The effects of the ultraviolet wavelengths of radiation present in sunlight on human cells in vitro

Seeing beyond the limit: A guide to choosing the right super-resolution microscopy technique

Super-resolution microscopy has become an increasingly popular and robust tool across the life sciences to study minute cellular structures and processes. However, with the increasing number of available super-resolution techniques has come an increased complexity and burden of choice in planning imaging experiments. Choosing the right super-resolution technique to answer a given biological question is vital for understanding and interpreting biological relevance. This is an often-neglected and complex task that should take into account well-defined criteria (e.g., sample type, structure size, imaging requirements). Trade-offs in different imaging capabilities are inevitable; thus, many researchers still find it challenging to select the most suitable technique that will best answer their biological question. This review aims to provide an overview and clarify the concepts underlying the most commonly available super-resolution techniques as well as guide researchers through all aspects that should be considered before opting for a given technique.

Wavelengths and temporal effects on the response of mammalian cells to UV radiation: Limitations of action spectra illustrated by genotoxicity

All photobiological events depend on the wavelength of the incident radiation. In real-life situations and in the vast majority of laboratory experiments, exposure always involves sources with various emission spectra spreading over a wide wavelength range. Action spectra are often used to describe the efficiency of a process at different wavelengths and to predict the effects of a given light source by summation of the individual effects at each wavelength. However, a full understanding of the biological effects of complex sources requires more than considering these concomitant events at each specific wavelength. Indeed, photons of different energies may not have additive but synergistic or inhibitory effects on photochemical processes and cellular responses. The evolution of a photobiological response with post-irradiation time must also be considered. These two aspects may represent some limitations to the use of action spectra. The present review, focused on mammalian cells, illustrates the concept of action spectrum and discusses its drawbacks using theoretical considerations and examples taken from the literature. Emphasis is placed on genotoxicity for which wavelength effects have been extensively studied. Other effects of UV exposure are also mentioned.

Whole human blood DNA degradation associated with artificial ultraviolet and solar radiations as a function of exposure time

Laboratory investigations were conducted to evaluate the effect of ultraviolet radiation components and solar radiation exposure as a function of time on the degradation of whole human blood DNA from the standpoint of forensic analysis. Ten μL of whole human male blood samples were exposed to UV-A, UV-B, UV-C, and solar radiation at 20 min intervals up to 120 min. Allele frequencies of 16 short tandem repeat (STR) markers were monitored by employing current forensic typing DNA techniques. The STR markers were grouped into high, medium, and low molecular weight categories. Results revealed that even 20 min exposure to 4.89 eV UV-C photons (ʎ = 254 nm) with radiation intensity of 1200 μW/cm² would degrade whole human male blood DNA samples significantly, making them unfit for human identification due to the breakdown of high molecular weight STRs. Exposure of blood samples to 4.11 eV UV-B photons (ʎ = 302 nm) with radiation intensity of 900 μW/cm² resulted in complete degradation of high molecular weight STRs after 60 min. Partial breakdown of medium and low molecular weight STRs started after 80 min exposure. The degradation index (DI) values appear to show that the degradation of the DNA template molecule was relatively less in the low molecular weight DNA fragments as compared with high molecular weight DNA fragments. This finding indicates that genetic profiles obtained from whole human male blood exposed to this radiation for 60 min will give inconclusive results. Samples exposed up to 120 min to 3.40 eV UV-A photons (ʎ = 365 nm) and 3.10-3.94 eV photons of solar radiation did not appear to produce appreciable degradation in any of three molecular weight STRs in the whole human blood DNA samples.

Photobiology/Photochemistry

Exposure of living organisms to non-ionizing electromagnetic radiation (here confined to the visible and part of the ultraviolet, 200-800 nm) can cause a toxic reaction. The details of the exposure, both in intensity and wavelength composition, will determine the degree of effect. If absorbing chromophores, both endogenous and exogenous, are present, additional response can be elicited. Whether the radiation reaches a sensitive target will depend upon the depth of penetration and the opacity of the cell or tissue. The final effect will be determined by the initial photoproducts produced, the subsequent reactions they cause, and the amount of repair of damage by cellular processes. In some cases it is possible to predict the complete response; in others it is variable.

Light-induced cell damage in live-cell super-resolution microscopy

Super-resolution microscopy can unravel previously hidden details of cellular structures but requires high irradiation intensities to use the limited photon budget efficiently. Such high photon densities are likely to induce cellular damage in live-cell experiments. We applied single-molecule localization microscopy conditions and tested the influence of irradiation intensity, illumination-mode, wavelength, light-dose, temperature and fluorescence labeling on the survival probability of different cell lines 20–24 hours after irradiation. In addition, we measured the microtubule growth speed after irradiation. The photo-sensitivity is dramatically increased at lower irradiation wavelength. We observed fixation, plasma membrane permeabilization and cytoskeleton destruction upon irradiation with shorter wavelengths. While cells stand light intensities of ~1 kW cm⁻² at 640 nm for several minutes, the maximum dose at 405 nm is only ~50 J cm⁻², emphasizing red fluorophores for live-cell localization microscopy. We also present strategies to minimize phototoxic factors and maximize the cells ability to cope with higher irradiation intensities.

Protein phosphatase-1 is involved in the maintenance of normal homeostasis and in UVA irradiation-induced pathological alterations in HaCaT cells and in mouse skin

The number of ultraviolet (UV) radiation-induced skin diseases such as melanomas is on the rise. The altered behavior of keratinocytes is often coupled with signaling events in which Ser/Thr specific protein kinases and phosphatases regulate various cellular functions. In the present study the role of protein phosphatase-1 (PP1) was investigated in the response of human keratinocyte (HaCaT) cells and mouse skin to UV radiation. PP1 catalytic subunit (PP1c) isoforms, PP1cα/γ and PP1cδ, are all localized to the cytoskeleton and cytosol of keratinocytes, but PP1cδ was found to be dominant over PP1α/γ in the nucleus. PP1c-silencing in HaCaT cells decreased the phosphatase activity and suppressed the viability of the cells. Exposure to a 10 J/cm(2) UVA dose induced HaCaT cell death and resulted in a 30% decrease of phosphatase activity. PP1c-silencing and UVA irradiation altered the gene expression profile of HaCaT cells and suggested that the expression of 19 genes was regulated by the combined treatments with many of these genes being involved in malignant transformation. Microarray analysis detected altered expression levels of genes coding for melanoma-associated proteins such as keratin 1/10, calcium binding protein S100A8 and histone 1b. Treatment of Balb/c mice with the PP1-specific inhibitor tautomycin (TM) exhibited increased levels of keratin 1/10 and S100A8, and a decreased level of histone 1b proteins following UVA irradiation. Moreover, TM treatment increased pigmentation of the skin which was even more apparent when TM was followed by UVA irradiation. Our data identify PP1 as a regulator of the normal homeostasis of keratinocytes and the UV-response.

