Examination of percutaneous application in a 26-week carcinogenicity test in CB6F1-TG rasH2 mice.

We examined the possibility of expanding applications of rasH2 mice, which are genetically manipulated mice for short-term carcinogenicity tests, to percutaneous application. A 26-week short-term carcinogenicity study was performed on a total of 300 mice including 75 male and female rasH2 mice each, and 75 male and female non-Tg mice each from the same litter as the rasH2 mice divided into untreated group, an ethanol group, a white Vaseline group, an acetone group, and a phorbol 12-myristate 13-acetate (TPA) group. Only shaving of dorsal skin was performed on the untreated mice. As a positive control, TPA was administered percutaneously at a dose of 2.5 microg/kg and 3 times/week for 26 weeks based on the protocol for Tg.AC mice in the ILSI/HESI international validation study. In the ethanol, white Vaseline, and acetone groups, no tumorous changes were observed on the skin at the administration site. In the TPA group, nodular changes at the administration site were observed from seven weeks after the start of administration in rasH2 mice, and the incidence in males and females was 50.0% (7/14) and 53.3% (8/15), respectively. In a pathological examination, nodules in 21.4% (3/14) of males and 46.7% (7/15) of females were diagnosed as skin papilloma or keratoacanthoma, and the rest as squamous cell hyperplasia. In the non-Tg mice, no nodules or tumorigenic changes were observed at the administration site. These findings show that percutaneous application in rasH2 mice is possible in 26-week carcinogenicity tests.

Use of IC tags in short-term carcinogenicity study on CB6F1 TGrasH2 mice.

We studied the effect of IC tags, subcutaneously implanted animal identification tools, on rasH2 mice. A 26-week short-term carcinogenicity study was performed on a total of 299 mice including 75 male and female rasH2 mice each, and 74 male and 75 female non-Tg mice from the same litter as the rasH2 mice divided into a non-IC tag group, the IC-tag group, acetone group, TPA group and MNU group (all of the animals except for those in the non-IC tag group) had IC tags implanted subcutaneously in their backs. The administration methods of the positive control drugs TPA (2.5 micro g/kg, 3 times/week, percutaneously) and MNU (75 mg/kg, single intraperitoneal injection) were based on the protocol of the ILSI/HESI international collaborative study. The results showed no differences in the tumorigenic incidence and organs developing tumors between the IC tag and non-IC tag groups in both rasH2 and non-Tg mice. In the positive control MNU group, the tumorigenic incidence and organs developing tumors were the same as the background data and no promotion of carcinogenesis was observed. In all IC tag groups including the TPA group and MNU group, a fibrous capsule was formed around the IC tags subcutaneously, but no inflammatory changes or neoplastic changes were observed. From these findings, it was concluded that the IC tag has no effect on a 26-week carcinogenicity test of rasH2 mice under the conditions of the present study.

Lack of susceptibility of heterozygous p53-knockout CBA and CIEA mice to phenolphthalein in a 6-month carcinogenicity study.

Phenolphthalein has carcinogenic activity, causing malignant lymphomas in B6C3F1 mice at a dietary dose of 3000 ppm in a 2-year carcinogenicity study and in female heterozygous p53-knockout TSG mice (C57BL/6 background) at the same dose in a 6-month study. To examine whether carcinogenic potential of phenolphthalein can be detected in other p53-knockout mouse [p53 (+/-)] strains such as p53 (+/-) CBA mice or p53 (+/-) CIEA mice (C57BL/6 background) and their littermates, they were given a diet containing 0, 6000 or 12000 ppm for 6 months. Unequivocal induction of neoplastic lesions was not apparent, suggesting that p53 (+/-) CBA mice and p53 (+/-) CIEA mice are resistant to the induction of malignant lymphomas by the treatment of phenolphthalein.

Mutation analysis of vinyl carbamate or urethane induced lung tumors in rasH2 transgenic mice.

Previous studies showed that significant differences in mutation frequency of the human c-Ha-ras transgene between vinyl carbamate (VC)- and ethyl carbamate (urethane)-induced lung tumors were observed in rasH2 mice. It remains unclear why the point mutation frequency is extremely low in VC-induced lung tumors, although this compound is much more carcinogenic than urethane. In this study, we examined the somatic point mutations of the transgene at the RNA level in VC- and urethane-induced lung tumors of rasH2 mice. We did not find any mutation at codon 12 of the transgene in any of these lung tumors, but codon 61 showed frequent mutations in not only urethane-induced lung tumors (15 out of 16) but also VC-induced lung tumors (11 out of 11) in rasH2 mice. These results suggested that point mutations at codon 61 of the transgene play an important role in the carcinogenesis of VC- and urethane- induced lung tumors in rasH2 mice.

