THE ROLE OF HOST-CELL REPAIR IN LIQUID-HOLDING RECOVERY OF U.V.-IRRADIATED ESCHERICHIA COLI

Abstract— The experiments reported give evidence that liquid-holding recovery (LHR) of u.v. irradiated E. coli cells involves basically the same type of dark repair which causes reactivation of phage and which results in much increased survival of the cells themselves [host-cell reactivation (HCR)]. LHR is very small in the two HCR(-) strains B syn^- and B_s-1, but occurs to larger but different extents in the three HCR(+) strains B, B/r, and B/r (Λ). LHR is inhibited if the liquid contains caffeine or acriflavine, both of which are known to inhibit HCR. The results indicate that most of the LHR effect, if not all, occurs during the liquid holding, rather than under growth conditions after liquid holding. It is assumed that the holding itself allows a prolonged time for, and therefore an enhancement of, HCR. It is thus implicit that LHR can be observed only where otherwise HCR of repairable u.v. damage would be incomplete, and that different extents of LHR, as observed in the three HCR(+) strains, reflect different extents of incompleteness of HCR. It is concluded that the repairable u.v. hits which are not fully repaired by HCR are predominantly those concerned with the extra u.v. sensitivity of the strains B and B/r (Λ), relative to B/r.     

THE EFFECTS OF HOST-CELL REACTIVATION ON ASSAY OF U.V.-IRRADIATED HAEMOPHILUS INFLUENZAE TRANSFORMING DNA

Abstract— The host cell reactivation (HCR) mechanism in Haemophilus influenzae cells is inhibited by sub-microgram concentrations of acriflavine (as is already known to be true for Escherichia coli ). Exposure of these cells to similar concentrations of the drug during bacterial transformation increases the apparent ultraviolet light (u.v.) sensitivity of previously irradiated transforming DNA, indicating a repair of this DNA after uptake by the cells under normal conditions. Repair is inhibited by applying acriflavine at any time up to one hour after competent cells contact the irradiated transforming DNA. The fraction of the u.v. damage repaired by HCR is very different for different genetic markers. Those markers which are most u.v. sensitive when assayed in the absence of acriflavine are most poorly repaired, suggesting that this is the reason for their higher sensitivity. For all markers the fraction of the damage repairable by in vitro photoreactivation is approximately constant, and strongly overlaps the damage repairable by HCR. The degree of HCR achieved can be altered by experimental treatment of the H. influenzae DNA prior to transformation. Thus treatment of irradiated DNA with an enzyme from Micrococcus lysodeikticus –known to attack u.v. damaged, but not undamaged DNA–prevents subsequent intracellular repair of the same u.v. lesions whose repair is inhibited by acriflavine. Similarly, partial replacement of the thymine in transforming DNA by 5-bromouracil (BU) strongly inhibits repair of subsequent u.v. damage. As in bacteriophage, the BU effect is relieved if the u.v. exposure occurs in the presence of cysteamine. It is clear that intracellular repair must be considered in interpreting experiments with u.v.-irradiated transforming DNA.     

Photoreactivation in the yeast Schizosaccharomyces pombe

Abstract— Visible light (VL) illumination of u.v.-irradiated cells of the fission yeast Schizosaccharomyces pombe does not increase the survival of wild-type cells, but does increase the survival of some specific UVS strains. This photoreactivation has been studied in the U VS 1,₁ mutant in the stationary growth phase.

• 1 It is not dependent on temperature during VL illumination.
• 2 The effect of pre-u.v. or post-u.v. illumination on survival is the same.
• 3 There is an overlap of photoreactivation and liquid holding recovery.
• 4 VL does increase the growth delay after irradiation. It is concluded from these results that the photoreactivation is not due to a photoreactivating enzyme, but to an indirect process. The existence in this yeast of two different repair pathways of u.v. lesions has been demonstrated previously. The study of indirect photoreactivation in different strains, blocked in one or the other repair pathway by mutation or by a repair inhibitor (caffeine), leads to the conclusion that the VL treatment favours only one of these two repair mechanisms, which is presumably the excision-repair pathway. The strain UVS A, which would repair u.v. lesions by a recombinational mechanism, does not show any photoreactivation.

