THE EFFECT OF A PERMANENT ELECTRIC FIELD ON THERMOLUMINESCENCE OF CHLOROPLASTS

Abstract— The effect of a permanent electric field on the thermoluminescence (TL) of pea chloroplasts was studied. The field was applied to suspensions at lowtemperatures(–15 to -40_oC) and to dry films of various humidity. A permanent electric field increased TL at low temperatures at the expense of the peaks above OA_oC. When the field strength was high, an increase in the quantum yield could be observed. When a field was applied at -15_OC, the band around +10_oC was reduced preferentially, but when a field was applied at – 40_AoC, TL bands emitted above OA_oC decreased to a similar extent. Analogies between the behaviour of solid suspensions and dry films of various humidity, and the isotope effect with D₂O, indicated that the efficiency and mode of action of an electric field on TL depends on the conformational mobility of the microsurroundings of the traps in the membrane.     

Synthesis of a New Cationic Pyropheophorbide Derivative and Studies of its Aggregation Process in Aqueous Solution

Abstract— A new water-soluble cationic pyropheophorbide was prepared from pyropheophorbide a by a Curtius rearrangement. The self-aggregation process of this chlorhydrate of aminopyropheophorbide was investigated from the changes observed in its spectroscopic properties when passing from ethanol to aqueous solutions. The formation of aggregates was characterized in the absorption spectrum by a broadening of the Qy band, which is slightly shifted to the red, a significant increase in signals of circular dichroism and a drastic quenching of the fluorescence intensity at 674 nm. Analysis of the nonlinear variation of the fluorescence intensity with the dye concentration in Tris-buffered solutions shows that dimerization is the dominant aggregation process. The dimerization equilibrium constant(at 25_AoC, pH 7.5 in 5 m M Tris buffer, 10 m M NaCl) was determined to be 3.10₆ M _-l. NMR measurements performed in DMSO at various dye concentrations showed that only the chemical shifts of some atoms are affected by these changes, indicating the part of the ring involved in the overlap of the two molecules in the dimer.A molecular modeling study of the packing arrangement of the aminopyropheophorbide molecules in aggregates performed by both semi-empirical quantum chemical PM3 and force field MM2 methods provided a structure consistent with these spectroscopic data.     

EXCISION REPAIR OF PYRIMIDINE DIMERS IN MARSUPIAL CELLS

Monodelphis domestica was further characterized as a model for photobiological studies by measuring the excision repair capabilities of this mammal's cells both in vivo and in vitro. Excision repair capability of the established marsupial cell line, Pt K2 ( Potorous tridactylus ), was also determined. In animals held in the dark, we observed that ˜50% of the dimers were removed by 12 and 15 h after irradiation with 400 J m⁻² and 600 J m⁻², respectively, from an FS-40 sunlamp (280–400 nm). Cells from primary cultures of M. domestica excised ˜50% of the dimers by 24 h after irradiating with 50 J m⁻² and 36 h after exposure to 100 J m⁻² with no loss of dimers observed 24 h following a fluence of 300 J m⁻². Pt K2 cells were observed to have removed -50% of the dimers at -12 h after 50 J m⁻² with only -10% of the dimers removed at 24 h following 300 J m⁻². The observed loss of pyrimidine dimers from epidermal DNA of UV-irradiated animals and from fibroblasts in culture, held in the dark, suggests that these marsupial cells are capable of DNA excision repair.     

REC A +-DEPENDENT SYNERGISM BETWEEN 365 NM AND IONIZING RADIATION IN LOG-PHASE ESCHERICHIA COLI: A MODEL FOR OXYGEN-DEPENDENT NEAR-UV INACTIVATION BY DISRUPTION OF DNA REPAIR

Abstract —The oxygen dependence of 365 nm inactivation of colony-forming ability of Escherichia coli has been investigated in two series of DNA repair-deficient K12 mutants grown to mid-exponential phase. All strains except a uvr A rec A double mutant are more sensitive to inactivation under O₂ and show a lower threshold dose. The inactivation of photoreactivating enzyme in a crude cell extract and DNA repair disruption are both reduced when irradiation is carried out under nitrogen. The rec A gene-dependent synergism between 365 nm and ionising radiation is reversible if cells are incubated in full growth medium before ionising radiation treatment. In a wildtype strain, incubation for 2.5 h in full growth medium after 10⁶ J m^-2 365 nm radiation changes a sensitised response to a protection from ionising radiation. Protection is not seen at 1.5 times 10⁶ J m^-2. A tentative model for near UV lethality in logarithmic phase cells is suggested which proposes two classes of lesions. One requires oxygen for it's induction, is rapidly fixed as a lethal event as a result of repair disruption, and is primarily responsible for cell death after aerobic 365 nm irradiation. The other lesion, possibly pyrimidine dimers, may lead to cell death under anaerobic conditions.     

