DNA-protein crosslinking in normal and solar UV-sensitive ICR 2A frog cell lines exposed to solar UV-radiation

DNA-protein crosslinks (DPC) were measured following exposure to the solar UV wavelengths produced by a fluorescent sunlamp in ICR 2A frog cells and two solar UV-sensitive mutants derived from this cell line. Approx. 5-7 DPC per 10(10) dalton were induced in these cells by either 150 kJ/m2 of sunlamp UV greater than 315 nm plus photoreactivating light (PRL) or 10 kJ/m2 of sunlamp UV greater than 295 nm. The irradiated cells were then incubated for 0-24 h and the level of DPC measured using alkaline elution. It was found for the ICR 2A cells exposed to sunlamp UV greater than 315 nm that the level of DPC increased about 3-fold during a 2-h postirradiation incubation and then decreased. The mutant cell lines also showed an enhancement in the level of DPC following irradiation, although it was much less pronounced and the levels decreased much more rapidly. In a similar fashion, the level of DPC increased in ICR 2A cells exposed to sunlamp UV greater than 295 nm with more than a 5-fold enhancement after a 4-h incubation. Once again, the mutant cell lines showed an increase in the level of DPC that was smaller and more transient than the effect in the ICR 2A cells. These results suggests that this enhancement in DPC may be indicative of a process that plays a role in cellular survival following solar UV-irradiation.     

Quantitation of ultraviolet radiation-induced cyclobutyl pyrimidine dimers in DNA by video and photographic densitometry

We have compared video and photographic methods for calculating the number of ultraviolet radiation (uv)-induced pyrimidine dimers in DNA from the bacteriophage T7 exposed to uv (0 to 800 J/m2) from an FS40 sunlamp. DNA was incubated with a pyrimidine dimer-specific Micrococcus luteus uv endonuclease, subjected to alkaline agarose gel electrophoresis, neutralized, and stained with ethidium bromide, and the DNA fluorescence was recorded either with a video camera or on photographic film. The slopes of the dose-response curves for the number of uv-endonuclease-sensitive sites per 10(3) bases (pyrimidine dimers) was 1.2 (+/- 0.1) X 10(-4) uv-endonuclease-sensitive sites per J/m2 for the video analysis and 1.3 (+/- 0.04) X 10(-4) uv-endonuclease-sensitive sites per J/m2 for the photographic analysis. Results for pyrimidine dimer determination by either method were statistically comparable.     

Photorepair of ultraviolet radiation-induced pyrimidine dimers in corneal DNA

The induction and photorepair of pyrimidine dimers in DNA have been measured in the ultraviolet-irradiated, corneal epithelium of the marsupial, Monodelphis domestica, using damage-specific nucleases from Micrococcus luteus in conjunction with agarose gel electrophoresis. We observed that FS-40 sunlamps (280-400 nm) induced 7.2 +/- 1.0 X 10(-5) pyrimidine dimers per kilobase (kb) of DNA per J/m2. Following 100 J/m2, 50% and greater than 90% of the dimers were photorepaired during a 10- and 30-min exposure to photoreactivating light (320-400 nm), respectively. In addition, approximately 70% and approximately 60% of the dimers induced by 300 and 500 J/m2, respectively, were repaired by a 60-min exposure to photoreactivating light. The capacity of the corneal epithelium of M. domestica to photorepair pyrimidine dimers identifies this animal as a potentially useful model with which to determine whether pyrimidine dimers are involved in pathological changes of the irradiated eye.     

The contribution of the nuclear reaction 1H(n, gamma)2D to the yield of DNA single strand breaks in cultured mammalian cells irradiated by thermal neutrons

The yield of single strand breaks (ssb) in DNA of the HeLa S-3 cells after thermal neutron irradiation was examined using the alkaline sucrose gradient method. The contribution of the 1H(n, gamma)2D reaction to the yield of ssb was determined by substituting D2O for H2O in the irradiated medium. Calculation shows that when cells are irradiated in the H2O medium, the per cent contribution of the contaminating gamma-rays, the nuclear reaction 1H(n, gamma)2D and the other nuclear reactions is 31, 44 and 25 per cent respectively assuming additivity of effects. The estimated number of ssb induced by the nuclear reaction 1H(n, gamma)2D was at least 4.4 times greater than that by 60Co gamma-rays at the same absorbed dose. Two possible interpretations are discussed to explain the high efficiency of the 1H(n, gamma)2D reaction for ssb induction.     

