Inducible reactivation of bacteriophage T7 damaged by methyl methanesulfonate or UV light.

We examined the effects of host mutations affecting "SOS"-mediated UV light reactivation on the survival of bacteriophage T7 damaged by UV light or methyl methanesulfonate (MMS). Survival of T7 alkylated with MMS was not affected by the presence of plasmid pKM101 or by a umuC mutation in the host. The survival of UV light-irradiated T7 was similar in umuC+ and umuC strains but was slightly enhanced by the presence of pKM101. When phage survival was determined on host cells preirradiated with a single inducing dose of UV light, these same strains permitted higher survival than that seen with noninduced cells for both UV light- and MMS-damaged phage. The extent of T7 reactivation was approximately proportional to the UV light inducing dose inflicted upon each bacterial strain and was dependent upon phage DNA damage. Enhanced survival of T7 after exposure to UV light or MMS was also observed after thermal induction of a dnaB mutant. Thus, lethal lesions introduced by UV light or MMS are apparently repaired more efficiently when host cells are induced for the SOS cascade, and this inducible reactivation of T7 is umuC+ independent.     

Role of exonuclease III and endonuclease IV in repair of pyrimidine dimers initiated by bacteriophage T4 pyrimidine dimer-DNA glycosylase.

The role of exonuclease III and endonuclease IV in the repair of pyrimidine dimers in bacteriophage T4-infected Escherichia coli was examined. UV-irradiated T4 showed reduced survival when plated on an xth nfo double mutant but showed wild-type survival on either single mutant. T4 denV phage were equally sensitive when plated on wild-type E. coli or an xth nfo double mutant, suggesting that these endonucleases function in the same repair pathway as T4 pyrimidine dimer-DNA glycosylase. A uvrA mutant of E. coli in which the repair of pyrimidine dimers was dependent on the T4 denV gene carried on a plasmid was constructed. Neither an xth nor an nfo derivative of this strain was more sensitive than the parental strain to UV irradiation. We were unable to construct a uvrA xth nfo triple mutant. In addition, T4, which turns off the host UvrABC excision nuclease, showed reduced plating efficiency on an xth nfo double mutant.     

Survival and mutagenesis of bacteriophage T7 damaged by methyl methanesulfonate and ethyl methanesulfonate

We have examined survival and mutagenesis of bacteriophage T7 after exposure to the alkylating agents methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS). It was found that although both alkylating agents caused increased reversion of specific T7 mutations, EMS caused a higher frequency of reversion than did MMS. Exposure of the host cells to ultraviolet light so as to induce the SOS system resulted in increased survival (Weigle reactivation) of T7 phage damaged with either EMS or MMS. However, after SOS induction of the host we did not detect an accompanying increase in mutation frequency measured as either reversion of specific T7 mutants or by generation of mutations in the T7 gene that codes for phage ligase. Neither mutation frequency nor survival of alkylated phage was affected by the umuD,C mutation in the Escherichia coli host nor by the presence of plasmid pKM101. This may mean that the mode of Weigle reactivation that is detected in T7 is not mutagenic in nature.     

Repair-defective mutants of Alteromonas espejiana, the host for bacteriophage PM2

The in vivo repair processes of Alteromonas espejiana, the host for bacteriophage PM2, were characterized, and UV- and methyl methanesulfonate (MMS)-sensitive mutants were isolated. Wild-type A. espejiana cells were capable of photoreactivation, excision, recombination, and inducible repair. There was no detectable pyrimidine dimer-DNA N-glycosylase activity, and pyrimidine dimer removal appeared to occur by a pathway analogous to the Escherichia coli Uvr pathway. The UV- and MMS-sensitive mutants of A. espejiana included three groups, each containing at least one mutation involved with excision, recombination, or inducible repair. One group that was UV sensitive but not sensitive to MMS or X rays showed a decreased ability to excise pyrimidine dimers. Mutants in this group were also sensitive to psoralen plus near-UV light and were phenotypically analogous to the E. coli uvr mutants. A second group was UV and MMS sensitive but not sensitive to X rays and appeared to contain mutations in a gene(s) involved in recombination repair. These recombination-deficient mutants differed from the E. coli rec mutants, which are MMS and X-ray sensitive. The third group of A. espejiana mutants was sensitive to UV, MMS, and X rays. These mutants were recombination deficient, lacked inducible repair, and were phenotypically similar to E. coli recA mutants.     

