The kinetics of thymine dimer excision in ultraviolet-irradiated human cells

We have investigated the kinetics of the loss of thymine dimers from the acid-insoluble fraction of several ultraviolet (UV)-irradiated cultured human cell lines. Our results show that UV fluences between 10 and 40 J/m2 produce an average of 21-85 x 10(5) thymine dimers per cell and an eventual maximal loss per cell of 12-20 x 10(5) thymine dimers. The time for half-maximal loss of dimers ranged from 12-22 h after UV irradiation. In contrast, the time for half-maximal repair synthesis of DNA measured by autoradiography was 4.5 h. This figure agrees well with reported half-maximal repair synthesis times, which range from 0.5 to 3.6 h based on our analysis. The discrepancy in the kinetics of the loss of thymine dimers from DNA and repair synthesis is discussed in terms of possible molecular mechanisms of thymine dimer excision in vivo and in terms of possible experimental artifacts.     

Repair of ultraviolet light-induced damage in Micrococcus radiophilus, an extremely resistant microorganism.

Repair of ultraviolet radiation damage was examined in an extremely radioresistant organism, Micrococcus radiophilus. Measurement of the number of thymine-containing dimers formed as a function of ultraviolet dose suggests that the ability of this organism to withstand high doses of ultraviolet radiation (20,000 ergs/mm2) is not related to protective screening by pigments. M. radiophilus carries out a rapid excision of thymine dimers at doses of ultraviolet light up to 10,000 ergs/mm2. Synthesis of deoxyribonucleic acid is reduced after irradiation, but after removal of photodamage the rate approaches that in unirradiated cells. A comparison is drawn with Micrococcus luteus and M. radiodurans. We conclude that the extremely high resistance to ultraviolet irradiation in M. radiophilus is at least partly due to the presence of an efficient excision repair system.     

Repair of deoxyribonucleic acid in ultraviolet light-sensitive and -resistant Dictyostelium discoideum strains.

Some responses of the cellular slime mold Dictyostelium discoideum to ultraviolet light (UV) irradiation were investigated by analyzing two aspects of deoxyribonucleic acid (DNA) excision repair in the vegetative cells: (i) the fate of thymine-containing dimers and (ii) the production and rejoining of single-strand breaks. Experiments were done with the parental, radiation-resistant NC-4 strain and with the radiation-sensitive gammas-13 strain. The majority (greater than 85%) of the thymine-containing dimers produced in both strains by an energy fluence of 100/Jm2 were removed from the acid-insoluble DNA fraction within the first 3 to 4 h of reincubation in the dark. Moreover, as measured by alkaline sucrose gradients, single-strand breaks appeared in the DNA of both NC-4 and gammas-13 irradiated cells very rapidly and at low temperatures. This was presumed to be a result of the incision (nicking) step of excision repair as performed by UV-specific endonuclease(s). In NC-4 the time required for dimer excision correlated with the sealing of breaks as well as with the UV-induced division delays. In gammas-13 the single-strand breaks were closed at a slower rate than in NC-4. However, this was not accompanied by more extensive division delays.     

Dose response, wavelength dependence and rate of excision of ultraviolet radiation-induced pyrimidine dimers in mouse skin DNA

The yield of thymine-containing dimers produced in mouse skin DNA in vivo by 290 nm ultraviolet radiation was shown to increase with dose up to around 2000 J/m2 and subsequently at a much slower rate up to 8000 J/m2. The study of wavelength dependence of dimer formation in skin indicated that 290 nm was the most effective wavelength of those investigated, followed by 300, 280 and 260 nm, with 310 nm being by far the least effective. A reduction in the number of dimers present in skin DNA was shown to occur by 24 h post-irradiation in a dose-dependent manner. A significant percentage of the dimers was, however, found to persist in the skin until at least 72 h post-irradiation.     