Carcinogenic comparative study on rasH2 mice produced by two breeding facilities.

CByB6F1-Tg(HRAS)2Jic mice (brand name: rasH2 mouse) are produced by two breeding facilities, CLEA Japan, Inc. (Fuji, Shizuoka, Japan) and Taconic (Germantown, NY, USA), and supplied world wide. To confirm carcinogenic conformity of both mice, a 26-week carcinogenicity test was performed on a total of 120 mice obtained from both facilities under the same protocol and same timing in our facility. All mice were divided into a vehicle (citrate buffer at pH 4.5, 10 ml/kg, single intraperitoneal injection) group and a MNU (N-methyl-N-nitrosourea, 75 mg/kg, single intraperitoneal injection) group. Fifteen mice of each sex were assigned to each group. The survival rate of the vehicle group was maintained at 100% for mice from both facilities at completion of the test. In the MNU group, MNU-induced tumor death occurred from 9 to 12 weeks after administration, and the final survival rate for both facilities was 6.7%. In the pathological examination, only benign tumors of lungs, spleen, forestomach and skin were observed in a few mice in the vehicle group of both facilities. In the MNU group, the incidence of forestomach papilloma/squamous cell carcinoma in mice from both facilities was 100%. The incidences of malignant lymphoma in CLEA Japan mice and Taconic mice were 86.7% and 93.3%, respectively, and no significant difference was observed (Fisher's exact probability test). Although lung adenoma and skin papilloma/keratoacanthoma, which are major MNU induced tumors in this strain, were observed in several mice from both facilities, no significant differences were found. Consequently, carcinogenic conformity of rasH2 mice derived from two breeding facilities was confirmed by the present study.

Phenotypic abnormalities observed in aged cloned mice from embryonic stem cells after long-term maintenance.

Somatic/embryonic stem cell cloning has made it possible to produce an individual genomically identical to another individual. However, the cloned animals have a variety of abnormalities caused by the aberrant gene modification, with insufficient reprogramming in cloning. We previously reported abnormalities in cloned mice at birth. In this study, we examined what abnormalities could be seen in cloned mice after long-term maintenance. The aged cloned mice showed multiple abnormalities: increase of body weight, some phenotypic abnormalities in the kidneys, testes and thymus, and lower urea nitrogen in their serum biochemical values. The kidneys of all cloned mice were hypertrophied, with a metamorphic or whitish appearance. The multiple lesions, including the enlarged renal pelvis and distension of the renal veins in histology, might be the result of urine accumulation by urinary tract obstruction. The testes of the cloned mice were atrophied, and showed no sperm formation in histology. In contrast, the thymus was rather hypertrophied, and a comparably increased number of lymphocytes were observed in the medulla, consisting mainly of T cells. By conducting a progeny test between the cloned mice, it was confirmed that these abnormalities in the aged cloned mice were not transmitted to their offspring, indicating that the incomplete reprogramming in clones might be in part responsible for the abnormalities detected in aged clones. These results indicate that the postnatal abnormalities observed in aged cloned mice are varied and can be restored through the germ line.

The Tg rasH2 mouse in cancer hazard identification.