     

MISCHKLONE U.V.-INDUZIERTER MUTANTEN BEIM PHAGEN KAPPA

Abstract— Clear-plaque mutations of phage k of Serratia are induced by extracellular u.v.-irradiation in a 2–hit process. The 2–hit-nature cannot be due to induction of one hit in each of the two DNA-strands since replating the contents of 97 wildtype plaques of u.v.-survivors (u.v.-dose 4.5 min) revealed only 1 case of heterozygosity; at least 20 cases would have been expected if phage with 1–hit-mutations formed phages looking like wildtype. On the other hand, only 1 case of heterozygosity was observed among replatings of 94 c -mutants induced by the u.v.-dose 4.5 min (survival 10^-3); most of the plaques contained pure c -type. The pure c -mutant clones are very probably due to 'recessive' lethal lesions in the nonpremutated DNA-strand. This is indicated by the dose dependence of the frequency of heterozygotes; at a dose of 3 min u.v. (survival 1.2 × 10^--²) 9 heterozygotes were observed among 95 mutants tested. From these numbers the rate of induction by u.v. of the recessive lesions's can be calculated. The data at the higher dose are in satisfactory agreement with the calculated rate. Also other types of plaque mutations (e, t, b ) showed heterozygosity. Two cases of abnormal heterozygosity were observed; one contained 2 stable mutant types ( c and b ), another one wildtype, c -tm and l -type.     

SUPPRESSION OF PHAGE T4 BY CO-INFECTION WITH U.V.-INACTIVATED HOMOLOGOUS PHAGE

Abstract— Unirradiated phage T4v₁ may fail to produce viable progeny in cells which are co-infected with u.v.-irradiated homologous particles. The extent of this effect, called suppression , is positively correlated with the multiplicity of infection of the irradiated phage and with the U.V. dose. The suppression reaches a maximum level at about 30–600 lethal hits. Quantitative evaluation of the results shows that in some complexes one irradiated phage particle is sufficient to suppress an unirradiated phage. Two hypotheses are discussed to explain the results. (a) Lethal u.v.-damages are incorporated into the unirradiated phage genome by genetic recombination; ( b ) Genetic subunits (e.g. cistrons or operons) of the u.v.-irradiated phages produce informationally incorrect messenger RNA molecules, which compete with the correct ones from the unirradiated phage in the protein-synthetizing system. Hypothesis (6) appears to be more adequate to explain the experimental results.     

OVERLAPPING ACTION OF HOSTCELL REACTIVATION AND PHOTOREACTIVATION IN BACTERIA

Abstract— The photoreactivation rate of U.V. irradiated phages is decreased in u.v. irradiated bacteria. In contrast, the normal photoreactivation rate is observed if the irradiated bacteria are photoreactivated before phage infection. The decrease of the photoreactivation ratc is understood as a competing effect of the u.v. lesions in the bacterial nucleic acids for the photoreactivation enzyme. This competitive inhibition can be diminished not only by photoreactivation of the bacteria before phage infection but also by hostcell reactivation of the u.v. lesions in the bacterium. The results provide strong evidence that hostcell reactivation and photoreactivation revert the same u.v. photoproducts in bacterial nucleic acids. The experiments show that the hostcell reactivation enzyme is not induced by phage infection or by irradiation, but is normally present in the bacterial cell.     

DIFFERENTIAL, LETHAL AND MUTAGENIC ACTION OF 254 nm AND 320–400 nm RADIATION ON SEMI-DRIED BACTERIA

Abstract— The effect of culture conditions on the lethal and mutagenic action of 254 nm (u.v.) and 320–400 nm (b.l.) light has been examined. Ten strains of Escherichin coli were used in these investigations. It was found that semi-dehydration in aerosols greatly enhanced the lethal and mutagenic actions of both U.V. and b.l., Mutations induced by U.V. were found to be of a random kind, while those produced by b.l. were specific and of a particular biochemical type depending on the strain of cell and its stage of development. The presence of oxygen during irradiation enhanced b.l. effects but had no effect on U.V. damage while anaerobic growth endowed the cells with added resistance to b.l. and u.v., Stationary phase cells of E. coli B/r were found to be mutated by b.l. specifically at a thymine locus and to be more sensitive than E. coli B to the inhibition by b.l. of respiration. Some mutations induced by b.l. in E. coli B/r were found to hinder the cells ability to carry out the photoreversal of U.V. damage. It is suggested that b.1. affects a specific piece of DNA which is in contact with the cytochrome chain of the cytoplasmic membrane and that this contact point between the cytochrome chain and DNA alters sequentially as the cell proceeds through its life cycle.     

