGTP, dTTP triphosphates of deoxyadenosine, deoxyguanosine, deoxythymidine and deoxycytidine, respectively     

Effect of ultraviolet radiation on the Bacillus subtilis phages SPO2, SPP1 and phi 29 and their DNAs

A comparative study of the effects of ultraviolet radiation on three Bacillus subtilis phages is presented. Phages phi 29, SPP1 and SPO2c12 or their DNAs were irradiated by UVC (254 nm) and quantum yields for inactivation were calculated. For each phage, the purified DNA was found to be more sensitive than the intact virus when assayed in a uvr+ host. The data imply that this is because transfecting DNA is repaired less efficiently than DNA of the intact phage; rather than because of differences in sensitivity to lesion production. Even though phi 29 has the smallest target size of the three phages, phi 29 and its DNA are the most sensitive. Phages SPO2 and SPP1 code for gene products which complement the repair system of the host. The transfecting DNA of phage SPP1 is extremely sensitive to UV damage when assayed in a uvr-host. This is attributed to the fact that in transfection SPP1 DNA must undergo recombination for productive infection to occur. The recombination process strongly interferes with the repair of damaged DNA.     

Genetic and physiological studies of an Escherichia coli locus that restricts polynucleotide kinase- and RNA ligase-deficient mutants of bacteriophage T4.

The RNA ligase and polynucleotide kinase of bacteriophage T4 are nonessential enzymes in most laboratory Escherichia coli strains. However, T4 mutants which do not induce the enzymes are severely restricted in E. coli CTr5X, a strain derived from a clinical E. coli isolate. We have mapped the restricting locus in E. coli CTr5X and have transduced it into other E. coli strains. The restrictive locus seems to be a gene, or genes, unique to CTr5X or to be an altered form of a nonessential gene, since deleting the locus seems to cause loss of the phenotypes. In addition to restricting RNA ligase- and polynucleotide kinase-deficient T4, the locus also restricts bacteriophages lambda and T4 with cytosine DNA. When lambda or T4 with cytosine DNA infect strains with the prr locus, the phage DNA is injected, but phage genes are not expressed and the host cells survive. These phenotypes are unlike anything yet described for a phage-host interaction.     

Transfection of Escherichia coli Spheroplasts IV. Transfection of rec+ and rec? Spheroplasts by Native,Denatured, and Renatured T5 Bacteriophage DNA After Repair of Single-Strand Breaks by Polynucleotide Ligase

Transfection of Escherichia coli spheroplasts by native T5 phage DNA was not affected by treatment with polynucleotide ligase. Denatured T5 phage DNA infectivity, only 0.1% of the native DNA level, was increased slightly by polynucleotide ligase treatment. Renatured T5 phage DNA infectivity was also increased slightly by polynucleotide ligase treatment. To form an infective center with rec(+) spheroplasts, 1.6 to 2.1 native T5 phage DNA molecules were required; however, 1.4 T5 phage DNA molecules were required to form an infective center with recA(-)B(-) spheroplasts, and one molecule was sometimes sufficient for rec B(-) spheroplasts. Polynucleotide ligase treatment of T5 phage DNA had no effect on these parameters. Thus, the single-strand interruptions of T5 phage DNA are probably not essential to the survival of the parental T5 phage DNA, and T5 phage DNA, especially the denatured form, is highly sensitive to some nucleases in E. coli spheroplasts.     

In vitro repair of double-strand breaks accompanied by recombination in bacteriophage T7 DNA.

A double-strand break in a bacteriophage T7 genome significantly reduced the ability of that DNA to produce viable phage when the DNA was incubated in an in vitro DNA replication and packaging system. When a homologous piece of T7 DNA (either a restriction fragment or T7 DNA cloned into a plasmid) that was by itself unable to form a complete phage was included in the reaction, the break was repaired to the extent that many more viable phage were produced. Moreover, repair could be completed even when a gap of about 900 nucleotides was put in the genome by two nearby restriction cuts. The repair was accompanied by acquisition of a genetic marker that was present only on the restriction fragment or on the T7 DNA cloned into a plasmid. These data are interpreted in light of the double-strand gap repair mode of recombination.     

