Molecular spectrum of mutations induced at the HPRT locus by a cross-linking agent in human cell lines with different repair capacities

Abstract

Molecular characterizations of mutations photoinduced by a cross-linking agent 4,5′,8-trimethylpsoralen (Me3Pso), in normal human lymphoblasts was conducted in parallel with lymphoblasts derived from Fanconi anemia patients. Such cells have been previously described to be impaired in repair of psoralen photolesions. The endogenous HPRT locus was used as a target gene. The treatment of cells with Me3Pso in combination with 365 nm irradiation leads to the formation of interstrand cross-links, and specific monoadducts. Our analysis revealed that the mutagenic processing of Me3Pso photoadducts in normal human cells results essentially in base substitutions (84%). These are localized to sequences shown previously to be favored for the formation of Me3Pso monoadducts. The mutagenic processing of the same lesions in Fanconi anemia cells results in fewer base substitutions (22%), with deletions (66%) being the predominant class of mutation. In contrast to prokaryotic systems, frameshifts are poorly represented among Me3Pso induced mutations in human cells. In spite of important differences between the kinds of mutations observed in the two cell lines, our analysis reveals similarities in the type of base substitutions and their sequence distribution. In both normal and Fanconi anemia cell lines mutations, mostly targeted on thymine residues, are preferentially located on the non-transcribed strand.