Effects of UV wavelength on cell damages caused by UV irradiation in PC12 cells

Ultraviolet (UV) radiations present in sunlight are a major etiologic factor for many skin diseases and induce DNA damage through formation of cyclobutane pyrimidine dimer (CPD). This study was conducted to determine the toxicological effects of different wavelengths (250, 270, 290, and 310 nm) and doses of UV radiation on cell viability, DNA structure, and DNA damage repair mechanisms in a PC12 cell system. For this, we evaluated cell viability and CPD formation. Cell survival rate was markedly decreased 24h after UV irradiation in a dose-dependent manner at all wavelengths (except at 310 nm). Cell viability increased with increasing wavelength in the following order: 250<270<290<310 nm. UV radiation at 250 nm showed the highest cell killing ability, with a median lethal dose (LD50) of 120 mJ/cm(2). The LD50 gradually increased with increase in wavelength. Among the 4 wavelengths tested, the highest LD50 (6000 mJ/cm(2)) was obtained for 310 nm. CPD formation decreased substantially with increasing wavelength. Among the 4 wavelengths, the proportion of CPD formation was highest at 250 nm and lowest at 310 nm. On the basis of LD50 values for each wavelength, PC12 cells irradiated with UV radiation of 290 nm showed maximum DNA repair ability, whereas those irradiated with the 310-nm radiation did not show any repair ability. Toxicity of UV radiation varied with wavelengths and exposure doses.

Immuno-slot blot assay for detection of UVR-mediated DNA damage

Solar ultraviolet radiation (UVR), through the formation of DNA photolesions, is the primary cause of most skin cancers. A better understanding of the mechanisms of UVR-induced DNA damage may help prevent skin cancer and this may be achieved using methods to quantify DNA damage. The immuno-slot blot (ISB) method is routinely used for detection and quantification of any heat- and alkali-stable DNA adducts for which a sufficiently specific monoclonal antibody is available. The main steps in ISB are fragmentation and denaturation of the DNA, immobilization of DNA to a nitrocellulose filter, incubation with primary antibody against a specific DNA adduct, incubation with an enzyme-linked secondary antibody and finally chemiluminescence detection and quantification of the DNA adducts.

Clinical evidence of benefits of a dietary supplement containing probiotic and carotenoids on ultraviolet-induced skin damage

BACKGROUND

Lactobacillus johnsonii (La1) has been reported to protect skin immune system homeostasis following ultraviolet (UV) exposure.

OBJECTIVES

To assess the effects of a dietary supplement (DS) combining La1 and nutritional doses of carotenoids on early UV-induced skin damage.

METHODS

Three clinical trials (CT1, CT2, CT3) were performed using different UV sources: nonextreme UV with a high UVA irradiance (UV-DL, CT1), extreme simulated solar radiation (UV-SSR, CT2) and natural sunlight (CT3). All three clinical trials were carried out in healthy women over 18 years of age with skin type II-IV. In CT1, early markers of UV-induced skin damage were assessed using histology and immunohistochemistry. In CT2, the minimal erythemal dose (MED) was determined by clinical evaluation and by chromametry. Chromametry was also used to evaluate skin colour. Dermatologists' and subjects' assessments were compiled in CT3.

RESULTS

A 10-week DS intake prevented the UV-DL-induced decrease in Langerhans cell density and the increase in factor XIIIa+ type I dermal dendrocytes while it reduced dermal inflammatory cells. Clinical and instrumental MED rose by 20% and 19%, respectively, and skin colour was intensified, as shown by the increase in the ΔE* parameter. The efficacy of DS was confirmed by dermatologists and subjects under real conditions of use.

CONCLUSIONS

Nutritional supplementation combining a specific probiotic (La1) and nutritional doses of carotenoids reduced early UV-induced skin damage caused by simulated or natural sun exposure in a large panel of subjects (n=139). This latter result might suggest that DS intake could have a beneficial influence on the long-term effects of UV exposure and more specifically on skin photoageing.

17β-Estradiol modulates UVB-induced cellular responses in estrogen receptors positive human breast cancer cells

Genotoxic agents produce numerous cellular responses that are principally dedicated to maintain or restore DNA integrity. In human cells, nucleotide excision repair (NER) is one of the major pathways for the repair of DNA damage such as ultraviolet (UV) radiation-induced lesions. Endocrine disrupting compounds are environmental contaminants that interfere with the function of the endocrine system. Among them, the natural estrogen 17beta-estradiol (E(2)) exhibits the most potent activity. Some proteins directly or indirectly involved in NER also fulfill other functions such as transcription, DNA damage checkpoints or cell cycle. Moreover, steroids such as E(2) are believed to interact with a large number of proteins including some involved in NER and DNA damage checkpoint control. We therefore investigated the potential modulation of genotoxic stress-cells responses by E(2) treatment. Estrogen receptor (ER)-positive human breast cancer cells were submitted to E(2) before and/or after UVB irradiation and thereafter the repair kinetics of UV-induced DNA damage were evaluated. We report here that the repair rate of UVB-induced DNA damage is enhanced when cells are submitted to an estrogenic stimulation. Moreover, our results suggest that this response could be mediated by cell cycle regulatory proteins in a p53-independent manner.

Carteolol hydrochloride protects human corneal epithelial cells from UVB-induced damage in vitro

PURPOSE

To investigate whether carteolol hydrochloride has protective effects against ultraviolet B (UVB)-induced damage in human corneal epithelial cells (HCECs).

METHODS

Cultured HCECs were exposed to a single dose of UVB 300 mJ/cm, and the cell viability was measured 12 hours after the UVB irradiation using a cell-counting kit. Test samples at 0.01-1.0 mmol/L (carteolol hydrochloride, timolol maleate, betaxolol hydrochloride, levobunolol hydrochloride, or nipradilol) were added to the HCECs before, during, or after UVB irradiation. UV absorption spectra for each drug sample were determined using a spectrophotometer. Hydrogen peroxide (H2O2) and carteolol hydrochloride were simultaneously added to the HCECs for 10 minutes, and the cell viability was measured 12 hours later. The ability of carteolol hydrochloride to scavenge superoxide anion (O2) and singlet oxygen (O2) was investigated using the MCLA chemiluminescence method.

