OYGEN DEPENDENCE AND REPAIR OF LETHAL EFFECTS OF NEAR ULTRAVIOLET AND VISIBLE LIGHT*

Abstract— –Lethality in a repairable strain (WP2) and an excision repair deficient strain (WP2hcr) of Escherichia coli was studied at wavelengths of 254, 313, 365, and 390–750 nm. Survival curves were empirically fitted to the expression S= 1 - (1-e^-kl)“, where S is the fraction surviving, D is the incident dose in ergs mm^-2, k is the inactivation constant in units of (erg mm^-2)^-1 and n is the ‘shoulder constant’. The repairable sector (k(hcr^-)–k(hcr^-)lk(hcr^-), a conservative estimate of the repair capability of E. coli WP2, was 0.91 at 254 nm, 0.92 at 313 nm, 0.60 at 365 nm, and 0.13 at 390–750 nm. Although there was no oxygen enhancement of inactivation at 254 nm and 313 nm, a strong enhancement was identified at 365 nm and 390–750 nm. These results suggest that oxygen-dependent damage induced by near u.v. (365 nm) can be partially repaired by the excision-repair system in E. coli.     

Photoreactivation of killing in Streptomyces. II. Kinetics of formation and photolysis of pyrimidine dimers and adducts in S. coelicolor and S. griseus PHR-1

Abstract— A pyrimidine adduct, 6-4‘-[pyrimidine-2’-one] thymine (PO-T)?, observed in DNA hydrolysates of 254-nm ultraviolet (u.v.) irradiated conidia of Streptomyces coelicolor, increases linearly with u.v. dose up to 2 × 10⁵ ergs/mm². Yields of thymine dimer (T○) and uracil-thymine dimer (U○) level off at much lower doses. Initial relative rates of formation of these u.v. photoproducts are: 1:1.3:4.8 for PO-T, T○ and U○, respectively. Similar results were obtained with a Streptomyces griseus mutant, PHR-1. An equation is derived to estimate the ratio of the amount of PO-T to the total amount of thymine-derived photoproducts at low (biological) u.v. doses. The observed PO-T fractions compare well with the calculated values. Rapid photolysis of the precursor of PO-T was observed by post-u. v. treatment at 313 nm of conidia of S. coelicolor and of S. griseus PHR-1. The photolysis was much slower at 365 nm and did not occur at all at 405 nm. Pyrimidine dimers were not appreciably affected by post-u. v. treatment at the above wavelengths in these Streptomyces strains. Both of these strains are phenotypically photoreactivation-deficient, and the present results indicate that they do not possess active photoreactivating enzyme. In earlier papers[3,4,5], the pyrimidine adduct found in acid hydrolysates of DNA was loosely referred to as “uracil-thymine adduct (U-T adduct)”. Such terminology is not strictly correct. The pyrimidine adduct in acid hydrolysates is PO-T (sometimes called P₂B), which could theoretically result from removal of ammonia from a C-T adduct or removal of water from a U-T adduct (see [6]).     

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.

     

OXYGEN EFFECT IN THE PROTECTION OF E. COLI AGAINST U.V. INACTIVATION AND MUTAGENESIS BY ACRIDINE ORANGE*

Abstract— Protection by acridine orange against ultraviolet light effects in resting cells of E. coli B/r/1, try^- was studied with special reference to a possible oxygen effect. Dose-response relationships were described by the function S= 1–(1 - e-^kD)ⁿ where S is the surviving fraction and D is the u.v. dose in ergs/mm². For cells suspended in 5 × 10^--⁶M acridine orange (AO) in air, the radiation sensitivity k was reduced from 0.010 (ergs/mm²)^)-1 in the absence of the dye to 0.0053 (ergs/mm²)^-1 in the presence of the dye. Under anoxia at this AO concentration, k was further reduced to 0.0015 (ergs/mm²)^-1. The oxygen effect ratio, kO₂/k_N2, was 3.5 at this concentration of AO. Greater protection was observed in cells suspended in 2 × 10^--⁵M AO, the oxygen effect ratio was unchanged. No oxygen effect was detected in the u.v. response in the absence of the dye. The value of n was reduced from about 12 with no dye to about 5 at dye concentrations of 5 × 10^--⁶M AO or more when oxygen was present. Under anoxia, in the presence of AO, n was further reduced to about 1.3. Atebrin, an efficient u.v. protective agent but an inefficient photodynamic agent, had no oxygen effect for protection against u.v. inactivation. Acridine orange protected against u.v.-induced reversion to tryptophan indepence in E. coli WP2 to about the same extent as it did for inactivation. A similar oxygen effect was observed for both inactivation and mutagenesis.     

