Mutational spectrum of ICR-191 at the hprt locus in human lymphoblastoid cells.

Human TK6 lymphoblasts were treated with the acridine derivative ICR-191, and mutants at the hprt locus were isolated. Mutant hprt cDNA was reverse-transcribed from mRNA, amplified by polymerase chain reaction (PCR), and sequenced. Additions of single G:C base pairs (+1 frameshift mutations) in repetitive G:C sequences were found in 82% (32/39) of the mutants. Sixteen of the +1 frameshifts analyzed were located in a single sequence of six consecutive guanine bases in exon 3. The remaining +1 frameshifts occurred at six different GGG sequences (14 mutants) and a single GGGG sequence (2 mutants) in other hprt exons. The repetitive guanine sequences that underwent frameshift mutagenesis were located in both the transcribed and nontranscribed strands of hprt. No single base deletions (-1 frameshift mutations) were observed. Base substitutions were observed in 13% (5/39) of the clones analyzed and occurred at both G:C and A:T bases. Loss of exon 4 from the cDNA was also observed in 5% (2/39) of the mutants. Hprt mutants containing seven consecutive guanines (produced from a +1 frameshift in a GGGGGG sequence) were treated with ICR-191 and wild-type revertants selected in CHAT medium. Revertants were recovered at a frequency of approximately 10(-7) and contained the wild-type sequence (GGGGGG) in all clones analyzed. The observed frequency of ICR-191-induced-1 frameshift reversion in the GGGGGGG sequence was approximately 500-fold lower than the estimated frequency of +1 frameshifts observed in the wild-type GGGGGG sequence following the same ICR-191 treatment. These results suggest that ICR-191 produces predominantly +1 frameshift mutations at the hprt locus in human cells.

Effect of UV light on sister-chromatid exchanges, activation of alternative sites of replicon initiation and thymidine incorporation in CHO AA8, UV61 and UV5 cells.

The relative importance of the UV-induced pyrimidine(5-6)pyrimidine and the pyrimidine(6-4)-pyrimidone lesions in sister-chromatid exchanges (SCEs), activation of alternative sites of replicon initiation and thymidine incorporation were examined using wild-type Chinese hamster ovary (CHO) AA8 cells which remove both lesions, mutant CHO UV61 cells which remove only the (6-4) lesion and mutant CHO UV5 cells which remove neither lesion. Our data suggest that both lesions play a role in each end point examined. The relative importance of these lesions is dependent on the end point studied as well as the fluence used. For SCE induction and the activation of alternative sites of replicon initiation, the (6-4) lesion appears to play a predominant role, while for the thymidine incorporation studies the (6-4) lesion appears to play the predominant role at low fluences while the role of the (5-6) lesion increases at higher fluences.

Effect of UV light on DNA replication and chain elongation in Chinese hamster UV61 cells.

Exposure of eukaryotic cells to ultraviolet light results in a temporary inhibition of DNA replication as well as a temporary blockage of DNA fork progression. Recently there has been considerable debate as to whether the (5-6)cyclobutane pyrimidine dimer, the pyrimidine(6-4)pyrimidone lesion or both are responsible for these effects. Using cell lines that repair both of these lesions (CHO AA8), only (6-4) lesions (CHO UV61) or neither (CHO UV5), we have shown that in rodent cells both lesions appear to play a role in both the inhibition of thymidine incorporation and the blockage of DNA fork progression. Specifically, after exposure to 2.5 J/m2, AA8 cells recover normal rates of DNA replication within 5 h after exposure, while UV5 cells exhibit a greater depression in thymidine incorporation for at least 10 h. UV61 cells, on the other hand, show an intermediate response, both with respect to the extent of the initial depression and the rate of recovery of thymidine incorporation. UV61 cells also exhibit an intermediate response with respect to blockage of DNA fork progression. In previous publications we have shown that UV5 cells exhibit extensive blockage of DNA fork progression and only limited recovery of this effect within the first 5 h after exposure to UV. In this report we show that UV61 cells exhibit a more extensive blockage of fork progression than is observed in AA8 cells. These blocks also appear to be removed (or overcome) more slowly than in the AA8 cells, but more rapidly than in UV5 cells. Taken together we conclude that both lesions appear to be involved in the initial depression in thymidine incorporation and the initial blockage of DNA fork progression in rodent cells. These data also indicate that (6-4) lesions may be responsible for the prolonged depression in thymidine incorporation and the prolonged blockage of DNA fork progression observed in UV5 cells.