RESULTS

UVB irradiation decreased the number of viable HCECs in a dose-dependent manner. Carteolol hydrochloride at 1 mmol/L attenuated the UVB-induced cell damage when added before, during, or after UVB irradiation (P<0.01). Levobunolol hydrochloride at 1 mmol/L (P<0.01) added during or after irradiation and timolol maleate at 0.1 mmol/L or higher (P<0.05) added during irradiation attenuated the UVB-induced cell damage. Betaxolol hydrochloride and nipradilol had no effect. The UV absorption spectra of timolol maleate and levobunolol hydrochloride overlapped with the UVB wavelength spectrum, while carteolol hydrochloride, betaxolol hydrochloride, and nipradilol showed a partial overlap. Carteolol hydrochloride at 1 mmol/L (P<0.05) significantly inhibited H2O2-induced cell damage and was able to scavenge O2 (EC50 value: 48 mmol/L).

CONCLUSIONS

These data strongly suggest that carteolol hydrochloride has a protective action against UVB-induced HCEC damage, and its radical scavenging ability may be an important basis for this effect.

Protection from solar simulated radiation-induced DNA damage in cultured human fibroblasts by three commercially available sunscreens

Exposure to solar radiation can produce both acute and chronic changes in the skin, including sunburn, edema, immunosuppression, premature skin aging, and skin cancer. At the cellular level, solar radiation can produce adverse structural and functional changes in membrane proteins and lipids and in chromosomal and mitochondrial DNA. The increasing awareness of these adverse effects has led the public to demand better photoprotection. In this study, the alkaline comet assay was used to evaluate the photoprotective effects of three commercially available sunscreens at sun protection factors (SPF) 15 and 30. Human fibroblasts were used as target cells to conveniently study the effects of solar simulated radiation on DNA damage in the presence and absence of sunscreens. When human fibroblasts were exposed to various doses of solar simulated radiation, DNA damage, as measured in sunscreen-protected cells by the comet assay, was not significantly different from that detected in unexposed cells. At 1.0 and 1.5 minimal erythemal doses (MED), all sunscreens, at both SPF 15 and 30, provided nearly 100% photoprotection to the fibroblasts. Further studies are required to elucidate the role of UVA in the production and repair of DNA damage in cells exposed to sunlight.

Mechanisms for the formation of major oxidation products of adenine upon 365-nm irradiation with 2-methyl-1,4-naphthoquinone as a sensitizer

Recently we reported the isolation and characterization of N6-formyl- and N6-acetyladenine from 365-nm irradiation of dinucleoside monophosphates d(ApA), d(ApC), and d(CpA) in the presence of 2-methyl-1,4-naphthoquinone (menadione) (Wang et al. Biochem. Biophys. Res. Commun. 2002, 291, 1252-7). In this article we investigated the mechanisms for the formation of the two major products by carrying out photoirradiation with isotopically labeled menadione and 2,3-dimethyl-1,4-naphthoquinone. HPLC and electrospray ionization (ESI)-mass spectrometry (MS) and tandem MS studies of the products unambiguously established that the carbonyl group in the products arises from the photosensitizer: The N6-formyl group comes from oxidation of the methyl group and the N6-acetyl group stems from the methyl group and the adjacent ring carbon in menadione. From above results, we proposed mechanisms for the formation of the two products.

A computational study of physical and biological characterization of common UV sources and filters, and their relevance for substituting sunlight

Sunlight is the most important environmental UV source, affecting not only human health but also the whole terrestrial ecosystem. The use of artificial sources is advantageous since it is independent of geographical location and seasonal variations, however, in some photobiological/photochemical studies the choice of a specific UV source in relation to the biological end-point studied is sometimes questionable. Furthermore, it is often difficult to compare the results obtained in different laboratories due to 'slight' differences in the physical characteristics of the UV sources used. In an attempt to address these issues we calculated and compared the physical characteristics and the biological efficiency in UV-B and UV-A regions for two biological end-points (CPD and Fpg-sensitive sites formation) for frequently used UV-B, UV-A sources and solar light simulators (SLS). Our calculation shows that FS20 lamp is appropriate for studying the biological effects of UV-B radiation although differences in spectral characteristics of the associated filters may lead to at least 2-fold yields in CPD production. Furthermore, the use of a SLS with a Kodacel filter alone is inadequate for studying environmental UV effects. A metal-halide source with a Schott WG345 filter is appropriate for studies on biological effects due to UV-A region. Relative exposure duration was calculated to achieve equal amount of CPD or Fpg-sensitive sites, provided equal, total UV-(A+B) irradiance for the different UV sources.

Direct and indirect effects of UV radiation on DNA and its components

In this survey, emphasis was placed on the main photoreactions of nucleic acid components, involving both direct and indirect effects. The main UVB- and UVA-induced DNA photoproducts, together with the mechanisms of their formation, are described. Information on the photoproduct distribution within cellular DNA is also provided, taking into account the limitations of the different analytical methods applied to monitor the formation of the DNA damage. Thus, the formation of the main DNA dimeric pyrimidine lesions produced by direct absorption of UVB photons was assessed using a powerful HPLC-tandem mass spectrometry assay. In addition, it was found that UVA photooxidation damage mostly involves the guanine residues of cellular DNA as the result of singlet oxygen generation by still unknown endogenous photosensitizers.

Expression and modulation of apoptosis regulatory molecules in human melanocytes: significance in vitiligo

Although the aetiology of the hypopigmentary disorder vitiligo is ill understood, it is clear that pigment producing cells are absent from vitiliginous lesional skin. The present study was designed to investigate the possible role of melanocyte-expressed apoptosis regulatory molecules in melanocyte disappearance. Flow cytometric evaluation of p53, p21, Bcl-2 and Bax revealed no differences in in vitro expression levels between normal control and non-lesional melanocytes. Moreover, no in situ immunohistological differences were observed in melanocytes present in control, non-lesional and perilesional skin. However, an enhanced number of p53+ nuclei, in the absence of detectable p21 expression, was detected in involved areas. The observed p53 expression pattern did not involve melanocytes and could be the result of ultraviolet (UV) A irradiation. Further, we showed that UVB is capable of modulating melanocyte-expressed apoptosis regulatory molecules. Consequently, a lethal dose of UVB was given to two groups of cultured normal control and non-lesional melanocytes. No significant differences were found when comparing the percentages and kinetics of UVB-induced apoptosis in these groups. In conclusion, our results indicate that the relative apoptosis susceptibility of melanocytes in vitiligo is comparable with that of normal control cells. It is therefore unlikely that vitiligo is causally related to dysregulation of apoptosis regulatory molecules.

