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XERODERM A pigmentosum patients with a defect in the nucleotide-excision repair gene XPA are characterized by, for example, a > 1,000-fold higher risk of developing sunlight-induced skin cancer 1–3 . Nucleo tide-excision repair (NER) is involved in the removal of a wide spectrum of DNA lesions. The XPA protein functions in a pre-incision step, the recognition of DNA damage 4–7 . To permit the functional analysis of the XPA gene in vivo, we have generated XPA -deficient mice by gene targeting in embryonic stem cells. The XPA −f− mice appear normal, at least until the age of 13 months. XPA−1− mice are highly susceptible to ultraviolet (UV)-B-induced skin and eye tumours and to 7,12-dimethylbenz-[a]anthracene (DMBA)-induced skin tumours. We conclude that the XPA -deficient mice strongly mimic the phenotype of humans with xeroderma pigmentosum.

Xeroderma pigmentosum (XP) patients with a defect in the nucleotide excision repair gene XPA, develop tumors with a high frequency on sun-exposed areas of the skin. Here we describe that hairless XPA-deficient mice also develop skin tumors with a short latency time and a 100% prevalence after daily exposure to low doses of U.V.B. Surprisingly and in contrast to U.V.B.-exposed repair proficient hairless mice who mainly develop squamous cell carcinomas, the XPA-deficient mice developed papillomas with a high frequency (31%) at a U.V. dose of 32 J/m2 daily. At the highest daily dose of 80 J/m2 mainly squamous cell carcinomas (56%) and only 10% of papillomas were found in XPA-deficient hairless mice. p53 gene mutations were examined in exons 5, 7 and 8 and were detected in only 3 out of 37 of these skin tumors, whereas in tumors of control U.V.B.-irradiated wild type littermates this frequency was higher (45%) and more in line with our previous data. Strikingly, a high incidence of activating ras gene mutations were observed in U.V.B.-induced papillomas (in 11 out of 14 tumors analysed). In only two out of 14 squamous cell carcinomas we found similar ras gene mutations. The observed shift from squamous cell carcinomas in wild type hairless mice to papillomas in XPA-deficient hairless mice, and a corresponding shift in mutated cancer genes in these tumors, provide new clues on the pathogenesis of chemically- versus U.V.B.-induced skin carcinogenesis.

High levels of the p53 protein are immunohistochemically detectable in a majority of human nonmelanoma skin cancers and UVB-induced murine skin tumors. These increased protein levels are often associated with mutations in the conserved domains of the p53 gene. To investigate the timing of the p53 alterations in the process of UVB carcinogenesis, we used a well defined murine model (SKH:HR1 hairless mice) in which the time that tumors appear is predictable from the UVB exposures. The mice were subjected to a series of daily UVB exposures, either for 17 days or for 30 days, which would cause skin tumors to appear around 80 or 30 weeks, respectively. In the epidermis of these mice, we detected clusters of cells showing a strong immunostaining of the p53 protein, as measured with the CM-5 polyclonal antiserum. This cannot be explained by transient accumulation of the normal p53 protein as a physiological response to UVB-induced DNA damage. In single exposure experiments the observed transient CM-5 immunoreactivity lasted for only 3 days and was not clustered, whereas these clusters were still detectable as long as 56 days after 17 days of UVB exposure. In addition, ≈ 70% of these patches reacted with the mutant-specific monoclonal antibody PAb240, whereas transiently induced p53-positive cells did not. In line with indicative human data, these experimental results in the hairless mouse model unambiguously demonstrate that constitutive p53 alterations are causally related to chronic UVB exposure and that they are a very early event in the induction of skin cancer by UVB radiation.