Overproduction of the poly(ADP-ribose) polymerase DNA-binding domain blocks alkylation-induced DNA repair synthesis in mammalian cells.

The zinc-finger DNA-binding domain (DBD) of poly (ADP-ribose) polymerase (PARP, EC 2.4.2.30) specifically recognizes DNA strand breaks induced by various DNA-damaging agents in eukaryotes. This, in turn, triggers the synthesis of polymers of ADP-ribose linked to nuclear proteins during DNA repair. The 46 kDa DBD of human PARP, and several derivatives thereof mutated in its first or second zinc-finger, were overproduced in Escherichia coli, in CV-1 monkey cells or in human fibroblasts to study their DNA-binding properties, the trans-dominant inhibition of resident PARP activity, and the consequences on DNA repair, respectively. A positive correlation was found between the in vitro DNA-binding capacity of the recombinant DBD polypeptides and their inhibitory effect on PARP activity stimulated by the alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Furthermore, overproduced wild-type DBD blocked unscheduled DNA synthesis induced in living cells by MNNG treatment, but not that induced by UV irradiation. These results define a critical role for the second zinc-finger of PARP for DNA single-stranded break binding and furthermore underscore the importance for PARP to act as a critical regulatory component in the repair of DNA damage induced by alkylating agents.     

Changes of 8-OH-dG levels in DNA and its base excision repair activity in rat lungs after inhalation exposure to hexavalent chromium

The co-genotoxic effects of cadmium are well recognized and it is assumed that most of these effects are due to the inhibition of DNA repair. We used the comet assay to analyze the effect of low, non-toxic concentrations of CdCl2 on DNA damage and repair-induced in Chinese hamster ovary (CHO) cells by UV-radiation, by methyl methanesulfonate (MMS) and by N-methyl-N-nitrosourea (MNU). The UV-induced DNA lesions revealed by the comet assay are single-strand breaks which are the intermediates formed during nucleotide excision repair (NER). In cells exposed to UV-irradiation alone the formation of DNA strand breaks was rapid, followed by a fast rejoining phase during the first 60 min after irradiation. In UV-irradiated cells pre-exposed to CdCl2, the formation of DNA strand breaks was significantly slower, indicating that cadmium inhibited DNA damage recognition and/or excision. Methyl methanesulfonate and N-methyl-N-nitrosourea directly alkylate nitrogen and oxygen atoms of DNA bases. The lesions revealed by the comet assay are mainly breaks at apurinic/apyrimidinic (AP) sites and breaks formed as intermediates during base excision repair (BER). In MMS treated cells the initial level of DNA strand breaks did not change during the first hour of recovery; thereafter repair was detected. In cells pre-exposed to CdCl2 the MMS-induced DNA strand breaks accumulated during the first 2h of recovery, indicating that AP sites and/or DNA strand breaks were formed but that further steps of BER were blocked. In MNU treated cells the maximal level of DNA strand breaks was detected immediately after the treatment and the breaks were repaired rapidly. In CdCl2 pre-treated cells the formation of MNU-induced DNA single-strand breaks was not affected, while the repair was slower, indicating inhibition of polymerization and/or the ligation step of BER. Cadmium thus affects the repair of UV-, MMS- and MNU-induced DNA damage, providing further evidence, that inhibition of DNA repair is an important mechanism of cadmium induced mutagenicity and carcinogenicity.     

DNA repair in lymphocytes from patients with secondary leukemia as measured by strand rejoining and unscheduled DNA synthesis

The ability to repair damage to DNA was compared in 2 groups of patients having undergone treatment for leukemia, one of which developed secondary leukemia (SL), and the other without signs of secondary malignancy (treated controls). Both were related to normal controls. DNA repair was assessed in isolated peripheral lymphocytes from the patients by measuring the rejoining of strand breaks following alkylation damage to the lymphocytes or by measuring unscheduled DNA synthesis. Day-to-day variability in the assays was considerable, but findings were that 5 out of 7 SL patients had repair deficiencies as measured by their ability to rejoin strand breaks, and 5 out of 7 had increased unscheduled DNA synthesis compared to treated and normal controls. All patients with SL and 4 out of 8 treated controls had inherent strand breaks in their DNA as compared to the normal controls when measured by alkaline elution.     