EVIDENCE AGAINST DNA AS THE TARGET FOR 334 NM-INDUCED GROWTH DELAY IN ESCHERICHIA COLI*

Abstract— Growth delay was induced with near-UV (334 nm) radiation in Escherichia coli K12 bacterial strains followed by attempts at photoreactivation (PR) of this effect at 405 nm. In the UV-sensitive strain AB2480, a small PR of the observed population growth delay occurred after 334 nm irradiation at 35°C and a much larger PR after 334 nm irradiation at 5°C. However, much of the population growth delay in this strain can be explained as being due to killing, and all or most of the observed PR pertains only to this killed fraction of the population. The true cell growth delay (i.e. that of surviving cells) thus appears to be only slightly, if at all, photoreactivable. This conclusion is supported by studies with a wild-type strain KW8, which shows growth delay at non-lethal doses; this growth delay shows no PR, regardless of the temperature during 334 nm irradiation. These findings indicate that photoreactivable lesions (cyclo-butyl pyrimidine dimers) are not an important cause of near-UV-induced growth delay. Strain AB2480 lacks known dark-repair systems for DNA damage induced by far-UV (below 300 nm) radiation, yet shows the same efficiency for 334-nm-induced growth delay as the wild type, which possesses these dark repair systems. This indicates that lesions in DNA that are dark-repairable by the systems not tunctional in AB2480are not responsible for 334-nm-induced growth delay. It is possible, however, that fragmentary repair systems in AB2480 can operate on some DNA lesion that might cause growth delay. Spontaneously decaying lesions are unlikely, since growth-delay damage decays at a very low rate in non-nutrient medium. Since most of the known types of DNA damage and repair are thus eliminated, these considerations suggest that DNA damage is not involved in near-UV-induced growth delay.     

RECOVERY OF HAEMOPHILUS INFLUENZAE FROM ULTRAVIOLET AND X-RAY DAMAGE

Abstract— Results of experiments on reactivation of ultraviolet (u.v.)-irradiated Haemophilus influenzae and cellular reactivation of u.v.-damaged transforming deoxyribonucleic acid (DNA) and bacteriophage are reported. Liquid-holding recovery (LHR) is small for the u.v.-sensitive mutant BC100 which, relative to the wild type, also has greatly reduced host-cell reactivation (HCR) of u.v.-inactivated phage, and competent cultures show reduced competent cell reactivation (CCR) of u.v.-inactivated transforming DNA. BC100 cells can be transformed with DNA isolated from the wild type strain Rd to a u.v. resistance similar to that of Rd, and irradiation of the DNA reduces the transformation frequency for this marker (uvr). The u.v.-resistant mutant BC200 displays very little LHR under the usual conditions where reactivation occurs after plating. The colony-forming ability (cfa) of irradiated BC200 is greater than that of Rd, but HCR and CCR are the same on this mutant as on the wild type. The major difference between Rd and BC200 is the enhanced u.v. survival of cfa of the latter. It was determined that this difference reflects cell lysis of irradiated Rd and lack of lysis in BC200 cultures. That lysis is closely correlated with damage to the bacterial chromosome is suggested by the finding that the lytic response of Rd (as determined turbidimetrically) can be negated by the liquid-holding procedure, but lysis of BC100 (which lacks comparable DNA-repair ability) can be only partially inhibited by this procedure. LHR occurs when post-plating dark recovery is incomplete, is temperature-sensitive, and occurs unimpeded when post-u.v. protein synthesis is inhibited by chloramphenicol. It is suggested that enzymatically catalyzed reactivation of DNA occurs or is initiated during liquid-holding of u.v.-irradiated H. influenzae Rd and that the necessary enzyme(s) exists prior to appearance of u.v. lesions in the DNA. Results are reported for X-ray inactivation of transforming DNA as assayed on BC100, Rd and BC200 and of the cfa of the three strains.     

THE U.V. SENSITIVITY OF BACTERIA: ITS RELATION TO THE DNA REPLICATION CYCLE

Abstract— A striking increase in the shoulder of the u.v. survival curve but no change in the limiting slope is obtained when cultures of Escherichia coli strain TAU complete the DNA replication cycle in the absence of concommitant protein synthesis prior to irradiation. The u.v. sensitivity of protein synthesis or RNA synthesis is not altered significantly by this treatment.
In contrast to the result for strain TAU, there is no significant change in the u.v. survival curve for the u.v. sensitive E. coli B_s-1 when its DNA replication cycle is completed under similar conditions.
Following a period of inhibited protein synthesis there is a delay in the reinitiation of the normal DNA replication cycle when protein synthesis resumes. This delay would allow time for an intracellular repair system to operate before the attempted resumption of normal replication. Strain B_s-1, which is deficient in this repair system, would not be expected to benefit from such a delay, as consistent with the observed results. A model is presented to account for lethality due to attempted DNA replication during a period of repair synthesis. The maximum survival for a given u.v. dose would be predicted for a culture which has completed the normal DNA replication cycle prior to irradiation and which is not permitted to reinitiate the cycle until all possible repair synthesis is completed.     

