DNA repair-deficient Xpa and Xpa/p53+/- knock-out mice: nature of the models.

Xeroderma pigmentosum (XP) is a rare autosomal recessive disease in which repair of ultraviolet (UV)-induced DNA damage is impaired or is totally absent due to mutations in genes controlling the DNA repair pathway known as nucleotide excision repair (NER). XP is characterized, in part, by extreme sensitivity of the skin to sunlight, and XP patients have a more than 1000-fold increased risk of developing cancer at sun-exposed areas of the skin. To study the role of NER in chemical-induced tumorigenesis in more detail, the authors developed Xpa-/- homozygous knockout mice with a complete defect in NER (designated as Xpa mice or XPA model). Xpa mice develop skin tumors at high frequency when exposed to UV light, and as such, they mimic the phenotype of human XP. Moreover, the Xpa mice also appear to be susceptible to genotoxic carcinogens given orally. Based on these phenotypic characteristics, the Xpa mice were considered to be an attractive candidate mouse model for use in identifying human carcinogens. In an attempt to further increase both the sensitivity and specificity of the XPA model in carcinogenicity testing, the authors crossed Xpa mice with mice having a heterozygous defect in the tumor suppressor gene p53. Xpa/p53+/- double knockout mice develop tumors earlier and with higher incidences upon exposure to carcinogens as compared to their single knockout counterparts. Here the authors describe the development and features of the Xpa mouse and present some examples of the Xpa and Xpa/p53+/- mouse models' sensitivity towards genotoxic carcinogens. It appeared that the Xpa/p53+/- double knockout mouse model is favorable over both the Xpa and p53+/- single knockout models in short-term carcinogenicity testing. In addition to the fact that the double knockout mice respond more robustly to carcinogens, they also appear to respond in a very discriminative way. All compounds identified thus far are true (human) carcinogens, and, therefore, the authors believe that the Xpa/p53+/- mouse model is an excellent candidate for a future replacement of the chronic mouse bioassay, at least for certain classes of chemicals.

Xpa and Xpa/p53+/- knockout mice: overview of available data.

DNA repair deficient Xpa-/- and Xpa-/-/p53+/- knock-out mice in a C57BL/6 genetic background, referred to as respectively the XPA and XPA/p53 model, were investigated in the international collaborative research program coordinated by International Life Sciences Institute (ILSI)/Health and Environmental Science Institute. From the selected list of 21 ILSI compounds, 13 were tested in the XPA model, and 10 in the XPA/p53 model. With one exception, all studies had a duration of 9 months (39 weeks). The observed spontaneous tumor incidence for the XPA model after 9 months was comparable to that of wild-type mice (total 6%). For the XPA/p53 model, this was somewhat higher (9%/13% for males/females). The 3 positive control compounds used, B[a]P, p-cresidine, and 2-AAF, gave positive and consistent tumor responses in both the XPA and XPA/p53 model, but no or lower responses in wild-type mice. From the 13 ILSI compounds tested, the single genotoxic carcinogen (phenacetin) was negative in both the XPA and XPA/p53 model. Positive tumor responses were observed for 4 compounds, the immunosuppressant cyclosporin A, the hormone carcinogens DES and estradiol, and the peroxisome proliferator WY-14,643. Negative results were obtained with 5 other nongenotoxic rodent carcinogens, and 2 noncarcinogens tested. As expected, both DNA repair deficient models respond to genotoxic carcinogens. Combined with previous results, 6 out of 7 (86%) of the genotoxic human and/or rodent carcinogens tested are positive in the XPA model. The positive results obtained with the 4 mentioned nongenotoxic ILSI compounds may point to other carcinogenic mechanisms involved, or may raise some doubts about their true nongenotoxic nature. In general. the XPA/p53 model appears to be more sensitive to carcinogens than the XPA model.

Intestinal toxicity and carcinogenic potential of the food mutagen 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) in DNA repair deficient XPA-/- mice.