Direct demonstration of the monomerization of thymine-containing dimers in U.V.-irradiated DNA by yeast photoreactivating enzyme and light

Abstract— Ultraviolet-irradiated E. coli DNA (³H-thymine-labelled) was mixed with un-irradiated E. coli DNA (¹⁴C-thymine-labelled) and exposed to light in the presence of purified yeast photoreactivating enzyme. As the ³H-thymine-containing cyclobutane dimers disappeared during the photoreactivation, there was a stoichiometric increase of monomeric ³H-thymine as determined from the ³H/¹⁴C ratio in thymine. This is the first direct demonstration that thymine-containing dimers in u.v.-irradiated DNA are monomerized by yeast photoreactivating enzyme in the presence of light.     

Repair replication in Chinese hamster cells after damage from ultraviolet light

Abstract— After irradiation with u.v. light, Chinese hamster cells perform repair replication of their DNA. Small numbers of nucleosides are inserted into DNA, such that when BrUdR is used there is no detectable change in density. Repair replication begins immediately after irradiation, but it decelerates steadily and at least half is complete within 4 hr. Repair replication saturates above 200 ergs/mm² at a level which represents 0.055 per cent replacement of all thymine sites in 4 hr. Repair replication in mammalian cells, in contrast to that in microorganisms, does not appear to replace pyrimidine dimers excised from DNA in acid soluble form, and neither repair nor semiconservative replication discriminates between BrUdR and TdR.     

PHOTOREACTIVATION IN THE EXTREME HALOPHILIC ARCHAEBACTERIUM Halobacterium cutirubrum

Abstract— Photoreactivation in the extreme halophilic archaebacterium Halobacterium cutirubrum was studied both in vivo and in vitro. Cells irradiated with ultraviolet (UV)-fluences up to 350 J/m² could be completely photoreactivated, indicating very efficient repair of pyrimidine dimers in UV-irradiated DNA. Dark repair is apparently absent in Halobacterium since liquid holding under non-growth conditions did not influence the survival of UV-irradiated cells, while cells remained completely photoreactivable with no change in the kinetics of photoreactivation. Experiments with Halobacterium isolates of different carotenoid content indicated that carotenoids do not influence either UV-inactivation or photoreactivation. Small differences in the rates of UV-inactivation and photoreactivation could be assigned to the occurrence of gas vesicles. Flash experiments and the temperature dependence of photoreactivation indicated an enzymatical reaction. This was confirmed by in vitro experiments with partially purified photoreactivating enzyme. The in vivo action spectrum of photoreactivation showed a main band in the 400-470 nm region with a maximum at 440 nm. Comparison with action spectra of other microorganisms classified the Halobacterium enzyme as a 8-hydroxy-5-deazaflavin type photoreactivating enzyme.     

PHOTOREACTIVATION OF THYMINE-STARVED ESCHERICHIA COLIBs-1

Abstract —Thymine starvation prior to 254 nm ultraviolet light (UV) exposures has been found to decrease the level of maximum photoreactivation in Escherichia coli B _s-1. The dark equilibrium level of photoreactivating enzyme-substrate complexes was determined from the levels of photoreactivation obtained with exposures to single flashes of high-intensity light. The kinetics indicate that photoreactivating enzyme concentration does not decrease as a result of thymine starvation. The UV sensitivities of normal and thymine-starved cells are found to be the same. Photoreactivation by sequential flashes shows a lesser number of total photorepairable lesions in starved cells. It is concluded that thymine starvation renders a portion of the dimers inaccessible to the photoreactivating enzyme, thus lowering the level of maximum photoreactivation.     