Photogenotoxicity of Skin Phototumorigenic Fluoroquinolone Antibiotics Detected Using the Comet Assay

Abstract— The fluoroquinolone(FQ) antibiotics photosensitize human skin to solar UV radiation and are reported to photosensitize tumor formation in mouse skin. As tumor initiation will not occur without genotoxic insult, we examined the potential of ciprofloxacin, lomefloxacin, fle-roxacin, BAYy3118 (a recently developed monofluori-nated quinolone) and nalidixic acid to photosensitize DNA damage in V79 hamster fibroblasts in vitro. Cells were exposed to 37.5 kj/m₂ UVA (320-400 nm; glass filtered Sylvania psoralen + UVA (PUVA) tubes; calibrated Waldmann radiometer) at 4A_oC in the presence of FQ and immediately afterwards embedded in agarose, lysed and placed in an electrophoretic field at pH 12. Under these denaturing conditions, the presence of DNA single-strand breaks (SSB), alkali-labile sites (ALS) and double-strand breaks (DSB) can be visualized as DNA migrating away from the nucleus (characteristic "comet" appearance) after staining with a specific fluorochrome. At FQ concentrations that induced minimal loss of cell viability (neutral red uptake assay) the compounds tested induced comets with a rank order of BAYy3118 norfloxacin ciprofloxacin lomefloxacin fleroxacin nalidixic acid. If cells were incubated after treatment for 1 h at 37_oC, the comet score decreased, suggesting efficient removal of SSB/ALS/DSB. Addition of the DNA polymerase, inhibitor, aphidicolin, to cells treated with either ciprofloxacin alone or ciprofloxacin + UVA resulted in an accumulation of SSB due to the endo/exonuclease steps of excision repair. We have demonstrated that the FQ are photogenotoxic in mammalian cells but that FQ-pho-tosensitized SSB are efficiently repaired. Preliminary evidence that ciprofloxacin photosensitizes the formation of DNA lesions warranting excision repair may indicate production of more mutagenic lesions.     

POSTREPLICATION REPAIR IN uvrA AND uvrB STRAINS OF ESCHERICHIA COLI K-12 IS INHIBITED BY RICH GROWTH MEDIUM

Abstract Escherichia coli K-12 uvrA or uvrB strains grown to logarithmic phase in minimal medium showed higher survival after ultraviolet (UV) irradiation (254 nm) if plated on minimal medium (MM) instead of rich medium. This'minimal medium recovery'(MMR) was largely blocked by additional recA56 (92% inhibition) or lexA101 (77%) mutations, was partially blocked by additional recB21 (54%), uvrD3 (31%) or recF143 (22%) mutations, but additional polA1 or polA5 mutations had no effect on MMR. When incubated in MM after UV irradiation, the uvrB5 and uvrB5 uvrD3 strains showed essentially complete repair of DNA daughter-strand gaps (DSG) produced after UV radiation fluences up to ∼ 6 J/m² and ∼1 J/m², respectively, and then they accumulated unrepaired DSG as a linear function of UV radiation fluence. However, when they were incubated in rich growth medium after UV irradiation, they did not show the complete repair of DSG and unrepaired DSG accumulated as a linear function of UV radiation fluence. The fluence-dependent correlation observed for the uvrB and uvrB uvrD cells between UV radiation-induced killing and the accumulation of unrepaired DSG, indicates that the molecular basis of MMR is the partial inhibition of postreplication repair by rich growth medium. Rich growth medium can be just MM plus Casamino Acids or the 13 pure amino acids therein in order to have an adverse effect on survival, regardless of whether the cells were grown in rich medium or not before UV irradiation.     

