Ultraviolet reactivation of lambda phage: assay of infectivity of DNA molecules by spheroplast transfection

Prior irradiation of non-lysogenic bacteria by ultraviolet light leads to an increase in the viability of infecting irradiated λ phage (ultraviolet reactivation). Similarly, u.v. irradiation of wild type or uvrD bacteria lysogenic for λcIind^? increased the fraction of closed circular duplex phage DNA molecules formed after infection with u.v.-irradiated λ phage. The closed circular molecules isolated from the irradiated lysogens were shown to be free from u.v. damage by a spheroplast transfection assay. The increase of closed circular molecules is sufficient to explain the ultraviolet reactivation observed by the increase of viability of irradiated phage.In ultraviolet reactivation, damage must be erased on irradiated DNA molecules and the repair is independent of total replication of phage genomes, exchange of sister chromatids or recombination between phage genomes. Protein synthesis is necessary to increase the level of closed circular molecules of irradiated λ phage after irradiation of bacteria.     

Formation of pure and mixed clones of c mutants in serratiaphage sigma after treatment of the free virion with UV or hydroxylamine

The clone composition of c mutants of phage σ induced by UV irradiation of the free virion was studied, using Hcr⁺, Hcr^? and UV-irradiated Hcr⁺ cells as hosts and 2, 3 and 4 different UV doses, respectively. Most of the c plaques contained only mutant phages, and the distribution of mosaics was asymmetrical, i.e. most mixed clones contained >80% mutant type. The frequency of mosaics decreased with increasing UV dose in all three host systems; however, the decrease was significant only with the UV-irradiated Hcr⁺ host. Propagation of UV-irradiated σ in Hcr⁺ and Hcr^? hosts, respectively, did not lead to a significant difference in the frequency of mosaics, but, using UV-irradiated Hcr⁺ host significantly increased the percentage of mixed clones.The composition of plaques containing c mutants, after UV irradiation and treatment with hydroxylamine, was also studied by picking and testing all plaques (mutant and wild-type) of the survivors of a single UV dose and a single incubation time, respectively. In both experiments, besides pure and nearly pure (visible) c mutant plaques, many cryptic mutants containing predominantly >20% mutant type were found. The distribution of mosaics was of an almost “inverse symmetrical” type, the class of clones with about 50% mutant and 50% wild-type being the rarest.From these results incomplete recombinational repair is suggested to be responsible for the formation of pure mutant clones in mutation induction.     

On the mutagenicity of nitrofurans

UV (254 nm)-irradiated Tr phages infecting excision-repair-proficient E. coli cells undergo host-cell reactivation (HCR). Typically, the resulting survival curve is of a hetero-component type, i.e. extrapolation of the shallower curve component to zero UV dose gives ordinate values p < 1. This characteristics is accentuated if HCR is inhibited by UV irradiation of host cells prior to phage infection, or by the presence of caffeine or acriflavine. With increasing strenght of the inhibitory condition, p decreases and the slope of the steeper curve component increases, but the slope of the shallower curve component changes very little. In contrast, single-component curves are observed for Tr infecting excision-repair-deficient host cells, or for Tr undergoing photoenzymatic repair in these cells either with or without inhibition by caffeine or preirradiation of host cells. This indicates that throughout the population UV lesions are photorepaired or photorepair-inhibited independently of one another.Discussion of various possible interpretations of the hetero-component curves in the case of HCR suggests the existence of two modes of excision repair, one of them leading to a high degree of interdependence between repair events within individual phage particles. This mode of repair, which determines the slope and position of the shallower curve component, requires within an infected cell the occurrence of a “critical event”, whose probability is considerably lower than i and decreases with the strength of HCR inhibition. The other mode, leading to independent repair events, is of minor importance under our usual plating conditions, but plays a predominant role in liquid-holding recovery of the phage.     

A deficiency in the repair of UV and γ-ray damaged DNA in fibroblasts from Cockayne's syndrome

The host-cell reactivation of V antigen production for irradiated adenovirus was examined in fibroblasts from 5 unrelated patients with Cockayne's syndrome (CS) and 2 CS heterozygotes. The fibroblast cultures were infected with either irradiated or non-irradiated adenovirus and subsequently examined for the presence of viral structural antigens using immunofluorescent staining. All CS-homozygous strains showed a reduced host-cell reactivation (HCR) of this viral function for both UV- and γ-irradiated virus. For UV-irradiation of the virus, D₃₇ values expressed as a percentage of that obtained on normal strains, ranged from 14 to 35%. For γ-irradiation of the virus these values ranged from 61 to 80%. These results indicate some defect in the repair of both UV- and γ-ray-induced DNA damage for CS. 1 CS-heterozygote strain tested also showed a reduced HCR for UV-irradiated adenovirus intermediate between that of the patient strain and normal, whereas another CS-heterozygote strain showed an apparently normal HCR level.     

