Mutagenicity of 11 cigarette smoke condensates in two versions of the mouse lymphoma assay.

Cigarette smoke condensate (CSC) is genotoxic in nearly all assays in which it has been tested. In this study, we investigated the mutagenicity of 11 CSCs using the microwell and soft-agar versions of the mouse lymphoma assay (MLA). These CSCs were prepared from commercial or experimental cigarettes, 10 of them were produced using International Organisation for Standardisation (ISO) conditions and one CSC was generated using intense Massachusetts Department of Public Health (MDPH) conditions. In the presence of rat liver S9, the L5178Y/Tk(+/-) mouse lymphoma cells were treated with 11 CSCs at different concentrations (25-200 µg/ml) for 4 h. All CSCs resulted in dose-dependent increases of both cytotoxicity and mutagenicity in both versions of the MLA. The mutagenic potencies of the CSCs were calculated as mutant frequency per microgram CSC from the slope of the linear regression of the dose-response curves and showed no correlations with the tar yield of the cigarette or nicotine concentrations of the CSCs. Comparing two CSCs produced from the same commercial cigarettes using two different smoking conditions, the one generated under ISO conditions was more mutagenic than the other generated under intense conditions on a per microgram CSC basis. We also examined the loss of heterozygosity (LOH) at four microsatellite loci spanning the entire chromosome 11 for the mutants induced by 11 CSCs. The most common type of mutation observed was LOH with chromosome damage spanning less than ∼34 Mbp. These results indicate that the MLA identifies different genotoxic potencies among a variety of CSCs and that the results from both versions of the assay are comparable.

ACB-PCR quantification of K-RAS codon 12 GAT and GTT mutant fraction in colon tumor and non-tumor tissue.

K-RAS mutation is being developed as a cancer biomarker and tumor K-RAS is being used to predict therapeutic response. Yet, levels of K-RAS mutation in normal and pathological tissue samples have not been determined rigorously, nor inter-individual variation in these levels characterized. Therefore, K-RAS codon 12 GAT and GTT mutant fractions were measured in colonic mucosa of individuals without colon cancer, tumor-distal mucosa, tumor-proximal mucosa, normal tumor-adjacent tissues, colonic adenomas, and carcinomas. The results indicate K-RAS codon 12 GAT mutation is present at measurable levels in normal appearing mucosa. All tumors carried K-RAS mutation, in most cases as a mutant subpopulation.

Populations of p53 codon 270 CGT to TGT mutant cells in SKH-1 mouse skin tumors induced by simulated solar light.

The p53 codon 270 CGT to TGT mutation was investigated as a biomarker of sunlight-induced mutagenesis and carcinogenesis. The relationship between tumor development and abundance of this hotspot mutation was analyzed in mouse skin tumors induced by chronic exposure to simulated solar light (SSL). The 24 tumors analyzed had similar growth kinetics, with an average doubling time of approximately 16.4 d. Levels of the p53 codon 270 mutation were quantified in the 24 mouse skin tumors using allele-specific competitive blocker-polymerase chain reaction (ACB-PCR). All tumors contained measurable amounts of the mutation. The p53 codon 270 CGT to TGT mutant fraction (MF) ranged from 2.29 x 10(-3) to 9.42 x 10(-2), with 3.26 x 10(-2) as the median. These p53 MF measurements are lower than expected for an initiating mutation involved in the development of tumors of monoclonal origin. There was no evidence of a correlation between p53 codon 270 MF and either tumor area or an estimate of tumor cell number. Thus, the data do not support the idea that p53 mutation accumulates linearly during tumor development. To investigate how p53 mutation was distributed within tumors, 19 needle biopsies from seven different tumors were analyzed by ACB-PCR. This analysis demonstrated that p53 codon 270 mutation is heterogeneously distributed within tumors. The long-term goal of this research is to combine morphological and p53 MF measurements from tissues corresponding to the various stages of tumor development, in order to derive mathematical models relating the p53 codon 270 mutation to the development of SSL-induced skin tumors.

Simulated solar light-induced p53 mutagenesis in SKH-1 mouse skin: a dose-response assessment.

Sunlight and ultraviolet-induced mutation of the p53 gene is a frequent, possibly obligate step in skin cancer development, making quantitative measurement of p53 mutation an ideal biomarker for sunlight-induced skin carcinogenesis. To understand how the appearance of p53 mutation relates to skin tumor development, SKH-1 hairless mice were exposed 5 d per week to one of four different doses of simulated solar light (SSL; 0, 6.85, 13.70, 20.55 mJ x CIE/cm(2)) previously characterized for their tumorigenic potential. Allele-specific competitive blocker-PCR (ACB-PCR) was used to measure levels of p53 codon 270 CGT to TGT mutation within DNA isolated from dorsal skin of exposed mice. For each dose, p53 mutant fraction (MF) was measured after 4, 16, and 28 wk of exposure. Significant dose- and time-dependent increases in p53 MF were identified. All p53 MF measurements were integrated by relating the observed p53 MF to the cumulative dose of SSL. The increase in the logarithm of p53 MF was described by the linear function: log(10) MF = alpha + 0.0016 x d, where alpha is the spontaneous log(10) MF after a particular time point and d is the dose of SSL in mJ x CIE/cm(2). The p53 MF induced in nontumor bearing skin by 28 wk of exposure at the high dose of SSL was significantly lower than that found in skin tumors induced by approximately 32 wk of exposure to the same dose of SSL. p53 MF showed a strong negative correlation with tumor latency, suggesting this quantitative biomarker has the potential to predict tumorigenicity.

Quantifying levels of p53 mutation in mouse skin tumors.

Allele-specific competitive blocker PCR (ACB-PCR) amplification and quantification was developed for mouse p53 codon 270 CGT-->TGT base substitution and codon 244/245 AAC/CGC-->AAT/TGC tandem mutation. PCR products corresponding to p53 mutant and wild-type DNA sequences were generated. These DNAs were mixed in known proportions to construct samples with defined mutant fractions and the allele-specific detection of each mutation was systematically optimized. Each assay was used to analyze eight simulated solar light (SSL)-induced tumors. By analyzing mutant fraction (MF) standards in parallel with PCR products generated from tumor samples, p53 mutants could be quantified as subpopulations within the tumors. All eight tumors contained detectable levels of p53 codon 270 CGT-->TGT mutation. Three tumors had p53 MFs between 10(-4) and 10(-3). Five tumors had p53 MFs between 10(-3) and 10(-2). None of the eight mouse skin tumors had measurable levels of p53 codon 244/245 tandem mutation. Frequent detection of p53 codon 270 CGT-->TGT mutation provides additional evidence that a pyrimidine dinucleotide overlapping a methylated CpG site (Pyr(me)CG) is a susceptible target for SSL-induced mutagenesis. The absence of p53 codon 244/245 mutation in tumors may be explained by its mutant p53 phenotype and/or indicate that this site is not methylated. These initial results indicate that p53 codon 270 CGT-->TGT mutation may be a sensitive biomarker for SSL- or UV-induced mutagenesis. This mutational endpoint may be useful for evaluating the co-carcinogenicity of compounds administered in combination with UV or SSL.