Glutathione requirement for the rejoining of radiation-induced DNA breaks in misonidazole-treated cells

The role of glutathione (GSH) in the rejoining of radiation-induced single-strand DNA breaks (ssb) was studied in human fibroblast cultures sensitized to radiation by a 30 min treatment with 1 mM misonidazole (MISO). Hypoxically irradiated cells, deficient in GSH, either inherently, or due to a 16 h incubation with 1 mM buthionine sulphoximine (BSO), rejoined the breaks after MISO treatment at a lower rate and to a lesser extent than did GSH-proficient cells. Without MISO treatment, the hypoxically induced ssb were rejoined in the GSH-deficient cells as effectively as in the proficient cells. It is concluded that a large proportion of the breaks which arise after hypoxic irradiation in the presence of MISO are of a different type to those which arise in the absence of the drug, and require a particular GSH-dependent, enzymatic repair system. This requirement for rejoining in hypoxically irradiated, MISO-treated cells is similar to that seen earlier in MISO-untreated, oxically irradiated cells, and suggests that the ssb induced by radiation in the presence of MISO or oxygen are of a similar nature.     

Chromatin decondensed by acetylation shows an elevated radiation response

V-79 Chinese hamster lung fibroblasts exposed to 5 mM n-sodium butyrate were irradiated with 60Co gamma rays and cell survival was determined by the cell colony assay. In a separate set of experiments the acetylated chromatin obtained from these cells was irradiated and the change of molecular weight of the DNA was evaluated by alkaline sucrose density centrifugation. At a survival level of 10(-2) to 10(-4) cells exposed to butyrate were found to be 1.3-1.4 times more radiosensitive than control cells. Exposure of isolated chromatin to 100 Gy of 60Co gamma irradiation generated 0.9 +/- 0.03 single-strand breaks (ssb) per 10 Gy per 10(8) Da and 2.0 +/- 0.3 ssb/10 Gy/10(8) Da for control and acetylated chromatin, respectively. The elevated radiation sensitivity of chromatin relaxed by acetylation is in good agreement with previous results on chromatin expanded by histone H1 depletion [Heussen et al., Radiat. Res. 110, 84-94 (1987)]. Packing and accessibility of DNA in chromatin appear to be major factors which influence the radiation sensitivity. The intrinsic radiation sensitivity of chromatin in various packing states is discussed in light of the variation of radiation sensitivity of whole cells in the cell cycle which incorporates repair.     

Inhibition of semiconservative DNA synthesis in ICR 2A frog cells by pyrimidine dimers and nondimer photoproducts induced by ultraviolet radiation

DNA synthesis was examined in ultraviolet (uv)-irradiated ICR 2A frog cells in which either pyrimidine dimers or nondimer photoproducts represented the major class of DNA lesions. Dimers were induced by exposure of cells to 254 nm uv, while nondimer photoproducts were induced by irradiation of cells with uv produced by a fluorescent sunlamp (FSL) that was filtered through 48A Mylar (removes wavelengths less than 310 nm). The FSL-irradiated cultures were also treated with photoreactivating light (PRL) which removed most of the small number of dimers induced by the irradiation, leaving a relatively pure population of nondimer photoproducts. In addition, cells were exposed to 60Co gamma rays. The cultures were pulse-labeled and the size distribution of the DNA synthesized was estimated using both sucrose gradient sedimentation and alkaline step elution. Using either of these techniques, it was found that the presence of dimers resulted in a reduction principally in the synthesis of high molecular weight (MW) DNA. In contrast, nondimer photoproducts caused a strong inhibition in the synthesis of low MW DNA, as was also observed in gamma-irradiated cells. Hence the induction of pyrimidine dimers in DNA mainly affected the elongation of replicons, whereas nondimer lesions primarily caused an inhibition of replicon initiation.     