THE VARIATION OF RADIATION SENSITIVITY OF BACTERIA FED TETRAHYMENA PYRIFORMIS DURING THE GROWTH CYCLE AND FACTORS RELATED TO ITS ORIGIN

Abstract— Tetrahymena pyriformis shows a cyclic variation of sensitivity (for lethality) to u.v. light while the response to X-rays is almost constant throughout the growth (division to division) cycle. It is demonstrated in this paper, and elsewhere, that survival of caffeine treated animals is higher after higher doses than after the lower doses of radiation; such a response indicates that the increased radiation dose induces a resistant state not existing at lower doses. Response of synchronized animals to postirradiation treatment with caffeine is interpreted as indicating that recovery from the lethal effect of radiation has two components as previously postulated: (1) a caffeine sensitive recovery system (termed the ' N ' system) and, (2) an activated recovery capacity (termed the ' T' system) which is less sensitive to caffeine.
The maximum activated ( T ) system repair capacity only equals the repair capacity of the ( N ) non-activated system for X-ray induced lesions and, since the N system does not seem to show a cyclic variation of effectiveness for X-ray induced lesions, the X-ray survival remains constant throughout the growth cycle.
The repair capacity of the activated ( T ) repair system is, throughout most of the cycle and especially during the S period, much greater than that of the N system for u.v. induced lesions. Thus the u.v. response vanes in a manner largely dependent upon the capacity of the activated system and the fraction of the population showing the activated response; in G 2, a time when the activated repair system is rather ineffective, the non-activated ( N ) system appears to become unusually efficient in the repair of u.v. induced lesions.     

EFFECTS OF DOSE FRACTIONATION ON ULTRAVIOLET SURVIVAL OF ESCHERICHIA COLI

Abstract— Exposure of E. coli B/r and B at low average dose rates of u.v. radiation (2537 Å), produced either by fractionated doses or by continuous irradiation at a very low dose rate (80 ergs/mm²/hr), results in much increased survival compared to single exposure at high dose rate. This increase is attributed to repair taking place during the irradiation period. The effect is small in the repair-deficient strains E. coli B_8-1_, and C syn- , and is absent in phage T1 and T4, which cannot undergo repair in the extracellular state. However, the prolonged time available for repair in these experiments accounts for only a very minor part of the increase in survival. The principal factor apparently is that the number of lesions present at any time remains relatively low. Presumably complete repair, not only the excision step, can occur in buffer during the irradiation period. This interpretation is supported by experiments in which cells were exposed to combinations of highly fractionated irradiation and single-dose irradiation. We therefore propose that mutual interference in repair, possibly by overlapping of repair regions in complementary DNA strands, reduces considerably the repair efficiency if many lesions are present. This hypothesis explains the 'shouldered' survival curves of B/r and possibly other E. coli strains as due to decreasing repair efficiency with increasing u.v. dose     

