Specificity of mutations induced by the food-associated heterocyclic amine 2-amino-1-methyl-6-phenylimidazo-[4,5-b]-pyridine in colon cancer cell lines defective in mismatch repair.

Recently, we have shown a hypermutable response to the food-associated heterocyclic amine 2-amino-1-methyl-6-phenylimidazo-[4,5-b]-pyridine (PhIP) in human cells defective in mismatch repair (MMR). These findings suggest that exogenous compounds such as PhIP may play an important role in the generation of tumors in MMR-defective individuals. The specificity of mutations induced by PhIP exposure at the endogenous HPRT locus was determined in cell lines defective in MMR to better understand the mutagenic effects of PhIP in MMR-defective individuals and to gain insight into the molecular mechanism of carcinogenesis induced by PhIP. Eighty-six induced HPRT mutants from two different cell lines were isolated and sequenced after exposure to 10 microM PhIP. Nineteen (22%) of these mutants contained G:C to T:A transversion mutations, consistent with the promutagenic adduct of PhIP at the C8 position of guanine miscoding with adenine. This level of PhIP-induced G:C to T:A transversions was approximately 4.5-fold higher than spontaneous G:C to T:A frequencies. Additionally, a hotspot for mutation was observed in a run of six guanines in HPRT exon 3, where a total of 23 (27%) of all PhIP-induced mutations occurred. These mutations consisted of transversions, transitions, and frameshift mutations. The increase in mutant frequency at this run of guanines corresponded to a 24-fold elevation above the spontaneous frequency in one cell line and a 3.3-fold increase in the other. These data suggest that PhIP may increase the risk of human carcinogenesis mediated by MMR by increasing mutations at runs of guanine residues. PhIP may thereby promote tumorigenesis by mutating growth-regulating genes that contain runs of guanines in their coding sequences, such as BAX, the insulin-like growth factor II receptor IGFIIR, and even the mismatch repair gene hMSH6.

Analysis of sequence alterations in a defined DNA region: comparison of temperature-modulated heteroduplex analysis and denaturing gradient gel electrophoresis.

The ability to detect DNA sequence heterogeneity quickly and reliably is becoming increasingly important as more genes involved in disease processes are discovered. We have assessed the ability of a high pressure liquid chromatography technique (HPLC) termed temperature-modulated heteroduplex analysis (TMHA) to detect a collection of 20 point mutations distributed throughout a 279 base pair fragment spanning the exon 8 region of the human HPRT gene. All mutant/wild type heteroduplexes formed from mutations in the lowest temperature melting domain of the fragment were easily resolved from the corresponding mutant and wt homoduplexes, while those generated from mutants in the next higher melting domain barely resolved from their parental homoduplexes. For comparison, identical heteroduplex samples were subjected to denaturing gradient gel electrophoresis (DGGE). Heteroduplexes in the lowest temperature melting domain were easily resolved, while no resolution was achieved with those in the next higher melting domain. These results suggest that TMHA and DGGE are measuring similar melting characteristics in heteroduplex molecules. TMHA appears to be a robust approach for detecting and/or purifying a wide variety of mutations in a defined region of DNA, provided that the melting characteristics of the fragment under study are carefully considered.

A comparative study of in vivo mutation assays: analysis of hprt, lacI, cII/cI and as mutational targets for N-nitroso-N-methylurea and benzo[a]pyrene in Big Blue mice.

We have compared the response of the native hprt gene and the lacI, cII, and cI transgenes in Big Blue B6C3F1 mice following treatment with either N-nitroso-N-methylurea (MNU) or benzo[a]pyrene (BaP). Three weeks after mutagen treatment splenic T cells were isolated from the animals, and samples were either cultured to measure mutation at the native hprt locus or used to extract genomic DNA for transgene mutation analysis. Phage rescued from extracted DNA were plated in the presence of 5-bromo-4-chloro-3-indolyl-beta-d-galactopyranoside (X-gal) to score lacI mutations, or plated on a hflAB lawn to score cII and cI mutants. With MNU hprt mutant frequency increased in a dose-related, sublinear manner up to 78-fold above background at the highest dose tested (20 mg/kg). In comparison, the lacI transgene yielded only a 3.1-fold increase at this dose, and the cII and cI transgenes did not show any increase. With 150 mg/kg BaP a 5.8- and 8.7-fold increase in mutant frequency was observed at hprt and lacI, respectively, while only a 1.3-fold increase was observed at cII. DNA sequencing revealed an increase in GC-->TA transversions among the cII mutants, suggesting that the increase was related to BaP exposure. No significant increase in cI mutant frequency was observed. Therefore, the order of mutation assay sensitivity was hprt>lacI>cII/cI with MNU, and hprt approximately lacI> cII/cI with BaP. While the hflAB selection system offers significant advantages with respect to cost and effort when compared to the lacI assay, additional evaluation of its sensitivity is warranted.

