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 WAVELENGTH DEPENDENCE OF ULTRAVIOLET INACTIVATION OF HOST CAPACITY IN A MAMMALIAN CELL-VIRUS SYSTEM

Abstract. The ability of UV-irradiated African green monkey kidney cells (CV-1) to support the growth of unirradiated herpes simplex virus type 1 as measured by plaque forming ability has been investigated. The lowering of plaque formation by the virus when the host cell was irradiated was examined at thirteen different wavelengths. An action spectrum for this cellular parameter (capacity) was obtained in the wavelength region of 235–302 nm. This action spectrum points to nucleic acid as the critical target molecule for this effect.     

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.     

REACTIVATION OF UV- AND γ-IRRADIATED HERPES VIRUS IN UV- AND X-IRRADIATEDCV–1 CELLS

Abstract— Enhanced reactivation of UV- and y-irradiated herpes virus was investigated by the plaque assay onCV–1 monkey kidney monolayer cells irradiated with UV light or X-rays. Both UV- and X-irradiatedCV–1 cells showed enhancement of survival of UV-irradiated virus, while little or no enhancement was detected for y-irradiated virus assayed on UV- or X-irradiated cells. The enhanced reactivation of UV-irradiated virus was greater when virus infection was delayed 24 or 48 h, than for infection immediately following the irradiation of cells. It is demonstrable that the UV- or X-irradiatedCV–1 cells are able to enhance the repair of UV damaged herpes virus DNA, but not of y-ray damaged ones.     

UV-ENHANCED REACTIVATION OF MINUTE-VIRUS-OF-MICE: STIMULATION OF A LATE STEP IN THE VIRAL LIFE CYCLE

Abstract— UV-enhanced reactivation of minute-virus-of-mice (MVM), an autonomous parvovirus, was studied in parasynchronous mouse A9 cells. The survival of UV-irradiated MVM is increased in cells which have been UV-irradiated prior to infection. UV-enhanced reactivation can be explained neither by facilitated plaque detection on UV-treated indicator cells, nor by altered kinetics of virus production by UV-irradiated cells. No effect of the multiplicity of infection on virus survival was detected in unirra-diated or irradiated cells. The magnitude of UV-enhanced reactivation is a direct exponential function of the UV dose administered to the virus while virus survival is inversely proportional to the UV dosage. The expression of UV-enhanced reactivation can be activated in cells arrested in G₀, it requires de novo protein synthesis and it is maximal when cells are irradiated 30 h before the onset of viral DNA replication. Early phases of the viral cycle, such as adsorption to cellular receptors, migration to the nucleus and uncoating, were not affected by cell irradiation and are unlikely targets of the UV-enhanced reactivation function(s). These results, together with the single-strandedness of the viral genome, strongly suggest that the step stimulated in UV-irradiated cells functions concomitant with, or subsequent to, viral DNA replication.     

Radiation enhanced reactivation of nuclear replicating mammalian viruses.

Abstract— When CV-1 monkey kidney cells were UV-irradiated (0–18 J/m²) or X-irradiated (0–10krads) before infection with UV-irradiated simian adenovirus 7 (SA7) or simian virus 40 (SV40), increases in the infectivity of these nuclear replicating viruses as measured by plaque formation were observed. These radiation enhanced reactivations, UV enhanced reactivation (UVER) and X-ray enhanced reactivation (X-ray ER), occurred both when virus infection immediately followed irradiation of the cells (except for X-ray ER with SA7) and when virus infection was delayed until 3–5 days after cell irradiation. While there was little difference in the levels of reactivation of UV-irradiated SV40 between immediate and delayed infection, delayed infection resulted in higher levels of reactivation of SA7. X-ray enhanced reactivation of UV-irradiated Herpes simplex virus persisted for several days but did not increase. Thus, X-ray enhanced and UV enhanced reactivations of these mammalian viruses were relatively long-lived effects. Essentially no UVER or X-ray ER was found in CV-1 cells for either immediate or delayed infection with UV-irradiated vaccinia virus or poliovirus, both of which replicate in the cell cytoplasm. These results suggest UVER and X-ray ER in mammalian cells may be restricted to viruses which are replicated in the cell nucleus.     