Toxicity and mutagenicity of radiation from fluorescent lamps and a sunlamp in L5178y mouse lymphoma cells

Unfiltered broad spectrum radiation emitted by black light, cool white, and black light blue fluorescent lamps and a sunlamp, is both toxic and mutagenic to L5178Y mouse lymphoma cells when the cells are irradiated in phosphate-buffered saline. The increase in mutant frequency seen after exposure of the cells is linear throughout the range of exposures tested. The linear increase in mutagenesis is observed even at exposure levels which do not cause significant toxicity. To facilitate comparison of the differing rates of mutagenesis derived from exposure-response curves obtained for each light source, we have defined a parameter, joule-equivalent mutagenesis (jem), equal to mutants per 10(5) survivors per joule per square meter. Jem values are calculated using the integrated irradiance of each lamp. Based on jem values, the relative mutagenicity of the various lamps tested (compared with a germicidal ultraviolet lamp) is 3 x 10(-3) for the sunlamp, 1 x 10(-4) for the black light and cool white lamps, and 3 x 10(-5) for the black light blue lamp. The toxic and mutagenic effects of the lamps are in reasonable agreement with their relative spectral output from 290 to 330 nm.     

Influence of mid-ultraviolet (UVB) radiation on the physiology of the marine planktonic copepod Acartia omorii and the potential role of photoreactivation

The damaging effect of mid-ultraviolet (UVB, 280-320 nm) radiationon the marine planktonic copepod Acartia omorii was investigatedby using egg-hatching success, survival of various naupliarand copepodite stages, and feeding and egg production of adultfemales, as physiological parameters under different radiationconditions in the laboratory. No deleterious effect was inducedby UVA (320-400 nm) or PAR (400-700 nm), but UVB inflicted amore damaging effect with increasing UVB dose, Among variouslife stages, eggs, particularly freshly-spawned ones (< 2hold), were most susceptible₅₀= 2.76 kJ m^–2) and adultfemales least susceptible (LD₅₀= 22.0 kJ m^–2). The feedingand egg production of adult females were not significantly reduceduntil the UVB dose was elevated to 15.0 kJ m^–2. The UVB-induceddamage was alleviated under simultaneous irradiation with enhancedPAR. This photorepair mechanism was more effective for eggscompared with older stages. Our outdoor experiment using solarUVB demonstrated that present-day levels of solar UVB radiationcaused reduced hatching success of A. omorii eggs. In the habitatof A. omorii, however, due to high attenuation properties ofthe water, the solar UVB radiation may affect only young developmentalstages distributed near the sea surface.     

Analysis of the excision repair of nondimer DNA damage induced by solar ultraviolet radiation in ICR 2A frog cells

The excision repair of solar uv-induced nondimer DNA damage was examined in ICR 2A frog cells through the use of the bromodeoxyuridine (BrdUrd) photolysis assay. A relatively pure population of nondimer DNA photoproducts was induced by irradiation of ICR 2A cells with the Mylar-filtered solar ultraviolet (uv) wavelengths produced by a fluorescent sunlamp followed by exposure to photoreactivating light (PRL) which removes most of the small yield of pyrimidine dimers induced by this treatment. Cultures of cells were also exposed to 254 nm uv, which induces primarily dimers, and 60Co gamma rays. Through use of a modification of the BrdUrd photolysis assay possessing enhanced sensitivity, it was found that the solar uv-induced nondimer DNA damage was repaired by a short patch repair mechanism in which less than approximately 20 nucleotides are inserted into a repaired region. Similar results were also obtained for gamma-irradiated cells. In contrast, excision repair of 254-nm-induced dimers was accomplished by a long-patch process in which an average of about 180 nucleotides are inserted into the repaired sites.     

Laser effects on cellular adhesion and influence on the interrelation between HeLa S3 and human diploid cells