Structure of repaired sites in human DNA synthesized in the presence of inhibitors of DNA polymerases alpha and beta in human fibroblasts

Excision repair of ultraviolet damage in human fibroblasts was partially inhibited by drugs that block DNA polymerases alpha or beta (cytosine arabinoside, aphidicolin and dideoxythymidine) causing a reduction in unscheduled synthesis and an accumulation of single-strand breaks. The strand breaks accumulated in the presence of aphidicolin could be resealed within 30 min after removal of the drug, but those accumulated by cytosine arabinoside took many hours. Digestion of repaired DNA with exonuclease III or S1 nuclease revealed that even the highest concentration of polymerase inhibitors, singly or in combination, that produced maximal accumulation of single-strand breaks only blocked 37-86% of repair sites. Use of single-strand break frequencies to measure the number of repair events can therefore be in error by as much as a factor of 3. The blocked patches with free 3'OH termini were, on average, 22% of normal length, corresponding to between 6 and 17 bases (assuming a normal patch of 25-75 bases in length). Patches that remained unsealed in vivo were also resistant to sealing by T4 ligase in vitro. The data are more consistent with a mechanism of repair in which long single-strand gaps are first made by excision enzymes and subsequently filled in by DNA polymerase alpha. Strand displacement or nick translation mechanisms seem unlikely.     

The effect of aphidicolin on DNA repair in resting and mitogen stimulated human lymphocytes

Aphidicolin inhibits DNA repair in human lymphocytes as measured by unscheduled DNA synthesis and the rejoining of strand breaks. When the lymphocytes are mitogen stimulated, sensitivity of DNA repair towards aphidicolin decreases, possibly due to the induction of the beta DNA polymerase.     

The effect of deoxyadenosine plus deoxycoformycin on replicative and repair synthesis of DNA in human lymphoblasts and isolated nuclei

Deoxyadenosine plus deoxycoformycin (dCf) causes increased DNA breaks in lymphoid cells. This study explored the possible inhibition of repair synthesis of DNA by dAdo plus dCf as a cause of DNA breakage. It was shown that DNA breaks accumulated in a human T-lymphoblast cell line, CCRF-CEM, following incubation with dAdo plus dCf and were not fully repaired 20 h after their removal. Analysis of the density distribution of radiolabeled DNA on alkaline CsCl gradient showed that incubation of CCRF-CEM cells with dAdo plus dCf caused inhibition of semiconservative, but not repair synthesis of DNA. Semiconservative synthesis of DNA was also inhibited in CCRF-CEM nuclei isolated from cells pretreated with dAdo and dCf, suggesting damage to DNA replicative machinery. However, no such inhibition was observed in the nuclei of a similarly treated CCRF-CEM mutant that was deficient in adenosine kinase and deoxycytidine kinase. This suggests that dAdo must be phosphorylated in intact cells to exert its effect. Using [3H]dTTP incorporation in isolated CCRF-CEM nuclei to measure DNA synthesis, it was found that a high concentration (greater than 100 microM) of dATP inhibits semiconservative but not repair synthesis of DNA. The present studies thus indicate that accumulation of DNA strand breaks induced by dAdo plus dCf is not the consequence of inhibition of repair DNA synthesis. This implies the mechanism may involve perturbation of DNA ligation or activation of a certain process which causes DNA strand breaks. In addition, dATP may interfere with some steps of semiconservative DNA synthesis, but not the repair synthesis of DNA.     

Nature of DNA lesions induced in human hepatoma cells, human colonic cells and human embryonic lung fibroblasts by the antiretroviral drug 3'-azido-3'-deoxythymidine