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.     

Identification and preliminary characterization of a mutant defective in the bacteriophage T4-induced unfolding of the Escherichia coli nucleoid.

The nucleoids of Escherichia coli S/6/5 cells are rapidly unfolded at about 3 min after infection with wild-type T4 bacteriophage or with nuclear disruption deficient, host DNA degradation-deficient multiple mutants of phage T4. Unfolding does not occur after infection with T4 phage ghosts. Experiments using chloramphenicol to inhibit protein synthesis indicate that the T4-induced unfolding of the E. coli chromosomes is dependent on the presence of one or more protein synthesized between 2 and 3 min after infection. A mutant of phage T4 has been isolated which fails to induce this early unfolding of the host nucleoids. This mutant has been termed "unfoldase deficient" (unf-) despite the fact that the function of the gene product defective in this strain is not yet known. Mapping experiments indicate that the unf- mutation is located near gene 63 between genes 31 and 63. The folded genomes of E. coli S/6/5 cells remain essentially intact (2,000-3,000S) at 5 min after infection with unfoldase-, nuclear disruption-, and host DNA degradation-deficient T4 phage. Nuclear disruption occurs normally after infection with unfoldase- and host DNA degradation-deficient but nuclear disruption-proficient (ndd+), T4 phage. The host chromosomes remain partially folded (1,200-1,800S) at 5 min after infection with the unfoldase single mutant unf39 x 5 or an unfoldase- and host DNA degradation-deficient, but nuclear disruption-proficient, T4 strain. The presence of the unfoldase mutation causes a slight delay in host DNA degradation in the presence of nuclear disruption but has no effect on the rate of host DNA degradation in the absence of nuclear disruption. Its presence in nuclear disruption- and host DNA degradation-deficient multiple mutants does not alter the shutoff to host DNA or protein synthesis.     

Ultraviolet-Sensitive Mutator Strain of Escherichia coli K-12

An ultraviolet (UV)-sensitive mutator gene, mutU, was identified in Escherichia coli K-12. The mutation mutU4 is very close to uvrD, between metE and ilv, on the E. coli chromosome. It was recessive as a mutator and as a UV-sensitive mutation. The frequency of reversion of trpA46 on an F episome was increased by mutU4 on the chromosome. The mutator gene did not increase mutation frequencies in virulent phages or in lytically grown phage lambda. The mutU4 mutation predominantly induced transitional base changes. Mutator strains were normal for recombination and host-cell reactivation of UV-irradiated phage T1. They were normally resistant to methyl methanesulfonate and were slightly more sensitive to gamma irradiation than Mut(+) strains. UV irradiation induced mutations in a mutU4 strain, and phage lambda was UV-inducible. Double mutants containing mutU4 and recA, B, or C were extremely sensitive to UV irradiation; a mutU4 uvrA6 double mutant was only slightly more sensitive than a uvrA6 strain. The mutU4 uvrA6 and mutU4 recA, B, or C double mutants had mutation rates similar to that of a mutU4 strain. Two UV-sensitive mutators, mut-9 and mut-10, isolated by Liberfarb and Bryson in E. coli B/UV, were found to be co-transducible with ilv in the same general region as mutU4.     