PHOTOREVERSION VON VIER GRUPPEN UV-INDUZIERTER MUTATIONEN ZUR GIFTRESISTENZ IM NICHTPHOTOREAKTIVIERBAREN E. COLI

Abstract— In the non-photoreaclivable bacterial strain E. coli B/phr^-/MC2 the photoreversion of four groups of u.v.-induced mutations were investigated. They lead to resistance to Chloramphenicol (2 mg/l; "C"), Penicillin (13 or 16 mg/l; "P13" and "P16") or Streptomycin (3 mg/l; "S"). The u.v.-dose curve is concave for the C-mutations (two to three hits), about linear for P13 and S, and they reach peaks and decrease at high u.v.-doses. Though no photoreactivation of killing (PR) is present there is photoreversion of all four types of mutations (PRM). At u.v.-doses below the peaks in average about 43 per cent mutations are photoreversible. At high u.v.-doses the curves with light-post treatment (L) cross the darkcurves (D). In the photoreactivable strain B/r (by the spontaneous mutation MC2 to Mitomycin-resistance strain B/phr^- was made about as u.v.-resistant as B/r is) the photoreversion of the mutation groups C, P13 and P16 (S was not investigated here) was much higher, in average about 77 per cent at low doses. It is assumed that the difference in PRM of about 34 per cent between both strains is due to a PRM-mechanism present in B/r but not in B/phr^-/MC2; this mechanism may be the photoreactivating enzyme that opens thymine-dimers. The PRM in B/phr-/MC2 must then be due to a second mechanism which is probably not the dimer opening enzyme. It may be the same mechanism as in the case of mutations of phage kappa which are induced by u.v. and reversed partially by light, both extra cellularly. The premutations giving this second type of PRM may perhaps be cytosine-hydrate in the DNA. Tn average about 23 per cent mutations of B/r are photostable. Since this ratio decreases with low u.v.-doses in the C-mutations and increases in P13 and in P16 probably two types of photostable premutations seem to exist.     

ULTRAVIOLET-INDUCED LETHALITY AND REVERSION TO PROTOTROPHY IN ESCHERICHIA COLI STRAINS WITH NORMAL AND REDUCED DARK REPAIR ABILITY

Abstract— Two derivatives of E. coli B/r having the same auxotrophic marker but differing in their ability to dark repair u.v.-induced dimers in DNA were compared for their sensitivity to u.v.-induced lethality and reversion to prototrophy. Ability to dark repair influenced both biological endpoints to the same extent. Thus, dimers may be primary photochemical lesions for both effects. A possible model for the system was proposed. According to this model, organisms which have more than a critical number of dimers are inactivated and organisms with the critical number or slightly fewer, survive as revertants. Post-irradiation influences which enhance or reduce repair of dimers, in effect shift the population distribution of dimers. The result is either a net increase or decrease in the number of revertants depending upon the U.V. dose and upon whether repair is enhanced or reduced.     

DELAY IN GROWTH AND DIVISION INDUCED BY NEAR ULTRAVIOLET RADIATION IN ESCHERICHIA COLI B AND ITS ROLE IN PHOTOPROTECTION AND LIQUID HOLDING RECOVERY

Abstract. Microscopic observations show that growth delay and division delay occur on nutrient agar after Escherichia coli B has been irradiated at 3341 Å. These effects also occur in nutrient broth.
A near u.v. action spectrum for growth delay in nutrient broth has been obtained. It shows a single peak at 3380 Å and is indistinguishable from the action spectrum for photo-protection from far u.v. (2537 Å) killing in the same organism. Furthermore, photoprotected cells show a much greater growth delay than cells that have not been photoprotected. These, as well as kinetic data, suggest that the essential action of a photoprotection treatment consists in the induction of a growth-division delay. This delay would presumably permit more time for intracellular recovery systems to operate on the far u. v. damage to nucleic acids.
Liquid holding recovery (effected by holding cells in phosphate buffer after far u. v. irradiation) shows complete overlap with photoprotection. It is concluded that photoprotection and liquid holding recovery operate on the same far u. v. damage. As with photoprotection, it is probable that the essential action of a liquid holding treatment is the induction of a growth-division delay.
No photoprotection is observed of intracellular T2 bacteriophage or of E. coli B_s-l (Hill).     

MUTATION INDUCTION BY AND MUTATIONAL INTERACTION BETWEEN MONOCHROMATIC WAVELENGTH RADIATIONS IN THE NEAR-ULTRAVIOLET AND VISIBLE RANGES

Abstract— The induction of mutations (reversion to tryptophan independence) by various UV (254, 313, 334 and 365 nm) and visible (405 and 434 nm) wavelengths was measured in exponential phase populations of Escherichia coli B/r thy trp and B/r thy trp uvrA by assay of irradiated populations on semi-enriched media. No mutations were induced in the repair proficient strain at wavelengths longer than 313 nm. Mutations were induced in the excisionless strain at wavelengths as long as 405 nm but less than expected from the known amount of DNA damage induced. Irradiation at the longer wavelengths (434, 405, 365 and 334 nm) suppressed the appearance of 254- or 313-nm-induced mutations in the repair competent strain but not in the excision deficient strain. The relative dose-requirement for mutation suppression was related to the relative efficiency of these wavelengths in inducing growth delay. These results suggest that the growth delay induced by near-UV and visible wavelengths allows more time for the 'error-free" excision repair process to act on the potentially mutagenic lesions induced by 254- and 313-nm radiations, thereby reducing the mutation frequency observed in the repair-proficient strain. The level of near-UV mutation induced in the excision deficient strain is lower than expected from the DNA damage known to be induced. It is possible that near-UV radiation induces a class of lethal lesions that are not susceptible to error-prone repair.     