This study tried to clarify the question if nuclear genotoxicity played a role in 3'-azido-3'-deoxythymidine (AZT) toxicity. We investigated cytotoxic and DNA-damaging effects of AZT on human hepatoma HepG2 and human colonic CaCo-2 cells as well as on human diploid lung fibroblasts HEL. The amount of induced DNA damage was measured by standard alkaline single cell gel electrophoresis (SCGE). The nature of induced DNA lesions was evaluated (1) by modified SCGE, which includes treatment of lysed cells with DNA repair enzymes Endo III and Fpg and enables to recognize oxidized bases of DNA, and (2) by SCGE processed in parallel at pH 13.0 (standard technique) and pH 12.1, which enables to recognize alkali labile DNA lesions and direct DNA strand breaks. Cytotoxicity of AZT was evaluated by the trypan blue exclusion technique. Our findings showed that 3-h treatment of cells with AZT decreased the viability of all cell lines studied. SCGE performed in the presence of DNA repair enzymes proved that AZT induced oxidative lesions to DNA in all cell types. In hepatoma HepG2 cells and embryonic lung fibroblasts HEL the majority of AZT-induced DNA strand breaks were pH-independent, i.e. they were identified at both pH values (12.1 and 13.0). These DNA lesions represented direct DNA breaks. In colonic Caco-2 cells DNA lesions were converted to DNA strand breaks particularly under strong alkaline conditions (pH>13.0), which is characteristic for alkali-labile sites of DNA. DNA strand break rejoining was investigated by the standard comet assay technique during 48 h of post-AZT-treatment in HepG2 and Caco-2 cells. The kinetics of DNA rejoining, considered an indicator of DNA repair, revealed that AZT-induced DNA breaks were repaired in both cell types slowly, though HepG2 cells seemed to be more repair proficient with respect to AZT-induced DNA lesions.     

DNA excision in repair proficient and deficient human cells treated with a combination of ultraviolet radiation and acridine mustard (ICR-170) or 4-nitroquinoline 1-oxide

Excision repair was measured in normal human and xeroderma pigmentosum group C fibroblasts treated with ultraviolet radiation and the carcinogens acridine mustard (ICR-170) or 4-nitroquinoline 1-oxide (4NQO) by the techniques of unscheduled synthesis, photolysis of bromodeoxyuridine incorporated into parental DNA during repair, and assays of sites sensitive to ultraviolet (UV)-endonuclease. Doses of ICR-170 and 4NQO, low enough not to inhibit unscheduled DNA synthesis (UDS), caused damage to DNA that was repaired by a long patch type mechanism and the rates of UDS decreased rapidly in the first 12 h after treatment. Repair after a combined action of UV plus ICR-170 or UV plus 4NQO was additive in normal cells and no inhibition of loss of endonuclease sensitive sites was detected. In xeroderma pigmentosum (XP) C cells there was less repair after UV plus ICR-170 than after each treatment separately; whereas there was an additive effect after UV plus 4NQO and no inhibition of loss of endonuclease sensitive sites. The results indicate that in normal human fibroblasts there are different rate limiting steps for removal of chemical and physical damages from DNA and that XP cells have a different repair system for ICR-170, not just a lower level, than normal cells. Possibly the same long patch repair system works on 4NQO damage in both normal and XP cells.     

Role of active oxygen species in metal-induced DNA strand breakage in human diploid fibroblasts

The ability of 6 metal salts to induce DNA damage in human diploid fibroblasts was examined. Cadmium, magnesium, manganese, chromium(VI), zinc and selenite were all shown to induce DNA strand breaks as measured by two independent assays. DNA strand breaks were repaired within 2-4 h after removal of metal and this repair appeared not to be sensitive to "long-patch" repair inhibitors. With the exception of selenite, metal-induced DNA damage appeared to be mediated via the formation of active oxygen species since oxygen scavengers when administered simultaneously with the metal, antagonized strand break formation. Selenite-induced DNA damage (as previously reported) was dependent on the formation of a selenite-glutathione conjugant and was not affected by oxygen radical scavengers. Scavenger treatment did not enhance cloning ability of metal-treated cells suggesting that DNA strand breaks may not be important in metal-induced cytotoxicity.     

A retarded rate of DNA replication and normal level of DNA repair in Werner's syndrome fibroblasts in culture

We investigated the cloning efficiency, DNA repair, and the rate of DNA replication in the skin fibroblasts from patients with Werner's syndrome (WS) of an autosomal recessive premature aging disease. Five WS strains exhibited normal levels of sensitivity toward X-ray and UV killings and repair of X-ray induced single strand breaks of DNA (rejoining) and UV damage to DNA (unscheduled DNA synthesis). The sedimentation of newly synthesizing DNA in alkaline sucrose gradients demonstrated a characteristic feature that only the elongation rate of DNA chains, estimated by the molecular weight increase, was significantly slower during early passages in WS cells than in normal Hayflick Phase II fibroblasts. In addition, plating efficiencies as well as the replicative potentials of five WS strains were more limited than those of normal cells under the identical culture conditions. It seems therefore that at least in the WS cells tested, the slow rate of DNA replication may be more related to the shortened lifespan and enhanced cell death, as manifestation of premature senescence at the cellular level, than be the DNA repair ability.     