A New Epistasis Group for the Repair of DNA Damage in Bacteriophage T4: Replication Repair

The gene 32 mutation amA453 sensitizes bacteriophage T4 to the lethal effects of ultraviolet (UV) irradiation, methyl methanesulfonate and angelicin-mediated photodynamic irradiation when treated particles are plated on amber-suppressing host cells. The increased UV sensitivity caused by amA453 is additive to that caused by mutations in both the T4 excision repair (denV) and recombination repair (uvsWXY) systems, suggesting the operation of a third kind of repair system. The mutation uvs79, with many similarities to amA453 but mapping in gene 41, is largely epistatic to amA453. The mutation mms1, also with many similarities to amA453, maps close to amA453 within gene 32 and is largely epistatic to uvs79. Neither amA453 nor uvs79 affect the ratio of UV-induced mutational to lethal hits, nor does amA453 affect spontaneous or UV-enhanced recombination frequencies. Gene 32 encodes the major T4 ssDNA-binding protein (the scaffolding of DNA replication) and gene 41 encodes a DNA helicase, both being required for T4 DNA replication. We conclude that a third repair process operates in phage T4 and suggest that it acts during rather than before or after DNA replication.     

Ultraviolet mutagenesis in bacteriophage T-4. I. Irradiation of extracellular phage particles

Drake, John W. (University of Illinois, Urbana). Ultraviolet mutagenesis in bacteriophage T4. I. Irradiation of extracellular phage particles. J. Bacteriol. 91:1775-1780. 1966.-Ultraviolet (UV) irradiation of extracellular T4 phage particles induces about 2 x 10(-4)r mutations per lethal hit. The mutants largely escape detection unless the irradiated phages are plated with very soft overlay agar. Multiplicity reactivation is not a prerequisite for mutagenesis. A much higher frequency of base pair substitution-type mutants is induced than is found in the spontaneous background, but sign mutants are also induced. Nearly half of the mutants map into previously identified UV hot spots. The rII mutants induced extracellularly are very similar to those induced intracellularly. The mutants also appear to result from direct radiation effects upon the bacteriophage deoxyribonucleic acid.     

Mini-Mu-duction as a test for genetic complementation in Escherichia coli.

In mini-Mu-duction, segments of host DNA bracketed between two copies of an internally deleted Mu phage (a mini-Mu) can be packaged within Mu phage particles. Upon infection of a second host strain, the DNA injected by these particles can insert into the chromosomal DNA in a reaction catalyzed by the phage A gene product (transposase), which is independent of homologous recombination. This results in a partially diploid host strain in which the duplicated host DNA is bracketed by two copies of the mini-Mu phage (Faelen et al., Mol. Gen. Genet. 176:191-197, 1979). The frequency of mini-Mu-duction reported previously was low (10(-8) to 10(-9) per recipient cell) thus limiting its use to rather stable mutational lesions. I have increased the frequency of mini-Mu-duction 10- to 100-fold by use of a helper phage lacking the kil gene and by UV irradiation of the phage stocks. I have also shown that mini-Mu-duction is a reliable complementation assay in rec+ as well as recA recipient strains. This genetic complementation test does not require prior gene localization and (due to the extended host range of phage Mu) should be applicable to many enterobacterial species.     

Host Cell Deoxyribonucleic Acid Polymerase I and the Support of T4 Bacteriophage Growth

Ultraviolet irradiation of Escherichia coli polA(-) cells reduces their capacity to support the growth of T4 phage. There is no additional loss of capacity observed in pol tsA(-)recA(-) double mutants at the nonpermissive temperature. The reversion frequency of a T4 rII mutant after ultraviolet irradiation is not changed by the absence of host deoxyribonucleic acid polymerase I.     

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.     

