CELL DENSITY DEPENDENCE OF ULTRAVIOLET LIGHT ENHANCED REACTIVATION OF Herpes simplex TYPE I AND THE LARGE PLAQUE EFFECT IN C3H/10T1/2 MOUSE FIBROBLASTS

C3H/10T1/2 mouse fibroblasts were grown to different cell densities either by plating at low density and allowing different growth periods, or by plating at a series of increasing densities and allowing the same growth period. These plates were UV irradiated at 7.5 J/m2 or mock irradiated and 24 h later infected with UV-irradiated Herpes simplex type I virus which had been UV irradiated at 50 or 125 J/m2 or mock irradiated. The numbers and sizes of plaques were measured and these data used to calculate the extent of UV-enhanced host cell reactivation, the capacity enhancement, the large plaque effect (LPE) and the small plaque effect (SME). The influence of cell density on these phenomena was similar for both series of density experiments. Ultraviolet-enhanced host cell reactivation could be demonstrated only for cultures of lower density. The capacity of the cells for Herpes simplex type I virus decreased with cell density, but UV irradiated cells showed an increase in capacity with cell density. Plaque sizes decreased in all cases with cell density but the LPE and SPE were not significantly altered. The greatest variation in the above parameters occurred just as the cells were approaching confluence, where most host cell reactivation experiments are carried out. We conclude that the reproducibility of such experiments depends critically on cell density, a dependence which may be relevant to mechanistic interpretations of the UV-dependent phenomena.     

THE EFFECTS OF ULTRAVIOLET RADIATION EXPOSURE OF ADJACENT CELLS ON PLAQUE FORMATION WITH Herpes simplex VIRUS TYPE I

African green monkey kidney cells (CV-1P) were exposed to low fluences of 254 nm germicidal radiation and then infected with Herpes simplex virus, type I. The result of this treatment was an increase in viral plaque development rate, the large plaque effect (LPE). A measurement of the kinetics of plaque development suggested that a large portion of the effect could be due to events occurring in those cells that are adjacent to the initially infected cell. An infectious center assay was employed in order to isolate the effects of ultraviolet radiation (UV) on the initially infected cells from those effects on the adjacent cells that became infected as the plaque spread radially outward. Plaque development began earlier in UV irradiated cells and progressed at a uniformly accelerated rate compared to untreated cells. Results indicate that although the initially infected cell contributes to the LPE, the major effect is due to events that occur in the adjacent cells. Each round of viral replication appears to contribute equally to the LPE. The virally induced rate of fusion of the initially infected cell with its immediate neighbors is not affected by UV.     

THE EFFECTS OF ULTRAVIOLET AND VISIBLE RADIATION ON MOUSE ASCITES TUMOUR CELLS

Abstract— Effects of ultraviolet and visible radiation on the viability of Landschutz ascites tumour cells have been tested by growing control and treated tumour samples in adult mice. The tumour cells were irradiated as a dilute suspension in isotonic buffered salt solution, and were equilibrated at 0°C with oxygen or with nitrogen before irradiation.
Tumour cell proliferation was measured by a variety of techniques. The preferred assay-method was the growth of solid tumours in the axillae and groins of mice after sub-cutaneous inoculation of varying dilutions of treated or control ascites tumour cells. The immune response of the mice to the injected cells was reduced by whole body irradiation with a 300r dose of x-rays two days before inoculation. Results were calculated from parallel line assays using the reciprocal of the delay in appearance of the solid tumours up to 30 days post-innoculation. This reciprocal (1/T) was linearly related to the logarithm of the number of cells inoculated.
Photoreactivation has been demonstrated for this system, in which both U.V. and visible radiations were absorbed by the same cells. Light delivered alone in oxygen or in nitrogen was without effect on cell-viability, but it increased cell-survival after u.v.-irradiation in nitrogen and decreased survival after u.v.-irradiation in oxygen. Ultraviolet radiation alone was not significantly more lethal in oxygen than in nitrogen. A further observation in this work was an interaction between irradiated and control tumour cells injected into the same animal.
It is suggested that the radiation used may affect the antigenic character of the tumour cells as well as their reproductive capadity.     

