Analysis of chromate-induced DNA-protein crosslinks with the comet assay

Modifications of the comet assay have been introduced to measure crosslinks by determining the reduction of induced DNA migration. Our previous results indicated that the modified protocol of the alkaline comet assay is a sensitive tool for the detection of formaldehyde-induced DNA-protein crosslinks. But results for mitomycin C and cisplatin suggested that the modified protocol is not well suited for the evaluation of DNA-DNA crosslinkers. We now used the comet assay to investigate in V79 cells the effect of potassium chromate (K2CrO4), another DNA-protein crosslinker, to see whether the results obtained for formaldehyde can be generalized. However, chromate did not reduce spontaneous or radiation-induced DNA migration in the alkaline (pH 13) comet assay but led to a small but significant induction of DNA migration. A crosslinking effect of chromate could also not be detected with the alkaline comet assay after postincubation of cells in normal medium after chromate treatment to enable repair of other (migration-inducing) lesions that might mask the crosslinking effect. Exposure of slides to proteinase K further increased DNA migration of chromate-treated cells, thus indicating the presence of DNA-protein crosslinks. In contrast to the alkaline comet assay, a neutral version at pH 9 was suited to demonstrate reduced induction of DNA migration after gamma -irradiation of chromate-treated cells. The crosslinking effect was seen immediately at the end of the chromate treatment as well as after a 3 h postincubation period. Using the neutral protocol in combination with proteinase K, we were able to demonstrate the presence of DNA-protein crosslinks as the probable cause for the migration-reducing effect. Further investigations will have to show whether this protocol can be recommended as a universal approach for the detection of DNA-protein crosslinks and also of DNA-DNA crosslinks with the comet assay. (C) 2000 Elsevier Science B.V. All rights reserved.