Replicon size and excision repair as factors in the inhibition and recovery of DNA synthesis from ultraviolet damage

Cellular Senescence in Neurodegenerative Diseases

Cellular senescence is a homeostatic biological process characterized by a permanent state of cell cycle arrest that can contribute to the decline of the regenerative potential and function of tissues. The increased presence of senescent cells in different neurodegenerative diseases suggests the contribution of senescence in the pathophysiology of these disorders. Although several factors can induce senescence, DNA damage, oxidative stress, neuroinflammation, and altered proteostasis have been shown to play a role in its onset. Oxidative stress contributes to accelerated aging and cognitive dysfunction stages affecting neurogenesis, neuronal differentiation, connectivity, and survival. During later life stages, it is implicated in the progression of cognitive decline, synapse loss, and neuronal degeneration. Also, neuroinflammation exacerbates oxidative stress, synaptic dysfunction, and neuronal death through the harmful effects of pro-inflammatory cytokines on cell proliferation and maturation. Both oxidative stress and neuroinflammation can induce DNA damage and alterations in DNA repair that, in turn, can exacerbate them. Another important feature associated with senescence is altered proteostasis. Because of the disruption in the function and balance of the proteome, senescence can modify the proper synthesis, folding, quality control, and degradation rate of proteins producing, in some diseases, misfolded proteins or aggregation of abnormal proteins. There is an extensive body of literature that associates cellular senescence with several neurodegenerative disorders including Alzheimer’s disease (AD), Down syndrome (DS), and Parkinson’s disease (PD). This review summarizes the evidence of the shared neuropathological events in these neurodegenerative diseases and the implication of cellular senescence in their onset or aggravation. Understanding the role that cellular senescence plays in them could help to develop new therapeutic strategies.

PCNA appears in two populations of slow and fast diffusion with a constant ratio throughout S-phase in replicating mammalian cells

DNA replication is a fundamental cellular process that precedes cell division. Proliferating cell nuclear antigen (PCNA) is a central scaffold protein that orchestrates DNA replication by recruiting many factors essential for the replication machinery. We studied the mobility of PCNA in live mammalian cells using single-particle tracking in combination with photoactivated-localization microscopy (sptPALM) and found two populations. The first population which is only present in cells with active DNA replication, showed slow diffusion and was found to be located in replication foci. The second population showed fast diffusion, and represents the nucleoplasmic pool of unbound PCNA not involved in DNA replication. The ratio of these two populations remained constant throughout different stages of S-phase. A fraction of molecules in both populations showed spatially constrained mobility. We determined an exploration radius of ~100 nm for 13% of the slow-diffusing PCNA molecules, and of ~600 nm for 46% of the fast-diffusing PCNA molecules.

Regulation of DNA replication by the S-phase DNA damage checkpoint

Cells slow replication in response to DNA damage. This slowing was the first DNA damage checkpoint response discovered and its study led to the discovery of the central checkpoint kinase, Ataxia Telangiectasia Mutated (ATM). Nonetheless, the manner by which the S-phase DNA damage checkpoint slows replication is still unclear. The checkpoint could slow bulk replication by inhibiting replication origin firing or slowing replication fork progression, and both mechanisms appear to be used. However, assays in various systems using different DNA damaging agents have produced conflicting results as to the relative importance of the two mechanisms. Furthermore, although progress has been made in elucidating the mechanism of origin regulation in vertebrates, the mechanism by which forks are slowed remains unknown. We review both past and present efforts towards determining how cells slow replication in response to damage and try to resolve apparent conflicts and discrepancies within the field. We propose that inhibition of origin firing is a global checkpoint mechanism that reduces overall DNA synthesis whenever the checkpoint is activated, whereas slowing of fork progression reflects a local checkpoint mechanism that only affects replisomes as they encounter DNA damage and therefore only affects overall replication rates in cases of high lesion density.