DNA REPAIR IN THE VARIABLE PLATYFISH (Xiphophorus variatus) IRRADIATED in vivo WITH ULTRAVIOLET B LIGHT

Abstract— Dark- and light-dependent DNA repair processes were studied in vivo in the variable platyfish, Xiphophorus vuriatus . Excision (dark) repair of the (6–4) photoproduct was more efficient than that of the cyclobutane dimer with ∼ 70% of the (6–4) photoproducts reniovcd by 24 h post-UVB radiation compared to ∼30% of the cyclobutane dimers. Exposure to photoreactivating light resulted in rapid loss of most (>90%) of the cyclobutane dimers and increased excision repair of the (6–4) photoproduct. Preexposure to photoreactivating light 8 h prior to UVB radiation increased the rate of photoreactivation two-fold.     

PHOTOREACTIVATION and EXCISION REPAIR OF UV INDUCED PYRIMIDINE DIMERS IN THE UNICELLULAR CYANOBACTERIUM GLOEOCAPSA ALPICOLA (SYNECHOCYSTIS PCC 6308)

Abstract— The survival curve obtained after UV irradiation of the unicellular cyanobacterium Synecho-cystis is typical of a DNA repair competent organism. Inhibition of DNA replication, by incubating cells in the dark, increased resistance to the lethal effects of UV at higher fluences. Exposure of irradiated cells to near ultraviolet light(350–500 nm) restored viability to pre-irradiation levels. In order to measure DNA repair activity, techniques have been developed for the chromatographic analysis of pyrimidine dimers in Synechocystis. The specificity of this method was established using a haploid strain of Sacchar-omyces cerevisiae. In accordance with the physiological responses of irradiated cells to photoreactivating light, pyrimidine dimers were not detected after photoreactivation treatment. Incubation of irradiated cells under non-photoreactivating growth conditions for 15 h resulted in complete removal of pyrimidine dimers. It is concluded that Synechocystis contains photoreactivation and excision repair systems for the removal of pyrimidine dimers.     

PHOTOREACTIVATION OF ULTRAVIOLET LIGHT-INDUCED DAMAGE IN CULTURED FISH CELLS AS REVEALED BY INCREASED COLONY FORMING ABILITY AND DECREASED CONTENT OF PYRIMIDINE DIMERS

Abstract— Cultured cells derived from a goldfish were irradiated with 254nm ultraviolet light. Cell survival and splitting of pyrimidine dimers after photoreactivation treatment with white fluorescent lamps were examined by colony forming ability and by a direct dimer assay, respectively. When UV-irradiated (5 J/m²) cells were illuminated by photoreactivating light, cell survival was enhanced up to a factor of 9 (40min) followed by a decline after prolonged exposures. Exposure of UV-irradiated (15 J/m²) cells to radiation from white fluorescent lamps reduced the amounts of thymine-containing dimers in a photoreactivating fluence dependent manner, up to about 60% reduction at 120 min exposure. Keeping UV-irradiated cells in the dark for up to 120min did not affect either cell survival or the amount of pyrimidine dimers in DNA, indicating that there were not detectable levels of a dark-repair system in the cells under our conditions. Correlation between photoreactivation of colony forming ability and photoreactivation of the pyrimidine dimers was demonstrated, at least at relatively low fluences of photoreactivating light.     

PHOTOREACTIVATION OF DNA-CONTAINING CAULIFLOWER MOSAIC VIRUS AND TOBACCO MOSAIC VIRUS RNA ON DATURA

Abstract— Datura stramonium L. is a local lesion host for TMV-RNA and DNA-containing cauliflower mosaic virus (CAMV). Datura can photorepair UV-damaged TMV-RNA and CAMV, giving photoreac-tivation sectors of 0.40 and 0. 33 , respectively. Dose response curves for photoreactivation of TMV-RNA and CAMV show that 4540 min of cool white light (15 W.m^-2) is required for maximum photoreactivation. Blue light and near UV are equally effective in photoreactivating UV-irradiated TMV-RNA, whereas near UV is initially more effective than blue light for the photorepair of UV-inactivated CAMV. Higher doses of near UV apparently inactivate the CAMV photorepair system. In the case of CAMV, photoreactivating light must be applied immediately after inoculation with the virus. Two to three hours of incubation in the dark after inoculation results in complete loss of response to photoreactivating irradiation. In contrast, limited photoreactivation of TMV-RNA occurs even after 4 h of dark incubation after inoculation, although photoreactivating irradiation is most effective when applied immediately after inoculation. Light is required for the maintenance of photoreactivation for both TMV-RNA and CAMV. Daturas placed in the dark for six days lose their ability to photoreacti-vate. Recovery of the TMV-RNA photorepair system is rapid; complete recovery attained with 90 or more min of white light (15 W m-'). Recovery of CAMV photorepair system is slow; 90% recovery attained after only 20 h of light. However, full recovery can be induced by as little as 6h of light when CAMV is inoculated 24 h after the onset of illumination. These results suggest two photorepair systems are present in Datura .     

