Faculty Bibliography

We determined the mutant fractions (MF) and mutational specificities in the cII gene in histologically confirmed normal, non-involved and tumor mammary tissues of female transgenic (Big Blue F344 x Sprague-Dawley)F1 rats treated with the environmental pollutant 6-nitrochrysene (6-NC). At 30 days of age, three groups were set up for oral treatment with 6-NC dissolved in trioctanoin, or trioctanoin alone once a week for 8 weeks. Two dose levels of 6-NC (100 and 200 micromol/rat) were selected on the basis of our previous carcinogenicity bioassays with CD rats. The rats were decapitated 32 weeks after the last carcinogen dose. Both incidence and multiplicity of mammary adenocarcinomas were significantly elevated in the high dose (36%, 0.57, P < 0.01) group but at the low dose these outcomes (16%, 0.23, P < 0.1) were not significantly different from those of control rats (3%, 0.03). The MF in normal, non-involved and tumor tissues from the mammary glands of 6-NC-treated rats were comparable. At the high and low doses, respectively (4.8 +/- 2.0, 3.2 +/- 2.1) the MF of 6-NC-treated rats, were significantly higher (P < 0.05) than that observed in control rats (1.2 +/- 0.6). Control mutants consisted primarily of GC --> AT transitions, whereas 6-NC-induced mutants were comprised of several major classes of mutations with GC --> TA, GC --> CG, AT --> GC and AT --> TA as the most prevalent. Further studies indicated that the structures of 6-NC-DNA adducts in the mammary tissue are consistent with the mutational specificities. This is the first report that defines the relationship between carcinogenesis and mutagenesis, as well as between structures of 6-NC-DNA adducts and mutation characteristics in the target organ in vivo.

Bleomycin and ferric nitrilotriacetate (Fe-NTA) give rise to reactive oxygen species (ROS). Bleomycin was mutagenic in lacZ mouse kidney, liver and lung, but Fe-NTA was non-mutagenic in kidney and lung and marginally mutagenic in liver. Fe-NTA-treatment led to an increase in 8-hydroxydeoxyguanosine levels in kidney and liver, while the corresponding levels in bleomycin-treated mice were if anything, lower than those for bleomycin. It appears that factors other than simply the ability to generate ROS, play a role in mutagenesis by these compounds.

We recently discovered an error in the abstract of the above article (Mutat. Res. 518 (2002) 85-93). The correct concentration of 4-nitroquinoline-N-oxide is 20 mug/ml, not mg/ml. This was indicated correctly in the Materials and Methods section, but not in the Abstract. We apologize for this error

The effects of dietary administration of 1,4-phenylenebis(methylene)selenocyanate (p-XSC) and Vitamin E on 4-nitroquinoline-N-oxide (4-NQO)-induced mutagenesis in lacZ mouse upper aerodigestive tissues were investigated. 4-NQO was a potent mutagen in tongue, other pooled oral tissues and esophagus when given in drinking water for 4 weeks at a concentration of 20 microg/ml [corrected]. The mutant fractions (MFs) in these tissues were: 144+/-73, 130+/-52 and 61+/-24 mutants/10(5), respectively. Background levels were 3.7+/-1.9 in tongue, 2.9+/-1.2 in esophagus and 2.4+/-1.0 in pooled oral tissue. Vitamin E at levels of 200 and 400 IU/kg diet led to no significant effects on mutagenesis although a small decrease in the MF was observed in all tissues at the higher dose. Dietary p-XSC at levels of 2.5 and 10 ppm selenium also resulted in no statistically significant effects on mutagenesis, but mutagenesis was somewhat reduced in esophagus and pooled oral tissue at the higher dose. However, the combination of the low doses of p-XSC and Vitamin E resulted in nearly a 40% decrease in mutagenesis in tongue and esophagus, and this decrease was statistically significant (P=0.008 and 0.023, respectively. No inhibition was observed using a combination of the higher doses of p-XSC and Vitamin E. These results lend support to the use of low doses of inhibitors of mutagenesis in combinations. The application of in vivo mutagenesis assays to the screening of chemopreventive agents enables investigators to evaluate potential inhibitors when given individually and in combinations on the initiation stage of carcinogenesis in a short-term in vivo bioassay.