Integrating S-phase checkpoint signaling with trans-lesion synthesis of bulky DNA adducts

Bulky adducts are DNA lesions generated in response to environmental agents including benzo[a]pyrene (a combustion product) and solar ultraviolet radiation. Error-prone replication of adducted DNA can cause mutations, which may result in cancer. To minimize the detrimental effects of bulky adducts and other DNA lesions, S-phase checkpoint mechanisms sense DNA damage and integrate DNA repair with ongoing DNA replication. The essential protein kinase Chk1 mediates the S-phase checkpoint, inhibiting initiation of new DNA synthesis and promoting stabilization and recovery of stalled replication forks. Here we review the mechanisms by which Chk1 is activated in response to bulky adducts and potential mechanisms by which Chk1 signaling inhibits the initiation stage of DNA synthesis. Additionally, we discuss mechanisms by which Chk1 signaling facilitates bypass of bulky lesions by specialized Y-family DNA polymerases, thereby attenuating checkpoint signaling and allowing resumption of normal cell cycle progression.

DNA damage responses protect xeroderma pigmentosum variant from UVC-induced clastogenesis

Lack of DNA polymerase eta and the attendant defect in bypass replication of pyrimidine dimers induced in DNA by ultraviolet light (UV) underlie the enhanced mutagenesis and carcinogenesis observed in xeroderma pigmentosum variant (XP-V). We investigated whether diploid XP-V fibroblasts growing in culture are also more susceptible to UV-induced clastogenesis than normal human fibroblasts (NHF). This study utilized diploid fibroblasts immortalized by the ectopic expression of human telomerase. The cell lines displayed checkpoint responses to DNA damage comparable with those measured in the parental strains. Shortly after exposure to low doses of UVC (< or =4 J/m2), XP-V cells accumulated daughter strand gaps in excess of normal controls (>25-fold). Daughter strand gaps generated in UV-irradiated S phase cells are potential precursors of chromatid-type chromosomal aberrations. Nonetheless, chromatid-type chromosomal aberrations were only 1.5 to 2 times more abundant in XP-V than in NHF exposed to the same UVC dose. XP-V cells, however, displayed S phase delays at lower doses of UVC and for longer periods of time than NHF. These results support the hypothesis that aberrant DNA structures activate S phase checkpoint responses that increase the time available for postreplication repair. Alternatively, cells that cannot be properly repaired remain permanently arrested and never reach mitosis. These responses protect human cells from chromosomal aberrations, especially when other pathways, such as accurate lesion bypass, are lost.

Replication in UV-irradiated Caenorhabditis elegans embryos

Replication continues in wild-type (but not rad mutant) Caenorhabditis elegans embryos even after exposure to massive fluences of UV radiation. It is of interest to elucidate the mechanism(s) for this "damage-resistant" DNA synthesis. In this study, DNA from unirradiated and UV-irradiated wild-type embryos was examined using the electron microscope. Large fluences of UV radiation (180 J m-2) had little effect on either replication bubble size or distances between bubbles in wild-type embryos, indicating that the damage-resistant DNA synthesis was not grossly aberrant. Conversely, UV irradiation significantly decreased center-to-center distances between bubbles in excision-repair-deficient rad-3 embryos. This suggests that the decreased DNA synthesis observed after UV irradiation in rad-3 embryos is due largely to blockage of elongation of DNA synthesis.

UV-induced changes in cell cycle and gene expression within rabbit lens epithelial cells

Damage to lens epithelial cells is a probable initiation process in cataract formation mediated by UV radiation. In these experiments, we investigated the effects of exposure to 254 nm radiation on cell cycle progression and gene expression in the rabbit lens epithelial cell line N/N1003A. The RNA was harvested at various times following exposure to UV (254 nm) radiation and analyzed by dot-blot and northern blot hybridizations. These results revealed that during the first 6 h following exposure of the cells to UV, there was, associated with decreasing dose, a decrease in accumulation of transcripts specific for histones H3 and H4 and an increase in the mRNA encoding protein kinase C and beta- and gamma-actin. Using flow cytometry, we detected an accumulation of cells in G1/S phase of the cell cycle 1 h following exposure to 254 nm radiation. The observed changes in gene expression, especially the decreased accumulation of histone transcripts reported here, may play a role in UV-induced inhibition of cell cycle progression.