UV-ENHANCED VIRUS REACTIVATION IN MAMMALIAN CELLS: EFFECTS OF METABOLIC INHIBITORS*

Abstract—The induction process of UV-enhanced reactivation of UV-irradiated herpes simplex virus was investigated in CV-1 monkey kidney cells. A protein synthesis inhibitor, cycloheximide (0.5–5 μg/m/), present in the culture medium For 24 h between cell irradiation and virus infection decreased the enhanced virus survival normally found in UV-irradiated cultures. The enhanced virus reactivation became essentially resistant to the addition of cycloheximide by 6–8 h after cell irradiation, indicating that the cycloheximide-sensitive process necessary for enhanced reactivation was complete by that time. Since cycloheximide not only inhibits protein synthesis, but DNA synthesis as well, we investigated the effect of a DNA synthesis inhibitor, hydroxyurea. Hydroxyurea did not decrease UV-enhanced virus survival, but resulted in enhanced virus survival even in unirradiated cells. Therefore, the cycloheximide-caused inhibition of UV-enhanced reactivation did not arise from inhibition of DNA synthesis. The combined results indicate that (1) UV-enhanced virus reactivation in monkey kidney cells requires de novo protein synthesis during the first 6–8 h after cell irradiation and that (2) DNA synthesis inhibition may be the initiating event.     

THE WAVELENGTH DEPENDENCE OF 8-METHOXYPSORALEN PHOTOSENSITIZATION OF HOST CAPACITY INACTIVATION IN A MAMMALIAN CELL-VIRUS SYSTEM

Abstract— The addition of 8-methoxypsoralen to cultures of African green monkey cells (CV-I) sensitized the inactivation by near UV radiation (302–370 nm) of the ability of the cells to host herpes simplex virus. No sensitizing effect by drug addition was noted for far UV radiation (232–297 nm). An action spectrum for the photosensitized inactivation of this cellular parameter was obtained. This action spectrum is consistent with the absorption spectrum of 8-methoxypsoralen.     

UV-ENHANCED REACTIVATION IN MAMMALIAN CELLS: INCREASE BY CAFFEINE

Abstract— It has been reported that caffeine decreases UV-enhanced reactivation of UV-irradiated Herpes simplex virus in CV-1 monkey kidney cells. That occurred when there was no delay between cell irradiation and virus infection. In the present study, virus infection was delayed following cell irradiation to allow an 'induction'period separate from the 'expression'period which occurs during the virus infection. Thus, the effects of caffeine on 'induction'and 'expression'could be determined separately. Caffeine increased the expression of UV-enhanced reactivation, while causing a small decrease in the 'induction'of enhanced reactivation.     

THE EFFECTS OF ULTRAVIOLET LIGHT ON HOST CELL REACTIVATION AND PLAQUE SIZE OF Herpes simplex VIRUS TYPE I IN C3H/lOT1/2 MOUSE CELLS

— Herpes simplex virus — type 1 (HSV-I) plaque-forming ability and plaque size were measured on C3H/1OT1/2 cell monolayers as functions of pretreatment dose with UV light at different times before inoculation with virus, in order to determine if UV-enhanced reactivation (ER) of UV-irradiated virus. as well as associated phenomena, could be obtained in this cell system. The number of virus plaques observed (i.e. the capacity of the cells to support virus growth) and the size of the plaques were found to increase substantially with pretreatment of the cells with UV light. However, no significant ER was observed. Therefore, the mechanisms responsible for the increases in plaque size and cell capacity seem to be independent of those responsible for ER. In work by others. C3H/l0T1/2 cells have hcen transformed by UV light at doses similar to those used in this study; the absence of ER of UV-irradiated virus in this study indicates that the mechanism underlying ER is not required for transformation.     

THE WAVELENGTH DEPENDENCE OF THE EFFECT OF 8-METHOXYPSORALEN PLUS ULTRAVIOLET RADIATION ON THE INDUCTION OF LATENT SIMIAN VIRUS 40 FROM A MAMMALIAN CELL

Abstract— The effect of 8-methoxypsoralen (8-MOP) plus ultraviolet radiation (UV) of different wavelengths in the region 238–365 nm on the induction of SV40 from SV40-transformed Syrian hamster kidney cells was investigated. Results indicate that 8-MOP + UV treatment activates as much as 1000-fold more virus than UV alone at wavelengths in the region 302–365 nm. At wavelengths below 302 nm, 8-MOP addition to cells prior to irradiation shows little, if any, effect. A wavelength dependence for this viral induction is presented.     