MULTIPLE EFFECTS OF FLUORESCENT LIGHT ON REPAIR OF ULTRAVIOLET-INDUCED DNA LESIONS IN CULTURED GOLDFISH CELLS

Abstract— It is known that fluorescent light illumination prior to UV irradiation (FL preillumination) of cultured fish cells increases photorepair (PR) ability. In the present study, it was found that FL preillumination also enhanced UV resistance of logarithmically growing cells in the dark. This enhancement of UV resistance differs from induction of PR because it was not suppressed by cycloheximide (CH) and it occurred immediately after FL preillumination. The effects of FL preillumination on repair of UV-induced DNA lesions in the dark were examined by an endonuclease-sensitive site assay to measure the repair of cyclobutyl pyrimidine dimers, and by enzyme-linked immunosorbent assay to quantitate the repair of (6-4) photoproducts. It was found that excision repair ability for (6-4) photoproducts in the genome overall was increased by FL preillumination. Moreover, a decrease in (6-4) photoproducts by FL illumination immediately after UV irradiation of the cells was found, the decrement being enhanced by FL preillumination with or without CH.     

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 .     

THE EFFECT OF ULTRAVIOLET LIGHT ON THE CYCLIC NUCLEOTIDE SYSTEM OF HUMAN FIBROBLASTS

Abstract— The concentrations of cyclic AMP and cyclic GMP in human skin fibroblasts in culture were determined after exposing the cells to varying fluences of UV (254 nm) light. The cyclic nucleotide concentrations of cells irradiated in the log phase of growth were unchanged relative to controls. In contrast, there was a rise in the concentration of cyclic AMP in cells irradiated after they reached confluency. The increase in concentration was observed as early as 30 min after irradiation, reached a maximum of about 200% of control at 4 to 6 h after exposure, and returned to control values by 24 h after irradiation. The effect was proportional to a UV fluence from 5 to 20 J/m², and was blocked by the addition of the UV absorbing agent para-aminobenzoic acid. In contrast, our results indicated that UV light had no effect on the concentration of cyclic GMP in human fibroblast cell cultures. Because of the importance of cyclic nucleotides in the regulation of cellular function, it is reasonable to hypothesize that changes in cyclic AMP induced by UV light may affect the extranuclear functions of irradiated cells.     

EVIDENCE FOR DARK REPAIR OF FAR ULTRAVIOLET LIGHT DAMAGE IN THE BLUE-GREEN ALGA, GLOEOCAPSA ALPICOLA

Abstract— The inactivating effect of far UV light on the unicellular blue-green alga Gloeocapsa alpicola could be totally reversed by exposure to blue light immediately after irradiation. However, if the irradiated cells were held in the dark before exposure to blue light, reversal became progressively less efficient and almost disappeared after 60–80 h holding. Caffeine and acriflavine inhibited loss of photoreversibility, suggesting an involvement of excision functions. Chloramphenicol and rifampicin slightly increased the rate of loss of photoreversibility, indicating that inducible functions play only a minor role. Split UV dose experiments indicated that light-dependent repair remained operational during dark liquid holding. These results provide preliminary evidence for dark repair in G. alpicola .     

EFFECTS OF 8-METHOXYPSORALEN-INDUCED PHOTOTOXIC EFFECTS ON MAMMALIAN EPIDERMAL MACROMOLECULE SYNTHESIS IN VIVO

Abstract— The influence of 8-methoxypsoralen (8-MOP) and ultraviolet (UVA; 315–400 nm) radiation-induced phototoxic responses on DNA, RNA and protein synthesis and the DNA repair phenomenon were investigated utilizing the hairless mouse epidermis in vivo . The radioactive tracers TdR-³H, cytidine-³H and histidine-³H were used to examine changes in these macromolecules. Using these techniques, we found that the 8-MOP-UVA phototoxic injury inhibited premitotic semiconservative DNA synthesis in the germanitive layer of the epidermis within the first few hours post-irradiation. Recovery occurred by 24 h, followed by a progressive acceleration of this function over the next 7 days. No depression in RNA or protein formation was noted through 36 h. By 48 h the cells in the upper 1/2 to 1/3 of the epidermis lost their normal appearance and discontinued synthesizing these macromolecules. At 72 h RNA and protein synthesis was again active throughout the epidermis and the apparently dead cells had desquamated. At this time the epidermis was notably acanthotic and the epidermal cells were markedly enlarged. Examination for the dark repair response revealed no evidence of unscheduled DNA synthesis following irradiation indicating that the excision repair process was not demonstrable within the first 15min after the phototoxic injury. These responses differ in a number of parameters from the phototoxic reactions induced by UV rays shorter than 320 nm.     