Characterization of Excision Repair in Neurospora crassa

The excision of pyrimidine dimers from the deoxyribonucleic acid (DNA) of Neurospora crassa was examined. Postirradiation incubation in the presence of several chemicals known to inhibit various repair systems indicated that caffeine reduced the rate of excision twofold, but did not inhibit excision completely as did proflavine and quinacrine. Examination of the time course of excision showed that repair occurs at a relatively rapid rate: approximately 60 dimers excised per min after 500 ergs/mm(2). Further evidence for rapid excision was obtained by sedimentation analysis of DNA; the maximal number of breaks introduced during repair was three, suggesting that breaks are repaired almost as fast as they are made and that only a few dimers are repaired at a time. Repair synthesis was measured by prelabeling the DNA with (15)N and D(2)O, and then subjecting the DNA to equilibrium density gradient centrifugation after postirradiation incubation with (32)P. Accumulation of single-strand breaks with increasing dose of ultraviolet radiation suggested that the limiting step was subsequent to the incision and excision steps of repair. Equilibrium CsCl centrifugation demonstrated that the limiting step in excision was repair synthesis.     

Deoxyribonucleic acid excision repair in chromatin after ultraviolet irradiation of human fibroblasts in culture.

We have exposed confluent normal human fibroblasts to ultraviolet (UV) fluences of 5, 14, or 40 J/m2 and monitored the specific activity of post-UV repair synthesis in chromatin with [3H]thymidine pulses. We have shown that under conditions where no semiconservative deoxyribonucleic acid (DNA) synthesis is detectable, the specific activity of repair label in micrococcal nuclease resistant (core particle) DNA is about one-fifth that in bulk DNA at all three UV fluences. On the other hand, the distribution of thymine-containing pyrimidine dimers in bulk and nuclease-resistant regions measured either immediately after irradiation or at later times showed no significant differences; preferential labeling of linker (nuclease-sensitive) DNA during repair synthesis is thus apparently not due to a predominance of UV-induced photoproducts in linker relative to core particle DNA in the nucleosome. Pulse and pulse--chase experiments at 14 or 40 J/m2 with normal human or repair-deficient xeroderma pigmentosum (XP) cells showed that at most 30% of repair label in all these cells shifts from nuclease-sensitive (linker) DNA to nuclease-resistant (core particle) DNA.     

Recovery of DNA synthesis after ultraviolet irradiation of xeroderma pigmentosum cells depends on excision repair and is blocked by caffeine

Normal human and xeroderma pigmentosum (XP, excision-defective group A) cells (both SV40-transformed) pulse-labeled with [(3)H]thymidine at various times after irradiation with ultraviolet light showed a decline and recovery of both the molecular weights of newly synthesized DNA and the rates of synthesis per cell. At the same ultraviolet dose, both molecular weights and rates of synthesis were inhibited more in XP than in normal cells. This indicates that excision repair plays a role in minimizing the inhibition of chain growth, possibly by excision of dimers ahead of the growing point. The ability to synthesize normal-sized DNA recovered more rapidly than rates of synthesis in normal cells, but both parameters recovered in phase in XP cells. During recovery in normal cells there are therefore fewer actively replicating clusters of replicons because the single-strand breaks involved in the excision of dimers inhibit replicon initiation. XP cells have few excision repair events and therefore fewer breaks to interfere with initiation, but chain growth is blocked by unexcised dimers. In both cell types recovery of the ability to synthesize normal-sized DNA was prevented by growing cells in caffeine after irradiation, possibly because of competition between the DNA binding properties of caffeine and replication proteins.Our observations imply that excision repair and semiconservative replication interact strongly in irradiated cells to produce a complex spectrum of changes in DNA replication which may be confused with parts of alternative systems such as post-replication repair.     

