PHOTOMIMETIC EFFECT OF SEROTONIN ON YEAST CELLS IRRADIATED BY FAR-UV RADIATION

Abstract— The effect of serotonin on the survival of far-UV irradiated cells of the yeast Candida guillier-mondii was studied. Serotonin was found to have a photomimetic property. Preincubation of cells with serotonin results in protection against far-UV inactivation, whereas the post-radiation treatment with serotonin causes a potentiation of far-UV lethality. Both effects are similar to those produced by near-UV (334 nm) radiation. The observations provide support to the idea advanced by us previously that photosynthesized serotonin is the underlying cause of the two effects of near-UV radiation, photo-protection and potentiation of far-UV lethality. Experiments with an excision-deficient strain of the yeast Saccharomyces cerevisiae suggest that the effect of serotonin is by its binding to DNA.     

DAMAGE BY SOLAR RADIATION AT DEFINED WAVELENGTHS. INVOLVEMENT OF INDUCIBLE REPAIR SYSTEMS

Abstract The susceptibility of bacteriophage damaged by solar-ultraviolet (UV, 290-380 nm) radiations at denned wavelengths and by radiation at a visible wavelength (405 nm) to the Weigle reactivation system induced by far-UV (254 nm) irradiation of the host cell has been studied in a repair competent strain of Escherichia coli . The sector of inducible repair diminishes with wavelength, being very small after 313 nm irradiation and absent after irradiation at longer wavelengths. However, irradiation of bacteria at wavelengths as long as 313 nm induces a bacteriophage reactivation system as effectively as radiation at 254 nm in both the repair competent and an excision deficient host cell. At longer wavelengths pre-irradiation of the repair competent host cell enhances reactivation of 254 nm irradiated bacteriophage but the reactivation is smaller and the process quite distinct from that induced in the 254-313 nm region. We conclude that, with increasing wavelength, damage induced by solar UV radiations becomes increasingly less susceptible to repair systems induced by far-UV (pyrimidine dimers) and that this type of inducible repair system is no longer induced by wavelengths longer than 313 nm.     

ULTRAVIOLET ENHANCED REACTIVATION OF HERPES SIMPLEX VIRUS INACTIVATED BY DIFFERENT WAVELENGTHS OF UV RADIATION

The degree of ultraviolet enhanced reactivation (UVR) exhibited by mammalian cells when infected with Herpes simplex virus inactivated by different wavelengths of far ultraviolet (UV) radiation was measured. A wavelength dependence for this effect is presented over the wavelength region 238–297 nm. Within the limits of the deviations obtained, the degree of UVR exhibited is similar at each wavelength. This suggests that virus irradiated with different wavelengths of UV radiation received the same type of damage or that cells repaired the different types of viral damage with the same efficiency.     

RESTRICTION ENZYME CLEAVAGE OF UV-IRRADIATED DNA: A COMPARISON OF FAR-UV AND MID-UV WAVELENGTHS

UV-irradiated DNA is less susceptible to restriction by Type II endonucleases than unirradiated DNA presumably due to photolesions formed in the recognition sites. Previous reported studies have used 254 nm radiation or 313 nm plus acetophenone, both treatments which introduce pyrimidine dimers in preference to other photolesions. To assess the effect of a longer wavelength, at which the ratio of pyrimidine dimer formation to the formation of other photolesions is reduced, two different DNAs were irradiated with UV of either 254 or 313 nm and restricted with suitable restriction endonucleases. Restriction patterns were analysed for novel fragments resulting from UV-induced alteration of enzyme recognition sites. EcoRI restriction of 254 nm irradiated lambda DNA produced six novel bands, only three of which were observed following restriction of 313 nm irradiated lambda. These three represented the largest fragments resulting from single site blocks. Novel fragments involving adjacent site blocks observed at 254 nm were not found with 313 nm radiation. Comparison of 254 nm irradiated pSV₂gpt to that irradiated at 313 nm, both restricted with Dral, revealed a more complex pattern. Although all sites were singly blocked by radiation of both wavelengths, multiple site blocks produced by 313 nm radiation did not occur in the order predicted by the 254 nm radiation dose response. These data suggest that certain sites in pSV₂gpt may be more refractory to multiple site blocks than others when irradiated at 313 nm.     