The effects of the food mutagen 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) were studied in DNA repair deficient XPA(-/-) mice. The nullizygous XPA-knockout mice, which lack a functional nucleotide excision repair (NER) pathway, were exposed to dietary concentrations ranging from 10 to 200 p.p.m. The results show that PhIP is extremely toxic to XPA(-/-) mice, even at doses 10-fold lower than tolerated by wild-type C57BL/6 mice. XPA(-/-) mice rapidly lost weight and died within 2 and 6 weeks upon administration of 200 and 100 p.p.m., respectively. Intestinal abnormalities like distended and overfilled ileum and caecum, together with clear signs of starvation, suggests that the small intestines were the primary target tissue for the severe toxic effects. Mutation analysis in XPA(-/-) mice carrying a lacZ reporter gene, indicated that the observed toxicity of PhIP might be caused by genotoxic effects in the small intestine. LacZ mutant frequencies appeared to be selectively and dose-dependently increased in the intestinal DNA of treated XPA(-/-) mice. Furthermore, DNA repair deficient XPC(-/-) mice, which are still able to repair DNA damage in actively transcribed genes, did not display any toxicity upon treatment with PhIP (100 p.p.m.). This suggests that transcription coupled repair of DNA damage (PhIP adducts) in active genes plays a crucial role in preventing the intestinal toxicity of PhIP. Finally, PhIP appeared to be carcinogenic for XPA(-/-) mice at subtoxic doses. Upon treatment of the mice for 6 months with 10 or 25 p.p.m. PhIP, significantly increased tumour incidences were observed after a total observation period of one year. At 10 p.p.m. only lymphomas were found, whereas at 25 p.p.m. some intestinal tumours (adenomas and adenocarcinomas) were also observed.

Effect of heterozygous loss of p53 on benzo[a]pyrene-induced mutations and tumors in DNA repair-deficient XPA mice.

XPA-deficient mice have a complete deficiency in nucleotide excision repair, and as such they display a cancer predisposition after exposure to several carcinogens. Besides being sensitive to genotoxic agents applied to the skin, they are also susceptible to human carcinogens given orally, like benzo[a]pyrene (B[a]P). To study the role of the tumor suppressor gene p53 in DNA repair, gene mutation, and tumor induction, we crossed XPA-deficient mice with p53 knockout mice and lacZ (pUR288) gene marker mice. When treated orally (by gavage) with B[a]P, the XPA(-/-)/p53(+/-) double transgenic mice developed tumors much earlier and with higher frequency compared to their single transgenic counterparts. The major tumor type found in all genotypes was generalized lymphoma mainly residing in the spleen; several sarcomas were observed in p53(+/-) and XPA(-/-)/p53(+/-) mice. Next, we determined lacZ mutation frequencies in several (non)target tissues. It appeared that in the spleen (the major tumor target tissue) of XPA(-/-) and XPA(-/-)/p53(+/-) mice the lacZ mutation frequency was significantly elevated (80-100 x 10(-5)), and was two times higher as found in spleens of B[a]P-treated WT and p53(+/-) mice (P = 0.003). In nontumor target tissues like liver and lung, we found a moderate increase in the lacZ gene mutation frequency (30-40 x 10(-5)), which was independent of the genotype. The results obtained with the DNA-repair deficient XPA mice indicate that a significantly increased lacZ mutation frequency in a particular organ/tissue is an early marker for tumor development at later stages at the same site. However, the synergistic effect of a XPA(-/-)- and a p53(+/-)-deficiency in tumor development is not reflected by an absolute increase in the lacZ mutation frequency in the major tumor target tissue of XPA(-/-)/p53(+/-) or p53(+/-) mice compared to that of XPA(-/-) and WT mice, respectively.

Mouse model for the DNA repair/basal transcription disorder trichothiodystrophy reveals cancer predisposition.

Patients with the nucleotide excision repair (NER) disorder xeroderma pigmentosum (XP) are highly predisposed to develop sunlight-induced skin cancer, in remarkable contrast to photosensitive NER-deficient trichothiodystrophy (TTD) patients carrying mutations in the same XPD gene. XPD encodes a helicase subunit of the dually functional DNA repair/basal transcription complex TFIIH. The pleiotropic disease phenotype is hypothesized to be, in part, derived from a repair defect causing UV sensitivity and, in part, from a subtle, viable basal transcription deficiency accounting for the cutaneous, developmental, and the typical brittle hair features of TTD. To understand the relationship between deficient NER and tumor susceptibility, we used a mouse model for TTD that mimics an XPD point mutation of a TTD patient in the mouse germline. Like the fibroblasts from the patient, mouse cells exhibit a partial NER defect, evident from the reduced UV-induced DNA repair synthesis (residual repair capacity approximately 25%), limited recovery of RNA synthesis after UV exposure, and a relatively mild hypersensitivity to cell killing by UV or 7,12-dimethylbenz[a]anthracene. In accordance with the cellular studies, TTD mice exhibit a modestly increased sensitivity to UV-induced inflammation and hyperplasia of the skin. In striking contrast to the human syndrome, TTD mice manifest a dear susceptibility to UV- and 7,12-dimethylbenz[a]anthracene-induced skin carcinogenesis, albeit not as pronounced as the totally NER-deficient XPA mice. These findings open up the possibility that TTD is associated with a so far unnoticed cancer predisposition and support the notion that a NER deficiency enhances cancer susceptibility. These findings have important implications for the etiology of the human disorder and for the impact of NER on carcinogenesis.