Correlation between senescence and DNA repair in cells from young and old individuals and in premature aging syndromes

Cellular aging appears to be related to and perhaps caused by diminished DNA repair. To elucidate direct correlations between DNA repair capacity and senescence various parameters of cellular aging and DNA repair were studied simultaneously. Of special interest are features of DNA repair and senescence in cultured diploid fibroblasts derived either from healthy young or elderly probands as well as from patients suffering from premature senescence syndromes (Werner syndrome, Cockayne syndrome, ataxia telangiectasia and Down syndrome). Here we demonstrate the striking parallelism between reduced maximal lifespan, elevated levels of spontaneous chromosomal breaks, higher incidence of formation of micronuclei, a significant prolongation of cell cycle duration and a diminished reactivation of in vitro injured plasmid after transfection in cells from old individuals and from patients with premature senescence syndromes, suggesting a causal relationship between senescence and DNA damage.

Bromodeoxyuridine/DNA analysis of replication in CHO cells after exposure to UV light

The effects of ultraviolet light on cellular DNA replication were evaluated in an asynchronous Chinese hamster ovary cell population. BrdUrd incorporation was measured as a function of cell-cycle position, using an antibody against bromodeoxyuridine (BrdUrd) and dual parameter flow cytometric analysis. After exposure to UV light, there was an immediate reduction (approximately 50%) of BrdUrd incorporation in S phase cells, with most of the cells of the population being affected to a similar degree. At 5 h after UV, a population of cells with increased BrdUrd appeared as cells that were in G1 phase at the time of irradiation entered S phase with apparently increased rates of DNA synthesis. For 8 h after UV exposure, incorporation of BrdUrd by the original S phase cells remained constant, whereas a significant portion of original G1 cells possessed rates of BrdUrd incorporation surpassing even those of control cells. Maturation rates of DNA synthesized immediately before or after exposure to UV light, measured by alkaline elution, were similar. Therefore, DNA synthesis measured in the short pulse by anti-BrdUrd fluorescence after exposure to UV light was representative of genomic replication. Anti-BrdUrd measurements after DNA damage provide quantitative and qualitative information of cellular rates of DNA synthesis especially in instances where perturbation of cell-cycle progression is a dominant feature of the damage. In this study, striking differences of subsequent DNA synthesis rates between cells in G1 or S phase at the time of exposure were revealed.

Does trans-lesion synthesis explain the UV-radiation resistance of DNA synthesis in C. elegans embryos?

Over 10-fold larger fluences were required to inhibit both DNA synthesis and cell division in wild-type C. elegans embryos as compared with other model systems or C. elegans rad mutants. In addition, unlike in other organisms, the molecular weight of daughter DNA strands was reduced only after large, superlethal fluences. The molecular weight of nascent DNA fragments exceeded the interdimer distance by up to 19-fold, indicating that C. elegans embryos can replicate through non-instructional lesions. This putative trans-lesion synthetic capability may explain the refractory nature of UV radiation on embryonic DNA synthesis and nuclear division in C. elegans.