EVIDENCE AGAINST A PHOTOPROTECTIVE COMPONENT OF PHOTOREACTIVATION IN SACCHAROMYCES CEREVISIAE

Abstract— Photoreactivation-deficient ( phr ⁻) mutants of Saccharomyces cerevisiae were shown to lack in vitro DNA-photolyase activity. A phr ⁻ mutant was then compared with a phr ⁺ strain for near-UV induced photoprotection from far-UV irradiation. Neither strain exhibited a photoprotective effect.     

GENETIC CONTROL OF NEAR-UV (300–400nm) SENSITIVITY INDEPENDENT OF THE recA GENE IN STRAINS OF ESCHERICHIA COLI K12

Abstract— Stationary cells of isogenic pairs of Escherichia coli K12 strains presumably differing only in the recA function have been inactivated with near-UV (300–400 nm) radiation. Based on near-UV inactivation kinetics, the strains can be divided into two discrete categories in which near-UV sensitivity does not necessarily correlate with far-UV sensitivity conferred by two different recA alleles. Lack of overlap between near-UV and far-UV ( recA ) sensitivity can be explained hy assuming that a different chromosomal gene ( nur ) controls near-UV sensitivity. Support for this hypothesis comes from a mating experiment in which four selected recombinants, isogenic with respect to auxotrophic markers, were identified exhibiting all four possible combinations of far-UV ( recA 1 vs recA ⁺ ) and near-UV sensitivity ( nur vs nur⁺ ). Transduction with phase P1 has shown that introduction of the recA 1 allele into a recA⁺ recipient does not affect the near-UV sensitivity of the recipient. Additional matings together with transduction experiments suggest that the nur gene is located at a position on the E. coli linkage map clearly separable from recA (minute 58).     

INDUCTION OF DNA-PROTEIN CROSSLINKS IN HUMAN CELLS BY ULTRAVIOLET and VISIBLE RADIATIONS: ACTION SPECTRUM

Abstract— DNA-protein crosslinking was induced in cultured human P3 teratocarcinoma cells by irradiation with monochromatic radiation with wavelengths in the range254–434 nm (far-UV, near-UV, and blue light). Wavelength 545 nm green light did not induce these crosslinks, using the method of alkaline elution of the DNA from membrane filters. The action spectrum for the formation of DNA-protein crosslinks revealed two maxima, one in the far-UV spectrum that closely coincided with the relative spectrum of DNA at 254 and 290 nm, and one in the visible light spectrum at 405 nm, which has no counterpart in the DNA spectrum. The primary events for the formation of DNA-protein crosslinks by such long-wavelength radiation probably involve photosensitizers. This dual mechanism for DNA-protein crosslink formation is in strong contrast to the single mechanism for pyrimidine dimer formation in DNA, which apparently has no component in the visible light spectrum.     

Effect of UV irradiation at defined wavelengths on the tertiary structure of double-stranded covalently closed circular DNA

Double-stranded, covalently closed, supercoiled circular DNA from phage fd (replicative form) was irradiated with increasing doses of UV light at 254 nm, 290 nm, 313 nm and 365 nm, and subjected to electrophoresis on agarose slab gels. Increasing the doses of UV light at 254 and 290 nm promotes a smooth reduction in the electrophoretic mobility of the sample, as would be expected if the major effect of light at these two wavelengths were to induce the formation of photoproducts leading to the unwinding of the double strand. At high doses, UV light at 290 nm introduces single-strand breaks (1.2 kJ m-2 per nick per million phosphodiester bonds). UV light at 313 nm promotes an abrupt change in the electrophoretic mobility, as would be expected if the effect of this wavelength were to induce single-strand breaks, leading to the transformation of the supercoiled molecules in their relaxed form (23 kJ m-2 in order to introduce one nick per million phosphodiester bonds). UV light at 365 nm also promotes single-strand breaks in DNA (140 kJ m-2 per nick per million phosphodiester bonds).     

PHOTOREACTIVATION OF ICR 2A FROG CELLS AFTER EXPOSURE TO MONOCHROMATIC ULTRAVIOLET RADIATION IN THE 252–313 nm RANGE

Abstract— Exposure of ICR 2A frog cells to photoreactivating light after treatment with monochromatic ultraviolet (UV) radiation in the 252–313 nm range resulted in an increase in survival with similar photoreactivable sectors for each of the wavelengths tested. As photoreactivating enzyme is specific for the repair of pyrimidine dimers in DNA, these findings support the hypothesis that these are critical lesions responsible for killing of cells exposed to UV radiation in this wavelength range. The action spectra for cell killing and production of UV-endonuclease sensitive sites were similar to the DNA absorption spectrum though not identical. Because the number of endonuclease sensitive sites is a reflection of the yield of pyrimidine dimers, these data also suggest that the induction of dimers in DNA by UV radiation in the 252–313 nm range is the principal event leading to cell death.     