Evaluation of the Emu-pim-1 transgenic mouse model for short-term carcinogenicity testing.

The value of the chronic rodent carcinogenicity assay in adequately predicting cancer risk in humans has become a matter of debate over the past few years. Therefore, more rapid and accurate alternative tests are urgently needed. Transgenic mouse models, those harboring genetic changes that are relevant to the multistage cancer process, may provide such alternative tests. Transgenic Emu-pim-1 mice, developed by Berns and coworkers in 1989, contain the pimn-1 oncogene, which is expressed at elevated levels in their lymphoid compartments. As a result, these mice are predisposed to the development of T-cell lymphomas. Because of the low incidence of spontaneous tumors and the increased sensitivity to N-ethyl-N-nitrosourea-induced carcinogenesis, Emu-pim-1 mice were suggested to be one of the first potential and attractive candidates to be used in short-term carcinogenicity testing. In the present article, the results from 2 recent short-term assays (with mitomycin C and x-rays) are briefly presented, together with a review of all 11 performed bioassays and their corresponding histopathologic and molecular data. The overall results allow the first evaluation of the Emu-pim-1 mouse model with regard to its usefulness in short-term carcinogenicity testing. It has been shown that the model is primarily suitable as a sensitive short-term assay for genotoxic carcinogens that not only induce (at least) gene mutations and/or large deletions and rearrangements but that also sufficiently target the lymphoid system. However, the Emu-pim-1 mice lack sufficient sensitivity to justify their routine use in short-term carcinogenicity testing in general.

Use of DNA repair-deficient XPA transgenic mice in short-term carcinogenicity testing.

At present (putative) human carcinogens are identified via epidemiological studies and testing using the chronic 2-yr rodent bioassay. Both methods have severe limitations in that they are slow, insensitive, expensive, and are also hampered by many uncertainties. The development of methods to modify specific genes in the mammalian genome has provided promising new tools for use in identifying carcinogens and characterizing their (qualitative) risk. Several transgenic mouse lines are currently under study to test their possible use in short-term carcinogenicity testing. One such candidate alternative transgenic model is the XPA knock-out mouse. These mice have an almost complete deficiency in DNA nucleotide excision repair (NER). Nevertheless, XPA-deficient mice are viable and have a background of a low incidence of spontaneous development of cancers. Approximately 15% of the mice develop hepatocellular adenomas (only after 1.5 yr). After treatment with ultraviolet-B radiation or 7,12-dimethylbenz(a)anthracene, the XPA-deficient mice developed squamous cell carcinomas and papillomas, respectively, on their skin. Oral treatment of XPA-deficient mice with benzo[a]pyrene (B[a]P), 2-acetylaminofluorene (2-AAF), and 2-amino-1-methyl-6-phenylimidazo [4,5-b]-pyridine (PhIP) resulted in lymphomas (B[a]P), liver and bladder tumors (2-AAF), and intestinal adenomas plus lymphomas (PhIP). These results look encouraging, but it should be noted that the compounds and agents tested thus far have all been substrate for nucleotide excision repair. Animal studies with different genotoxic or nongenotoxic compounds, as organized for instance within the framework of the International Life Sciences Institute/Health and Environmental Sciences Institute program, are needed to further evaluate the suitability of the XPA model for short-term carcinogenicity testing.

Effects of dietary fat and a vegetable-fruit mixture on the development of intestinal neoplasia in the ApcMin mouse.