The interactions between HeLa S3 tumoral cells and human fibroblasts after nitrogen-laser irradiation (337.1 nm) have been studied by using an in vitro cell invasion model. For the quantitative and morphological evaluation of nitrogen-laser radiation action upon tumoral adhesion to the fibroblast monostrate, we used: a) 3H-thymidine labelling of HeLa S3 tumoral cells; b) morphological modifications studies by phase contrast and scanning electron microscopy. The results emphasized the following aspects: 1. In non-irradiated cell cultures we noticed three interaction stages: adhesion, tumoral spreading and displacement with fibroblasts destruction; on the other side, we found a reduced adhesion to non-irradiated human fibroblasts of laser irradiated tumoral cells. 2. Significant percent increasing of non-irradiated tumoral cells adhesion to fibroblast monostrate, irradiated with various laser fluences (e.g. 0.2 kJ/m2--48.1%; 0.8 kJ/m2--63.8% and for 1.6 kJ/m2--79.5%). This phenomenon evidenced the close interrelation between irradiation fluences and tumoral adhesion rates. 3. The importance of numerical ratio between tumoral cells and fibroblasts in tumoral adhesion and invasion processes (e.g. ratio 1:10 tumoral adhesion reached 8.1%; in 1:5--25.9%; in 1:1--59.4% and for 2:1--83.9%). 4. Marked cytotoxic effects for both cell types after exposure to high and very high laser fluences (1.6--6.4 kJ/m2). Our results emphasize near UV-laser irradiation effects upon some of tumoral adhesion and invasion mechanisms and demonstrate the interrelations between cell populations manifesting a different vital potential.     

Migration of Langerhans cells and gammadelta dendritic cells from UV-B-irradiated sheep skin

Depletion of dendritic cells from UV-B-irradiated sheep skin was investigated by monitoring migration of these cells towards regional lymph nodes. By creating and cannulating pseudoafferent lymphatic vessels draining a defined region of skin, migrating cells were collected and enumerated throughout the response to UV-B irradiation. In the present study, the effects of exposing sheep flank skin to UV-B radiation clearly demonstrated a dose-dependent increase in the migration of Langerhans cells (LC) from the UV-B-exposed area to the draining lymph node. The range of UV-B doses assessed in this study included 2.7 kJ/m2, a suberythemal dose; 8 kJ/m2, 1 minimal erythemal dose (MED); 20.1 kJ/m2; 40.2 kJ/m2; and 80.4 kJ/m2, 10 MED. The LC were the cells most sensitive to UV-B treatment, with exposure to 8 kJ/m2 or greater reproducibly causing a significant increase in migration. Migration of gammadelta+ dendritic cells (gammadelta+ DC) from irradiated skin was also triggered by exposure to UV-B radiation, but dose dependency was not evident within the range of UV-B doses examined. This, in conjunction with the lack of any consistent correlation between either the timing or magnitude of migration peaks of these two cell types, suggests that different mechanisms govern the egress of LC and gammadelta+ DC from the skin. It is concluded that the depression of normal immune function in the skin after exposure to erythemal doses of UV-B radiation is associated with changes in the migration patterns of epidermal dendritic cells to local lymph nodes.     

Annual patterns of ultraviolet radiation effects on temperate marine phytoplankton off Patagonia, Argentina

We carried out experiments to evaluate the effects of solarultraviolet radiation (UVR; 280–400 nm) upon primary productionof different natural phytoplankton assemblages (i.e. characteristicof a seasonal cycle) from Patagonia (Argentina) from January2001 to January 2002. The short-term impact of UVR (i.e. measuredas radiocarbon incorporation) was assessed by exposing samplesto solar radiation under six radiation treatments: uncoveredquartz tubes and tubes covered with different cut-off Schottfilters (WG295, WG305, WG320, WG360), and Plexiglas UF-3 (cut-offat 400 nm), so that samples received radiation at five differentintervals within the UVR in addition to photosynthetically activeradiation (PAR), and only PAR, respectively. Phytoplankton compositionand abundance allowed us to differentiate pre-bloom, bloom andpost-bloom periods, with pre- and post-bloom samples characterizedby small cells (e.g. flagellates <10 µm), whereas thebloom was dominated by large diatoms (50 µm). Absolutevalues of photosynthesis inhibition were lower during the bloom,but biological weighting functions (i.e. inhibition per unitenergy) indicated that this assemblage was more sensitive toUVR (especially in the UV-B region, 280–320 nm) than thoseof the pre- and post-bloom periods. UV-A radiation (320–400nm) accounted for most of the reduction in carbon incorporation(>60%), especially during the pre- and post-bloom periods.Most of the observed variability was inter-seasonal, althoughsmall intra-seasonal fluctuations were also observed. Our resultsindicate that the taxonomic composition and cellular size areespecially important when addressing UVR effects upon theseassemblages. However, other factors such as mixing can alsocontribute to the variability in responses to UVR.     