Alteration of uracil-DNA glycosylase activity by uracil dimers in DNA

Abstract The formation of colonies in solid medium was used as a criterion of viability to determine the effect of ultraviolet radiation on Trichomonas vaginalis. Both viability (colony) counts and total cell (hemocytometer) counts were used to estimate physiological ages of cell populations to be irradiated. Washed-cell suspensions in 0.6% saline were exposed to far- (254 nm) and near-UV (300–400 nm) radiation and dose-response survival curves were constructed from colony counts. The effect of far-UV was found to be independent of growth phase with the D₀ for exponential, early stationary, and late stationary cells 2.6, 2.7, and 2.7 J/m², respectively. Survival to near-UV increased with the age of cells with the estimated D₅₀ being 216 J/m² for exponential cells, 1360 J/m² for early stationary cells, and 4200 J/m² for late stationary cells. Exponential cells of Trichomonas gallinae irradiated with near-UV had a D₅₀ of 340 J/m². T. vaginalis is highly sensitive to far-UV relative to protozoa. T. vaginalis and T. gallinae are highly sensitive to near-UV relative to other microorganisms.     

EFFECT OF COLD STORAGE ON INACTIVATION OF ESCHERICHIA COLI BY 313 nm IRRADIATION

Abstract. Data are presented showing that the inactivation response of exponential phase Escherichia coli to 313 nm irradiation is affected by previous storage of cells at 3°C in M9 buffer. A similar effect of cold storage on the far-UV inactivation response was not observed. Cold storage alone causes exponential loss in cell viability. After 0.95 days, cell viability is only about 15% of that observed immediately after exposure of cells to cold incubation. However, irradiation at 313 nm causes reactivation of these cold-inactivated bacteria.     

The action spectrum (313-435 nm) for killing Hoechst 33258 treated Chinese hamster ovary cells containing bromodeoxyuridine substituted DNA

Abstract— The action spectrum (313–435 nm) for killing Chinese hamster ovary cells containing bromo-deoxyuridine substituted DNA and treated with Hoechst 33258 was very similar to the absorption spectrum of the dye bound to chromatin, indicating that sensitization was mediated through direct absorption of radiation by the dye. The ratio of sensitization cross sections for 365 nm (plus dye) to 313 nm (no dye) was approx. 30 while this ratio for strand breakage was about one. These results are in agreement with the hypothesis that strand breaks are not the major class of lethal photoproducts induced via Hoechst 33258 sensitization.     

EFFECT OF BASE SEQUENCE ON THE ULTRAVIOLET IRRADIATION PRODUCTS OF DOUBLE-STRANDED POLYNUCLEOTIDES CONTAINING BROMOURACIL AND ADENINE

Abstract —The effects of ultraviolet irradiation of double-stranded synthetic polynucleotides containing BrU and A have been investigated. Homopolymer pairs and alternating copolymers composed of either ribo- or deoxyribo-nucleotides were prepared and were irradiated with either 313 nm or ˜ 285 nm light. Strand separation and a modest amount of strand breakage followed irradiation of the homopolymer pairs. Changes in the ultraviolet absorption spectra of the polymers during irradiation reflected the sum of hyperchromic increases caused by progressive strand separation and loss of absorbance caused by photoproduct formation. Extensive debromination occurred. An RNase digest of irradiated poly(rA)–poly¹⁴C(rBrU), analysed by column chromatography, showed components similar to those found previously upon irradiation of single-stranded poly(rBrU). Little photoproduct was released by RNase digestion as mononucleotides. The major photoproduct was in the dinucleotide fraction, and may be 5,5'-diuracil. Base sequence had a profound effect on the sensitivity of the polynucleotides. Irradiation of alternating copolymers with doses of light comparable to those that produced major photochemical changes in the homopolymer pairs brought about little if any change in the copolymers of alternating base sequence.     