The variation in colorectal cancer (CRC) incidence worldwide strongly suggests a role for dietary influences. Based on epidemiological data, protective effects of vegetables and fruit intake on CRC are widely claimed, while other data indicate a possible increased CRC risk from (higher) dietary fat intake. Therefore, we have investigated single and interactive effects of dietary fat and a vegetable-fruit mixture (VFM) in the ApcMin mouse, a mouse model for multiple intestinal neoplasia. In this study, four different diets (A-D) were compared, which were either low in fat (20% energy diets A/B) or high in fat (40% energy diets C/D). In addition, 19.5% (wt/wt) of the carbohydrates in diets B and D were replaced by a freeze-dried VFM. The diets were balanced so that they only differed among each other in fat/carbohydrate content and the presence of specific plant-constituents. Because the initiation of intestinal tumors in ApcMin mice occurs relatively early in life, exposure to the diets was started in utero. Without the addition of VFM, mice maintained at a high-fat diet did not develop significantly higher numbers of small or large intestinal adenomas than mice maintained at a low-fat diet. VFM added to a low-fat diet significantly lowered multiplicity of small intestinal polyps (from 16.2 to 10.2/mouse, 15 animals/group), but not of colon tumors in male ApcMin mice only. Strikingly, addition of VFM to female mice maintained on a low-fat diet and to both sexes maintained on a high-fat diet significantly enhanced intestinal polyp multiplicity (from 16.5 to 26.7 polyps/mouse). In conclusion, our results indicate that neither a lower fat intake nor consumption of VFM included in a high-fat diet decreases the development of polyps in mice genetically predisposed to intestinal tumor development.

The effect of soy isoflavones on the development of intestinal neoplasia in ApcMin mouse.

Data from epidemiological studies suggest that isoflavones in soy may have a protective effect on the development of colon cancer in humans. Therefore, we have investigated whether soy isoflavones will inhibit intestinal tumour development in Apc(Min) mice. The mice were fed a Western-type high risk diet (high fat, low fibre and calcium) containing two different isolates of soy protein as a protein source. For the control and test groups this resulted in the administration of about 16 and 475 mg of total isoflavones per kg diet, respectively. As a positive control. a third group of mice was administered a low isoflavone diet supplemented with 300 ppm sulindac. No significant differences in the incidence, multiplicity, size and distribution of intestinal tumours were observed between Min mice fed low and high isoflavone-containing diets. However, a clear reduction in the number of small intestinal tumours was observed for the sulindac diet. Thus, in contrast to epidemiological studies, our results demonstrate that high amounts of soy isoflavones present in a Western-type high risk diet do not protect against intestinal tumour development in a relevant animal model such as the Min mice.

XPA-deficiency in hairless mice causes a shift in skin tumor types and mutational target genes after exposure to low doses of U.V.B.

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.

Defective transcription-coupled repair in Cockayne syndrome B mice is associated with skin cancer predisposition.

A mouse model for the nucleotide excision repair disorder Cockayne syndrome (CS) was generated by mimicking a truncation in the CSB(ERCC6) gene of a CS-B patient. CSB-deficient mice exhibit all of the CS repair characteristics: ultraviolet (UV) sensitivity, inactivation of transcription-coupled repair, unaffected global genome repair, and inability to resume RNA synthesis after UV exposure. Other CS features thought to involve the functioning of basal transcription/repair factor TFIIH, such as growth failure and neurologic dysfunction, are present in mild form. In contrast to the human syndrome, CSB-deficient mice show increased susceptibility to skin cancer. Our results demonstrate that transcription-coupled repair of UV-induced cyclobutane pyrimidine dimers contributes to the prevention of carcinogenesis in mice. Further, they suggest that the lack of cancer predisposition in CS patients is attributable to a global genome repair process that in humans is more effective than in rodents.

Spontaneous liver tumors and benzo[a]pyrene-induced lymphomas in XPA-deficient mice.

Defects in the xeroderma pigmentosum complementation group A-correcting (XPA) gene, which encodes a component of the nucleotide excision repair (NER) pathway, are associated with the cancer-prone human disease xeroderma pigmentosum. We previously generated mice lacking the XPA gene, which develop normally but are highly sensitive to ultraviolet-B and 7,12-dimethylbenz[a] anthracene-induced skin tumors. Here we report that XPA-deficient mice spontaneously developed hepatocellular adenomas at a low frequency as they aged. Furthermore, oral treatment of XPA-deficient mice with the carcinogen benzo[a]pyrene (B[a]P) resulted in the induction of mainly lymphomas. These tumors appeared earlier and with a higher incidence than in B[a]P-treated wild-type and heterozygous mice. Our results show for the first time that XPA-deficient mice also displayed an increased sensitivity to developing tumors other than tumors of the skin.

The role of UV-B light in skin carcinogenesis through the analysis of p53 mutations in squamous cell carcinomas of hairless mice.

