Kunie Yoshikawa

Comparative studies of chromosomal aberration and mutagenicity of trivalent and hexavalent chromium

The comparative cytogenetic and mutagenic effects between trivalent and hexavalent chromium were investigated. Five chromium compounds, K2Cr2O7 and K2CrO4 containing Cr6+, and Cr(CH3COO)3, Cr(NO3)3 and CrCl3 containing Cr3+, were examined for their ability to induce chromosomal damage in cultures of human leukocytes, for their reactivity with DNA by a rec-assay system and for mutagenicity in the E. coli Hs30R test system. Chromosome-breaking activity was significantly higher for the compounds with hexavalent than trivalent chromium, the efficiency being in the decreasing order K2Cr2OM greater than K2CrO4 greater than Cr(CHCOO)3 greater than Cr(NO3)3, CrCl3. In the rec-assay and mutation assay, hexavalent (K2Cr2O7 and K2CrO4) and trivalent Cr(CH3COO)3) compounds gave positive results, their mutagenic potential being higher in the same order of clastogenic magnitude.

An in vivo-in vitro replicative DNA synthesis (RDS) test using rat hepatocytes as an early prediction assay for nongenotoxic hepatocarcinogens screening of 22 known positives and 25 noncarcinogens.

To evaluate the applicability of an in vivo-in vitro replicative DNA synthesis (RDS) test using rat hepatocytes, we conducted the RDS test with 22 nongenotoxic (Ames-negative) hepatocarcinogens and 25 noncarcinogens under our standardized conditions and judgement criteria. Compared to controls (RDS incidence of under 1.0%), the RDS test gave positive results for 18 hepatocarcinogens (positive sensitivity: 82%), and negative results for 20 noncarcinogens (negative specificity: 80%), and thus the overall concordance was 81%. These findings strongly suggest that the RDS test is an extremely useful method for early detection of nongenotoxic hepatocarcinogens.

Studies on selenium-related compounds. V. Cytogenetic effect and reactivity with DNA

Five selenium compounds, Na2Se04, H2Se04, Na2Se03, H2Se03 and Se02, were tested for their capacity to induce chromosome aberrations in cultured human leukocytes and for their reactivity with DNA by a rec-assay system and inactivation of transforming activity in Bacillus subtilis. Chromosome-breaking activity was significantly higher for the compounds with four-valent than with six-valent selenium, the efficiency being in the decreasing order H2S03 greater than Na2Se03 greater than Se02 greater than H2Se04 greater than Na2Se04. Rec assay using B. subtilis with different recombination capacities suggested that damage to DNA was produced by selenites but not by selenates. The reactivity of selenites with DNA was also indicated by a significant loss of transformation of the tryptophan marker of B. subtilis DNA treated with H2Se03 and Se02.

Mutagenicities of carbadox and olaquindox — Growth promoters for pigs

Carbadox and olaquindox were examined for mutagenicities in the repair tests with Bacillus subtilis (rec assay) and Salmonella typhimurium (uvr assay) and in the reverse mutation test (TA100 and TA98 of S. typhimurium). Both compounds were positive in the rec and uvr assays, and were highly mutagenic for strains TA100 and TA98. Carbadox was about 6 times move mutagenic than olaquindox in the absence of S9 mix. When incubated in S9 mix or bacterial cytosol (BC) mix for various times at 37 degree C, carbadox was found to lose its mutagenic activities easier than olaquindox. The mutagenicity of carbadox was almost inactivated at 10 min after incubation with S9 mix, but olaquindox still retained its activities even at 20 min. While carbadox required 20 min to be inactivated in BC mix, olaquindox was not completely inactivated even if incubated for 60 min.