USE OF METABOLIC INHIBITORS TO INVESTIGATE THE EXCISION REPAIR OF PYRIMIDINE DIMERS AND NON-DIMER DNA DAMAGES INDUCED IN HUMAN AND ICR 2A FROG CELLS BY SOLAR ULTRAVIOLET RADIATION

Abstract— ICR 2A frog and normal human skin fibroblasts were exposed to either 5 J/m² of 254 nm UV or 50 kJ/m² of the Mylar-filtered solar UV wavelengths produced by a fluorescent sunlamp. Following these approximately equitoxic treatments, cells were incubated in medium containing the DNA synthesis inhibitors hydroxyurea (HU) and 1–β-D-arabinofuranosyl cytosine (ara C) for 0–20 min (human fibroblasts) or 0–4 h (frog cells) to accumulate DNA breaks resulting from enzymatic incision during excision repair. It was found that breaks were formed in human cells at about a 200-f-old higher rate compared with the ICR 2A cells indicating a relatively low capacity for excision repair in the frog cells. In addition, the rate of DNA break formation in solar UV-irradiated cells was only one-third of the level detected in 254 nm-irradiated cells. This result is consistent with the conclusion that the pathway(s) involved in the repair of solar UV-induced DNA damages differs from the repair of lesions produced in cells exposed to 254 nm UV.     

HERPES VIRUS PRODUCTION IN MONKEY KIDNEY AND HUMAN SKIN CELLS TREATED WITH ANGELICIN OR 8-METHOXYPSORALEN PLUS 365 nm LIGHT

Abstract—At an cquimolar concentration of 50 μM the bifunctional furocoumarin, 8-methoxypsoralen (8-MOP), is about 36 times more efficient in inhibiting the colony forming ability of CV-I monkey kidney cells than the monofunctional furocoumarin angelicin. In contrast 8-MOP is only 7.5 times more efficient than angelicin for the inhibition of herpes simplex virus (HSV) production in CV-1 cells. This latter factor seems to reflect differences in photoreactivity of the two compounds with host cell DNA.
A substantial recovery of HSV production was seen when cells were infected at different time intervals after treatment with angelicin-plus-light, whereas recovery was very limited after 8-MOP plus light treatment. The recovery process was slow as compared to that observed after UV (254 nm)-irradiation.
The repair capacities of treated normal and xeroderma pigmentosum (group A) skin fibroblasts were estimated by measuring HSV production and unscheduled DNA synthesis. XP-A cells repaired angelicin induced damage less efficiently than did normal cells. Neither cell type showed any repair activity after 8-MOP plus light treatment.     

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.     

PHOTODYNAMIC TREATMENT OF HERPES SIMPLEX VIRUS INFECTION IN VITRO

Abstract— The effects of photodynamic action on in vitro herpes simplex virus infections of CV-1 monkey kidney fibroblasts or human skin fibroblasts were determined using proflavine sulfate and white fluorescent lamps. Photodynamic treatment of confluent cell monolayers prior to virus infection inactivated cell capacity, i.e. the capacity of the treated cells to support subsequent virus growth as measured by plaque formation. The capacity of human cells was more sensitive to inactivation than the capacity of monkey cells when 6 μM proflavine was used. Treated cell monolayers recovered the capacity to support virus plaque formation when virus infection was delayed four days after the treatment. Experiments in which the photodynamically treated monolayers were infected with UV-irradiated virus demonstrated that this treatment induced Weigle reactivation in both types of cells. This reactivation occurred for virus infection just after treatment or 4 days later. A Luria-Latarjet-type experiment was also performed in which cultures infected with unirradiated virus were photodynamically treated at different times after the start of infection. The results showed that for the first several hours of the virus infection the infected cultures were more sensitive to inactivation by photodynamic treatment than cell capacity. By the end of the eclipse period the infected cultures were less sensitive to inactivation than cell capacity. Results from extracellular inactivation of virus grown in monkey cells at 6 μM proflavine indicated that at physiological pH the virus has a sensitivity to photodynamic inactivation similar to that for inactivation of cell capacity. The combined data indicated that photodynamic treatment of the cell before or after virus infection could prevent virus growth. Thus, photodynamic inactivation of infected and uninfected cells may be as important as inactivation of virus particles when considering possible mechanisms in clinical photodynamic therapy for herpes simplex.     