Mutation spectra of the p53 gene from human skin carcinomas have been connected to solar UV radiation. For comparison we have characterized the mutation spectrum of the p53 gene in a very large sample of squamous cell carcinomas from hairless mice induced with UV of wavelength 280-320 nm (UV-B), which have substantiated the mutagenic effects of UV-B radiation in vivo. Tumors from hairless mice, random bred SKH:HR1 as well as inbred SKH:HRA strains, which are analyzed for mutations in the conserved domains of the p53 protein present a very specific mutation spectrum. The observed mutation frequency after chronic UV-B radiation in the p53 gene ranged from 54% (SKH-HRA) to 73% (SKH-HR1) among the 160 tumors analyzed. Over 95% of the mutations were found at dipyrimidine sites located in the non-transcribed strand, the majority were C-->T transitions and 5% were CC-->TT tandem double mutations. Four distinct UV-B mutation hot spots have been identified for the first time: two major ones at codons 267 (33%) and 272 (19%) and two minor ones at codons 146 (10%) and 173 (4%). The codon 267 hot spot consists of a CpG preceded by a pyrimidine, which confirms in vivo an important role for this UV-B mutable site in UV-B-induced skin tumors that is not found in other types of mouse tumors. Comparison with mutation spectra from human skin carcinomas fully validates the merits of the hairless mouse model for studying the molecular mechanisms of skin carcinogenesis. For example, the murine hot spot at codon 272 does have a full equivalent in human skin carcinomas. In contrast, the human equivalent of the murine codon 267 lacks the dipyrimidine site and therefore fails to be a pronounced hot spot in human skin carcinomas; however, this site is one of the major hot spots in human internal cancers (evidently not induced by UV radiation but probably by deamination of the 5 methyl cytosine).

Use of E mu-PIM-1 transgenic mice short-term in vivo carcinogenicity testing: lymphoma induction by benzo[a]pyrene, but not by TPA.

E mu-pim-1 transgenic mice are predisposed to develop lymphomas. Due to their low spontaneous tumour incidence and their increased sensitivity towards the lymphomagen ethylnitrosourea these mice may present an interesting model for short-term carcinogenicity testing. Here, we report on the further exploration of this transgenic mouse model with two additional carcinogens known to have, among others, the lymphohaematopoietic system as target, i.e. benzo[a]pyrene (B[a]P) and 12-O-tetradecanoylphorbol-13-acetate (TPA). B[a]P, given three times a week (by gavage) for 13 weeks at 4.3, 13 or 39 mg/kg body weight, resulted in a dose-related increase in lymphomas up to a 90% incidence in E(mu)-pim-1 mice during the observation period of 40 weeks. B[a]P also induced tumours of the forestomach within this observation period, though at a lower incidence and apparently equally effective in wildtype and transgenic mice. TPA, on the other hand, was unable to induce lymphomas (or tumours in any other organ) in either transgenic or wildtype animals within the observation period of 44 weeks, when applied dermally at the maximum tolerated dose of 3 microg/mouse, twice a week for 35 weeks. Molecular analysis showed that B[a]P-induced lymphomas in transgenic mice were of T-cell origin, 80% of which had elevated levels of c-myc expression. None of the lymphomas had increased N-myc expression and mutation analysis of the ras-gene family revealed a K-ras mutation in only one out of eight tumours investigated. Also, none of the lymphomas showed aberrant expression of p53 as determined by immunohistochemistry. It is concluded that the E mu-pim-1 mouse model will not be very suitable for short-term carcinogenicity testing in general: only genotoxic chemicals that have the lymphohaematopoietic system as target for carcinogenesis in wild-type mice, appear to be efficiently identified.

Low incidence of p53 mutations in UVA (365-nm)-induced skin tumors in hairless mice.

Mutations with clear "UVB fingerprints" have been observed in the p53 gene of human nonmelanoma skin tumors and of experimentally UVB-induced murine skin tumors. Although UVA (315-400 nm) radiation is also a complete carcinogen, its contribution to sunlight-induced mutagenesis remains poorly characterized. There is experimental evidence that the production of reactive oxygen species plays a more dominant role with long-wave UVA than with UVB radiation. We have induced skin tumors (n = 42) in hairless SKH:HR1 mice (n = 14) by daily exposure to long-wave UVA (365-nm) radiation. The incidence of p53 alterations in these tumors is low compared to UVB-induced tumors; positive staining for the p53 protein was observed in only 50% of the tumors, and less than 15% of the tumors showed a mutation in one of the exons 5, 7, or 8 of the p53 gene. The pattern of p53 staining was more irregular and less dense compared to UVB, and the mutations (all C-->T) were mainly (six of seven) located at codon 267. Besides a general p53 hotspot, this codon is also the main hotspot for UVB-induced skin tumors in these mice. No mutations specific for UVA, ie., mutations specific for reactive oxygen species, could be detected.