Synthesis of a lacI gene analogue with reduced CpG content.

A lacI gene analogue with reduced CpG content has been synthesized. Codon usage in the lacI gene was manipulated to remove most CpG sites (82/95; 86%) while maintaining wild-type amino acid sequence. The double-stranded gene sequence was synthesized using standard beta-cyanoethyl phosphoramidite chemistry and subsequently cloned into pBR322. Bacterial promoter sequences with different levels of activity were attached upstream of the modified coding region to study its expression in E. coli. Production of lacI protein was confirmed in a lacI- E. coli strain by Western blot analysis and by measuring repression of the lacZ gene with the chromogenic lacZ indicator, 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-gal). The modified lacI gene construct can be used as a genetic target in cultured mammalian cells or in transgenic animals to avoid high levels of background mutation associated with methylated CpG sequences. The construction scheme described here provides a general approach to remove CpG sequences from gene constructs when methylation is undesirable.

Mutagenic response of the endogenous hprt gene and lacI transgene in benzo[a]pyrene-treated Big Blue B6C3F1 mice.

Big Blue (BB) and generic B6C3F1 mice were given one to three i.p. injections of 50 mg/kg benzo[a]pyrene (B[a]P) in DMSO every other day to achieve cumulative doses of 50 to 150 mg/kg. Three weeks after treatment, the mutation frequency at the endogenous hprt gene and lacI transgene was measured in splenic T cells. Generic mice given 50, 100, and 150 mg/kg B[a]P displayed induced hprt frequencies (observed hprt frequency minus control frequency) of 5.5 +/- 1.0, 11 +/- 2.0, and 19 +/- 2.6 x 10(-6), respectively (average +/- SEM). In contrast, BB mice given 50 and 150 mg/kg B[a]P displayed induced hprt frequencies of 0.9 +/- 0.6 and 9.1 +/- 1.5 x 10(-6). 32P postlabelling revealed that the lower hprt response in BB mice correlated with lower amounts of BP-DNA adducts in spleen, liver, and lung 24 hours after B[a]P exposure. Western blot analysis of liver samples from B[a]P-treated mice suggests that the reduced adduct load in turn may be due to lower P450 1A1 levels in BB mice. The frequency of induced, nonsectored blue plaques (observed blue plaque frequency minus control frequency) in BB mice receiving 50 and 150 mg/kg B[a]P was 41 +/- 9 and 134 +/- 10 x 10(-6) (15- to 40-fold higher than the induced hprt frequency in the same treated animals). Sectored plaques were observed in both control and B[a]P groups but their frequency showed no relationship to dose (sectored frequency in all groups was approximately 20 x 10(-6)). To test whether persistent DNA adducts in the packaged lambda vector were contributing to the observed blue plaque frequency, purified lambda-LIZ DNA was treated in vitro with B[a]P diol epoxide (BPDE), packaged, and plated on E. coli lawn cells. Treatment with BPDE did not produce significant increases in homogeneous blue plaques, suggesting that the majority of mutants obtained from B[a]P-treated BB mice occurred in vivo. These results indicate that B[a]P exposure produces many more mutations at the lacI transgene than at the endogenous hprt locus.

Relative sensitivity of the endogenous hprt gene and lacI transgene in ENU-treated Big Blue B6C3F1 mice.

Three-week-old Big Blue (BB) B6C3F1 mice were given a single i.p. injection of ENU. Three weeks later, splenic T cells were isolated from each animal by ficoll gradient centrifugation and divided into two samples. One sample was cultured to measure hprt- mutation and the other was used to extract DNA for lacI- analysis. T cells from BB mice exposed to 0, 4.5, 13.5, and 40 mg ENU/kg (9 or 10 animals per group) displayed dose-related increases in the frequency of both hprt- and lacI- mutations. Within each treatment group, the ENU-induced mutation frequency (average observed mutation frequency minus average control frequency) was remarkably similar at the two loci. This suggests that treatments that increase mutation frequency at the endogenous hprt gene also produce similar incremental increases at the BB lacI transgene. However, because of the ten-fold higher spontaneous mutation rate at lacI, the fold-increase over background produced by ENU at this locus was significantly less than the fold-increase produced at hprt. For example, the 4.5 mg ENU/kg treatment produced a 5.2-fold increase above background at hprt (P = 0.001), whereas only a 1.5-fold increase was produced at lacI (P = 0.140). Consequently, mutagenic insults that produce up to a fivefold increase in mutation frequency at an endogenous locus may be difficult to detect at the lacI transgene. Finally, the ENU-induced response at hprt in BB mice was identical to that in generic B6C3F1 mice, suggesting that there are no inherent differences between transgenic and normal mice in their response to this mutagenic agent.