HOST CELL REACTIVATION IN MAMMALIAN CELLS-V. PHOTOREACTIVATION STUDIES WITH HERPES VIRUS IN MARSUPIAL AND HUMAN CELLS

Abstract— The survival of UV-irradiated herpes simplex virus was determined in cultured Potoroo (a marsupial) and human cells under lighting conditions which promote photoreactivation. Photoreactivation was readily demonstrated for herpes virus in two lines of Potoroo cells with dose reduction factors of 0.7-0.8 for ovan cells and 0.5-0.7 for kidney cells. Light from Blacklite (near UV) lamps was more effective than from Daylight (mostly visible) lamps, suggesting that near UV radiation was more efficient for photoreactivation in Potoroo cells. The quantitative and qualitative aspects of this photoreactivation were similar to those reported for a similar virus infecting chick embryo cells. UV-survhal curves for herpes virus in Potoroo cells indicated a high level of "dark" host cell reactivation. No photoreactivation was found for UV-irradiated vaccinia virus in Potoroo cells. A similar photoreactivation study was done using special control lighting (Λ > 600 nm) and human cells with normal repair and with ceils deficient in excision repair (XP). No photoreactivation was found for UV-irradiated herpes virus in either human cell with either Blacklite or Daylight lamps as the sources of photoreacti-vating light. This result contrasts with a report of photoreactivation for a herpes virus in the same XP cells using incandescent lamps.     

EFFECTS OF ULTRAVIOLET LIGHT ON THYMIDINE INCORPORATION AND DNA CHAIN ELONGATION IN PHOTOREACTIVABLE INSECT CELLS

An insect cell line, IAL-PID2, was exposed to UV and analyzed for its ability to incorporate [3H]-thymidine and to elongate replicon-sized DNA fragments. After exposure to 5 or 10 J/m2 UV, the cells exhibited a rapid and prolonged depression in the rate of thymidine incorporation. Photoreactivation reduced this depression but did not entirely reverse it. For exposures of 5 J/m2 or above, full recovery did not occur until 18 h after exposure. The blockage of fork progression after UV exposure was fluence-dependent, with replication segments after exposure to 20 J/m2 being shorter than those observed after exposure to 10 J/m2. Immediately after exposure to either 10 or 20 J/m2, photoreactivation reversed blockage of fork progression, indicating that the (5-6) cyclobutyl pyrimidine dimer is responsible for blockage. This also indicates that blockage of fork progression may not be the only factor responsible for the prolonged depression seen in thymidine incorporation. Three hours after exposure to either 10 or 20 J/m2, replication segments were still significantly shorter than control segments. Photoreactivation completely reversed blockage after exposure to 10 J/m2, but did not completely reverse blockage after exposure to 20 J/m2, indicating that at such fluences, other lesions may play a role in UV-induced blockage of fork progression.     

MODULATION BY THIOLS OF THE MEROCYANINE 540-SENSITIZED PHOTOLYSIS OF LEUKEMIA CELLS, RED CELLS, AND Herpes simplex VIRUS TYPE 1

This paper reports on the role of endogenous and exogenous thiols in the merocyanine 540 (MC 540)-sensitized photoirradiation of L1210 leukemia cells, human erythrocytes, and human Herpes simplex virus type 1. Several measures taken to decrease the intracellular content of glutathione enhanced the cells' sensitivity to MC 540-sensitized photoirradiation while stimulation of glutathione biosynthesis or supplementation of the extracellular or extraviral thiol content decreased the photosensitivity of cells and viruses. Taken together, these data suggest that endogenous and exogenous thiols can modulate the sensitivity of cells and enveloped viruses to MC 540-sensitized photoirradiation. They also pose new questions as to the mechanism of MC 540-sensitized photolysis.     