Differences in liver homogenates from Donryu, Fischer, Sprague-Dawley and Wistar strains of rat in the drug-metabolizing enzyme assay and the salmonella/hepatic S9 activation test

Comparison studies for detecting differences between liver microsome and S9 preparations from 4 strains (Donryu, Fischer, Sprague-Dawley, Wistar) of young male rats were carried out with pretreatment of the animals by inducers such as PCBs and PB plus 5,6-BF. Each microsome fraction was assayed for the enzymic activity of metabolism of model substrates such as aniline, benzophetamine, BP, DMN and 7-ethoxycoumarin. The hepatic S9 sample was also compared, as regards its metabolizing ability to activate 9 pre-mutagens (2AA, AAF, o-AAT, BP, DAB, DMBA, DMN, m-PDA, quinoline) to directly acting mutagens in the Salmonella/hepatic S9 activation test by using TA98, TA100 and TA1537 strains with or without cytochrome P450 inhibitors (SKF-525A, metyrapone, 7,8-benzo-flavone). In the enzymic assay with PCBs-induced microsomes, BP hydroxylation a strain-specific difference: the microsomes from Fischer and Wistar rats were more effective for metabolizing BP than those from the other strains of rat. The effect of induction by BP plus 5,6-BF for Fischer rats showed relatively higher enzymic activity in the same induction group. Other microsomes prepared from rats with and without induction by PB plus, 5,6-BF did not show a clear-cut strain dependency in the enzymic activities assayed. In the mutation experiments with hepatic S9 samples, the examination of DAB and quinoline revealed a marked strain difference when S9 samples prepared from PCBs-pretreated and PB-plus-5,6-BF-induced rats were used: the S9 sample from Fischer rats was available for activating the two pre-mutagens to directly acting mutagens. No marked difference in the metabolic activation of the remaining 7-pre-mutagens was observed on other S9 preparations. In examinations of mutagenicity activities with the use of three inhibitors, the two S9 preparations made with the two induction methods showed inhibition profiles closely similar to each other. However, there were minor differences in the profiles by these inhibitors. From these findings it was concluded that Fischer rat-liver S9 is useful for detecting mutagens in the metabolic activation test, when induction by PB plus 5,6-BF was used in the Ames Salmonella test.

Studies on metabolism and toxicity of styrene: III. The effect of metabolic inactivation by rat-liver S9 on the mutagenicity of phenyloxirane toward Salmonella typhimurium

A comparative study on enzymic factors influencing the metabolic inactivation of phenyloxirane (styrene oxide), a major mutagenic metabolite of styrene in the liver, was carried out with respect to soluble glutathione S-transferase and microsomal epoxide hydratase in the 9000 X g supernatant fraction (S9) from a rat-liver homogenate. The mutagenic activity of phenyloxirane to Salmonella typhimurium TA100 was markedly reduced by S9 in the presence of glutathione but to a smaller extent in its absence. The retarding effect of glutathione on the inherent mutagenic activity of phenyloxirane was exerted by the soluble supernatant of S9 but not by microsomes. A gas-liquid chromatographic study indicated that the effect of glutathione was attributable to the disappearance of the mutagen from the microbial assay system. The rate of the disappearance was 10-20 times as fast in the soluble supernatant fraction as in the microsomes when fortified with more than 4 mM glutathione. Our results strongly suggest that in hepatic cells of the rat, cytosol glutathione S-transferase plays a much more important role than microsomal epoxide hydratase in the detoxication of the metabolite, phenyloxirane.

Differential mutagenicities of 6 N-nitroso-N-alkylurea derivatives in Escherichia coli strains with different DNA-repair capacities

Reverse mutations to prototrophy by, and killing effects of, 6 N-nitroso-N-alkylurea derivatives such as NMU, NEU, NPU, NBU, NIBU and NAU were studied with E. coli strains H/r30R (wild-type), Hs30R (uvrA-), O16 (polA-) and NG30 (recA-). Both strains polA- and recA- were far more sensitive to killing by the 6-compounds than were the wild-type and uvrA- strains, and there was no difference in the sensitivity between the latter 2 strains. NMU was mutagenic in all 4 strains; wild-type, uvrA- and polA- strains were almost equally mutable but the compound was slightly mutagenic in the recA- strain. The other 5 compounds, NEU, NPU, NBU, NIBU and NAU, caused hardly any mutation in the recA- strain. NEU, NPU and NBU were equally mutagenic in the wild-type, uvrA- and polA- strains; however, NIBU and NAU were more mutagenic in the uvrA- than in the wild type or polA-. From the differential mutagenicities and lethalities induced by the 6 N-nitroso-N-alkylureas into the 4 tester strains, mutational patterns of the compounds can be classified into 3 types.