Human repair gene restores normal pattern of preferential DNA repair in repair defective CHO cells.

The pattern of preferential DNA repair of UV-induced pyrimidine dimers was studied in repair-deficient Chinese hamster ovary (CHO) cells transfected with the human excision repair gene, ERCC-1. Repair efficiency was measured in the active dihydrofolate reductase (DHFR) gene and in its flanking, non-transcribed sequences in three cell lines: Wild type CHO cells, a UV-sensitive excision deficient CHO mutant, and the transfected line of the mutant carrying the expressed ERCC-1 gene. The CHO cells transformed with the human ERCC-1 gene repaired the active DHFR gene much more efficiently than the non-transcribed sequences, a pattern similar to that seen in wild type CHO cells. This pattern differs from that previously reported in CHO cells transfected with the denV gene of bacteriophage T4, in which both active and non-transcribed DNA sequences were efficiently repaired (Bohr and Hanawalt, Carcinogenesis 8: 1333-1336, 1987). The ERCC-1 gene product may specifically substitute for the repair enzyme present in normal hamster cells while the denV product, T4 endonuclease V, does not be appear to be constrained in its access to inactive chromatin.     

Deficient repair of the transcribed strand of active genes in Cockayne's syndrome cells.

Removal of ultraviolet light induced cyclobutane pyrimidine dimers (CPD) from active and inactive genes was analyzed in cells derived from patients suffering from the hereditary disease Cockayne's syndrome (CS) using strand specific probes. The results indicate that the defect in CS cells affects two levels of repair of lesions in active genes. Firstly, CS cells are deficient in selective repair of the transcribed strand of active genes. In these cells the rate and efficiency of repair of CPD are equal for the transcribed and the nontranscribed strand of the active ADA and DHFR genes. In normal cells on the other hand, the transcribed strand of these genes is repaired faster than the nontranscribed strand. However, the nontranscribed strand is still repaired more efficiently than the inactive 754 gene and the gene coding for coagulation factor IX. Secondly, the repair level of active genes in CS cells exceeds that of inactive loci but is slower than the nontranscribed strand of active genes in normal cells. Our results support the model that CS cells lack a factor which is involved in targeting repair enzymes specifically towards DNA damage located in (potentially) active DNA.     

Repair of radiation-induced DNA strand breaks does not occur preferentially in transcriptionally active DNA.

Certain DNA base lesions induced by ionizing radiation or oxidative stress are repaired faster from the transcribed strand of active genes compared to the genome overall. In this study, it was investigated whether radiation-induced DNA strand breaks are preferentially repaired in active genes compared to the genome as a whole in CHO cells. The alkaline unwinding technique coupled to slot-blot hybridization with specific DNA probes was used to study the induction and repair of DNA strand breaks in defined DNA sequences. Results using this technique showed a linear dose response for the formation of radiation-induced DNA strand breaks in the dihydrofolate reductase (DHFR) gene. Furthermore, the half-life of radiation-induced strand breaks was less than 5 min in the DHFR gene, in the ribosomal genes, and in the genome as a whole. These results suggest that the repair of DNA strand breaks is fast and uniform in the genome of mammalian cells.     

Gene-specific and strand-specific DNA repair in the G1 and G2 phases of the cell cycle.

We have analyzed the fine structure of DNA repair in Chinese hamster ovary (CHO) cells within the G1 and G2 phases of the cell cycle. Repair of inactive regions of the genome has been suggested to increase in the G2 phase of the cell cycle compared with other phases. However, detailed studies of DNA repair in the G2 phase of the cell cycle have been hampered by technical limitations. We have used a novel synchronization protocol (D. K. Orren, L. N. Petersen, and V. A. Bohr, Mol. Cell. Biol. 15:3722-3730, 1995) which permitted detailed studies of the fine structure of DNA repair in G2. CHO cells were synchronized and UV irradiated in G1 or early G2. The rate and extent of removal of cyclobutane pyrimidine dimers from an inactive region of the genome and from both strands of the actively transcribed dihydrofolate reductase (DHFR) gene were examined within each phase. The repair of the transcribed strand of the DHFR gene was efficient in both G1 and G2, with no major differences between the two cell cycle phases. Neither the nontranscribed strand of the DHFR gene nor an inactive region of the genome was repaired in G1 or G2. CHO cells irradiated early in G2 were more resistant to UV irradiation than cells irradiated in late G1. Since we found no major difference in repair rates in G1 and G2, we suggest that G2 resistance can be attributed to the increased time (G2 and G1) available for repair before cells commit to DNA synthesis.     