EARLY EFFECTS OF NEAR-ULTRAVIOLET RADIATION ON YEAST CELLS: CHANGES IN CELL SIZE

Exponentially growing yeast cells showed a drastic shrinkage when irradiated in water suspension (but not in buffer) with broad-band near-UV radiation. This was clearly seen soon after irradiation in size-distribution curves measured by a Coulter counter. This early shrinkage was observed at a near-UV fluence where the survival enters a region of exponential decline after a large shoulder. We further observed the formation of a distinct band in a density-gradient-centrifugation profile, presumably corresponding to the near-UV-affected cells. A survival test showed that the cells making up this band were dead.     

THE WAVELENGTH DEPENDENCE OF ULTRAVIOLET LIGHT—INDUCED CELL KILLING AND MUTAGENESIS IN L5178Y MOUSE LYMPHOMA CELLS

Abstract The wavelength dependence of ultraviolet radiation-induced cell killing and mutagenicity in L5178Y mouse lymphoma cells has been determined from 235 nm to 313 nm. Cells were irradiated in phosphate buffered saline at 20°C. The amount of cell killing was determined by cloning in soft agar medium immediately after irradiation. Mutation frequency was determined, after a 3-day expression time, by cloning in soft agar medium in the presence and the absence of 5-bromo-2'-deoxyuridine (BrdUrd). The endpoint used to quantitate lethal effects was the exposure necessary to reduce the surviving fraction to 10%, while the endpoint for mutagenesis was the exposure necessary to increase the frequency of BrdUrd-resistant colonies ten-fold over the background level. Data were corrected for quantum energy and the action spectra for cell killing and mutagenesis were plotted as relative biological effectiveness per quantum vs wavelength, relative to the effect at 265.2 nm. Both action spectra show broad maxima at 270 nm, and are very similar to the action spectra determined by Rothman and Setlow (1979) for pyrimidine dimer formation and cell killing in V-79 cells.     

EFFECTS OF FLUENCE FRACTIONATION ON UV-INDUCED MALIGNANT TRANSFORMATION AND CELL KILLING IN NON-CYCLING PLATEAU PHASE MOUSE CELLS

Plateau phase C3H 10T 1/2 mouse cells were used to measure the response to split fluence UV light irradiation in the absence of any cell cycle effects. It was found that fluence fractionation with up to 24 h between the fluences resulted in no survival enhancement. The frequency of malignant transformation was potentiated 2.5-fold when the time interval between the fluences was greater than 4h. This potentiation of transformation was attributed to plateau phase holding rather than to fluence fractionation per se.     

UROCANIC ACID ANALOGUES AND THE SUPPRESSION OF THE DELAYED TYPE HYPERSENSITIVITY RESPONSE TO Herpes simplex VIRUS

Ultraviolet irradiated urocanic acid (4-imidazoleacrylic acid) containing a mixture of cis- and trans-isomers has been shown previously to induce suppression of the delayed type hypersensitivity (DTH) response to Herpes simplex virus type 1 (HSV-1) in a murine model of infection. The cis-isomer of urocanic acid was prepared and the cis- and trans-isomers of 2-methylurocanic acid. 2-pyrroleacrylic acid, 2-furanacrylic acid, 2-thiopheneacrylic acid, 3-thiopheneacrylic acid as well as dihydrourocanic acid and histamine. Each was applied at concentrations of 1 and 50 micrograms per mouse to the shaved dorsal skin and the mice were infected subcutaneously with HSV 5 h later. After 8-10 days the DTH response to the virus was measured by an ear swelling test. It was found that cis-urocanic acid was effective in suppressing the DTH response at levels of 1 microgram per mouse or less. The cis- and trans-isomers of 2-furanacrylic acid, 2-pyrroleacrylic acid and 2-thiopheneacrylic acid were also effective, with the cis- form generally being more active than trans, and 2-pyrroleacrylic acid being particularly potent. Cis- and trans-3-thiopheneacrylic acid, on the other hand, were only marginally immunosuppressive while neither isomer of 2-methylurocanic acid had any suppressive ability. Dihydrourocanic acid and histamine were also shown to suppress the DTH response. Thus the structural features necessary for urocanic acid and its analogues to act as mediators of UV-induced immunosuppression could be deduced and implications for their mechanism of action discussed.     