Photoreactivation of UV damage in Escherichia coli uvrA6: lethality is more effectively reversed than either premutagenic lesions or SOS induction

The effect of cyclobutyl pyrimidine dimers on cytotoxicity, induction of synthesis of the RecA and UmuC proteins, and mutagenesis was studied in Escherichia coli uvrA6 cells possessing excess amounts of photoreactivating enzyme. Exposure of 254 nm ultraviolet-irradiated (10 J/m2) cells to radiation from daylight fluorescent lamps reduced the amounts of thymine-containing dimers in a photoreactivating fluence-dependent manner, up to about 90% reduction at 5 min exposure. Of the lethal ultraviolet damage, 85% was photoreactivable (i.e. cyclobutyl pyrimidine dimers) and 15% was non-photoreactivable. An incident fluence of 1 J/m2 resulted in approximately a 5-fold increase in the synthesis of the RecA and UmuC proteins, as compared to the spontaneous level. If the UV-irradiated cell suspensions were illuminated with a fluorescent lamp at a dose which resulted in the full photoreactivation of viability, the yields of both proteins were reduced to 60% of the non-photoreactivated control cells. Furthermore, photoreactivation was shown to be more effective in the repair of lethal damage than in the repair of premutational damage. These experiments suggest that, among lethal damages, non-photoreactivable damage plays a more important role in both induction of the SOS functions and mutagenesis in uvrA6 cells than do cyclobutyl pyrimidine dimers.     

Kinetics of unscheduled DNA synthesis in UV-irradiated chicken embryo fibroblasts

Unscheduled DNA synthesis induced by 254-nm UV radiation in chicken embryo fibroblasts was examined for 24 h following irradiation, while cells were kept in the dark. The effect on this repair process of a 2-4 h exposure to photoreactivating light immediately after UV was studied. Initial [3H]thymidine incorporation in the light-treated cells was only slightly different from that in cells not exposed to light, but a distinct difference in rate and cumulative amount of unscheduled DNA synthesis was seen several hours after irradiation. By varying the UV dose and the time allowed for photoreactivation, the amount of dimers (determined as sites sensitive to a M. luteus UV-endonuclease) and non-dimers could be changed. The results of these experiments suggest that excision repair of dimers, rather than non-dimer products, is responsible for the unscheduled DNA synthesis seen after UV irradiation.     

Inhibition of DNA repair by trifluoperazine

We examined the possible role of calmodulin in the excision repair of ultraviolet light-induced pyrimidine dimers in damaged DNA by means of specialized assay systems. These assays included bromodeoxyuridine photolysis, dimer chromatography and cytosine arabinoside incorporation in conjunction with hydroxyurea. The calmodulin antagonist, trifluoperazine, and the calcium-chelating agent, EGTA, were employed to ascertain what affect calmodulin played in the repair process. Normal human fibroblast cells were used in all studies described in this report. After exposure to 10 J/m2 of 254 nm light, we observed a decrease of about 30% in the number of single-strand breaks produced in the presence of 25 microM trifluoperazine (1.9 vs. 3.3) in controls although the numbers of bases re-inserted in the repaired regions were similar (64 vs. 72). Measurement of thymine-containing dimers remaining throughout a 24 h time period indicated a 30% difference in the excision of dimers when tested with either EGTA or trifluoperazine. We also observed a significant decrease in the number of cytosine arabinoside arrested repair sites in the presence of either EGTA or trifluoperazine. The results are discussed with relation to the possibility of calmodulin altering the initial incision by repair endonuclease.     

Inhibition of DNA replication by ultraviolet light.

DNA replication in ultraviolet-irradiated HeLa cells was studied by two different techniques: measurements of the kinetics of semiconservative DNA synthesis, and DNA fiber autoradiography. In examining the kinetics of semiconservative DNA synthesis, density label was used to avoid measuring the incorporation due to repair replication. The extent of inhibition varied with time. After doses of less than 10J/m2 the rate was initially depressed but later showed some recovery. After higher doses, a constant, low rate of synthesis was seen for at least the initial 6 h. An analysis of these data indicated that the inhibition of DNA synthesis could be explained by replication forks halting at pyrimidine dimers. DNA fiber autoradiography was used to further characterize replication after ultraviolet irradiation. The average length of labeled segments in irradiated cells increased in the time immediately after irradiation, and then leveled off. This is the predicted pattern if DNA synthesis in each replicon continued at its previous rate until a lesion is reached, and then halted. The frequency of lesions that block synthesis is approximately the same as the frequency of pyrimidine dimers.     