Induction of DNA adducts and mutations in spleen, liver and lung of XPA-deficient/lacZ transgenic mice after oral treatment with benzo[a]pyrene: correlation with tumour development.

We were interested to study the relationship between DNA lesions, DNA repair, mutation fixation, and tumour development. Therefore, mice harbouring lacZ reporter genes and being either wild-type or defective in the DNA excision repair gene XPA, were treated with the genotoxic carcinogen benzo[a]pyrene at an oral dose of 13 mg/kg b.w. (3 times/week). At different time points, i.e. 1, 5, 9 or 13 weeks after start of the oral administration, levels of BPDE-N2-dG adducts (the major formed DNA adduct by benzo[a]pyrene in mice), and lacZ mutation frequencies were measured both in target (spleen) and non-target (lung and liver) tissues. Both in wild-type and XPA-deficient mice, benzo[a]pyrene treatment resulted in increased BPDE-N2-dG adduct levels in all three tissues analysed. In XPA-deficient mice, BPDE-N2-dG adduct levels still increased up to 13 weeks of oral benzo[a]pyrene treatment, whereas in DNA repair proficient mice steady-state levels were reached after 5 weeks of treatment. After 13 weeks, the BPDE-N2-dG adduct levels observed in XPA-/- mice, were 2- to 3-fold higher than the steady state levels observed in XPA+/+ mice in the same tissues. Mutation frequencies in the lacZ reporter gene were the same in wild-type and XPA-deficient mice that were treated with the solvent only. Oral benzo[a]pyrene treatment resulted in an increase in mutation frequency in the lacZ marker gene in all three tissues, but this increase was most profound in the spleen. After 13 weeks of treatment, a 7-fold increase in lacZ mutation frequency was detected in the spleen of wild-type mice as compared to mutation frequencies in control mice. At the same time point, a 15-fold increase in lacZ mutation frequency was observed in the spleen of XPA-deficient mice. The data presented here show, that a defect in NER mainly results in enhanced mutation frequencies in lymphocytic cells after oral treatment with the genotoxic compound benzo[a]pyrene. Interestingly, as we established in a previously performed carcinogenicity assay, the same oral treatment with benzo[a]pyrene induced lymphomas residing in the spleen of XPA-deficient mice.

Early p53 alterations in mouse skin carcinogenesis by UVB radiation: immunohistochemical detection of mutant p53 protein in clusters of preneoplastic epidermal cells.

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, approximately 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.

Increased susceptibility to ultraviolet-B and carcinogens of mice lacking the DNA excision repair gene XPA.

Xeroderma 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. Nucleotide-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. 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-/-mice appear normal, at least until the age of 13 months. XPA-/-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.

Frequent p53 alterations but low incidence of ras mutations in UV-B-induced skin tumors of hairless mice.

We have investigated UV-B-induced skin tumors of hairless SKH-HRA mice for alterations in the p53 gene and for mutations in either of the three ras genes. Out of 32 tumors screened, only one contained a ras mutation, i.e. in codon 12 of the K-ras gene. Alterations in the p53 gene were much more abundant, as illustrated immunohistochemically by the accumulation of p53 protein in 75% of the tumor sections examined. Immunoreactivity was observed primarily in the proliferative cell compartment, but no clear correlation between p53 staining in tumor cells and histological parameters for malignancy was observed. Subsequent sequence analysis showed that point mutations in the p53 gene are detectable in 30% (nine out of 30) of the skin tumors examined. The majority of the mutations are located in codons 267 and 272, most likely originating from UV-B-induced photo-adducts at dipyrimidine sites in the non-transcribed strand. Codon 272 corresponds to the human codon 278, which is also a hotspot for p53 mutations in human non-melanoma skin cancers. Codon 267 matches the human codon 273, which does not contain a dipyrimidine site, but represents a CpG hotspot for p53 mutations in internal malignancies. Our results demonstrate that this hairless mouse model for UV-induced skin cancer corresponds closely to human non-melanoma skin cancers with respect to mutations in the p53 gene.