Dieter Pollet

Photochemical genotoxicity: principles and test methods. Report of a GUM task force.

In recent years, assessing the photogenotoxic potential of a compound became an issue for certain drugs and cosmetical products. Therefore, existing methods performed according to international guidelines (e.g. OECD guidelines) were adapted to the use of concurrent UV-visible (UV-Vis) light irradiation for the assessment of photomutagenicity/photogenotoxicity. In this review, photobiological bases of the processes occurring in the cell after irradiation with UV- and/or visible (vis)-light as well as a compilation of testing methods is presented. Methods comprise cell free investigations on naked DNA and in vitro methods, such as the photo-Ames test, the photo-HPRT/photo-mouse lymphoma assay (MLA), the photo-micronucleus test (MNT), the photo-chromosomal aberration test (CA) and the photo-Comet assay. A compilation of the currently available international literature of compounds tested on photogenotoxicity is given for each method. The state of the art of photogenotoxicity testing as well as the rational for testing are outlined in relation to the recommendations reached in expert working groups at different international meetings and to regulatory guidance papers. Finally, photogenotoxicity testing as predictor of photocarcinogenicity and in the light of risk assessment is discussed.

Kinetics of DNA strand breaks and protection by antioxidants in UVA- or UVB-irradiated HaCaT keratinocytes using the single cell gel electrophoresis assay

The aim of this study was to characterize the genotoxic action of UVA and UVB in human keratinocytes by application of the single cell gel electrophoresis assay (SCGE assay). Dose dependence of DNA damage, the time course of its repair, and the influence of cellular antioxidant status were assessed. Irradiation with UVA or UVB both resulted in a dose-dependent increase in the level of DNA damage. A time course study to evaluate the repair kinetics in keratinocytes irradiated with 5 J/cm2 UVA revealed an immediate occurrence of DNA effects which subsequently disappeared within about 1 h, indicating removal of DNA lesions. This rapid repair of DNA damage is consistent with the observation that 5 J/cm2 UVA did not impair cellular viability. In contrast, exposure to 15 mJ/cm2 UVB resulted in a prolonged repair of DNA damage which lasted about 25 h. Thus, the repair kinetics of UVA- and UVB-induced DNA damage clearly differed from each other, implicating the induction of different types of DNA lesions by UVA and UVB. Neither a pretreatment with Mg-ascorbyl phosphate or D,L-alpha-tocopherol, nor depletion of endogenous glutathione altered cellular sensitivity to UVB. In contrast, the DNA damaging effects of UVA could be counteracted by a pretreatment with these antioxidants. These observations confirm that the UVA-induced effects on DNA are related to radical mediated strand breaks and DNA lesions forming alkali-labile sites. The UVB-induced effects mainly occur as a consequence of excision repair-related strand breaks. The observed repair kinetics of DNA lesions and the influence of cellular antioxidant status may help to elucidate protective mechanisms against the carcinogenic effects of UV radiation present in sunlight.

Comparison of Activities Dependent on Glutathione S-Transferase and Cytochrome P-450 IA1 in Cultured Keratinocytes and Reconstructed Epidermal Models

There is an increasing need for in vitro testing of compounds for topical application. Reconstructed epidermal models may provide a suitable and relevant model for screening compounds that may affect the activities of phase I and II enzymes involved in epidermal detoxification. In this study, we measured the activity of a phase I enzyme, cytochrome P450 IA1, i.e. 7-ethoxyresorufin-O-deethylase (EROD) and 7-ethoxycoumarin-O-deethylase (ECOD) activities, and that of a phase II enzyme, glutathione S-transferase (GST). The enzyme activities were determined in cultured keratinocytes, reconstructed epidermal models and samples of human epidermis or hair follicle. EROD activity was detected in cultured keratinocytes and was induced by 3-methylcholanthrene (3-MC) and β-naphthoflavone. The level of induction increased with increasing confluence. Induced EROD activity could be inhibited by clotrimazole in a dose-dependent manner. However, EROD activity was not detected in either hair follicles or untreated epidermal models but could be induced by 3-MC. The ability to induce EROD activity in epidermal models was batch dependent, and clotrimazole was able to inhibit the induced EROD activity. ECOD activity was detected in untreated models and paralleled EROD activity. GST activity was detected in cultured keratinocytes and all epidermal models. GST activity in models was equal or higher than the activity in epidermal samples. Reconstructed skin models may be useful to study the effects of non-water-soluble topical formulations on xenobiotic metabolism.

Analysis of UV-B-induced DNA damage and its repair in heat-shocked skin cells.

The heat-shock response is a cellular defence mechanism against environmental stresses that is evolutionarily conserved from bacteria to man. Numerous reports demonstrate the beneficial effects of heat-shock protein induction on cell survival under toxic or oxidative stress, e.g., in cardiac and cerebral ischemia or prior to organ transplantation. However, there is little data on the effects of heat treatment on damage caused by UV irradiation. Applying three independent techniques, we have tested the influence of thermal pretreatment of skin cells (1 h, 43 degrees C) on the initial extent of UV-B-induced DNA damage and its subsequent repair. For cultured human epidermal keratinocytes and dermal fibroblasts we can show reduced levels of nucleotide-excision-repair-associated DNA strand incision in the comet assay. Moreover, immunostaining and flow cytometric quantitation of thymidine dimers immediately and one day after irradiation, respectively, reveal that the initial DNA damage is not (keratinocytes) or only moderately (fibroblasts) lower in heat-shocked cells as compared to untreated controls. However, excision repair of dimers is significantly attenuated during the first 24 h in both cell types. Furthermore, using a modified host-cell reactivation assay, we are able to demonstrate that repair of UV-B-damaged plasmid DNA is lower if the transfected cells are previously heat shocked. In summary, heat treatment (1 h, 43 degrees C) inducing heat-shock proteins reduces nucleotide excision repair of UV-B-mediated DNA lesions in fibroblasts and keratinocytes during the following 24 h. This is not necessarily caused by elevated heat-shock protein levels themselves. Possibly the direct thermal damage of repair enzymes is more severe than the potential protective effects of heat-shock proteins.

NAD(P)H:quinone reductase activity in human epidermal keratinocytes and reconstructed epidermal models

Reconstructed epidermal models may provide a suitable and relevant model for screening compounds such as quinones, which affect the activities of phase I and II enzymes involved in epidermal detoxification. Reconstructed epidermis may also allow the study of the metabolism of topically applied compounds by the phase I and II enzymes. We demonstrate that NAD(P)H:quinone reductase (NQR) activity is present in three different types of reconstructed epidermal models and that levels vary depending on the type of model. We also determined the inter- and intrabatch variability and demonstrate that NQR activity can be significantly inhibited by dicumarol treatment. The NQR activity in reconstructed epidermis is similar to that in human epidermis and lower than in cultured keratinocytes. Therefore reconstructed epidermis is a more suitable model for testing the effects of topically applied compounds on NQR activity or the metabolism of the compound by NQR.