Influence of cellular differentiation on repair of ultraviolet-induced DNA damage in murine proadipocytes

The effects of cellular differentiation on the repair of DNA damage induced by uv radiation were investigated in the murine 3T3-T proadipocyte cell culture system. Upon exposure to human plasma, actively cycling 3T3-T cells (stem cells) undergo growth arrest, which is followed by terminal differentiation into lipid-laden adipocytes. In response to uv irradiation, the level of unscheduled DNA synthesis is significantly lower in adipocytes as compared to stem cells. The alkaline elution assay was used to monitor the appearance of repair-induced strand breaks in 3T3-T cells after uv irradiation. DNA strand breaks were detected in stem cells by 4 min post-uv with essentially no further increase after 8 min. When terminally differentiated adipocytes were irradiated and allowed to repair, however, more strand breaks were present at 4 min and, in marked contrast to stem cells, continued to accumulate in adipocytes for at least 16 min post-uv. Inhibition of repair-replication with hydroxyurea and cytosine arabinoside significantly increased accumulation of repair-induced strand breaks in stem cells, yet had little effect on this accumulation in adipocytes. For stem cells and adipocytes, incision activity was linear out to at least 10 Jm-2 without saturation. These data suggested that 3T3-T cell differentiation is accompanied by a defect in some postincision process of the excision-repair pathway.     

Less repair of pyrimidine dimers and single-strand breaks in genes by scid cells.

Severe combined immunodeficient (Scid) mice have a mutation in the catalytic subunit of the DNA binding protein kinase that is involved in repair of double-strand breaks in DNA. To determine if the protein also influences repair of single-strand breaks, we examined the ability of Scid cells to repair lesions introduced by ultraviolet light and gamma-ray irradiation. DNA repair was measured both in total genomic DNA and in specific genes from murine Scid and wildtype fibroblast cell lines. The removal of pyrimidine dimers and repair of strand breaks in genes was measured using quantitative Southern blot analyses. After ultraviolet irradiation, there was no significant difference in the repair of photoproducts in bulk DNA between Scid and wildtype cells, as measured by cellular survival and unscheduled DNA synthesis. However, deficient repair was evident in genes, where Scid cells had 25-50% less repair in the c-myc and dihydrofolate reductase genes. After gamma-irradiation, Scid fibroblasts had 20-35% less repair of DNA breaks in immunoglobulin kappa and heavy constant genes than wildtype cells. The data suggest that intact DNA-PK enzyme is needed for the efficient operation of cellular repair of pyrimidine dimers and single-strand breaks in genes, as well as in its established role in rejoining double-strand breaks.     

亚硒酸钠诱发的晶状体上皮细胞DNA损伤及修复

观察了亚硒酸钠（Ｎａ２ＳｅＯ３）在体外作用于大鼠晶状体上皮细胞（ＲＬＥｃｅｌｌｓ）而造成的ＤＮＡ单链断裂（ｓｉｎｇｌｅｓｔｒａｎｄｂｒｅａｋｓ,ＳＳＢ）,并对其ＤＮＡ损伤、修复动力学做了初步研究．发现ＳＳＢ严重程度与亚硒酸钠的浓度呈线性相关,其ＳＳＢ重接修复约在３０～６０ｍｉｎ内完成．还作了有关非程序ＤＮＡ合成（ＵＤＳ）的检测,发现与ＳＳＢ相比,ＵＤＳ发生迟且持续时间更长,提示Ｎａ２ＳｅＯ３可能在体外对大鼠晶状体上皮细胞除造成ＳＳＢ以外,还可能造成其它种类的ＤＮＡ损伤．     

Inhibition of replicon initiation in human cells following stabilization of topoisomerase-DNA cleavable complexes.