EFFECT OF INTENSITY AND WAVELENGTH OF FLUORESCENT LIGHT ON CHROMOSOME DAMAGE IN CULTURED MOUSE CELLS

Abstract—A single 3- to 20-hr exposure of line NCTC 9266 mouse cells to cool-white fluorescent light (4.6 W/m²) produces chromatid breaks and exchanges. The effective wavelength is in the visible range and coincides with the mercury emission peak at 405 nm. Increasing light intensity from 4.6 W to 15.3 W/m² for 20 h causes a concomitant increase both in production of chromosome damage and formation of hydrogen peroxide (H₂O₂) in the serum-free medium. Cells washed free of medium and illuminated in saline for 3 h show chromosome damage to the same extent as cells illuminated in culture medium. Addition of catalase during the exposure period of 3 h eliminates the light-induced damage. We conclude that the light-induced chromatid breaks and exchanges result from H₂O₂ production within the cell and that exogenous catalase can enter the cell and prevent the damage.     

ACUTE EFFECTS OF NEAR ULTRAVIOLET AND VISIBLE LIGHT ON THE CUTANEOUS ANTIOXIDANT DEFENSE SYSTEM

Reactive oxygen species are considered to play an important role in cutaneous pathology. Enzymic and non-enzymic antioxidants can prevent oxidative damage but may be overcome by strong pro-oxidative stimuli. The acute effect of a single exposure to near ultraviolet (UVA)/visible radiation (greater than 320 nm) on various skin antioxidants was examined in hairless mice immediately after irradiation. Impairment of cutaneous catalase and glutathione reductase activity was observed. Superoxide dismutase and glutathione peroxidase were not significantly influenced. Inhibition of catalase may render skin more susceptible to the damaging effects of hydrogen peroxide and its reaction products such as the hydroxyl radical. Partially diminished glutathione reductase activity is not accompanied by a change in reduced/oxidized glutathione level immediately after irradiation. There was a tendential (not statistically significant) decrease in cutaneous tocopherol, ubiquinol + ubiquinone 9 and ascorbic acid levels, either indicating direct photodestruction or consumption by reaction products of photooxidative stress. This partial impairment of the cutaneous antioxidant defense system by near ultraviolet/visible light, showing that the most susceptible component in skin is catalase, suggests possible pharmacological interventions.     

EFFECTS OF ACRIDINE PLUS NEAR ULTRAVIOLET LIGHT ON ESCHERICHIA COLI MEMBRANES AND DNA IN VIVO

Results from a variety of experiments indicate that photodynamic damage to E. coli treated with the hydrophobic photosensitizer acridine plus near-UV light involves both cell membranes and DNA. Split-dose survival experiments with various E. coli mutants reveal that cells defective in rec A, uvr A, or pol A functions are all capable of recovery from photodynamic damage. Alkaline sucrose gradient analysis of DNA from control and treated cells revealed that acridine plus near-UV light treatment converts normal DNA into a more slowly sedimenting form. However, the normal DNA sedimentation properties are not restored under conditions where split-dose recovery is effective. Several lines of evidence suggest that membrane damage may be important in the inactivation of cells by acridine plus near-UV light. These include (a) a strong dependence of sensitivity on the fatty acid composition of the membranes; (b) a strong dependence of sensitivity on the osmolarity of the external medium; and (c) the extreme sensitivity of an E. coli mutant having a defect in its outer membrane barrier properties. Direct evidence that acridine plus near-UV light damages cell membranes was provided by the observations that (a) the plasma membrane becomes permeable to o-nitrophenyl-ß-D-galactopyranoside and (b) the outer membrane becomes permeable to lysozyme after treatment. A notable result was that cells previously sensitized to lysozyme by exposure to acridine plus near-UV light lose that sensitivity upon subsequent incubation. This strongly suggests that E. coli cells are capable of repairing damage localized in the outer membrane.     