Cytotoxic metabolites from the wood-decayed fungus Xylaria sp. BCC 9653

Chemical investigation of the wood-decayed fungus Xylaria sp. BCC 9653 has led to the isolation of a new methyl aminobenzoate (1) together with eleven known compounds. The structures were established by analysis of spectroscopic data. Cytochalasin D (2), one of the known metabolites, exhibited potent cytotoxicity against African green monkey kidney fibroblast (Vero) cells with an IC(50) value of 0.19 microM.     

RETARDATION OF ULTRAVIOLET LIGHT ACCELERATED CHLOROSIS BY VISIBLE LIGHT OR BY BENZYLADENINE IN NICOTIAN A GLUTINOSA LEAVES: CHANGES IN AMINO ACID CONTENT AND CHLOROPLAST ULTRASTRUCTURE*

Abstract— Low doses (180–720 Jm^-2) of ultraviolet light (254 nm) are known to accelerate the chlorosis of detached leaves in darkness. The development of such chlorosis is prevented by a photoreactivation treatment. However, we found that delayed light exposure or benzyladenine treatments (which were not effective in photorepair of UV-induced thymine dimers in cell DNA) were also effective in retarding the UV-accelerated chlorosis. Small drops of benzyladenine solution placed on the UV irradiated leaf formed green islands which acted as strong sinks for the accumulation of free amino acids during dark incubation. To a lesser degree, non–irradiated green tissues surrounded by irradiated yellow leaf tissue also acted as sinks for amino acid accumulation. The accelerated chlorophyll loss in UV-irradiated leaves was correlated with degradation of chloroplast ultrastructure. Visible light or benzyladenine retarded this chloroplast degradation. The accelerated senescence of UV irradiated leaf tissue, therefore, is ultrastructurally and physiologically similar to normal senescence of detached dark-incubated leaves, but progresses at a faster rate. When the lower leaf surface was irradiated with high UV doses (3600–10,800 Jm^-2), the chloroplast ultrastructure of the spongy cells (except the envelope) was preserved for 3 days after dark incubation. However, the chloroplasts of the palisade cells were in a late stage of senescence. Since the spongy cells were dead (plasmalemma, tonoplast and chloroplast envelope disappeared), the maintenance of green color and ultrastructure of chloroplasts could have been due to inhibition of degrading enzymes normally associated with senescence.     

ENHANCED REPLICATION OF DAMAGED SV40 DNA IN CARCINOGEN-TREATED MONKEY CELLS

Abstract Treatment of mammalian cells with certain chemical or physical carcinogens prior to infection with ultraviolet-irradiated virus results in enhanced survival or reactivation of the damaged virus. To investigate the molecular basis of this enhanced reactivation (ER), we have examined Simian virus 40 DNA replication in carcinogen-treated cells. We find that treatment of monkey kidney cells with N-acetoxy-2-acetylamino-fluorene or UV radiation 24 h prior to infection with ultraviolet-irradiated Simian virus 40 leads to enhancement of viral DNA replication measured at 36 h after infection by [³H]thymidine incorporation or hybridization. The enhancement of DNA replication is observed when cells are treated from 1 to 60 h before infection or 1 to 16 h after infection. The fact that enhancement is observed also when cells are treated after infection rules out the possibility that enhancement occurs at the level of adsorption or penetration of the virus. Measurements of the time course of viral DNA replication indicate that pretreatment of cells does not alter the time of onset of viral DNA replication. We conclude from these studies that ER of Simian virus 40 occurs at the level of viral DNA replication.     

EFFECTS OF CAFFEINE ON DNA REPAIR OF UV-IRRADIATED DICTYOSTELIUM DISCOIDEUM

Abstract— Caffeine enhances the UV-killing of amoeboid cells of NC-4, but UV-irradiated γs-13 is insensitive to caffeine. UV-irradiated NC-4 becomes insensitive to the effect of caffeine during a postirradiation incubation in buffer for about 90 min, but γs-13 remains unchanged in the sensitivity to caffeine throughout the incubation for 180 min. Amoeboid cells of γs-13 can remove pyrimidine dimers as well as NC-4 even in the presence of caffeine. Caffeine inhibits rejoining of strand-breaks of DNA in UV-irradiated NC-4, but the rejoining in γs-13 is insensitive to caffeine.