Participation of rec genes of Escherichia coli K 12 in W-reactivation of UV-irradiated phage lambda.

The effect of the recombinational deficiency on W-reactivation of UV-damaged phage lambda was explored. In this paper we show that W-reactivation is reduced by the recB21 and recF143 mutations after bleomycin (BM) and UV treatment. Combination of these mutations in the recB21recF143 double mutant blocks W-reactivation completely after BM induction, but leaves residual W-reactivation ability after UV-irradiation, which is abolished by the introduction of uvrB deficiency (delta(uvrB-chlA]. W-reactivation has been rendered constitutive in recB21C22sbcB15, but the efficiency of reactivation remained virtually constant over the range of BM and UV doses, indicating the role of the RecBC(D) enzyme in W-reactivation.     

W-reactivation of phage lambda in recF, recL, uvrA, and uvrB mutants of E. coli K-12.

Summary Assay conditions are described which permit detection of cryptic temperature sensitive RNA polymerases in vitro. RNA polymerase was prepared from fifteen different temperature sensitive mutants of Salmonella typhimurium chosen at random from a larger group isolated by localized mutagenesis and uridine suicide techniques. The dependence of enzyme activity on temperature, ionic strength and pH was studied in vitro. Assays at higher ionic strength (0.23 M) and temperature (50°C) distinguish three classes of mutants (Table 2). Activity of seven mutant RNA polymerases (called Class 1) under these conditions was 1% to 5% that of the parental RNA polymerase. Five mutant RNA polymerases (called Class 2) had 18% to 64% of the parental activity and three were not distinguishable from the parental enzyme under these conditions. Mixing experiments showed that the defect in Class 1 mutant enzymes is a property of the enzymes and not due to a diffusible inhibitor. In one case the lesion was shown to reside in the core enzyme. Class 1 mutant RNA polymerases were shown to be irreversibly inactivated during the assay at higher temperature and ionic strength. This suggests that the Class 1 enzymes may be more thermolabile than the wild type enzyme or may fail to be protected from thermal denaturation by formation of a ternary complex with template and product. We conclude that the method used to isolate these mutants (Young et al., 1976) and the assay described here (Table 2) are efficient ways to isolate and detect temperature sensitive RNA polymerase mutants of Salmonella typhimurium.     

Dark recovery of UV-irradiated phage T1 I. A minor recovery effect whose exclusion permits the study of survival kinetics under presumably repairless conditions

The survival of UV-irradiated phage T1 is much lower in excision repair-deficient than in excision repair-proficient E. coli cells, due to lack of “host cell reactivation” (HCR). An additional decrease in phage survival occurs when repair-deficient (HCR⁻) host cells have been exposed to UV doses from 3000–10 000 erg mm⁻² of 254 nm UV-radiation prior to infection. The observed effect is attributed to loss of a minor phage recovery process, which requires neither the bacterial excision repair nor the bacterial REC repair system. This type of recovery is little affected by caffeine or acriflavine at concentrations that preclude HCR completely. Its full inhibition by UV-irradiation of the cells requires an approximately 8 times larger dose than complete inhibition of HCR.

In heavily preirradiated cells, the T1 burst size is extremely small and multiplicity reactivation is considerably less extensive than in unirradiated cells. Presumably the survival of singly infecting T1 in these cells reflects absence of any type of repair. The observed phage sensitivity and shape of the curve are compatible with the expectation for completely repairless conditions. The mechanism underlying the minor recovery is not known; theoretical considerations make a phage REC repair mechanism seem likely.     