Protein phosphatase type 1-dependent dephosphorylation of the retinoblastoma tumor suppressor protein in ultraviolet-irradiated human skin and keratinocytes

This study provides evidence for the involvement of a type 1 protein serine/threonine phosphatase in the ultraviolet radiation-induced dephosphorylation of retinoblastoma tumor suppressor protein in human skin and cultured keratinocytes. The retinoblastoma gene product was localized to the nuclei and nucleoli of keratinocytes, and to the nuclei of basal and spinous layer cells of normal human epidermis. Western blot analysis of the retinoblastoma tumor suppressor protein antigen from keratinocytes and skin established the presence of the hypophosphorylated and hyperphosphorylated forms of retinoblastoma tumor suppressor protein. The exposure of keratinocytes and human skin to 200 J per cm2 of ultraviolet radiation, resulted in a rapid depletion in hyperphosphorylated retinoblastoma tumor suppressor protein, and the accumulation of growth inhibitory hypophosphorylated retinoblastoma tumor suppressor protein(105). In unirradiated and ultraviolet-irradiated keratinocytes retinoblastoma tumor suppressor protein was localized to the spindles of M-phase cells. In contrast, the exposure of keratinocytes to ultraviolet in the presence of 5 mM okadaic acid, resulted in an inhibition of retinoblastoma tumor suppressor protein translocation to the mitotic spindles of M-phase keratinocytes. In addition, the ultraviolet radiation-induced depletion in hyperphosphorylated retinoblastoma tumor suppressor protein, and accumulation of hypophosphorylated retinoblastoma tumor suppressor protein(105) was inhibited by 5 mM okadaic acid. Okadaic acid (0.5 nM), however, did not affect the ultraviolet radiation-induced dephosphorylation and depletion of hyperphosphorylation of the retinoblastoma tumor suppressor protein. Western blot analysis of ultraviolet-irradiated keratinocytes demonstrated that the hypophosphorylated growth inhibitory 105 kDa form of retinoblastoma tumor suppressor protein coimmunoprecipitated with the 38 kDa catalytic subunit of a type 1 protein serine/threonine phosphatase.

Formation of the main UV-induced thymine dimeric lesions within isolated and cellular DNA as measured by high performance liquid chromatography-tandem mass spectrometry

UVB radiation-induced formation of dimeric photoproducts at bipyrimidine sites within DNA has been unambiguously associated with the lethal and mutagenic properties of sunlight. The main lesions include the cyclobutane pyrimidine dimers and the pyrimidine (6-4) pyrimidone adducts. The latter compounds have been shown in model systems to be converted into their Dewar valence isomers upon exposure to UVB light. A new direct assay, based on the use of liquid chromatography coupled to tandem mass spectrometry, is now available to simultaneously detect each of the thymine photoproducts. It was applied to the determination of the yields of formation of the thymine lesions within both isolated and cellular DNA exposed to either UVC or UVB radiation. The cis-syn cyclobutane thymine dimer was found to be the major photoproduct within cellular DNA, whereas the related (6-4) adduct was produced in an approximately 8-fold lower yield. Interestingly, the corresponding Dewar valence isomer could not be detected upon exposure of human cells to biologically relevant doses of UVB radiation.

Wavelength dependence of ultraviolet-induced DNA damage distribution: involvement of direct or indirect mechanisms and possible artefacts

DNA damage profiles have been established in plasmid DNA using purified DNA repair enzymes and a plasmid relaxation assay, following exposure to UVC, UVB, UVA or simulated sunlight (SSL). Cyclobutane pyrimidine dimers (CPDs) are revealed as T4 endonuclease V-sensitive sites, oxidation products at purine and pyrimidine as Fpg- and Nth-sensitive sites, and abasic sites are detected by Nfo protein from Escherichia coli. CPDs are readily detected after UVA exposure, though produced 10(3) and 10(5) times less efficiently than by UVB or UVC, respectively. We demonstrate that CPDs are induced by UVA radiation and not by contaminating UVB wavelengths. Furthermore, they are produced at doses compatible with human exposure and are likely to contribute to the mutagenic specificity of UVA [E. Sage et al., Proc. Natl. Acad. Sci. USA 93 (1996) 176-180]. Oxidative damage is induced with a linear dose dependence, for each region of the solar spectrum, with the exception of oxidized pyrimidine and abasic sites, which are not detectable after UVB irradiation. The distribution of the different classes of photolesions varies markedly, depending on wavelengths. However, the unexpectedly high yield of oxidative lesions, as compared to CPDs, by UVA and SSL led us to investigate their production mechanism. An artificial formation of hydroxyl radicals is observed, which depends on the material of the sample holder used for UVA irradiation and is specific for long UV wavelengths. Our study sheds light on a possible artefact in the production of oxidative damage by UVA radiation. Meanwhile, after eliminating some potential sources of the artefact ratios of CPDs to oxidized purine of three and five upon irradiation with UVA and SSL, respectively, are still observed, whereas these ratios are about 140 and 200 after UVC and UVB irradiation.

DNA repair and survival in human lens epithelial cells with extended lifespan

PURPOSE

Ultraviolet-B radiation (290-320 nm) produces cataracts in animals and has been associated with human cataract formation in several epidemiological studies. UVB radiation decreases the long-term cell survival and changes the pattern of protein synthesis in cultured lens epithelial cells. However, the relationship between DNA photoproduct formation and long term cell survival in human lens epithelial cells is not known. In the present work, we used human lens epithelial cells with extended lifespan (HLE B-3 cells) to examine the kinetics of DNA repair and cell survival after UVB exposure.

METHODS

Cyclobutane pyrimidine dimers and pyrimidine-pyrimidone (6-4) photoproducts were analyzed by radioimmunoassay. Long-term survival of the cells was determined by measuring their ability form colonies when plated at low density.

RESULTS

HLE B-3 cells were repair competent after UVB (302 nm) exposure. Excision repair of the (6-4) photoproduct was more efficient than that of the cyclobutane dimer. Ninety five percent of the (6-4) photoproducts were repaired 24 h after 400 J/m2 UVB exposure, whereas 50% of the cyclobutane dimers were repaired during this time. When cells were split for the clonogenic assay immediately after irradiation, only 10% of the cells formed colonies following 7 days of culture in the serum-containing medium. When cells were split for the clonogenic assay after a 48 hour incubation in serum-containing medium, the colony-forming ability of the irradiated cells increased to 60% following culture in a serum-containing medium.

CONCLUSIONS

These results indicate a close correlation between the repair of cyclobutane dimers and the increase in the long-term survival of the cells as measured by their colony-forming ability. The extended lifespan human lens epithelial cells HLE B-3 may be a useful model to investigate the mechanism and regulation of UVB-induced DNA repair in human lens cells.