Diploid human fibroblast strains were treated for 10 min with inhibitors of type I and type II DNA topoisomerases, and after removal of the inhibitors, the rate of initiation of DNA synthesis at replicon origins was determined. By alkaline elution chromatography, 4'-(9-acridinylamino)methanesulfon-m-anisidide (amsacrine), an inhibitor of DNA topoisomerase II, was shown to produce DNA strand breaks. These strand breaks are thought to reflect drug-induced stabilization of topoisomerase-DNA cleavable complexes. Removal of the drug led to a rapid resealing of the strand breaks by dissociation of the complexes. Velocity sedimentation analysis was used to quantify the effects of amsacrine treatment on DNA replication. It was demonstrated that transient exposure to low concentrations of amsacrine inhibited replicon initiation but did not substantially affect DNA chainelongation within operating replicons. Maximal inhibition of replicon initiation occurred 20 to 30 min after drug treatment, and the initiation rate recovered 30 to 90 min later. Ataxia telangiectasia cells displayed normal levels of amsacrine-induced DNA strand breaks during stabilization of cleavable complexes but failed to downregulate replicon initiation after exposure to the topoisomerase inhibitor. Thus, inhibition of replicon initiation in response to DNA damage appears to be an active process which requires a gene product which is defective or missing in ataxia telangiectasia cells. In normal human fibroblasts, the inhibition of DNA topoisomerase I by camptothecin produced reversible DNA strand breaks. Transient exposure to this drug also inhibited replicon initiation. These results suggest that the cellular response pathway which downregulates replicon initiation following genotoxic damage may respond to perturbations of chromatin structure which accompany stabilization of topoisomerase-DNA cleavable complexes.     

Measurement of the kinetics of DNA repair synthesis after uv irradiation using immunochemical staining of incorporated 5-bromo-2'-deoxyuridine and flow cytometry

The kinetics of unscheduled DNA synthesis in normal human fibroblasts was characterized by flow cytometry utilizing the immunofluorescent detection of 5-bromo-2'-deoxyuridine (BrdUrd) incorporated into cellular DNA during the repair process. Quiescent normal human fibroblasts were irradiated with ultraviolet light and incubated in the presence of BrdUrd during a postirradiation repair period. The amount of unscheduled DNA synthesis was then quantified in the quiescent cells by immunofluorescence staining using monoclonal antibodies against BrdUrd incorporated into the DNA. Significant amounts of unscheduled DNA synthesis were measured after doses as low as 0.1 J/m2 and for time periods as short as 15 min. The initial repair rate was found to be linear with time at all doses tested until repair neared completion. Interestingly, the initial repair rate was constant for doses over the range of 5 to 40 J/m2, whereas the time to completion of repair was dose dependent. These results suggest that above 5 J/m2 in normal human fibroblasts, the repair process is saturated but continues to function until all available regions are repaired. Using this methodology for measuring unscheduled DNA synthesis in combination with second and third flow markers, it is now possible to measure unscheduled DNA synthesis in heterogeneous mixtures of cells.     

Inhibitors of repair DNA synthesis.

We have measured repair DNA synthesis in UV-irradiated normal human fibroblasts, grown to a defined state of quiescence in order to avoid the problem of discriminating repair from replicative DNA synthesis. We have assessed the effects of various DNA synthesis inhibitors on repair. Inhibition of repair synthesis by hydroxyurea, 1-beta-D-arabinofuranosylcytosine and aphidicolin is associated with the ability to accumulate DNA breaks due to enzymic incision at DNA damage sites; the inhibition by novobiocin is in accord with its known ability to block incision.     

DNA strand breaks: the DNA template alterations that trigger p53-dependent DNA damage response pathways.

The tumor suppressor protein p53 serves as a critical regulator of a G1 cell cycle checkpoint and of apoptosis following exposure of cells to DNA-damaging agents. The mechanism by which DNA-damaging agents elevate p53 protein levels to trigger G1/S arrest or cell death remains to be elucidated. In fact, whether damage to the DNA template itself participates in transducing the signal leading to p53 induction has not yet been demonstrated. We exposed human cell lines containing wild-type p53 alleles to several different DNA-damaging agents and found that agents which rapidly induce DNA strand breaks, such as ionizing radiation, bleomycin, and DNA topoisomerase-targeted drugs, rapidly triggered p53 protein elevations. In addition, we determined that camptothecin-stimulated trapping of topoisomerase I-DNA complexes was not sufficient to elevate p53 protein levels; rather, replication-associated DNA strand breaks were required. Furthermore, treatment of cells with the antimetabolite N(phosphonoacetyl)-L-aspartate (PALA) did not cause rapid p53 protein increases but resulted in delayed increases in p53 protein levels temporally correlated with the appearance of DNA strand breaks. Finally, we concluded that DNA strand breaks were sufficient for initiating p53-dependent signal transduction after finding that introduction of nucleases into cells by electroporation stimulated rapid p53 protein elevations. While DNA strand breaks appeared to be capable of triggering p53 induction, DNA lesions other than strand breaks did not. Exposure of normal cells and excision repair-deficient xeroderma pigmentosum cells to low doses of UV light, under conditions in which thymine dimers appear but DNA replication-associated strand breaks were prevented, resulted in p53 induction attributable to DNA strand breaks associated with excision repair. Our data indicate that DNA strand breaks are sufficient and probably necessary for p53 induction in cells with wild-type p53 alleles exposed to DNA-damaging agents.     