ULTRAVIOLET ACTION SPECTRA FOR PHOTOBIOLOGICAL EFFECTS IN CULTURED HUMAN LENS EPITHELIAL CELLS

Abstract— The action spectrum for cell killing by UV radiation in human lens epithelial (HLE) cells is not known. Here we report the action spectrum in the 297–365 nm region in cultured HLE cells with an extended lifespan (HLE B-3 cells) and define their usefulness as a model system for photobiological studies. Cells were irradiated with monochromatic radiation at 297, 302, 313, 325, 334 and 365 nm. Cell survival was determined using a clonogenic assay. Analysis of survival curves showed that radiation at 297 nm was six times more effective in cell killing than 302 nm radiation; 297 nm radiation was more than 260, 590, 1400 and 3000 times as effective in cell killing as 313, 325, 334 and 365 nm radiation, respectively. The action spectrum was similar in shape to that for other human epithelial cell lines and rabbit lens epithelial cells. The effect of UV radiation on crystallin synthesis was also determined at different wavelengths. To determine whether exposure to UV radiation affects the synthesis of β-crystallin, cells were exposed to sublethal fluences of UV radiation at 302 and 313 nm, labeled with [³⁵S]methionine and the newly synthesized βY-crystallin was analyzed by immunoprecipitation and western blotting using an antibody to β-crystallin. The results show a decrease in crystallin synthesis in HLE cells irradiated at 302 and 313 nm at fluences causing low cytotoxicity. The effect of radiation on membrane perturbation was determined by measuring enhancement of synthesis of prostaglandin E₂ (PGE₂). Synthesis of PGE₂ occurs at all UV wavelengths tested in the 297–365 nm region. The slope of the PGE₂ response curves was higher than that of cell killing curves in cultured HLE cells. These data show that cultured HLE cells with extended lifespan are a suitable system for investigating photobiological responses of cells to UV radiation.     

ACTION SPECTRA IN ULTRAVIOLET WAVELENGTHS (150-250 nm) FOR INACTIVATION AND MUTAGENESIS OF Bacillus subtilis SPORES OBTAINED WITH SYNCHROTRON RADIATION

Bacillus subtilis spores were exposed in vacuo to monochromatic UV radiation from synchrotron radiation in the wavelength range of 150 nm to 250 nm. Survival and frequency of mutation to histidine-independent reversion were analysed for three types of spores differing in DNA-repair capabilities. UVR spores (wild-type DNA repair capability) exhibited nearly equal sensitivity to the lethal effects of far-UV (220 nm and 250 nm) and of vacuum-UV radiation (150 and 165 nm), but showed marked resistance to 190 nm radiation. UVS spores (excision-repair and spore-repair deficient) and UVP spores (a DNA polymerase I-defective derivative of UVS) exhibited similar action spectra; pronounced sensitivity at 250 and 220 nm, insensitivity at 190 nm and a gradual increase of the sensitivity as the wavelength decreased to 165 nm. In all strains, the action spectra for mutation induction paralleled those for the inactivation, indicating that vacuum-UV radiation induced lethal and mutagenic damages in the spore DNA. The insensitivity of the spores to wavelengths around 190 nm may be explicable by assuming that radiation is absorbed by materials surrounding the core in which DNA is situated.     

PHOTOLYSIS OF POLYRIBOBROMOURIDYLIC ACID

Abstract— Photolysis of polyribobromouridylic acid with 313 nm light at neutral pH caused extensive debromination and a loss of A₂₈₀ (280–nm absorbance) without comparable increase in A₂₆₀. At an exposure of 190μE/cm ² , strand breakage occurred on the average of one break every 170 BrU residues. Little if any pyrimidine hydrate was produced. Exhaustive RNase hydrolysis of photolysed polymer gave a mixture of mononucleotides and oligonucleotides. The mononucleotide fraction was found to be composed of unaltered BrUMP and contained little if any UMP. Irradiation of the polymer at alkaline pH caused little or no debromination or spectral change.     

INTERACTION BETWEEN TYROSINE AND DIVALENT SULFUR IN FLUORESCENCE QUENCHING AND IN THE PHOTOCHEMISTRY OF RIBONUCLEASE

Abstract— –Ribonuclease is inactivated in aqueous solution by u.v. light through different mechanisms according to whether divalent sulfur or aromatic amino acids are the primary light absorbers. At 284 nm, absorbed mainly by tyrosine, the presence of O₂ inhibits photoinactivation and H₂S formation, but does less so at 254 or 313 nm. Based on data with model substances containing disulfide groups a mechanism is indicated in which excited tyrosine is quenched through electron transfer to adjacent divalent sulfur within the protein. Disulfide compounds are shown to be very efficient quenchers of tyrosine fluorescence.     

