Tumor profile of novel p53 heterozygous Tg.AC (v-Ha-ras) bitransgenic mice treated with benzo(a)pyrene and fed dietary N-acetyl-L-cysteine (NAC).

We designed a novel short-term bitransgenic model to better characterize the effects of benzo(a)pyrene (BP) exposure on multi-organ carcinogenesis and to evaluate the effects of a well-recognized antioxidant, N-acetyl-L-cysteine (NAC), on neoplasia. We selected the p53 heterozygous Tg.AC (v-Ha-ras) mouse model for our studies because these mice possess a carcinogen-inducible ras oncogene and one functional p53 tumor suppressor allele. Both mutations occur frequently in human cancers. In a 2 x 2 experimental design, both female and male mice were fed basal diet alone or containing 3% NAC and administered by gavage corn oil vehicle alone or containing 20 mg BP/kg body weight given twice weekly for 10 weeks. Mice (n = 15 for each grouping and sex) were subsequently observed an additional 18 weeks followed by tissue collection for evaluation of multi-organ pathology. Benzo(a)pyrene increased neoplasia in the thymus, spleen, stomach, and hematopoietic system after 28 weeks. We observed modest NAC-associated decreases in BP-induced pathology of the liver, papilloma formation and hyperplasia in the forestomach, and the occurrence of malignant lymphoma. Benzo(a)pyrene exposure reduced survival to approximately 40% in male mice, suggesting toxicity; however, survival in control groups was approximately 60%. Survival decreased to approximately 30% for females in all groups. We noted a clear, but nonsignificant, 15% decline in body weights of male, but not female, mice fed NAC, although food intake did not differ. Collectively, the data suggested carcinogen and antioxidant-associated effects on neoplasia that appeared sex-dependent. Thus, this novel short-term bitransgenic model may potentially be useful for testing dietary modulation of carcinogenesis.

Tumor spectrum in the p53 heterozygous zeta globin-promoted Tg.AC (v-Ha-ras) bitransgenic mouse model.

The use of a bitransgenic mouse model for cancer is an effective approach for studying the impact of specific carcinogens and the occurrence of tissue-specific lesions. We studied the novel p53 heterozygous zeta globin-promoted Tg.AC (v-Ha-ras) mouse model because these mice contain a carcinogen-inducible ras oncogene and one functional p53 tumor suppressor allele, both of which occur frequently in human cancers. Our aim was to characterize the short-term control and chemically induced tumor spectrum in this novel model. Mice were placed on basal semipurified diet containing 20% soy protein for 2 weeks prior to random allocation to groups. Subsequently, 15 male and 15 female mice were administered corn oil vehicle alone or containing benzo(a)pyrene (20 mg/kg body weight) via oral gavage 2 times per week for 10 weeks with subsequent observation for 18 weeks. Mice exhibited lesions characteristic of FVB/N, p53 heterozygous and Tg.AC mouse models. However, an array of unique, novel lesions were observed including uterine leiomyosarcomas, mammary gland carcinomas, mammary squamous cell carcinomas, and parotid salivary gland carcinomas suggesting tissue-specific interactions of the 2 genotypes. Thus, this bitransgenic model may provide further insight into the mechanistic interaction of 2 genes commonly mutated in neoplasia.

Timing of supplementation with the antioxidant N-acetyl-L-cysteine reduces tumor multiplicity in novel, cancer-prone p53 haploinsufficient Tg.AC (v-Ha-ras) transgenic mice but has no impact on malignant progression.

Epidemiological studies support the protective role of dietary antioxidants in preventing cancer. However, emerging evidence suggests that antioxidant supplements may actually exacerbate carcinogenesis. We explored this paradox in a model containing two common genotypic characteristics of human cancers. We selected p53 haploinsufficient Tg.AC (v-Ha-ras) mice as a model, because it contains an activated, carcinogen-inducible ras oncogene and an inactivated p53 tumor suppressor gene. These mice develop chemically induced benign and malignant skin tumors rapidly. Mice were fed basal diet with or without 3% N-acetyl-L-cysteine (NAC) before and after topical application of the carcinogen benzo[a]pyrene (64 micrograms twice per week for 7 wk) until 50% of mice within a group displayed at least one lesion. Half each of mice fed the basal and the NAC-supplemented diet were then switched to the alternate diet. Mice fed the NAC-supplemented diet or switched from the NAC-supplemented to the basal diet displayed 38% and 26% reductions, respectively, in tumor multiplicity and a 15% reduction if switched from the basal to the NAC-supplemented diet. Although latency was unaffected, NAC induced a lag in tumor incidence, which exceeded 90% at 10 wk for all groups. The timing of NAC supplementation did not affect malignant progression. Thus dietary NAC was chemoprotective by slowing tumorigenesis but did not affect malignant conversion.