Trivalent chromium is neither cytotoxic nor mutagenic in permeabilized hamster fibroblasts.

BHK cells became reversibly permeable by a 30-min incubation in hypertonic medium. During permeabilization they were exposed to water-soluble Cr(VI) (K2Cr2O7) and Cr(III) (CrCl3). Thymidine uptake in the intracellular nucleotide pool, DNA replication, DNA damage and repair and sister-chromatid exchanges (SCE) were examined to detect the cytotoxic and genetic effects of Cr compounds. Cr(III) remained inactive also in permeabilized cells. An apparent induction of DNA damage by Cr(III), suggested by the Painter's test, was considered unreliable. Cr(VI) cytotoxic and genetic activity was enhanced in permeabilized cells, as demonstrated by increased inhibition of DNA replication and higher frequency of SCE.

Genetic effects of chromium compounds.

Seven different test systems were utilized to investigate the genetic activity of chromium compounds: infidelity of DNA replication in vitro by DNA pol alpha from calf thymus, damage of DNA detected by alkaline elution in treated mammalian cells or in DNA purified and treated in vitro, DNA repair synthesis in mammalian cells in vitro detected by autoradiography or scintillation counting after labelling with [3H]dThd, gene mutations in the Salmonella typhimurium Ames test, gene mutations (6TG resistance) in cultured hamster cells, sister-chromatid exchanges in different rodent cell cultures, and transformation to anchorage-independent growth of hamster cells in vitro (soft-agar assay). Potassium dichromate and chromium chloride were used as water-soluble Cr(VI) and Cr(III) salts. Several reference mutagens (EMS, MMS, MMC, 4NQO) were included in the single tests as positive controls. Cr(VI) was active in all the tested systems, except in the induction of DNA damage and DNA repair synthesis in cultured cells. Cr(III), on the other hand, was absolutely inactive unless a direct interaction with purified DNA was permitted by the test conditions. The relevance of data from the various tests to the understanding of the mechanisms of the genotoxic activity of chromium is discussed. Effects other than the direct interaction of Cr(III) with DNA are inferred, which can cause infidelity of the DNA polymerase functions.

Induction of DNA repair synthesis by ultraviolet radiation and methylmethanesulphonate in cultured mouse lymphocytes.

The induction of DNA repair synthesis by UV-radiation and methyl-methanesulphonate (MMS) was studied in mouse lymphocytes and leukemic cells by means of autoradiography and scintillation counting, after labelling in vitro with tritiated thymidine ([3H]dThd). Repair stimulation was detected by both procedures in LSTRA and YC8 leukemic cell lines as well as in primary fibroblasts of BALB/c and BALB/Mo mice. No stimulation was observed in primary cultures of lymphocytes from the spleen, thymus and lymph-nodes of the same mice. In primary lymphocytes neither stimulation with concanavalin A (Con A) nor pre-incubation with 5-bromodeoxyuridine (BUdR) were effective in making evident DNA repair. The data put into question the reliability of the repair test for the prediction of carcinogenic potential of chemicals.

The scintillometric evaluation of DNA repair synthesis can be distorted by changes of thymidine pool radioactivity.

The induction of DNA repair synthesis by UV radiation and methylmethane sulphonate (MMS) in mammalian cell lines of human (EUE, HeLa, FT, KB) and hamster (CHO, BHK) origin has been evaluated by means of autoradiography and the scintillometric procedure which implied the use of hydroxyurea (HU) to suppress DNA replication. While with UV radiation both methods produce concordant positive results, in the case of MMS the evidence of DNA repair synthesis obtained from the autoradiograms is occasionally accompanied by a lack of increase of DNA radioactivity in the treated cultures, as detected by scintillation counting. In such instances MMS is shown to reverse the enhancement of pool radioactivity in the cultures incubated with HU and even to reduce the radioactivity of thymidine pool below control values. By normalizing DNA radioactivities on the basis of pool variations, the discrepancy between autoradiography and scintillation counting is solved. The chromatographic analysis of thymidine pool components justifies the normalization procedure as it demonstrates that also in cultures treated with MMS or MMS + HU pool variations closely parallel the variations of thymidine triphosphate (dTTP) level. The normalization of DNA radioactivities based on the overall pool radioactivities gives an improved evaluation of the actual rate of DNA synthesis. It can be recommended for screening studies of DNA repair inducers because it allows one to correct false negative results without producing false positive data. Compared with the dTTP levels, overall pool radioactivities used as normalizing factors still produce an underestimate of DNA repair when high doses of MMS are applied to hamster cell cultures.

Effects of hexavalent chromium on the adenylate pool of hamster fibroblasts.

The mechanisms through which Cr(VI) reduces the intracellular levels of ATP in hamster fibroblasts (BHK 21 line) were investigated. Leakage of pool components during treatment of cells prelabelled with [3H]adenosine was examined. Adenylate pool composition was analyzed by thin-layer chromatography (TLC) in cells incubated with [3H]adenosine immediately after treatment with Cr(VI), and the endogenous concentrations of different nucleotides were determined by high-performance liquid chromatography (HPLC). Interference of Cr(VI) with different steps of ATP biosynthesis could be assessed. Treated cells showed increased loss of radioactive hypoxanthine and inosine in the treatment medium, but no nucleotides were detected outside the cells. A marked unbalance of the endogenous adenylate pool was produced by chromium, consisting in a strong decrease of ATP, accompanied by a very pronounced increase of ADP and AMP. Treatment with Cr(VI) caused an altered distribution of label among the different adenylate pool components, especially an accumulation of radioactivity in the ADP and AMP fractions. Also other effects on the soluble pool were detected by HPLC analysis, namely the reduction of NAD content and variations in the guanylate pool which closely paralleled the ones observed in the adenylate pool. Energy charge values, calculates on the basis of HPLC and TLC data, allowed to detect a specific inhibition of ADP phosphorylation to ATP. An interference with the early steps of adenylate synthesis could be inferred from the enhanced amounts of hypoxanthine and inosine in the treated cultures.