LEAKAGE OF 86Rb+ AFTER ULTRAVIOLET IRRADIATION OF Escherichia coli K-12

Abstract— Stationary phase cultures of a DNA repair proficient Escherichia coli K-12 strain showed a release of intracellular material as assessed by three different methods (260 nm absorption; [methyl-³H]thymidine leakage and ⁸⁶Rb⁺ leakage) after broad-band (Black-Light Blue) near-UV radiation but not after far-UV (254 nm) radiation. As a control response for membrane damage to cells, this leakage of intracellular material was also determined by each method after mild-heat (52°C) treatment of E. coli K-12. An action spectrum for the release of ⁸⁶Rb⁺ from E. coli K-12 after irradiation with monochromatic wavelengths, from 254 to 405 nm, is also presented. The action spectrum for lethality (F₃₇ values) obtained for this strain, shows that leakage of ⁸⁶Rb⁺ occurs at fluences equivalent to or slightly less than fluences causing inactivation at wavelengths above 305 nm. In contrast, at wavelengths below 305 nm, leakage of ⁸⁶Rb⁺ from irradiated cells can be induced but only at fluences significantly greater than was required to cause cell inactivation. These results indicate, therefore, that near-UV radiation can induce a damaging effect on the cell's permeability barrier which may be significant in causing the death of the cell, whereas the effect is not significant in causing the death of cells by far-UV radiation where DNA damage is known to be the main cause of lethality.     

POSSIBLE INVOLVEMENT OF MEMBRANE DAMAGE IN THE IN ACTIVATION BY BROAD-BAND NEAR-UV RADIATION IN Saccharomyces cerevisiae CELLS

Multiple cellular effects of near-UV radiation (300-380 nm) on inactivation, disruption of the permeability barrier and induction of gene conversion at the trp 5 locus were simultaneously measured in the same culture of a diploid strain of the yeast Saccharomyces cerevisiae in order to assess the critical lethal damage. Inactivation of exponential phase cells in water appeared to be closely related to the disruption of the permeability barrier. Inactivation and membrane damage were remarkably oxygen dependent, whereas the induction of genetic changes was very low and dependent much less on oxygen. The dependence on the temperature for inactivation and membrane damage was both low, conforming with the expectation that the processes are mainly photochemical and not enzymatic. These features are very contrasted with the characteristics of far-UV radiation effects. Possible involvement of membrane damage in near-UV inactivation of exponential phase yeast cells is discussed.     

SPECTRAL DEPENDENCE OF UV-INDUCED IMMEDIATE AND DELAYED APOPTOSIS: THE ROLE OF MEMBRANE AND DNA DAMAGE

Abstract— The phototoxicity of each waveband region of UV radiation (UVR), i.e., UVA (32CM100 nm), UVB (290–320 nm) and UVC (200–290 nm), was correlated with an apoptotic mechanism using equilethal doses (10% survival) on murine lymphoma L5178Y-R cells. Apoptosis was qualitatively monitored for DNA "ladder" formation (multiples of 200 base pair units) using agarose gel electrophoresis, while the percentages of apoptotic and membrane-permeabilized cells were quantified over a postexposure time course using flow cytometry. The UVA1 radiation (340–400 nm) induced both an immediate (<4 h) and a delayed (>20 h) apoptotic mechanism, while UVB or UVC radiation induced only the delayed mechanism. The role of membrane damage was examined using a lipophilic free-radical scavenger, vitamin E. Immediate apoptosis and membrane permeability increased in a UVA1 dose-dependent manner, both of which were reduced by vitamin E. However, vitamin E had little effect on UVR-induced delayed apoptosis. In contrast, the DNA damaging agents 2,4- and 2,6-diaminotoluene exclusively induced delayed apoptosis. Thus, immediate apoptosis can be initiated by UVA 1-induced membrane damage, while delayed apoptosis can be initiated by DNA damage. Moreover, the results suggest that immediate and delayed apoptosis are two independent mechanisms that exist beyond the realm of photobiology.