Immunoprecipitation of pyrimidine(6-4)pyrimidone photoproducts and cyclobutane pyrimidine dimers in uv-irradiated DNA

Biological studies suggest that a significant proportion of the cytotoxicity observed in mammalian cells after uv irradiation may be due to damage other than cyclobutane dimers in DNA. Although pyrimidine-pyrimidone (6-4) photoproducts have been implicated as major contributors to cell lethality, their induction has been measured at considerably less than cyclobutane pyrimidine dimers when measured by chromatographic techniques. Because the yield of (6-4) photoproducts may be reduced by their lability to extreme heat and pH, we have advised an alternative, immunological quantification which does not require DNA hydrolysis. Affinity-purified rabbit antisera were used to precipitate low molecular weight 32P-labeled PM2 DNA irradiated with increasing fluences of uv light. DNA of known molecular weight was used to determine rates of induction for antibody-binding sites associated with (6-4) photoproducts and cyclobutane dimers. These rates were calculated to be 0.6 (6-4) photoproducts and 1.2 cyclobutane dimers/10(8) Da/J/m2. At low uv fluences (6-4) photoproducts were induced at one-half the rate of cyclobutane dimers, whereas at higher fluences (6-4) photoproducts predominated.     

UV-induced photoproducts of 5-methylcytosine in a DNA sequence context.

In order to detect possible m5C photoproducts, highly purified rat liver DNA-cytosine methyltransferase was used to specifically generate m5C with a radioactive methyl group. When these DNAs were subjected to a large dose (10 kJ/m2) of 254 nm or 302 nm ultraviolet light (UVB) to enhance the yield, two labeled photoproducts were detected and isolated by reverse phase HPLC after formic acid hydrolysis. Further studies using acetone as a triplet state sensitizer and UVB irradiation suggested that photoproduct II was activated via a triplet state while the more polar photoproduct I was not. Photoreversion of the purified photoproducts with 10 kJ/m2 254 nm light demonstrated the following reactions: Photoproduct I regenerated m5C, while photoproduct II is split and regenerated m5C and photoproduct I. These results suggest that photoproduct I is monomeric while photoproduct II dimeric, and from the latter's elution position possibly a cyclobutyl type dimer arising from a reaction with an adjacent cytosine. Using d[TTG] and d[Cm5CG] as models of typical sequences, irradiation with 10 kJ/m2 254 nm or 302 nm, respectively, gave rise to a small component having altered mobility in sequencing gels. The altered mobility trinucleotides were resistant to degradation by PI and micrococcal nucleases as expected from photodimerization of the pyrimidine bases. Furthermore, oligonucleotide substrates containing m5C were synthesized and shown to be susceptible to T4 endonuclease v action at locations consistent with d[Cm5C] photodimer formation when irradiated in the UVB range.     

Photoreactivation of pyrimidine dimers in the DNA of normal and xeroderma pigmentosum cells.

Photoproducts formed in the DNA of human cells irradiated with ultraviolet light (uv) were identified as cyclobuytl pyrimidine dimers by their chromatographic mobility, reversibility to monomers upon short wavelength uv irradiation, and comparison of the kinetics of this monomerization with that of authentic cis-syn thymine-thymine dimers prepared by irradiation of thymine in ice. The level of cellular photoreactivation of these dimers reflects the level of photoreactivating enzyme measured in cell extracts. Action spectra for cellular dimer photoreactivation in the xeroderma pigmentosum line XP12BE agree in range (300 nm to at least 577 nm) and maximum (near 400 nm) with that for photoreactivation by purified human photoreactivating enzyme. Normal human cells can also photoreactivate dimers in their DNA. The action spectrum for the cellular monomerization of dimers is similar to that for photoreactivation by the photoreactivating enzyme in extracts of normal human fibroblasts.     