Molecular and cellular effects of ultraviolet light-induced genotoxicity

Exposure to the solar ultraviolet spectrum that penetrates the Earth's stratosphere (UVA and UVB) causes cellular DNA damage within skin cells. This damage is elicited directly through absorption of energy (UVB), and indirectly through intermediates such as sensitizer radicals and reactive oxygen species (UVA). DNA damage is detected as strand breaks or as base lesions, the most common lesions being 8-hydroxydeoxyguanosine (8OHdG) from UVA exposure and cyclobutane pyrimidine dimers from UVB exposure. The presence of these products in the genome may cause misreading and misreplication. Cells are protected by free radical scavengers that remove potentially mutagenic radical intermediates. In addition, the glutathione-S-transferase family can catalyze the removal of epoxides and peroxides. An extensive repair capacity exists for removing (1) strand breaks, (2) small base modifications (8OHdG), and (3) bulky lesions (cyclobutane pyrimidine dimers). UV also stimulates the cell to produce early response genes that activate a cascade of signaling molecules (e.g., protein kinases) and protective enzymes (e.g., haem oxygenase). The cell cycle is restricted via p53-dependent and -independent pathways to facilitate repair processes prior to replication and division. Failure to rescue the cell from replication block will ultimately lead to cell death, and apoptosis may be induced. The implications for UV-induced genotoxicity in disease are considered.

Ultraviolet light attenuates heat-inducible gene expression

Ultraviolet light (UV) induces a stress response mediated through transcription factors such as NF-kB and AP-1, yet little is known about its effect on other transactivators of stress gene expression such as heat shock factor (HSF1). Analysis of UV-treated HeLa cells unexpectedly revealed uncoupling of the heat shock response. UV weakly induced HSF1 into its DNA bound state and markedly attenuated heat-inducible gene expression. HSF1 was further analyzed as a potential target for the uncharacteristic uncoupling of the thermal stress response by another type of stress. Heat-inducible multimerization and nuclear translocation of HSF1 were found to be intact in UV-treated cells; however, the monomeric rather than the multimeric form of HSF1 become hyperphosphorylated by UV. This effect could be partially abolished by the antioxidant N-acetyl cysteine with partial reconstitution of hs gene expression. The reported role of a MAP kinase blockade of HSF1 transactivating properties could not be confirmed by an inhibitor of the MAP kinase pathway. Fibroblasts defective in SAP kinase activity also did not exhibit resistance to UV-inducible phosphorylation of HSF1. Two-dimensional phosphopeptide mapping of HSF1 revealed a single tryptic peptide to be affected by UV, but no new pattern of phosphorylation was evident relative to tryptic phosphopeptide profile observed in control cells. These data suggest that UV uncoupling of the hs response possibly involves steps in addition to those associated with phosphorylation the monomeric form of HSF1.

Comparative effects of UV A and UV B on clonogenic survival and delayed cell death in skin cell lines from humans and fish

The effects of UV radiation on humans and animals are receiving increasing attention and much interest has recently been focused on the environmental effects of UV A and UV B. This study compares the in vitro effects of UV A and UV B on the clonogenic survival of two human skin keratinocyte cell lines, HaCaT which are immortal but not tumorigenic and HPV-G transfected keratinocytes which form non malignant tumours in nude mice. The effects were also studied on an EPC fish cell line. The aim of the work was to establish if similar initial and delayed survival responses occurred in both species. The cells were exposed to ultraviolet lamps emitting maximally at 365 nm (UV A) and 302 nm (UV B). Clonogenic survival was determined at appropriate times post exposure. Results for the initial survival curves show that the HaCaT and HPV-G cells did not show any appreciable difference in their response to UV A but the EPC cells were more sensitive at doses < 3000 Jm-2. The EPC cells were more sensitive to UV B at doses < 200 Jm-2 in comparison to the human HaCaT and HPV-G cells with the HPV-G cells showing the most sensitivity to UV B at doses > 200 Jm-2. The possible contribution of lethal mutations (delayed cell death) to the UV radiation response in the HaCaT and EPC cell lines was examined. The results showed that lethal mutations were expressed in the HaCaT cells following exposure to UV A and UV B but no lethal mutations were expressed in the EPC cells.

UVB DNA dosimeters analyzed by polymerase chain reactions

Purified bacteriophage lambda DNA was dried on a UV-transparent polymer film and served as a UVB dosimeter for personal and ecological applications. Bacteriophage lambda DNA was chosen because it is commercially available and inexpensive, and its entire sequence is known. Each dosimeter contained two sets of DNA sandwiched between UV-transparent polymer films, one exposed to solar radiation (experimental) and another protected from UV radiation by black paper (control). The DNA dosimeter was then analyzed by a polymerase chain reaction (PCR) that amplifies a 500 base pair specific region of lambda DNA. Photoinduced damage in DNA blocks polymerase from synthesizing a new strand; therefore, the amount of amplified product in UV-exposed DNA was reduced from that found in control DNA. The average lesion frequency per 500 base pair per strand at 16 PCR cycles was approximately 1.22, 1.00, 0.70 and 0.50 for 30 ng, 50 ng, 100 ng and 150 ng of dried DNA, respectively, after a total dose of 60 kJ m(-2) delivered with a solar UVB simulator. Although the average lesion frequency increases linearly with increasing doses for four different amounts of template DNA, the lesion frequency seems to be averaged by the amplified products from the protected lambda DNA molecules below the top few layers. The average daily dose, equivalent to the UV dose applied with the solar UVB simulator was 10.2 +/- 0.4 kJ m(-2) with the 50 ng containing DNA dosimeter in September 1995 in Melbourne, FL. Both 50 ng and 150 ng containing DNA dosimeters produced the same average daily dose within experimental error in January 1996, which was 5.2 +/- 0.3 kJ m(-2) at the same location. The dried lambda DNA dosimeter is compact, robust, safe and transportable, stable over long storage times and provides the total UVB dose integrated over the exposure time.

Induced melanin reduces mutations and cell killing in mouse melanoma

When melanin absorbs light energy, it can produce potentially damaging active oxygen species. There is little doubt that constitutive pigment in dark-skinned individuals is photoprotective against skin cancer, but induced pigment-as in tanning-may not be. The first step in cancer induction is mutation in DNA. The most suitable systems for evaluating the role of melanin are those in which pigment can be varied and mutations can be measured. Several cell lines from Cloudman S91 mouse melanoma can be induced to form large quantities of melanin pigment after treatment with a number of different agents enabling comparison of mutant yields in the same cells differing principally in pigment concentration. In these studies, melanin was induced with synthetic alpha-melanocyte-stimulating hormone and with isobutyl methyl xanthine in the cell line S91/mel. The former inducer produced about 50% more pigment than the latter. Survival and mutation induction at the Na+/K(+)-ATPase locus were studied using ethyl methane sulfonate (EMS), a standard mutagen and five UV lamps emitting near monochromatic and polychromatic UV light in the three wave-length ranges of UV. There was greater protection against killing and mutation induction in the more heavily pigmented cells after exposure to EMS and after irradiation with monochromatic UVC and UVB. There was significant protection against killing by polychromatic UVB + UVA (FS20), but the small degree of protection against mutation was not significant. No significant change in killing and mutation using the same protocol was seen in S91/amel, a related cell line that does not respond to these inducers. No mutants were produced by either monochromatic or polychromatic UVA at doses that killed 50% of the cells. Our results show that induced pigment-shown earlier to be eumelanin (K. A. Cieszka et al., Exp. Dermatol. 4, 192-198, 1995)-is photo- and chemoprotective, but it is less effective in protection against mutagenesis by polychromatic UVB + UVA in a spectrum that more nearly approximates the solar spectrum.