Excision repair of ultraviolet damage in mammalian cells. Evidence for two steps in the excision of pyrimidine dimers

The incidence of pyrimidine dimer formation and the kinetics of DNA repair in African green monkey kidney CV-1 cells after ultraviolet (UV) irradiation were studied by measuring survival, T4 endonuclease V-sensitive sites, the fraction of pyrimidine dimers in acid-insoluble DNA as determined by thin layer chromatography (TLC), and repair replication. CV-1 cells exhibit a survival curve with extrapolation number n = 7.8 and Do = 2.5 J/m2. Pyrimidine dimers were lost from acid-insoluble DNA more slowly than endonuclease-sensitive sites were lost from or new bases were incorporated into high molecular weight DNA during the course of repair. Growth of CV-1 cultures in [3H]thymidine or X-irradiation (2 or 10 krads) 24 h before UV irradiation had no effect on repair replication induced by 25 J/m2 of UV. These results suggest that pyrimidine dimer excision measurements by TLC are probably unaffected by radiation from high levels of incorporated radionuclides. The endonuclease-sensitive site and TLC measurements can be reconciled by the assumption that pyrimidine dimers are excised from high molecular weight DNA in acid-insoluble oligonucleotides that are slowly degraded to acid-soluble fragments.     

Response of tobacco and Haplopappus cells to ultraviolet irradiation after posttreatment with photoreactivating light

Experiments were performed to test whether significant amounts of pyrimidine dimers are produced in cultured cells of tobacco (Nicotiana tabacum L. var. Xanthi) and of Haplopappus gracilis by ultraviolet light in the biological dose range and whether either or both dark and light repair systems exist in these cells. Thymine-containing dimers were found to be formed quite readily in both kinds of cells, but neither kind appeared to possess the excision repair system. Results indicated that UV-induced growth inhibition of tobacco cells could be photoreactivated and that tobacco cells could monomerize UV-induced, thymine-containing dimers in the DNA. On the other hand, neither increase in growth nor monomerization of dimers was observed in the UV-irradiated Haplopappus cell culture after treatment with photoreactivating light.     

Quantification of ultraviolet-C irradiation induced cyclobutane pyrimidine dimers and their removal in Beauveria bassiana conidiospore DNA

Ultraviolet (UV) radiation-induced DNA damage leading to entomopathogenic fungal inactivation is commonly measured by viability counts. Here we report the first quantification of UV-induced cyclobutane pyrimidine dimers (CPD) in DNA of the entomopathogenic fungus, Beauveria bassiana. Changes in the mobility of UV-C irradiated DNA were resolved with CPD specific bacteriophage T4 endonuclease V and alkaline agarose gel electrophoresis. The maximum number of CPD formed in B. bassiana DNA in vitro by UV-C irradiation was 28 CPD/ 10 kb after 720 J/m2 dose. The maximum number of CPDs formed in B. bassiana conidiospore DNA irradiated in vivo was 15 CPD/10 kb after 480 J/m2 dose and was quantified from conidiospores that were incubated to allow photoreactivation and nucleotide excision repair. The conidiospores incubated for photoreactivation and nucleotide excision repair showed decreased number of CPD/10 kb DNA and a higher percent survival of conidiospore populations than conidiospores not allowed to repair.     

Preapoptotic chromatin changes induced by ultraviolet B irradiation in human erythroleukemia K562 cells

Exponentially growing human erythroleukemia K562 cells were permeabilized and the dose dependent decrease of DNA synthesis rate was measured after ultraviolet (UV B, 290 nm) irradiation. Cells were able to overcome 2 and 5 J/m2 UV doses, partial recovery was observed at 15 J/m2, while at high (25 J/m2) UV dose replicative DNA synthesis remained suppressed. K562 cells were subjected to synchronization prior to and after UV irradiation (24 J/m2) and 18 fractions were collected by centrifugal elutriation. Cell cycle analysis by flow cytometry did not show early apoptotic cells after UV irradiation. The gradual increase in DNA content typical for non-irradiated cells was contrasted by an early S phase block between 2.2 and 2.4 C-values after UV irradiation. Cell cycle dependent chromatin changes after ultraviolet irradiation were seen as a fine fibrillary network covering the mainly fibrous chromatin structures and incompletely folded primitive chromosomes. Based on observations after UV irradiation and on earlier results with cadmium treatment and gamma irradiation, we confirm that typical chromatin changes characteristic to genotoxic agents can be recognized and classified.     