Following cell-fate in E. coli after infection by phage lambda

The system comprising bacteriophage (phage) lambda and the bacterium E. coli has long served as a paradigm for cell-fate determination. Following the simultaneous infection of the cell by a number of phages, one of two pathways is chosen: lytic (virulent) or lysogenic (dormant). We recently developed a method for fluorescently labeling individual phages, and were able to examine the post-infection decision in real-time under the microscope, at the level of individual phages and cells. Here, we describe the full procedure for performing the infection experiments described in our earlier work. This includes the creation of fluorescent phages, infection of the cells, imaging under the microscope and data analysis. The fluorescent phage is a "hybrid", co-expressing wild- type and YFP-fusion versions of the capsid gpD protein. A crude phage lysate is first obtained by inducing a lysogen of the gpD-EYFP (Enhanced Yellow Fluorescent Protein) phage, harboring a plasmid expressing wild type gpD. A series of purification steps are then performed, followed by DAPI-labeling and imaging under the microscope. This is done in order to verify the uniformity, DNA packaging efficiency, fluorescence signal and structural stability of the phage stock. The initial adsorption of phages to bacteria is performed on ice, then followed by a short incubation at 35°C to trigger viral DNA injection. The phage/bacteria mixture is then moved to the surface of a thin nutrient agar slab, covered with a coverslip and imaged under an epifluorescence microscope. The post-infection process is followed for 4 hr, at 10 min interval. Multiple stage positions are tracked such that ~100 cell infections can be traced in a single experiment. At each position and time point, images are acquired in the phase-contrast and red and green fluorescent channels. The phase-contrast image is used later for automated cell recognition while the fluorescent channels are used to characterize the infection outcome: production of new fluorescent phages (green) followed by cell lysis, or expression of lysogeny factors (red) followed by resumed cell growth and division. The acquired time-lapse movies are processed using a combination of manual and automated methods. Data analysis results in the identification of infection parameters for each infection event (e.g. number and positions of infecting phages) as well as infection outcome (lysis/lysogeny). Additional parameters can be extracted if desired.     

Primary structure of an EcoRI fragment of lambda imm434 DNA containing regions cI-cro of phage 434 and cII-o of phage lambda.

Digestion of phage lambda imm434 DNA with restriction endonuclease EcoRI yields 7 fragments. The shortest among them (1287 bp) contains the right part of the phage 434 immunity region and the phage DNA portion proximal to it. The complete primary structure of this fragment has been determined using the chemical method of DNA sequencing. Hypothetical amino-acid sequences of proteins coded by the cro gene of phage 434 and the cII gene of phage lambda, as well as NH2-terminal amino-acid sequences of the cI protein of phage 434 and the O protein of phage lambda, have been deduced solely on the basis of the DNA sequence. The fragment studied contains also the pR and probably prm promoters and the oR operator of phage 434. The sequence coding for them differs from the respective DNA sequence of phage lambda.     

Cloning and characterization of the termination site tI for the gene int transcript in phage lambda

A series of plasmid vectors containing the multiple cloning site (MCS7) of M13mp7 has been constructed. In one of these vectors a kanamycin-resistance marker has been inserted into the center of the symmetrical MCS7 to yield a restriction-site-mobilizing element (RSM). The drug-resistance marker can be cleaved out of this vector with any of the restriction enzymes that recognize a site of the flanking sequences of the RSM to generate an RSM with either various sticky ends or blunt ends. These fragments can be used for insertion mutagenesis of any target molecule with compatible restriction sites. Insertion mutants are selected by their resistance to kanamycin. When the drug-resistance marker is removed with PstI, a small in-frame insertion can be generated. In addition, two new MCSs having single restriction sites have been formed by altering the symmetrical structure of MCS7. The resulting plasmids pUC8 and pUC9 allow one to clone doubly digested restriction fragments separately with both orientations in respect to the lac promoter. The terminal sequences of any DNA cloned in these plasmids can be characterized using the universal M13 primers.     

The last duplex base-pair of the phage lambda chromosome. Involvement in packaging, ejection and routing of lambda DNA.