Effects of ultraviolet A and antioxidant defense in cultured fibroblasts and keratinocytes

Lipid peroxidation, measured by the thiobarbituric acid-reactive substances assay, was evaluated for cultured human skin fibroblasts and keratinocytes exposed to ultraviolet A radiation (320-400 nm, UVA). Peroxidation increases with increasing UVA doses and is much lower for keratinocytes than for fibroblasts. Immediate UVA-induced cytotoxicity, monitored by the trypan blue exclusion assay, is also lower for keratinocytes. Thus, cultured human skin keratinocytes are less sensitive than fibroblasts to the immediate deleterious effects of UVA with respect to membrane damage and lipid peroxidation. As a first attempt to understand this lower sensitivity of keratinocytes, basal levels of antioxidant defenses including total glutathione, superoxide dismutase, glutathione peroxidase and catalase were evaluated in both keratinocytes and fibroblasts from the same donors. We failed to correlate this lower susceptibility of keratinocyte to UVA-induced lipid peroxidation and cytotoxicity with a higher antioxidant status.

Oxidative stress associated with exercise, psychological stress and life-style factors

Oxidative stress is a cellular or physiological condition of elevated concentrations of reactive oxygen species that cause molecular damage to vital structures and functions. Several factors influence the susceptibility to oxidative stress by affecting the antioxidant status or free oxygen radical generation. Here, we review the effect of alcohol, air pollution, cigarette smoke, diet, exercise, non-ionizing radiation (UV and microwaves) and psychological stress on the development of oxidative stress. Regular exercise and carbohydrate-rich diets seem to increase the resistance against oxidative stress. Air pollution, alcohol, cigarette smoke, non-ionizing radiation and psychological stress seem to increase oxidative stress. Alcohol in lower doses may act as an antioxidant on low density lipoproteins and thereby have an anti-atherosclerotic property.

Ultraviolet-A induces activation of AP-1 in cultured human keratinocytes

UV-A irradiation induces a time-dependent activation of AP-1 in NCTC 2544 human keratinocytes. 4 h after irradiation, a 2-3-fold increase in AP-1 activity is observed in human keratinocytes and fibroblasts. Activation is still detectable 24 h later. The UV-A induced AP-1 binding complex is shown to contain c-Fos and c-Jun proteins. Lipophilic vitamin E impedes UV-A induced lipid peroxidation but does not prevent AP-1 activation which is inhibited by N-acetylcysteine, a hydrophilic antioxidant. This finding suggests that UV-A-dependent AP-1 activation is sensitive to the cellular redox state but is not related to membrane lipid peroxidation.

Use of the alkaline comet assay to detect DNA repair deficiencies in human fibroblasts exposed to UVC, UVB, UVA and gamma-rays

The alkaline single cell gel electrophoresis (comet) assay applied to human fibroblasts allowed us to analyze the response to components of the solar spectrum (UVB and UVA) in comparison with the well-established response to UVC and gamma-rays. DNA strand breaks related to nucleotide excision repair of DNA photoproducts were produced 1 h after exposure to UVB or UVC in the normal cell line but not in the repair deficient XPD and TTD-2 cell lines. In contrast, the immediate production of DNA strand breaks observed in all cell lines after exposure to UVA or gamma-rays was followed by restitution of high molecular weight DNA upon post-exposure incubation. These results imply that (1) fibroblasts as well as lymphocytes can be analysed by the comet assay and (2) the comet assay clearly distinguishes cellular nucleotide excision repair capacity without the use of inhibitors of DNA synthesis.

Induction and repair of DNA damage in UV-irradiated human lymphocytes. Spectral differences and repair kinetics

The alkaline elution assay has been employed to study the induction and repair kinetics of DNA damage in human lymphocytes after irradiation with biologically relevant doses of UVB (297 and 302 nm) or UVA (365 nm) radiation. At 365 nm, when the predominant lesions are single-strand breaks, the rate of lesion induction was 1.5 x 10(-3) per 10(8) Da per kJ m-2. The number of breaks decayed with a half-life of about 50 min after a dose of 20 kJ m-2. In the UVB region, cyclobutyl pyrimidine dimers and 6-4 photoproducts are formed, both of which are repairable via the nucleotide excision repair pathway. By using repair inhibitors, the rate of induction of such lesions at 297 and 302 nm was found to be 0.07 per 10(8) Da per J m-2. Lesions were removed with a half-life of about 100 min. Mathematical modelling of the excision repair process revealed a time-dependent polymerization-ligation rate: after an initial lag phase the polymerization-ligation rate increased, reaching 50% of its maximum rate at 80-100 min after the start of repair incubation. This course of development might be due to a damage-associated regulation of DNA precursors synthesis.

DNA UVB dosimeters

DNA can be used to establish and monitor solar UVB dose. Since the principal molecular site of UVB damage in living organisms is DNA, it is logical to quantitate biologically effective solar UVB in DNA dosimeters. In addition to their particular sensitivity to UVB, DNA dosimeters have the advantage of a 2 pi geometry for collecting diffuse UVB radiation from all vectors, low cost, small size and portability, and no moving parts. Both molecular (cyclobutane pyrimidine dimers) and biological (bacteriophage plaques) dosimeters can be quantitated as endpoints to yield the total dose. DNA dosimeters integrate the absorbed energy of all UVB wavelengths (290-320 nm), are highly sensitive to the differential biological effectiveness of these wavelengths, and also integrate over time in hours, days or weeks of exposure. Our experiments have focused on the demonstration of DNA solar dosimeters in the ocean at various depths, the application of the dosimeters to the terrestrial monitoring of solar UVB under various conditions, and the development of a mini-dosimeter which uses nanograms of DNA and is assayed by polymerase chain reaction.