PHOTOREACTIVATING ENZYME FROM Streptomyces griseus—VI. ACTION SPECTRUM AND KINETICS OF PHOTOREACTIVATION

Abstract— A high resolution action spectrum for photoreactivation was determined using purified photoreactivating enzyme from Streptomyces griseus. Conversion of pyrimidine dimers in UV-irradiated DNA, the substrate for photoreactivating enzyme, was measured with a Haemophilus influenzae transformation assay. A high similarity was found between action spectrum (max. at 445 nm) and the long wavelength absorption band (max. at 443 nm)of photoreactivating enzyme. In addition to the400–470 nm region considerable photoreactivation was found with wavelengths between 280 and 320 nm. No evidence was obtained for the presence of nonenzymatic photoreactivation. Comparison of in vitro and in vivo action spectra revealed that the sharp peak at 313 nm found in vivo is probably the result of counteracting photoreactivation and inactivation effects. Comparison of the action spectrum with the absorption spectrum of 8-hydroxy-10-methyl-5-deazaisoalloxazine in an aprotic dipolar solvent (which serves as a model for the 8-hydroxy-5-deazaflavin chromophore in photoreactivating enzyme) indicates the possible presence of other chromophore(s) involved in the photorepair process. From kinetic measurements and flash experiments values were obtained for the rate constants of the photoreactivation reaction. The quantum yield of photoreactivation was estimated to be approximately 1.     

PHOTOREACTIVATING ENZYME FROM NEUROSPORA CRASSA*

Abstract— Extracts of Neurospora crassa contain photoreactivating enzyme by the criteria of ability to split thymine-containing dimers and to increase the transforming ability of u.v.-irradiated Hemophilus influenzae DNA. The latter activity is heat-labile and is destroyed by trypsin. The action spectrum of such in vitro photoreactivation is a simple one (with a single maximum at 405 nm in the range 313 to 436 nm), differing from the more complicated in vitro spectra for yeast and Escherichia coli. However, the in vitro Neurospora spectrum coincides closely with the in vivo spectrum for this organism, suggesting that there is little or no “indirect” photoreactivation in Neurospora. It is concluded that the Neurospora photoreactivating enzyme is probably of a different type than those of yeast and Escherichia coli.     

Mechanism and computer simulation of the phototactic accumulation of Euglena in a beam of light

Abstract— A mechanistic model is proposed which describes the phototactic behavior of Euglena during accumulation in an illuminated region. Measurements of the lag time occurring between illumination of the culture and net accumulation in the lighted zone as a function of culture density indicate that the relative strengths of the negative phototactic response inside and of the positive phototactic response outside this region are the prime factors controlling the lag phenomenon. Further evidence for this is provided by studies of the temperature dependence of the phototactic responses to polarized actinic light. It is shown that negative phototaxis as measured in the 7lsquo;phototaxigraph’ is not directed, but rather a shock-mediated response. A ‘FOCAL’ computer program for simulation of experiments in the phototaxigraph has been written on the basis of our model. It correctly predicts the observed results under a variety of simulated experimental conditions. Measurements of the lag time and of the rate of accumulation in different parts of the actinic zone allow the calculation of motilities of the organisms with illumination and in the dark, the latter value being 0.08 mm/sec. For a 2–3-weekold culture, the rate of negative phototaxis remained constant at light intensities above 40 ergs/cm²sec at 500 nm. At this wavelength, the threshold for the positive photophobic response was 100 ergs/cm² sec.     