ULTRAVIOLET-INDUCED APOCHLOROSIS AND PHOTOREACTIVATION IN TWO STRAINS OF EUGLENA GRACILIS*

Abstract— Very low doses of ultraviolet irradiation result in a complete loss of the ability to synthesize chlorophyll in two closely related strains of Euglena gracilis (var. hacillaris and strain Z). Both strains are equally sensitive in this response under non-photoreactivating conditions. The ability to synthesize chlorophyll is completely photoreactivated by visible light in E. grncilis var. bacillaris , even after lethal doses of u.v.: the Z strain. however, while photoreactivable following low doses of u.v., remains bleached after doses adequate to kill only 10–20 per cent of the cells.     

Ultraviolet action spectra in perspective: with special reference to mutation

Abstract— Problems of determining action spectra are considered as well as various types of action spectra for U.V. action upon cell activities. U.V. is an effective mutagenic agent producing point mutations and chromosomal changes. U.V. is readily absorbed by superficial layers of cells in tissues; therefore, special experimental procedures are necessary for induction of mutations in animals or plants. U.V. is, however, suitable for mutagenesis in microorganisms because their cells are small, permitting the radiation to reach the nuclei. Action spectrum studies reveal that u.v. mutagenesis results from absorption of the radiation by nucleic acid. The most prominent alteration in DNA following absorption of u.v. is dimerization of pyrimidines, chiefly thymine. Such a change not only retards DNA replication but results in errors (mutations). U.V. mutagenesis therefore depends upon the conditions before, during and after irradiation. Thus immediate post-treatment with visible and long u.v. light splits pyrimidine dimers, thereby reversing impending u.v. mutagenesis. For cells kept in the dark, conditions which prevent DNA replication by interfering with the metabolism of the cell provide time for dark repair of the DNA lesion and so for reversal of the impending mutation.     

PHOTOBIOLOGY OF RNA BACTERIOPHAGES—I. ULTRAVIOLET INACTIVATION AND PHOTOREACTIVATION STUDIES*

Abstract— Biologically active f2-RNA, Obtained from bacteriophage f2, was inactivated by ultraviolet (u.v) light (2537 Å) with a quantum yield of 3.3 ± 0.3 times 10^-3 when assayed in the dark with protoplasts of an F- strain of E. coli k12. Assay under “black light” gave a quantum yield of 2.7 ± 0.5 times 10^-3 which was just enough lower to suggest that 17 per cent photorecovery of the u.v. lesions has taken place. Intact phage f2 was inactivated by u.v. radiation with a quantum yield of 0.7 ± 0.12 times 10^-3, Thus the whole phage is much less sensitive than the free RNA. No evidence of photorecovery was found in u.v.-irradiated RNA phage 7S assayed in its host Pseudomonas aeruginosa.     

REPAIR OF NEAR (365 nm)- AND FAR (254 nm)-UV DAMAGE TO BACTERIOPHAGE OF ESCHERICHIA COLI

Abstract: Intact bacteriophage have been irradiated at 365 nm or at 254 nm and then analysed for DNA photoproducts or injected into their bacterial host to test susceptibility of the damage to both phage and host-cell mediated repair systems. Both thymine dimers and single-strand breaks are induced in the phage DNA by 365 nm radiation. The dimers appear to be the major lethal lesion (approximately 2 dimers per lethal event) in both repair deficient bacteriophage T4 and bacteriophage λ. after irradiation with either 254 nm or 365 nm radiation. Damage induced in T4 by either wavelength is equally susceptible to x -gene reactivation (repair sector approximately 0.5). v -gene reactivation acts on a larger fraction of the near-UV damage (repair sector of 0.82 at 365 nm as against 0.66 at 254 nm). The host-cell mediated photoreactivation system is only slightly less effective for near-UV damage but host-cell reactivation (as measured by comparing survival of phage λ. on a uvr⁺ and a uvr^- host) is effective against a far smaller sector of near-UV damage (0.35) than far-UV damage (0.85). Weigle-reactivation (far-UV induced) of near-UV damage to phage λ is not observed. The results suggest that unless the near-UV damaged phage DNA is repaired immediately after injection. the lesions rapidly lose their susceptibility to repair with a consequent loss of activity of the phage particles.