cosN is the site at which the bacteriophage lambda DNA packaging enzyme, terminase, introduces staggered nicks to generate the cohesive ends of mature lambda chromosomes. Genetic and molecular studies show that cosN is recognized specifically by terminase and that effects of cosN mutations on lambda DNA packaging and cosN cleavage are well correlated. Mutations affecting a particular base-pair of cosN are unusual in being lethal in spite of causing only a moderate defect in cosN cleavage and DNA packaging. The particular base-pair is the rightmost duplex base-pair in mature chromosomes, at position 48,502 in the numbering system of Daniels et al; herein called position - 1. A G.C to T.A transversion mutation at position - 1, called cosN - 1T, reduces the particle yield of lambda fivefold, and the particles formed are not infectious. lambda cosN - 1T particles have wild-type morphology, and contain chromosomes that have normal cohesive ends. The chromosomes of lambda cosN - 1T particles, like the chromosomes of lambda + particles, are associated with the tail. lambda cosN - 1T particles, in spite of being normal structurally, are defective in injection of DNA into a host cell. Only approximately 25% of lambda cosN - 1T particles are able to eject DNA from the capsid in contrast to 100% for lambda +. Furthermore, for the 25% that do eject, there is a further injection defect because the ejected lambda cosN - 1T chromosomes fail to cyclize, in contrast to the efficient cyclization found for wild-type chromosomes following injection. The cosN - 1T mutation has no effect on Ca2+ mediated transformation by lambda DNA, indicating that the effect of the mutation on DNA fate is specific to the process of DNA injection. Models in which specific DNA : protein interactions necessary for DNA injection, and involving the rightmost base-pair of the lambda chromosome, are considered.     

Detection of mutagen-induced lesions in isolated DNA by marker rescue of Bacillus subtilis phage phi 105

A new mutagenesis assay is described which detects the induction of forward mutations in isolated DNA. The assay utilizes replicative from DNA of the temperate Bacillus subtilis phage φ105 and tests the ability of chemicals to induce lesions which inactivate phage genes involved in lysogen formation. There is a cluster of such genes tightly linked to the φ105 genetic marker Jsus11 which restricts the host range of the phage to cells capable of suppressing sus mutations. In the actual assay chemically treated DNA, from wild-type J⁺ phage, is added to competent cells which are infected with φ105Jsus11. Wild-type phage, capable of producing plaques on cells which are nonpermissive for φ105Jsus11, are produced by recombination between the added chemically-treated DNA and infecting φ105Jsus11 DNA. If the added DNA also carried mutagenic lesions in any of the genes controlling lysogeny, clear plaque mutants are produced which are readily distinguishable from the turbid plaquing wild-type phage. This report demonstrates the capacity of this marker rescue-based assay to detect as mutagens the following DNA-reactive chemicals: hydroxylamine (HA); N-methyl-N′-nitro-N-nitrosoguanidine (MNNG); chloroacetaldehyde (CAA); propylene oxide (PO) and N-acetyl-N-acetoxy-2-amino-fluorene (AAAF). The effect of using a host cell, defective for excision repair, on the sensitivity with which the assay detected the mutagenic activities of CAA, PO and AAAF also was examined.The new mutagenesis assay offers 2 advantages over several other previously described transformation-based assays: (1) in contrast to assays based on the induction of ribosome-associated drug resistances, the new assay can detect frameshift as well as base-substitution-type mutagens and (2) the mutants generated can be detected at high plating densities. The assay thus may be useful for general mutagen screening especially with highly bactericidal compounds which are not readily tested in other microbial assays.     

Effect of Mg2+ during reactivation and refolding of guanidine hydrochloride-denatured creatine kinase

Creatine kinase (ATP: creatine N-phosphotransferase, EC 2.7.3.2) was completely denatured using 3 M guanidine hydrochloride for 2 h as in previous studies [Yao et al. (1982), Sci. Sin. 25B, 1296–1302; Yao et al. (1984), Biochemistry 23, 2740–2744; Yao et al. (1982), Sci. Sin. 25B, 1186–1193]. Under suitable conditions, about 60–70% of the activity can be recovered in the presence of different Mg²⁺ concentrations. Both the reactivation and the refolding processes follow two-phase courses after dilution in the proper solutions. A comparison of the rate constants for the refolding of unfolded creatine kinase with those for the recovery of its catalytic activity at various Mg²⁺ concentrations shows that these are not synchronized. The reactivity of guanidine hydrochloride-denatured creatine kinase can be inhibited by Mg²⁺; however, the rates of reactivation are independent of the Mg²⁺ concentration. In addition, Mg²⁺ affects the fluorescence intensity, but the rate constants of refolding are independent of Mg²⁺ concentration. Although the reactivation of GdHCl-denatured creatine kinase is complete about 3 h after dilution with reactivation solutions, the conformational changes during refolding occur in a much slower reaction. Mg²⁺ can induce complex changes in the relative fluorescence intensity during refolding over a broad range of concentrations.