In Vitro Packaging of UV Radiation-Damaged DNA from Bacteriophage T7

When DNA from bacteriophage T7 is irradiated with UV light, the efficiency with which this DNA can be packaged in vitro to form viable phage particles is reduced. A comparison between irradiated DNA packaged in vitro and irradiated intact phage particles shows almost identical survival as a function of UV dose when Escherichia coli wild type or polA or uvrA mutants are used as the host. Although uvrA mutants perform less host cell reactivation, the polA strains are identical with wild type in their ability to support the growth of irradiated T7 phage or irradiated T7 DNA packaged in vitro into complete phage. An examination of in vitro repair performed by extracts of T7-infected E.coli suggests that T7 DNA polymerase may substitute for E. coli DNA polymerase I in the resynthesis step of excision repair. Also tested was the ability of a similar in vitro repair system that used extracts from uninfected cells to restore biological activity of irradiated DNA. When T7 DNA damaged by UV irradiation was treated with an endonuclease from Micrococcus luteus that is specific for pyrimidine dimers and then was incubated with an extract of uninfected E. coli capable of removing pyrimidine dimers and restoring the DNA of its original (whole genome size) molecular weight, this DNA showed a higher packaging efficiency than untreated DNA, thus demonstrating that the in vitro repair system partially restored the biological activity of UV-damaged DNA.     

Host transfer RNA cleavage and reunion in T4-infected Escherichia coli CTr5x.

T4 mutants lacking polynucleotide kinase (pnk-) or RNA ligase (rli-) do not grow on E. coli CTr5x. During the abortive infections there accumulate host tRNA fragments that match into two species severed 3' to the anticodon. The CTr5x-specific fragments appear only transiently with wt phage, implicating the affected enzymes in phosphoryl group rearrangement and religation [David et al. (1982) Virol. 123, 480]. In a search for the vulnerable host tRNAs and putative religation products, tRNA ensembles from uninfected E. coli CTr5x or cells infected with various phage strains were fractionated and compared. A tRNA species absent from rli- infected cells but present in uninfected cells or late in wt infection was thus detected. RNase T1 finger prints of this species, isolated before or after wt infection, were compared with that of an in vitro ligated pair of CTr5x-specific fragments. The results indicated that this tRNA is cleaved upon infection and later on restored to it's original or to a very similar form, by polynucleotide kinase and RNA ligase reactions. It is suggested that depletion of such vulnerable host tRNA species underlies the restriction of pnk- or rli- phage on E. coli CTr5x.     

Bacteriophage T4 anticodon nuclease, polynucleotide kinase and RNA ligase reprocess the host lysine tRNA.

Host tRNAs cleaved near the anticodon occur specifically in T4-infected Escherichia coli prr strains which restrict polynucleotide kinase (pnk) or RNA ligase (rli) phage mutants. The cleavage products are transient with wt but accumulate in pnk- or rli- infections, implicating the affected enzymes in repair of the damaged tRNAs. Their roles in the pathway were elucidated by comparing the mutant infection intermediates with intact tRNA counterparts before or late in wt infection. Thus, the T4-induced anticodon nuclease cleaves lysine tRNA 5' to the wobble position, yielding 2':3'-P greater than and 5'-OH termini. Polynucleotide kinase converts them into a 3'-OH and 5' P pair joined in turn by RNA ligase. Presumably, lysine tRNA depletion, in the absence of polynucleotide kinase and RNA ligase mediated repair, underlies prr restriction. However, the nuclease, kinase and ligase may benefit T4 directly, by adapting levels or decoding specificities of host tRNAs to T4 codon usage.     