EVIDENCE FOR A MAJOR STRONG BINDING SITE FOR TETRACHLOROSALICYLANILIDE ON HUMAN SERUM ALBUMIN

Abstract— Solutions of human serum albumin(HSA) monomer were irradiated with UV light(360 nm) in the presence of [₁₄C]-3,3.4'S-tetrachlorosalicylanilide([₁₄C]-T₄CS).The [₁₄C]-T₄ CS-labeiled HSA was cleaved by cyanogen bromide and separated into two fractions. These fractions were reduced carboxymethylated and separated into their seven characteristic peptides and monitored for radioactivity. Tetrachlorosalicylanilide was found to bind mainly to one region of the sequence of HSA and this covalent binding site was located in residues 124 (Cys) to 298 (Met) of the molecule. The binding of 3,5-dichlorosalicylamido-4-(2,2,6.6-tetramethylpiperidine-l-oxyl (DCS-TEMPO),a spin-label analogue of T₄CS, to HSA was studied by electron spin resonance spectroscopy. In the absence of UV light. DCS-TEMPO bound non-covalently (k = 6.1 times 10₆M₁) to one major binding site on HSA. These results are evidence for the existence of a major strong binding site for the photochemical binding of T₄CS to HSA.     

SURVIVAL AND PYRIMIDINE DIMERS IN CULTURED FISH CELLS EXPOSED TO CONCURRENT SUN LAMP ULTRAVIOLET AND PHOTOREACTIVATING RADIATIONS

Abstract— Cultured fishcells(RBCF–1 line) were irradiated with filtered sun lamp ultraviolet (SL-UV; > 280 nm) together with or followed by illumination with daylight(DL) radiation (> 350 nm). The colony forming ability of the cells decreased with increasing fluence of SL-UV. Concurrent exposure of cells to SL-UV and DL, however, increased survival relative to exposure to SL-UV alone. The photoreactivable fraction reached 0.52 at22–25_‡C. By using a constant fluence modification factor of 86, the shape of dose-survival curve was found to be almost the same for 254 nm and SL-UV. In parallel with photoreactivation of cell survival, changes in the numbers of pyrimidine dimers in permeabilized cell DNA and in extracted total DNA were determined by measurements of endonuclease-sensitive sites (ESS). The yield of ESS in both DNA's increased almost linearly with increasing SL-UV fluence, although the yield in extracted DNA was about double of that in permeabilized cell DNA. The yield of ESS per unit fluence by 254 nm was about 70-fold greater than SL-UV. The fraction of cells inactivated per ESS was almost the same for 254 UV and SL-UV. In SL-UV-irradiated cells, the photoreactivable fractions in terms of ESS were _‡ 10% higher in extracted DNA than in the DNA of permeabilized cells and also were higher when DL was administered separately after SL-UV-irradiation. When irradiated cells were exposed to DL at 0_‡C, the photoreactivable fractions of both DNAs were appreciably less, indicating that the photoreactivation of ESS was enzymatic. These results support the suggestion that the mechanism for cell killing, mainly formation of pyrimidine dimers, by SL-UV is the same as that by 254 UV.     

PHOTOSENSITIVE PHENOMENA OF NITRILE HYDRATASE OF Rhodococcus sp. N-771

Abstract— When the washed cells of Rhodococcus sp. N-771 were incubated at 5°C in the dark under aerobic condition, their nitrile hydratase was inactivated after several days. Most of this activity was recovered by light irradiation. The speed of inactivation in the dark was affected by incubation temperature and amount of oxygen supply. Under anerobic conditions, however, this reversible dark inactivation was not observed; the photoirradiation of the cells irreversibly inactivated the initial cell activity by about 15%. The enzyme activity of the cell-free extract of the inactivated cells can also be recovered when photoirradiated. This process did not require oxygen, and was not prevented by dialysis. However, the enzyme of the cell-free extract could not be inactivated by dark, aerobic incubation nor by photoirradiation after dark anaerobic incubation.     

LASER-UV-MICROIRRADIATION OF CHINESE HAMSTER CELLS: THE INFLUENCE OF THE DISTRIBUTION OF PHOTOLESIONS ON UNSCHEDULED DNA SYNTHESIS

Abstract— Fibroblastoid Chinese hamster cells synchronized by mitotic selection were microirradiated in G1, using a low power laser-UV-microbeam (λ= 257 nm). The incident energy was either concentrated on a small part of the nucleus (mode 1) or distributed over the whole nucleus (mode 11). Using the same incident UV energy, the local UV fluences were estimated to differ by two orders of magnitude. Following microirradiation the cells were incubated with [³H]-thymidine for 2 h and thereafter processed for autoradiography. Silver grains were concentrated over the microirradiated part after mode 1 and distributed over the whole nucleus after mode 11 irradiation. To quantify the amount of unscheduled DNA synthesis, the number of grains per nucleus was determined. It increased with the total incident energy, but was not or only slightly affected by the mode of microirradiation, if appropriate autoradiographic conditions were used. The findings suggest that within the investigated range of energy densities (2.7–1000 J/m²), the total amount of unscheduled DNA synthesis depends on the total number of pyrimidine dimers but not on their distribution in nuclear DNA.     