Effect of Thymine Starvation on Deoxyribonucleic Acid Repair Systems of Escherichia coli K-12

Thymine starvation of Escherichia coli K-12 results in greatly increased sensitivity to ultraviolet light (UV). Our studies, using isogenic strains carrying rec and uvr mutations, have shown the following. (i) Common to all strains tested is a change from multihit to single-hit kinetics of survival to UV after 60 min of thymine starvation. However, the limiting slope of UV survival curves decreases in the rec(+)uvr(+) strain and changes very little in several rec mutant strains and one uvrB mutant strain. Thus, when either the rec or uvr system is functioning alone, the limiting slopes of the UV survival curves are relatively unaffected by thymine starvation. (ii) Thymine starvation does not significantly inhibit repair processes carried out by either repair system alone; i.e., host cell reactivation of irradiated phage (carried out by the uvr system), excision of thymine dimers (uvr), or X-ray repair (rec). (iii) In a rec(+)uvr(+) strain, repair appears to be a synergistic rather than additive function of the two systems. However, after thymine starvation, repair capacity is reduced to about the sum of the repair capacities of the independent systems. (iv) The kinetics of thymineless death are not changed by rec and uvr mutations. This indicates that the lesions responsible for thymineless death are not repaired by rec or uvr systems. (v) Withholding thymine from thy rec(+)uvr(+) bacteria not undergoing thymineless death has no effect on UV sensitivity. Under these conditions one sees higher than normal UV resistance in the presence or absence of thymine. This is due to increased repair carried out by the uvr system. To explain these results we postulate that thymine starvation does not inhibit either the rec or uvr repair pathway directly. Rather it appears that thymine starvation results in increased UV sensitivity in part by inhibiting a function which normally carries out efficient coordination of rec and uvr pathways.     

Alteration of bacteriophage attachment capacity by near-UV irradiation.

Near-UV (NUV) (300 to 400 nm) and far-UV (FUV) (254 nm) radiations damage bacteriophage by different mechanisms. Host cell reactivation, Weigle reactivation, and multiplicity reactivation were observed upon FUV, but not upon NUV irradiation. Also, the number of his+ recombinants increased with P22 bacteriophage transduction in Salmonella typhimurium after FUV, but not after NUV irradiation. This loss of reactivation and recombination after NUV irradiation was not necessarily due to host incapability to repair phage damage. Instead, the phage genome failed to enter the host cell after NUV irradiation. In the case of NUV-irradiated T7 phage, this was determined by genetic crosses with amber mutants, which demonstrated that either "all" or "none" of a T7 genome entered the Escherichia coli cell after NUV treatment. Further studies with radioactively labeled phage indicated that irradiated phage failed to adsorb to host cells. This damage by NUV was compared with the protein-DNA cross-link observed previously, when phage particles were irradiated with NUV in the presence of H2O2. H2O2 (in nonlethal concentration) acts synergistically with NUV so that equivalent phage inactivation is achieved by much lower irradiation doses.     

Characterization of a bacteriophage T4 mutant lacking DNA-dependent ATPase.

A DNA-dependent ATPase has previously been purified from bacteriophage T4-infected Escherichia coli. A mutant phage strain lacking this enzyme has been isolated and characterized. Although the mutant strain produced no detectable DNA-dependent ATPase, growth properties were not affected. Burst sizes were similar for the mutant phage and T4D in polA1, recB, recC, uvrA, uvrB, uvrC, and various DNA-negative E. coli. UV sensitivity and genetic recombination were normal in a variety of E. coli hosts. Mapping data indicate that the genetic locus controlling the mutant occurs near gene 56. The nonessential nature of this gene is discussed.     

gamma-Ray mutagenesis in bacteriophage T4 is not enhanced by oxygen.

As in the induction of r mutants in bacteriophage T4 by gamma-rays, the radiation-induced reversion of T4 amber mutants to wild-type was found to depend on the product of the DNA-repair gene x of the phage. Neither the efficiency of induction of r mutants nor the efficiency of reversion of ambers was enhanced by the presence of oxygen during irradiation. T4 differed in this respect from phage T7, for which no indication has been found that gamma-ray mutagenesis results from error-prone repair of DNA damage. Notwithstanding the substantial contribution of misrepair to mutation induction in T4, the efficiency of induction per base-pair observed for irradiation under oxygen was lower than that found previously for T7.     