Ultraviolet action spectra for photobiological effects in cultured human lens epithelial cells

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 beta-crystallin, cells were exposed to sublethal fluences of UV radiation at 302 and 313 nm, labeled with [35S]methionine and the newly synthesized beta-crystallin was analyzed by immunoprecipitation and western blotting using an antibody to beta-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.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultraviolet-B-light-induced mutagenesis of C-H-ras codons 11 and 12 in human skin fibroblasts

Mutations in the ras oncogene are detected with a high frequency in non-melanoma skin cancer. Approximately half of the squamous-cell carcinomas (SCC) and one third of the basal-cell carcinomas (BCC) carry mutations at the second position of Ha-ras codon 12 (GGC to GTC), whereas mutations in Ki-ras codon 12 occur less frequently. Since the mutations in the Ha-ras and Ki-ras oncogenes are located opposite potential pyrimidine dimer sites (C-C), it is likely that the mutations are induced by ultraviolet radiation present in sunlight. We studied the capacity of ultraviolet B (UVB) light to induce base-pair changes in Ha-ras codons 11 and 12 in human skin fibroblasts. UVB induced mostly C to T and G to A transitions and C to A and G to T transversions. The base-pair change with the highest relative abundance was C to T in the middle position of codon 11 followed by (in diminishing relative abundance) C to A in the middle position of codon 11, G to A and G to T in the middle position of codon 12. The C to T and G to A transitions are compatible with pyrimidine photodimers as pre-mutagenic lesions, whereas the C to A and G to T transversions could be generated due to the formation of 8-hydroxyguanine, which is the major oxidation product of guanine. The relative abundance of mutations induced by UVB in Ha-ras codons 11 and 12 does not correlate with mutations observed in the DNA from non-melanoma skin cancer, where the G to T transversion in the middle position of codon 12 is selected.

The action spectra for UV-induced suppression of MLR and MECLR show that immunosuppression is mediated by DNA damage

Ultraviolet-B (UVB, 280-320 nm) radiation can promote the induction of skin cancer by two mechanisms: damage of epidermal DNA and suppression of the immune system, allowing the developing tumor to escape immune surveillance. The mixed lymphocyte reaction (MLR) and the mixed epidermal cell lymphocyte reaction (MECLR) are commonly used methods to study the immunosuppressive effects of UVB radiation. To obtain a better understanding of the mechanism by which UVB radiation decreases the alloactivating capacity of in vitro-irradiated cells, action spectra for the MLR and MECLR were determined. Suspensions of peripheral blood mononuclear cells or epidermal cells were irradiated with monochromatic light of 254, 297, 302 or 312 nm and used as stimulator cells in the MLR or MECLR. Using dose-response curves for each wavelength, the action spectra were calculated. Both MLR and MECLR action spectra had a maximum at 254 nm and a relative sensitivity at 312 nm that was a thousand times lower than at 254 nm. Strikingly, the action spectra corresponded very closely to the action spectra that were found by Matsunaga et al. (Photochem. Photobiol. 54, 403-410, 1991) for the induction of thymine dimers and (6-4)photoproducts in irradiated calf thymus DNA solutions, strongly suggesting that the UV-induced abrogation of the MLR and MECLR responses is mediated by UV-induced DNA damage. Furthermore, the action spectra for the MLR and MECLR were similar, suggesting that they share a common mechanism for UV-induced suppression.

Molecular cloning of the human gene SUVCC2 associated with mutagenesis following the induction of non-dimer DNA damages by solar UV radiation

A mutant cell line, DRP 512, sensitive to the induction of non-dimer DNA damages produced by solar UV radiation was derived from ICR 2A frog cells. In addition, the DRP 512 cells exhibited an abnormally high level of ouabain-resistant mutants after exposure to solar UV. A level of 1.1. mutants per 10(6) survivors per kJ m-2 was measured for ICR 2A whereas the yield was 4.2 mutants per 10(6) survivors per kJ m-2 for the solar-UV-sensitive cell line. The DRP 512 cells were transfected with human DNA and a secondary transformant obtained in which normal solar UV sensitivity and mutation induction were restored. DNA from this secondary transformant was used to construct a genomic DNA library from which a recombinant phage was isolated containing the human gene capable of restoring normal solar UV sensitivity and mutation induction to DRP 512. This gene has been designated SUVCC2.

Mutation spectra in Salmonella of sunlight, white fluorescent light, and light from tanning salon beds: induction of tandem mutations and role of DNA repair

We evaluated the mutagenicity of sunlight (SUN), uncovered coolwhite fluorescent light (FLR), and light from a tanning salon bed (TAN) at the base-substitution allele hisG46 of Salmonella in four DNA repair backgrounds (wild type, uvrB, pKM101, and uvrB + pKM101). Approximately 80% of the radiation emitted by TAN was within the ultraviolet (UV) range, whereas only approximately 10% of the SUN and approximately 1% of the FLR radiation was UV. TAN emitted similar amounts of UVA and UVB, whereas SUN emitted 50-60x and FLR emitted 5-10x more UVA relative to UVB. Based on total dose (UV + visible), the mutagenic potency ranking was TAN > FLR > SUN. Using colony probe hybridization and PCR/DNA sequence analysis, approximately 3000 revertants were analyzed to determine the mutational specificity of the three light sources. The mutation spectra and those induced by 254-nm UV had common features. The uvrB mutation enhanced the mutagenicity of the environmental UV sources more (20-216x) than did the pKM101 plasmid (approximately 20x) relative to wild type DNA repair. All light sources induced equal proportions of transitions and transversions in excision repair-proficient strains, but they induced more transitions relative to transversions in uvrB-containing strains. The majority of the mutations were G.C-->A.T transitions that were induced equally frequently at the first or second position of the CCC codon of the hisG46 allele in all strains except TA1535 (uvrB), where SUN and FLR induced transitions preferentially at the first position, and TAN induced them preferentially at the second position. Identified or presumptive multiple mutations, which constituted the only mutational class enhanced by all three light sources in the presence of uvrB and pKM101 either alone or together, accounted for 3-5% of the induced mutations in the plasmid-containing strains, and their increases (38-82-fold) in TA100 (uvrB, pKM101) were the highest of any mutational class. Of the TAN-induced multiple mutations, 83% (19/23) were CC-->TT tandem transitions. These results show that exposures to the nonsolar environmental UV sources FLR and TAN produce mutations similar to those produced by SUN, a known carcinogen.

Correlation of UVC and UVB cytotoxicity with the induction of specific photoproducts in T-lymphocytes and fibroblasts from normal human donors

By using specific monoclonal antibodies in situ and a computer-assisted image analysis system we have determined the relative induction of cyclobutane dimers, (6-4) photoproducts and Dewar isomers in human mononuclear cells and fibroblasts following irradiation with UVC, broad-spectrum UVB and narrow-spectrum UVB. The lamps produced these lesions in different proportions, with broad-spectrum UVB inducing a greater combined yield of (6-4) photoproducts and Dewar isomers per cyclobutane dimer than UVC or narrow-spectrum UVB. The relative induction ratios of (6-4) photoproducts compared to cyclobutane dimers were 0.15, 0.21 and 0.10 following irradiation with UVC, broad- or narrow-spectrum UVB, respectively. Although Dewar isomers were induced by UVC, their relative rate of formation compared to cyclobutane dimers was significantly greater after irradiation with either broad-spectrum or narrow-spectrum UVB. These values were 0.001, 0.07 and 0.07, respectively. With each lamp source, we have determined the survival of normal human T-lymphocytes and fibroblasts at fluences, which induce equivalent yields of cyclobutane dimers, (6-4) photoproducts or (6-4) photoproducts plus Dewar isomers. Killing of fibroblasts appears to be associated with (6-4) photoproduct formation, whereas killing of T-lymphocytes seems to be mediated by combined (6-4) plus Dewar yields. These results emphasize the need to study the biological effects of UVB because cellular responses may be different from those following UVC irradiation.