ENHANCEMENT OF PHOTOREPAIR OF ULTRAVIOLET-DAMAGE BY PREILLUMINATION WITH FLUORESCENT LIGHT IN CULTURED FISH CELLS

Fluorescent light (FL) illumination of RBCF-1 cells, derived from a goldfish, prior to 254 nm UV-irradiation enhanced their ability to photorepair. The cells were illuminated with FL for 1 h (29 W/M2) and incubated for 8 h in the dark before being irradiated with 10 J/m2 UV. The surviving fraction of FL-treated cells after UV-irradiation rose about 7-fold (from 3 to 20%) by 20 min photorepair treatment with the same FL source, whereas 4-fold (from 1.6 to 6%) in the FL non-treated cells. Flow cytometric analysis showed that FL treatment did not affect the distribution of cell cycle phase at the time of UV-irradiation (8 h after FL treatment). Pyrimidine dimers induced by UV were measured by the use of UV endonuclease of Micrococcus luteus and alkaline agarose gel electrophoresis. Initial yields of dimers after exposure to 10 J/m2 UV were almost the same (about 0.11 dimer/kb) between FL treated and non-treated cells. But after 20 min photorepair treatment, about 70% of dimers were removed in the FL treated samples, while less than 20% were removed in the non FL-treated ones.     

PHYSIOLOGICAL EFFECTS OF ULTRAVIOLET LIGHTON DICTYOSTELIUM DISCOIDEUM SPORE GERMINATION

Abstract— The spore germination in Dictyostelium discoideum consists of four stages: activation, postactivation lag, swelling and emergence. Ultraviolet irradiation (total fluence of 250 J/m²) of spores at any time prior to late spore swelling allows full swelling, but inhibits the emergence of myxamoebae. In the case of freshly activated spores, a UV exposure time of 30 s (total fluence of 50 J/m²) is sufficient to reduce emergence to about 6% when measured after 24 h of incubation. This same fluence results in about 10% viability as measured by plaque forming ability. Experiments utilizing 'fractionated exposures' result in the same percentage inhibition of emergence as that found for 'single exposures' provided the total fluence is equivalent. The higher fluences (250 J/m²) which completely prevent emergence, do not affect the endogenous oxygen uptake of spores during swelling. Ultraviolet light irradiated spores respond to the same activation and deactivation treatments as control unirradiated spores. Ultraviolet irradiation after late spore swelling allows emergence to occur in only a small fraction of the population. This fraction of cells which can emerge after UV treatment is said to have passed a 'competence point', which is believed to be the time when all the events necessary for emergence have been completed. Though the sites of UV inactivation in spores can only be postulated at present, it is apparent that the initial stages of germination (activation, postactivation lag and spore swelling) occur independently of the UV sensitive sites. The final stage of germination (emergence), however, is dependent on UV sensitive functions.     

THE ACTION SPECTRUM AND DOSE RESPONSE STUDIES OF UNSCHEDULED DNA SYNTHESIS IN NORMAL HUMAN FIBROBLASTS

Abstract— Excision repair of DNA damage by UV has been assessed in normal human fibroblasts in culture by measuring unscheduled DNA synthesis. Dose response experiments indicated that the same chromophore was involved in UV-induced damage and excision repair at three different wavelengths between 260 and 300 nm. Action spectra for unscheduled DNA synthesis were determined at wavelengths between 260 and 320 nm 30 min after irradiation using 2 doses of UV, 100 J m^-2and 10Jm^-2. Experiments at the lower dose were carried out because it appeared that repair was saturated with the higher dose at 260 and 280 nm. To explore this part of the spectrum further, experiments were performed with different doses at 260 and 280 nm and unscheduled DNA synthesis assessed 30 min and 24 h after irradiation. At 24 hr after irradiation a significantly greater amount of unscheduled DNA synthesis occurred at 280 nm. It is suggested, therefore, that both DNA and protein are concerned in the absorption of UV which leads to DNA damage and excision repair.