Processing of abasic DNA clusters in hApeI-silenced primary fibroblasts exposed to low doses of X-irradiation

Clustered damage in DNA includes two or more closely spaced oxidized bases, strand breaks or abasic sites that are induced by high- or low-linear-energy-transfer (LET) radiation, and these have been found to be repair-resistant and potentially mutagenic. In the present study we found that abasic clustered damages are also induced in primary human fibroblast cells by low-LET X-rays even at very low doses. In response to the induction of the abasic sites, primary fibroblasts irradiated by low doses of X-rays in the range 10–100 cGy showed dose-dependent up-regulation of the DNA repair enzyme, ApeI. We found that the abasic clusters in primary fibroblasts were more lethal to cells when hApeI enzyme expression was down-regulated by transfecting primary fibroblasts with hApeI siRNA as determined by clonogenic survival assay. Endonuclease activity of hApeI was found to be directly proportional to hApeI gene-silencing efficiency. The DNA repair profile showed that processing of abasic clusters was delayed in hApeI-siRNA-silenced fibroblasts, which challenges the survival of the cells even at very low doses of X-rays. Thus, the present study is the first to attempt to understand the induction of cluster DNA damage at very low doses of low-LET radiation in primary human fibroblasts and their processing by DNA repair enzyme ApeI and their relation with the survival of the cells.     

The role of deoxynucleoside triphosphate pools in the inhibition of DNA-excision repair and replication in human cells by hydroxyurea

The effects of hydroxyurea (HU) on the DNA-excision repair process in human cells has been systematically examined. It is demonstrated that HU induces DNA single-strand break accumulation in a dose-dependent fashion in ultraviolet-irradiated and MMS-treated confluent but not log-phase fibroblasts and that these breaks are clearly the consequence of the inhibition by HU of the enzyme, ribonucleotide reductase. The breaks form rapidly, are stable for at least 10 h and largely disappear by 20 h. The production of these DNA-strand breaks is antagonized by a combined treatment of 10 microM deoxyadenosine, deoxycytidine and deoxyguanosine whereas thymidine potentiates strand-break formation at low HU concentrations. It is also confirmed that HU, while inhibiting replicative synthesis has no apparent inhibitory effect on unscheduled DNA synthesis (UDS) although the increased uptake of labeled DNA precursors into HU-treated cells makes it difficult to assess the actual effects on the repair-synthetic process. Analysis of the effects of HU on deoxynucleoside triphosphate pool levels and the demonstration of the failure of the HU block to replicative synthesis to be reversed by high (1 mM) concentrations of added deoxynucleosides lend support to the notion of compartmentalized dNTP pools for repair and replication.     

In vivo non-enzymatic repair of DNA oxidative damage by polyphenols

The non-enzymatic repair of DNA oxidative damage can occur in a purely chemical system, but data show that it might also occur in cells. Human hepatoma cells (SMMC-7721) and human hepatocyte cells (LO2) were treated with 200 μM H₂O₂ for 30 min to induce oxidative DNA damage quantified by amount of 8-OHdG and degree of DNA strand breaks, without inducing enzymatic repair. The dynamics of enzymatic repair activity quantified by unscheduled DNA synthesis, within 30 min after removal of H₂O₂ enzymatic repair mechanism has not been initiated. However, pre-incubation with low micromolar level polyphenols, quercetin or rutin can significantly attenuate DNA damage in both cell lines, indicating that the polyphenols did not work through an enzymatic mechanism. Unscheduled DNA synthesis after removal of H₂O₂ was also markedly decreased by quercetin and rutin. Combined with our previous studies of fast reaction chemistry, the inhibitory effect of polyphenols have to be assigned to non-enzymatic repair mechanism rather than to enzymatic repair mechanism or antioxidant mechanism.