Consumption of lycopene has been associated with reduced risk of prostate cancer. We have investigated the effects of lycopene, fed as a lycopene-rich tomato oleoresin (LTO) at two doses, on in vivo mutagenesis in prostate, colon, and lungs of lacZ mice. Both short-term benzo[a]pyrene (BaP)- induced and long-term spontaneous mutagenesis were monitored. Non-significant inhibition of spontaneous mutagenesis in prostate and colon was observed at the higher dose of LTO, and the observation of inhibition in colon was facilitated by an unusually high spontaneous mutagenesis rate. BaP-induced mutagenesis was slightly inhibited by LTO in prostate. However, enhancement of BaP-induced-mutagenesis was observed in colon and lung. These results indicate that any antimutagenic effects of LTO may be organospecific.

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and nitrosonornicotine (NNN) were administered to lacZ mice (MutaMouse) at equal concentrations in drinking water (2 weeks at 0.1 followed by 2 weeks at 0.2 mg/ml) over a 4 week period, for a total estimated dose of 615 mg/kg) and mutagenesis in a number of organs was measured. For mutagenesis induced by NNK the potency order was: liver > lung> pooled oral tissues kidney > esophagus > tongue. The mutant fraction varied from approximately 6 to 40 mutants per 10(-5) plaque forming units This corresponds to approximately 2-13 times the background levels. A somewhat different pattern was observed with NNN, where the order was liver > esophagus oral tissue approximately tongue > lung > kidney. The potency of NNK was about twice that of NNN in liver and lung, but somewhat less in aerodigestive tract tissue. When compared with results previously obtained for a similar administered dose of benzo[a]pyrene, NNK was approximately 10-100% as mutagenic in the corresponding organs. Reported target organs for carcinogenesis by NNN and NNK in rodents were targets for mutagenesis, but mutagenesis was also observed at other sites, suggesting that these sites are initiated. The effect of green tea consumption on mutagenesis by NNK was also investigated. Green tea reduced mutagenesis by approximately 15-50% in liver, lung, pooled oral tissue and esophagus.

4-Nitroquinoline-N-oxide (4-NQO) was administered to lacZ mice at a concentration of 20 microg/ml in drinking water for 2 weeks, and the mutagenic fractions in a number of organs were assayed. The mutant fractions in tongue, esophagus and other pooled oral tissues were, respectively, 117+/-26, 73+/-15, and 48+/-15 mutants/10(5) plaque-forming units (pfu) (ca. 15-40xbackground). 4-NQO was not mutagenic in lung, liver or colon at conditions used here. We had previously demonstrated that the synthetic organoselenium compound, 1,4-phenylenebis(methylene)selenocyanate (p-XSC), an established chemopreventive agent, greatly reduced carcinogenicity in 4-NQO in rat tongue, and we observed here that administration of p-XSC (10 ppm se) in the diet for 6 weeks (2 weeks before, during, and 2 weeks after 4-NQO) resulted in a 33% decrease in mutagenesis in oral tissue, a 17% decrease in esophagus, and a slight increase in tongue. Only the decrease in oral tissue reached statistical significance (p<0.04). The results reported here demonstrate that 4-NQO was extremely mutagenic in lacZ mouse tongue, with lower, but highly significant activities in esophagus and other pooled oral tissues. The high activity of 4-NQO in lacZ mouse tongue is consistent with the organ specificity of 4-NQO in the rat. Inhibition of 4-NQO-induced mutagenesis by p-XSC was observed mainly in pooled oral tissues, other than tongue. Possible reasons for the difference between inhibition of mutagenesis and carcinogenesis in tongue are discussed, as well as advantages and disadvantages of in vivo mutagenesis assays as surrogates for carcinogenicity assays in chemoprevention studies.