Photoreactivation of RNA in UV-irradiated insect eggs (Smittia sp., Chironomidae, Diptera) II. Evidence for heterogeneous light-dependent repair activities

Abstract. Two biological effects of UV radiation upon Smittia eggs are observed, both of which seem to be associated with the formation of pyrimidine dimers in the RNA (largely ribosomal) of the eggs. While irradiation of the anterior pole region causes the formation of an aberrant segment pattern (double abdomen induction), irradiation of entire eggs leads to an arrest of their development (inactiva-tion). Both UV effects are photoreversible with different action spectra of the photoreactivating light. A dose rate dependence of the photoreactivation can be observed after both UV effects. The saturating dose rate is about 6 W/m² (at 440 nm) after UV induction of double abdomens. Upon UV inactivation, the saturating dose rate level for the photoreactivating light is much higher, and a single light flash causes both a considerable biological reactivation and the disappearance of about 7 × 10⁹ pyrimidine dimers from the total RNA per egg. The results indicate the presence of heterogeneous light-dependent repair activities acting upon UV induced pyrimidine dimers in the RNA of the eggs.     

Absence of photoreactivation of pyrimidine dimers in the epidermis of hairless mice following exposures to ultraviolet light

Abstract—The influence of photoreactivating light on the fate of UV-induced DNA damage has been measured in the epidermis of hairless mice using damage-specific endonuclease from Micrococcus luteus. Groups of mice were exposed to varying fluences of UV at 297nm or from an FS40 fluorescent sun lamp to induce UV photoproducts. The same fluence-dependent DNA damage was observed in high molecular weight epidermal DNA regardless of whether the mice were killed immediately, or maintained in the dark or under photoreactivating light for 20 h after UV. Thus, no detectable photoreactivation of UV-induced pyrimidine dimers could be demonstrated in mouse epithelial cells in vivo.     

ULTRAVIOLET-RADIATION-ACCELERATED LEAF CHLOROSIS: PREVENTION OF CHLOROSIS BY REMOVAL OF EPIDERMIS OR BY FLOATING LEAF DISCS ON WATER*

Abstract— Low doses (1800–7200 ergs/mm²) of ultraviolet (U V) radiation accelerated chlorosis in the mesophyll of Nicotiana glutinosa leaves when the lower epidermis of the leaves was irradiated. This occurred in either a subsequent light or dark incubation. However, within 12 h after irradiation, peeling of the lower epidermis prevented this accelerated chlorosis. The accelerated chlorosis was also prevented by floating irradiated leaf discs on water during the incubation period without removal of the epidermis. These results suggest that accelerated chlorosis in mesophyll tissue caused by low doses of UV is due to an indirect effect of the UV-damaged epidermis, possibly mediated by some toxic substance released from the epidermal cells. High UV doses (36,000–108,000 ergs/mm²) prevented normal yellowing of the leaf. The irradiated portion of the leaf remained green, while the nonirradiated area turned yellow upon dark incubation. However, if the irradiated leaf was incubated in continuous light, bleaching of the irradiated area took place, and the irradiated area became yellow faster than the nonirradiated area. Peeling of the epidermis did not affect the outcome of these experiments. These results suggest that high UV doses directly damage the mesophyll tissue.     

Action spectra for photoreactivation of mutation of prototrophy in strains of Escherichia coli possessing and lacking photoreactivating-enzyme activity

Abstract— The action spectrum and dose-rate dependence for photoreactivation of mutation to prototrophy in late-lag-phase cultures of Escherichia coli H³r30 (which lacks active photo-reactivating enzyme) are roughly similar to those for photoprotection from killing in other strains. It is suggested that photoreactivation of this mutation in H/r30 is an indirect effect, similar in mechanism to photoprotection. The action spectrum and dose-rate dependence for photoreactivation of mutation to prototrophy in late-lag-phase cultures of E. coli H³r30-R (which possesses active photoreactivating enzyme) are roughly similar to those for photoreactivation of killing in most other strains. It is suggested that photoreactivation of this mutation in H/r30-R is a direct effect at long wavelengths, but that there is an indirect component at short wavelengths. A quite different interpretation of these data is noted. Finally, it is found that, under the conditions of these experiments, indirect photoreactivation of killing in H/r30 and H/r30-R is weak or nonexistent.     

BIPHASIC PHOTOCHEMISTRY: THE FIRST ACTINOMETRIC REACTION ON A SOLID SUPPORT

Abstract Measurements were performed to determine the action spectrum and dose dependence for photoreactivation of E. coli B_s-1 cells after γ-irradiation. The similarities between photoreactivation after UV- and after γ-irradiation in action spectra, kinetics, and other characteristics indicate that the increased survival of γ-irradiated cells after illumination with photoreactivating light is the result of true photoenzymatic repair.