Bacteriophage T4 Inhibits Colicin E2-Induced Degradation of Escherichia coli Deoxyribonucleic Acid I. Protein Synthesis-Dependent Inhibition

The deoxyribonucleic acid (DNA) of Escherichia coli B is converted by colicin E2 to products soluble in cold trichloroacetic acid; we show that this DNA degradation (hereafter termed solubilization) is subject to inhibition by infection with bacteriophage T4. At least two modes of inhibition may be differentiated on the basis of their sensitivity to chloramphenicol. The following observations on the inhibition of E2 by phage T4 in the absence of chloramphenicol are described: (i) Simultaneous addition to E. coli B of E2 and a phage mutated in genes 42, 46, and 47 results in a virtually complete block of the DNA solubilization normally induced by E2; the mutation in gene 42 prevents phage DNA synthesis, and the mutations in genes 46 and 47 block a late stage of phage-induced solubilization of host DNA. (ii) This triple mutant inhibits equally well when added at any time during the E2-induced solubilization. (iii) Simultaneous addition to E. coli B of E2 and a phage mutated only in gene 42 results in extensive DNA solubilization, but the amount of residual acid-insoluble DNA (20 to 25%) is more characteristic of phage infection than of E2 addition (5% or less). (iv) denA mutants of phage T4 are blocked in an early stage (endonuclease II) of degradation of host DNA; when E2 and a phage mutated in both genes 42 and denA are added to E. coli B, extensive solubilization of DNA occurs with a pattern identical to that observed upon simultaneous addition of E2 and the gene 42 mutant. (v) However, delaying E2 addition for 10 min after infection by this double mutant allows the phage to develop considerable inhibition of E2. (vi) Adsorption of E2 to E. coli B is not impaired by infection with phage mutated in genes 42, 46, and 47. In the presence of chloramphenicol, the inhibition of E2 by the triple-mutant (genes 42, 46, and 47) still occurs, but to a lesser extent.     

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.     

Physiological and Genetic Aspects of Abortive Infection of a Shigella sonnei Strain by Coliphage T7

Phage T7 adsorbed to and lysed cells of Shigella sonnei D(2) 371-48, although the average burst size was only 0.1 phage per cell (abortive infection). No mechanism of host-controlled modification was involved. Upon infection, T7 rapidly degraded host deoxyribonucleic acid (DNA) to acid-soluble material. Phage-directed DNA synthesis was initiated normally, but after a few minutes the pool of phage DNA, including the parental DNA, was degraded. Addition of chloramphenicol, at the time of phage infection, prevented both the initiation of phage-directed DNA synthesis and the degradation of parental phage DNA. Addition of chloramphenicol 4.5 min after phage was added permitted the onset of phage-directed DNA synthesis but prevented breakdown of phage DNA. Mutants of T7 (ss(-) mutants) have been isolated which show normal growth in strain D(2) 371-48. Upon mixed infection of this strain with T7 wild type and an ss(-) mutant, infection was abortive; no complementation occurred. The DNA of the ss(-) mutants was degraded in mixed infection like that of the wild type. Revertant mutants which have lost their ability to grow on D(2) 371-48 were isolated from ss(-) mutants; they are, in essence, phenotypically like T7 wild type. Independently isolated revertants of ss(-) mutants did not produce ss(-) recombinants when they were crossed among themselves. When independently isolated ss(-) mutants were crossed with each other, wild-type recombinants were found; ss(-) mutants could then be mapped in a cluster compatible with the length of one cistron. We concluded that T7 codes for an active, chloramphenicol-sensitive function [ss(+) function (for suicide in Shigella)] which leads to the breakdown of phage DNA in the Shigella host.     

Different photodynamic action of proflavine and methylene blue on bacteriophage

Summary Photodynamically induced DNA damage in Serratiaphase may be repaired by the host cell. The extent of this host cell reactivation (HCR) depends on the photosensitizing dye used: HCR of proflavine+visible light induced DNA damage appears to be more efficient than the one of DNA damage induced by methylene blue+visible light. This significant difference in HCR is not due to a preferential inhibition of the enzymes of DNA dark repair by either one of the dyes injected into the host cell along with the phage's genome.