Quantification of aminofluorene adduct formation and repair in defined DNA sequences in mammalian cells using the UVRABC nuclease

Using the UVRABC nuclease as a reagent coupled with DNA restriction and hybridization analysis we have developed a method to quantify N-acetoxy-2-acetylaminofluorene (NAAAF)-induced DNA damage in the coding and noncoding sequences of the dihydrofolate reductase (DHFR) gene in Chinese hamster ovary (CHO) cells. High performance liquid chromatography analysis shows that the only DNA adduct formed in NAAAF-treated CHO cells is N-(deoxyguanosine-C8-yl)-2-aminofluorene (dG-C8-AF). DNA sequencing analysis demonstrates that the UVRABC nuclease incises at all potential sites in which dG-C8-AF adduct may form in linear DNA fragments. We have found that the formation and removal of dG-C8-AF adducts in the coding and 3' downstream noncoding sequences of the DHFR domain are similar in cells treated with 10 microM NAAAF (3.1 adducts/14 kilobases); DNA adduct removal attains 70% for both sequences within 24 h. This result contrasts with that obtained for the repair of cyclobutane dipyrimidines in the DHFR gene, in which the repair efficiency is much higher in the coding region than in the 3' downstream noncoding region. Our results suggest that in CHO cells the repair pathway for aminofluorene DNA adducts is not the same as that for cyclobutane dipyrimidines. This new technique has the potential to detect a variety of chemical carcinogen induced DNA adducts at the gene level in cultured cells and in DNA isolated from animal tissues.     

DNA repair in an active gene: removal of pyrimidine dimers from the DHFR gene of CHO cells is much more efficient than in the genome overall

DNA repair was measured in the dihydrofolate reductase gene in Chinese hamster ovary cells, amplified for the gene, by quantitating pyrimidine dimers with a specific UV-endonuclease. More than two thirds of the dimers had been removed from a 14.1 kb restriction fragment of the gene by 26 hr after irradiation (20 J/m2), while little removal was detected in fragments upstream of the gene and only 15% were removed from the genome overall. This suggests that damage processing can vary according to function or activity of affected sequences, which has general implications for correlations of DNA repair with survival and mutagenesis. Perhaps preferential repair of vital sequences facilitates UV-resistance of these cells despite low overall repair levels.     

Strand specificity for UV-induced DNA repair and mutations in the Chinese hamster HPRT gene.

DNA excision repair modulates the mutagenic effect of many genotoxic agents. The recently observed strand specificity for removal of UV-induced cyclobutane dimers from actively transcribed genes in mammalian cells could influence the nature and distribution of mutations in a particular gene. To investigate this, we have analyzed UV-induced DNA repair and mutagenesis in the same gene, i.e. the hypoxanthine phosphoribosyl-transferase (hprt) gene. In 23 hprt mutants from V79 Chinese hamster cells induced by 2 J/m2 UV we found a strong strand bias for mutation induction: assuming that pre-mutagenic lesions occur at dipyrimidine sequences, 85% of the mutations could be attributed to lesions in the nontranscribed strand. Analysis of DNA repair in the hprt gene revealed that more than 90% of the cyclobutane dimers were removed from the transcribed strand within 8 hours after irradiation with 10 J/m2 UV, whereas virtually no dimer removal could be detected from the nontranscribed strand even up to 24 hr after UV. These data present the first proof that strand specific repair of DNA lesions in an expressed mammalian gene is associated with a strand specificity for mutation induction.