Formation of DNA strand breaks in UV-irradiated human fibroblast preparations

The formation of DNA strand breaks was characterized in human fibroblasts prepared by several methods. In quiescent monolayer cultures of normal human fibroblasts (NHF), exposure to 254 nm radiation (UV) caused the rapid appearance of DNA strand breaks as monitored by alkaline elution analysis. Maximal levels of DNA breaks were seen 30 min after 10 J/m2; thereafter, strand breaks disappeared. Breakage soon after irradiation appeared to saturate at fluences above 10 J/m2. Xeroderma pigmentosum fibroblasts belonging to complementation group A (XPA) did not display this response which reflects operations of the nucleotidyl DNA excision repair pathway. When fibroblast strains were released from culture dishes by enzymatic digestion with trypsin or by scraping with a rubber policeman, UV-dependent DNA breakage displayed altered dose and time responses. Few breaks were detected in detached preparations of NHF after 10 J/m2 indicating inactivation of nucleotidyl DNA excision repair. The fluence response in detached fibroblasts was linear up to an incident fluence of 100 J/m2. Moreover, after 25 or 50 J/m2, strand breaks accumulated as a linear function of time for up to 2 h after irradiation. This UV-dependent and time-dependent incision activity was also observed in XPA monolayers and released-cell preparations. In permeable fibroblast preparations, DNA breaks accumulated in unirradiated cells that had been released with trypsin or by scraping. Permeabilization in situ saponin to open the plasma membrane produced a cell preparation that accumulated fewer UV-independent breaks. In saponin-permeabilized NHF that were irradiated with 10 J/m2, UV-dependent strand incision activity occurred at about 30% of the rate of incision seen in intact monolayer NHF. These results reveal at least 3 DNA strand incision activities in human fibroblast preparations of which only one reflects operation of the nucleotidyl DNA excision repair pathway.     

Repair of UV-induced pyrimidine dimers in the individual genes Gart, Notch and white from Drosophila melanogaster cell lines.

The excision repair of UV-induced pyrimidine dimers was investigated in three genes: Gart, Notch and white in a permanent Drosophila cell line Kc, derived from wild type Drosophila melanogaster embryonic cells. In this cell line Gart and Notch are actively transcribed, whereas white is not expressed. In all three genes UV-induced pyrimidine dimers were removed with the same rate and to the same extent: 60% removal within 16 hours, up to 80-100% in 24 hours after irradiation with 10 or 15 J/m2 UV. These kinetics are similar to the time course of dimer removal measured in the genome overall. No difference in repair of the inactive white locus compared to the active Gart and Notch genes was found. Similar results were obtained using a different wild type cell line, SL2, although repair appeared to be somewhat slower in this cell line. The results are discussed with respect to the data found for gene specific repair in other eukaryotic systems.     

Repair rate in human fibroblasts measured by thymine dimer excorporation

Summary The UV photoproduct, thymine dimer ( ), is excorporated with a remarkably low rate from the DNA of human fibroblasts grown in cell culture. An UV dose of 18 J/m² creates 0.045% (related to thymine). Within the first two days of repair logarithmically growing and quiescent fibroblasts exhibit the same repair rates; thereafter, the proportion of is lower in growing cells due to recovery of DNA replication. Only about 50% of the lesions are excised within 24 h. In quiescent cells, 13% of the thymine dimers originally present can be detected as late as a week after UV-irradiation. Two distinct first-order rate constants indicate that approximately half of the dimers are less accessible to repair. Repair measured by the nucleoid decondensation technique corresponds to the faster repair rate, whereas the slow repair rate cannot be detected by this method. Saturation of repair is found beyond 27 J/m². The remarkably slow rate of excision indicates that thymine dimers are not lethal lesions in human fibroblasts.