Large-scale overproduction and rapid purification of the Escherichia coli ssb gene product. Expression of the ssb gene under lambda PL control

We report a rapid procedure for the large-scale purification of the Escherichia coli encoded single-strand binding (SSB) protein, helix-destabilizing protein which is essential for replication, recombination, and repair processes in E. coli. To facilitate the isolation of large quantities of the ssb gene product, we have subcloned the ssb gene into a temperature-inducible expression vector, pPLc28 [Remaut, E., Stanssens, P., & Fiers, W. (1981) Gene 15, 81-93], carrying the bacteriophage lambda PL promoter. A large overproduction of the ssb gene product results upon shifting the temperature of E. coli strains which carry the plasmid and also produce the thermolabile lambda cI857 repressor. After 5 h of induction, the ssb gene product represents approximately 10% of the total cell protein. The overexpression of the ssb gene and the purification protocol reported here enable one to isolate SSB protein (greater than 99% pure) with final yields of approximately 3 mg of SSB protein/g of cell paste. In fact, very pure (greater than 99%) SSB protein can be obtained after approximately 8 h, starting from frozen cells in the absence of any columns, although inclusion of a single-stranded DNA-cellulose column is generally recommended to ensure that the purified SSB protein possesses DNA binding activity. The ability to easily purify 1 g of SSB protein from 300-350 g of induced cells will facilitate physical studies requiring large quantities of this important protein.     

Nonenzymatic modifications of amino sugars in vitro

Browning reactions of amino sugars were observed in a variety of sterile pH buffers at 25-37 degrees C. These reactions were signaled by an increase in absorbance at 273 nm, followed by an increase in absorbance at 320-360 nm. The reactions were maximal at pH 7.0 in phosphate buffer. Acidic solutions (pH less than 2.2) of 50 mM D-glucosamine hydrochloride gave only a negligible reaction and 2-acetamido-2-deoxy-D-glucose was unreactive. Half of the D-glucosamine in a 100 mM solution in sterile 0.2 M sodium phosphate buffer, pH 7.4, at 37 degrees C decomposed or was transformed in 27 h. A comparison of reactivity in generating A273 and A340 chromophores showed D-mannosamine greater than D-galactosamine greater than D-glucosamine. Permanganate oxidation of incubated glucosamine solutions afforded a compound which chromatographed like 2,5-pyrazinedicarboxylic acid and gave the same ultraviolet absorption spectrum. This, together with fractionating and thin-layer chromatography of the products of glucosamine incubation, suggests that 2,5-bis(tetrahydroxybutyl)pyrazine is formed as one of the products of autocondensation of D-glucosamine in accord with the report of Candiano et al. (1988, Carbohydr. Res. 184, 67-75) on products formed in glucosamine-lysine incubation mixtures. Formation of products absorbing at 325-360 nm was inhibited by the chelator diethylene-triaminepentaacetic acid. This suggests that the later reactions may be mediated by a metal-stimulated free radical mechanism. After 4 days incubation high molecular weight products with absorbance maxima at 273 nm and 325-360 nm were detected. Some of these were retained by dialysis membranes of molecular weight cut-off greater than 3500 and greater than 12,000.     

Sublethal effects of ultraviolet b radiation on miracidia and sporocysts of Schistosoma mansoni: intramolluscan development, infectivity, and photoreactivation

Schistosoma mansoni occurs in tropical regions where levels of ultraviolet B (UVB; 290-320 nm) light are elevated. However, the effects of UVB on parasite transmission are unknown. This study examines effects of UVB on the miracidia and sporocysts of S. mansoni, focusing specifically on intramolluscan development, infectivity, and the ability to photoreactivate (repair DNA damage using visible light). Histology revealed that miracidia irradiated with 861 J x m(-2) underwent abnormal development after penetrating Biomphalaria glabrata snails. Total number of sporocysts in snail tissues decreased as a function of time postinfection (PI), among both nonirradiated and irradiated parasites; however, this decrease was greater in the latter. Moreover, whereas the proportion alive of nonirradiated sporocysts increased PI, that of irradiated sporocysts, i.e., derived from irradiated miracidia, decreased. Irradiation of miracidia with UVB resulted in decreased prevalence of patent infection (defined by presence of daughter sporocysts) in a dose-dependent manner, and no infections occurred at a dose of 861 J x m(-2). Like many aquatic organisms, including the snail host, parasites were able to photoreactivate if exposed to visible light following UVB irradiation, even subsequent to penetrating snails. These photoreactivation results suggest cyclobutane-pyrimidine dimers in DNA as the primary mechanism of UVB damage, and implicate photoreactivation, rather than nucleotide excision, as the main repair process in S. mansoni.