Studies on the substrate specificity of the T 4 excision repair endonuclease

Previous studies have shown that the v gene of bacteriophage T4 codes for an endonuclease that specifically attacks pyrimidine dimer sites in UV-irradiated DNA. The present studies have examined the role of this endonuclease in the repair of DNA damaged by nitrogen mustard, N-methyl-N′-nitro-N-nitrosoguanidine (NTG), mitomycin C and 4-nitroquinoline-N-oxide. The observation by Harm that the v gene product of phage T4 facilitates repair of UV damage to the host DNA of excision-repair defective strains enabled us to test whether it does the same with other cellular DNA lesions. It was shown that infection of UV-irradiated E. coliB_s−1 with UV-inactivated phage T4v+ resulted in rescue of a certain fraction of the host cells. However no v gene mediated repair E. coli B_s−1 was observed following treatment with the chemical agents mentioned. Furthermore, though phage T4v₁ is more sensitive to UV-irradiation than phage T4, there was no observed difference in the sensitivity of these phages to nitrogen mustard or NTG. On the basis of these observations it was concluded that the v gene coded endonuclease of T4 is specific for the excision repair of pyrimidine dimers and does not participate in the repair of chemically damaged DNA. In vitro enzymatic degradation of DNA alkylated with nitrogen mustard was observed, but it is probable that this degradation is not part of a repair reaction in vivo.     

Effectivity of bacterial repair systems in near UV radiation-induced damage

Inactivation of seven strains derived fromEscherichia coli B differing in their capacity to repair damage to their DNA (exc, pol, rec) after irradiation with far (254 nm) and middle and near (300 to 380 and 320–400 nm) UV light was investigated. The same bacterial strains were also used as hosts for the UV-irradiated pliage T7. The damage induced in bacteria and the phage by the near UV radiation was repaired only to a lesser extent by the investigated repair mechanisms or was not repaired at all.     

Genetics and Physiology of Bacteriophage T4 3′-Phosphatase: Evidence for Involvement of the Enzyme in T4 DNA Metabolism

Mutants of bacteriophage T4D which fail to induce the deoxyribonucleotide-specific T4 3'-phosphatase have been isolated. These mutants (T4pseT) grow as well as wild-type T4 in most strains of Escherichia coli, but not in the T4-sensitive "Hospital Strain," CT196, or in a derivative strain, CTr5x. Both the formation of infectious centers and the final yield of phage are reduced by 98% when CTr5x is infected by T4pseT mutants. The growth defects are accompanied by a 50% reduction in the rate of T4 DNA synthesis, a decrease in the single-strand length of the DNA product to about one-half the mature length, and greatly reduced packaging of DNA into phage particles. Introduction of an extra-cistronic suppressor mutation (stp) into T4pseT eliminates both the requirement for the T4 3'-phosphatase in infected CTr5x and the other observed effects of the pseT mutations. The pseT gene lies between genes 63 and 31. The stp gene lies in the nonessential region between rIIB and ac. Our results suggest that 3'-phosphoryl termini can disrupt T4 DNA replication to the extent that T4 3'-phosphatase becomes required for phage production.     

A Bacteriophage-lysing Strain of Staphylococcus Employed in the Manufacture of Dry Sausage

A bacteriophage of a certain Staphylococcus (a strain of Staphylococcus lactis) employed in the manufacture of dry sausage has been characterized. The host range of this bacteriophage is wide. In addition to the original host, 15 other strains (out of 40 strains tested) were found to support reproduction of the phage. The sensitive strains represented Staphylococcus saprophyticus and different types of S. lactis.

The growth rate of the bacterial host did not influence the rates of phage adsorption, nor the maximal reproduction rate of new particles. With increasing bacterial growth rate, the “lag” observed before phage reproduction started was distinctly decreased. This phase was shorter with the original host strain than with other sensitive strains.

Resistant cultures of the original host strain were easily obtained. These cultures grew as rapidly and gave as good yields of cell mass as the original phage-sensitive host. However, phage resistance was frequently lost.