Ultraviolet B light-induced mutagenesis of p53 hotspot codons 248 and 249 in human skin fibroblasts

Mutations in the p53 tumor suppressor gene are detected in approximately half of non-melanoma skin cancers. The type of base-pair changes observed strongly suggests solar radiation as the causative mutagen. Mutations are distributed nonrandomly and form moderate hotspots. We studied the capacity of ultraviolet B light (UVB, 280-320 nm) to induce base-pair changes into the p53 exon 7 sequence extending from nt 14067 to 14075 in human skin fibroblasts. This sequence contains hotspot codon 248. UVB induced mostly C-->A and G-->T transversions. The base-pair change with the highest relative abundance was C-->A in the first position of codon 250 (CCC-->ACC), followed by (in diminishing relative abundance) G-->T in the third position of codon 249 (AGG-->AGT), C-->A in the first position of codon 248 (CGG-->AGG), and C-->A in the third position of codon 247 (AAC-->AAA). The C-->T transition in the third position of codon 247 (AAC-->AAT) occurred with moderate efficiency. These base-pair changes are compatible with pyrimidine photodimers as premutagenic lesions, but they could also form opposite 8-hydroxyguanine, which is the major oxidation product of guanine. No evidence was obtained for the presence of tandem double CC-->TT transitions in the untranscribed strand at codons 247/248 and 250. The relative abundance of mutations induced by UVB in the p53 sequence extending from codon 247 to 250 in human fibroblasts does not correlate with mutations observed in the DNA from non-melanoma skin cancer. This lack of correlation suggests that the mutability of this p53 sequence at the DNA level plays only a minor role in the pathogenesis of non-melanoma skin cancer in humans.

Optimization of photopolymerized bioerodible hydrogel properties for adhesion prevention

The aim of this study was to optimize the properties of a lubricious bioerodible hydrogel barrier for the prevention of postoperative adhesions. Water-soluble macromers based on block copolymers of poly(ethylene glycol) (PEG) and poly(lactic acid) or poly(glycolic acid) with terminal acrylate groups were used, and these macromers were gelled in vivo by exposure to long wavelength ultraviolet light. The precursor was photopolymerized from buffered saline solution while in contact with the tissues. This resulted in the conformal coating of the tissue with an adherent hydrogel film, while forming a nonadhesive barrier at the free surface, on the treated wound site. The hydrogels were evaluated in two animal models of postsurgical adhesions, first in a rat cecum abrasion model and then in a rabbit uterine horn ischemia model. In the rat cecum model, six of seven animals treated with a hydrogel, with glycolide in the precursor as the comonomer, showed no adhesions; untreated animals and animals treated with precursor, but not gelled with light, showed consistent dense adhesions. In the rabbit uterine horn ischemia model, using hydrogels with lactide in the precursor as the comonomer, and PEG of molecular weight from 6,000 to 18,500 Da, adhesions were dramatically reduced, with occurrence in none of seven animals treated with a gel containing PEG 10,000. By contrast, the seven animals in the control group demonstrated a mean of 35% involvement of the horn length in dense, fibrous adhesions. These materials, photopolymerized in vivo in direct contact with the tissues, appear to form an adherent hydrogel barrier that is highly effective in reducing postoperative adhesions in the models used.(ABSTRACT TRUNCATED AT 250 WORDS)

UVB-induced DNA breaks interfere with transcriptional induction of c-fos

Oxidative stress may play an important role in the carcinogenic action of UVB light (290 to 320 nm). UVB light induces the growth-related immediate-early gene c-fos in JB6 mouse epidermal cells, but at the same time it causes structural damage to DNA, in particular DNA strand breakage. We have studied the effect of the modulation of the frequencies of DNA breaks on the transcriptional induction of c-fos by changing the cellular antioxidant defense or by inhibiting break repair. Reduction of UVB-induced DNA breakage in a stable transfectant with an increased complement of glutathione peroxidase enhanced the induction of c-fos. In contrast, c-fos induction was diminished in stable transfectants with Cu,Zn-superoxide dismutase. Increasing the stationary concentration of UVB-induced DNA breaks by inhibition of repair in the presence of the adenosine diphosphoribose (ADPR)-transferase inhibitor 3-amino-benzamide suppressed the induction of c-fos. We conclude that DNA breaks which are induced by UVB via oxidative processes interfere with the transcriptional induction of c-fos. DNA breaks appear to exert a long-range effect on chromatin conformation which is incompatible with efficient transcription. This notion is supported by the observation that inhibition of break rejoining by 3-amino-benzamide suppressed the UVB induction of the endogenous c-fos gene and of a stably integrated construct containing the c-fos regulatory sequences linked to a reporter gene. In contrast, the induction of the same construct was not inhibited when it remained extrachromosomal in transient transfection experiments.

UVB-induced DNA breaks interfere with transcriptional induction of c-fos

Oxidative stress may play an important role in the carcinogenic action of UVB light (290 to 320 nm). UVB light induces the growth-related immediate-early gene c-fos in JB6 mouse epidermal cells, but at the same time it causes structural damage to DNA, in particular DNA strand breakage. We have studied the effect of the modulation of the frequencies of DNA breaks on the transcriptional induction of c-fos by changing the cellular antioxidant defense or by inhibiting break repair. Reduction of UVB-induced DNA breakage in a stable transfectant with an increased complement of glutathione peroxidase enhanced the induction of c-fos. In contrast, c-fos induction was diminished in stable transfectants with Cu,Zn-superoxide dismutase. Increasing the stationary concentration of UVB-induced DNA breaks by inhibition of repair in the presence of the adenosine diphosphoribose (ADPR)-transferase inhibitor 3-amino-benzamide suppressed the induction of c-fos. We conclude that DNA breaks which are induced by UVB via oxidative processes interfere with the transcriptional induction of c-fos. DNA breaks appear to exert a long-range effect on chromatin conformation which is incompatible with efficient transcription. This notion is supported by the observation that inhibition of break rejoining by 3-amino-benzamide suppressed the UVB induction of the endogenous c-fos gene and of a stably integrated construct containing the c-fos regulatory sequences linked to a reporter gene. In contrast, the induction of the same construct was not inhibited when it remained extrachromosomal in transient transfection experiments.