GERMICIDAL ULTRAVIOLET LIGHT INDUCES ORNITHINE DECARBOXYLASE IN MOUSE EPIDERMAL CELLS AND MODIFIES THE INDUCTION CAUSED BY PHORBOL ESTER TUMOR PROMOTERS

Germicidal ultraviolet light (UVC. 8–10 J/m²) induces ornithine decarboxylase (ODC) in mouse epidermal cells in vitro in a biphasic manner with maxima of 2–3 fold induction at 4–6 h and of 10–20 fold induction at 15–18 h after irradiation. At this dose of UVC overall protein synthesis is inhibited by 10–30% and RNA synthesis by 40–50%. Induction of both ODC peaks is prevented by actinomycin D or cycloheximide. Similar culture factors appear to influence the extent of ODC induction by UVC and by the tumor promoter, 12-O-tetradecanoyl phorbol-13-acetate (TPA), since the ratio of peak activities is approximately constant at 2, whereas absolute values vary considerably between experiments. If cells are irradiated with UVC and then exposed to TPA, the effects are additive at 10 J/m², less than additive at higher and enhanced at lower doses of UVC.     

THE EFFECTS OF ULTRAVIOLET C ON in vitro NUCLEOSOME ASSEMBLY AND STABILITY

Abstract The effects of ultraviolet C (UVC) irradiation on nucleosome assembly and its stability were investigated quantitatively using an in vitro nucleosome assembly system comprising a plasmid DNA of pBR322 and core histones isolated from rat ascites hepatoma cells. Nucleosomal formation was estimated by analyzing the resulting DNA supercoils. When UVC-irradiated (3000 J/m²) DNA was used as a substrate for the nucleosome assembly system, the nucleosomal formation efficiency was reduced by half compared with nonirradiated DNA. On the other hand, when the reconstituted nucleosomes (minichromosomes) on the nonirradiated DNA were irradiated with UVC (3000 J/m²), about half each were disrupted and retained. These results indicate that it is difficult for UV-damaged DNA regions to supercoil around the histone octamers to form nucleosomes and that the histone octamers in the UV-damaged nucleosomes tend to be dissociated from DNA.     

STUDY OF THE EFFECTS OF ULTRAVIOLET LIGHT ON BIOMEMBRANES—IV. THE EFFECT OF OXYGEN ON UV-INDUCED HEMOLYSIS AND LIPID PHOTOPEROXIDATION IN RAT ERYTHROCYTES AND LIPOSOMES

Abstract— Hemolysis induced by irradiation with ultraviolet (UV) light at 254 nm showed a pronounced oxygen effect: under irradiation in vacuum, the rate of hemolysis was decreased by an order of magnitude. Irradiation at 254 nm in air but not under vacuum caused the peroxidation of erythrocyte membrane lipids. These results suggest that membrane lipid photoperoxidation is one of the causative factors of UV hemolysis. Irradiation at different wavelengths showed that UV-induced lipid photoperoxidation in erythrocyte membranes developed while the antioxidant α-tocopherol was directly photooxidized. It is shown that the process of lipid photolysis in erythrocyte membranes involves sensitization, possibly by protoporphyrin, whose presence in liposomes accelerates the photoperoxidation at 254 and 365 nm of unsaturated fatty acid residues in lecithin. Possible mechanisms of photochemical damage to erythrocyte membranes are discussed.     

THE CYTOTOXIC AND MUTAGENIC EFFECTS OF UVA RADIATION ON L5178Y MOUSE LYMPHOMA CELLS

Abstract— A broad-band UVA source that emits primarily350–400 nm radiation and no measurable radiation below 340 nm was used to test toxicity and mutagenicity at the thymidine kinase locus in L5178Y, subclone 3.7.2C (TK⁺/^-) mouse lymphoma cells. Cells were exposed to a fluence of 0 to 80 × 10⁴ J/m². The relationship between UVA fluence and survival was found to have a shoulder region followed by an exponential decrease in survival at higher fluence levels. An exposure-dependent increase in mutation was observed with increasing fluences from 0 to about 60 × 10⁴ J/m². An approximately 3- to 4-fold increase in mutations (trifluorothymidine resistance) over unexposed, control cells was seen at a fluence that resulted in 90% cell killing. We conclude that UVA radiation is a mutagen in the L5178Y mouse lymphoma cells used in this study.