The Tg rasH2 transgenic mouse has been developed as an altemative to the lifetime mouse bioassay to predict the carcinogenic potential of chemicals. Unlike the p53+/- mouse, the Tg rasH2 mouse is sensitive to both genotoxic and nongenotoxic carcinogens. The Tg rasH2 mouse, officially designated CB6F1-TgN (RasH2), contains multiple copies of the human c-Ha-ras oncogene and promoter within its genome. These mice develop spontaneous andchemically inducedneoplasms earlierin life and in greaternumbersthan wild-type mice, reflectingtheirenhanced sensitivity to neoplasia. The most common spontaneous neoplasms in control Tg rasH2 mice 8 to 9 months of age are lung adenomas and carcinomas (7.4% incidence), splenic hemangiomas and hemangiosarcomas (5.4%), forestomach squamous cell papillomas and carcinomas (2.4%), and skin neoplasms (1.2%). Simulations have demonstrated that 20 to 25 mice/sex/treatment group are required to provide the assay with adequate statistical power. Four of 6 known or suspected human carcinogens tested in Tg rasH2 mice were positive in this assay. For 19 nonmutagenic agents testing positive in conventional rodent bioassays, 7 chemicals were positive, 10 chemicals were negative, and 2 were equivocal. None of the 10 nonmutagenic rodent carcinogens that were negative in the Tg rasH2 mouse model are considered to be human carcinogens. All nonmutagenic chemicals that were negative in the conventional rodent bioassays were also negative in the Tg rasH2 model. Results for 15 of 18 mutagenic chemicals tested in Tg rasH2 mice agreed with the results of conventional rodent bioassays, and 3 results were equivocal. The Tg rasH2 mouse model appears to predict known or suspected human carcinogens as well as the traditional mouse bioassay, but with fewer positive results for nongenotoxic compounds that are not considered human carcinogens. The Tg rasH2 mouse model is the most thoroughly tested in vivo altemative to the lifetime mouse bioassay for nongenotoxic compounds administered by oral or parenteral routes. The U.S. FDA Carcinogenicity Assessment Committee has determined that the Tg rasH2 model has been adequately evaluated for consideration for carcinogenicity testing of pharmaceutical candidates and its use could contribute to the weight of evidence for carcinogenicity assessment. The FDA will consider proposals to replace lifetime mouse carcinogenicity studies with 6-month Tg rasH2 mouse studies to support pharmaceutical registration on a case-by-case basis.

Skeletal myopathy in transgenic mice carrying human prototype c-Ha-ras gene.

Skeletal myopathy was found in almost all-transgenic mice carrying the human prototype c-Ha-ras gene (rasH2 mouse). Microscopically, variation of the muscle fiber size, centrally placed nuclei, regenerating fibers, and interstitial fibrosis were evident; hyalinization and necrosis were sometimes observed in the skeletal muscle (femoralis and pectoralis) of the rasH2 mice. Inflammatory changes in the skeletal muscle or abnormality of adjacent peripheral nerve were not observed. The features were essentially similar to those of muscular dystrophy. Although the severity was relatively mild compared to 34-week-old rasH2 mice, the skeletal myopathy was also observed in younger male (10 weeks of age) rasH2 mice. In nontransgenic littermates, skeletal myopathy was not observed. The mRNA of human c-Ha-ras product was detected in femoral muscle from the rasH2 mice by RT-PCR. In conclusion, these data suggest that skeletal myopathy is occurring in almost all rasH2 mice. Integration of c-Ha-ras gene is thought to be crucial to pathogenesis of skeletal myopathy in the rasH2 mice. Further characterization of the muscular lesion and its pathogenesis are needed to explore the possibility of rasH2 mouse becoming a new model for muscular dystrophy.

Interlaboratory comparison of short-term carcinogenicity studies using CB6F1-rasH2 transgenic mice.

In order to evaluate a short-term carcinogenicity testing system using CB6F1 -Tg rasH2 (rasH2-Tg) mice carrying a human prototype c-Ha-ras gene, 26-week studies were conducted in 12 different facilities as a part of an International Life Science Institute Health and Environmental Science Institute (ILSI HESI) international collaborative project. In each study N-methyl-N-nitrosourea (MNU) was administered to a separate group of rasH2-Tg mice by single intraperitoneal injection (75 mg/kg) as a positive control. We herein have summarized the mortality, body weight change, and neoplastic and nonneoplastic lesions detected in these positive control groups as representative historical positive control data. Also, we performed an interlaboratory comparison of the response of rasH2-Tg mice to MNU based on the data of 11 positive control groups from these studies. Although the body weight of rasH2-Tg mice showed lower values than that of non-Tgmice during the experimental period, body weight gain in the rasH2-Tg mice was similar to that in non-Tg mice. The mortality of rasH2-Tg mice during the study period was very low, the same as for the non-Tg mice. Incidences of spontaneous alveolar/bronchiolar adenomas and splenic hemangiomas/hemangiosarcomas were also low in the rasH2-Tg mice. Nonneoplastic lesions detected in the rasH2-Tg mice were similar to those in non-Tg mice, excluding the incidence of myopathy. There were interlaboratory differences in mortality and incidence of some lesions in the MNU-treated groups. However, the causes of death were common among the 11 laboratories and almost all the MNU-treated rasH2-Tg mice developed forestomach squamous cell papillomas/carcinomas or malignant lymphomas. This suggests that there is no appreciable difference in the response of the rasH2-Tg mouse to MNU used as a positive control. Therefore, it is concluded that MNU would be an adequate positive control compound in this testing system.