Nuclear DNA synthesis is blocked by UV irradiation in Dictyostelium discoideum

We have used a thymidine auxotroph of the simple eukaryote, Dictyostelium discoideum and alkaline sucrose gradients of isolated nuclei to study alterations in DNA synthesis following irradiation of replicating haploid cells with 254 nm UV light. Three responses were characterized using pulse-chase protocols: (1) Lags in DNA synthesis as measured by the amount of label incorporated were 4, 9, and 20 h after 10, 50, and 200 J/m2. (2) The DNA synthesized during a 15-min pulse immediately after irradiation was of lower single strand molecular weight: 7, 3.5, and 3 x 10(6) dalton after 0, 50, and 200 J/m2. (3) The time required for maturation of the nascent DNA to full-sized single strands of about 2 x 10(8) dalton was 45-50 min for unirradiated cells, 3 h after 10 J/m2, and 20 h after 200 J/m2. The DNA of the irradiated cells did not mature uniformly during these delays; instead, a period of no increase in size was followed by a rapid, nearly control rate of maturation. We conclude: (a) at least some UV lesions block elongation of replicons; (b) the elongation of the replicons and their subsequent joining to yield mature high molecular weight DNA occurs after most of the lesions are repaired; (c) the timing of the different aspects of recovery suggest that initiation of replication is also inhibited.

Damage-resistant DNA synthesis in eukaryotes

The molecular basis of sensitivity of ionizing radiation and other damaging agents is not clearly defined in eukaryotes. While a large number of mutants have been described only a few have been demonstrated to have a defect in the repair of damage to DNA. An interesting characteristic of a sub-group of these mutants, in different species extending throughout the phylogenetic scale, is the presence of damage-resistant DNA synthesis. This phenomenon is observed in cells from individuals with the genetic disorder ataxia telangiectasia, in HeLa cells treated with fluorodeoxyuridine prior to UV irradiation, in mutants of the fungus Neurospora crassa, the slime mould Dictyostelium discoideum, the fruit fly Drosophila melanogaster and possibly in the "wasted" mouse mutant. In the case of ataxia telangiectasia sensitivity is only observed to ionizing radiation or radiomimetic chemicals whereas sensitivity to a wider spectrum of mutagens is reported for the lower eukaryotic mutants. In all cases a reduced inhibition of DNA synthesis is obtained after exposure to an agent to which the cell type is hypersensitive. It is unclear how damage-resistant DNA synthesis contributes to increased sensitivity in these cells, but is unlikely to be the major mechanism predisposing to radiation-induced cell death. The description of a derivative of an ataxia telangiectasia cell line with normal sensitivity to radiation but still maintaining resistant DNA synthesis partially uncouples radioresistant DNA synthesis and radiosensitivity. This paper is designed to review the phenomenon of damage-resistant DNA synthesis in a number of mutants.

Rapid diagnosis of sensitivity to ultraviolet light in fibroblasts from dermatologic disorders, with particular reference to xeroderma pigmentosum

A rapid and simple method for determining the sensitivity of human fibroblasts to ultraviolet light is described. As an alternative to the colony formation assay, this method can be used for the rapid diagnosis of ultraviolet light sensitivity in fibroblasts from photosensitive disorders. The method is based on growth of small numbers of cells in 1-cm wells of culture trays for 4 or more days after irradiation and determination of cell survival by the incorporation of [3H]hypoxanthine. D37 values (the dose at which 37% of the control level of incorporation remains) obtained from this procedure showed the same relative sensitivity of normal and xeroderma pigmentosum fibroblasts as was obtained by colony formation. Untransformed and SV40-transformed fibroblasts, which have different growth rates and different responses to high cell densities, gave different D37 values by this assay in culture trays as compared with colony formation. Comparison of relative sensitivities to irradiation should therefore be made only between cell types with similar growth characteristics. The similar sensitivity of normal and xeroderma pigmentosum cells to mitomycin C was also determined by this culture tray method. By increasing cell density at the beginning of the experiments, a greater capacity of group C compared with group D fibroblasts for recovery from potentially lethal damage was also detected.

Benzo[alpha]pyrene diol epoxide I binds to DNA at replication forks

The distribution of lesions in DNA caused by (+/-)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-tetrahydrobenzo [alpha]pyrene (B[alpha]P diol epoxide-I) was studied in synchronized C3H/10T1/2 cells treated in S phase. Sites of carcinogen modification of DNA were identified by polyclonal rabbit antibodies elicited against DNA modified with B[alpha]P diol epoxide-I in vitro. This antigenic DNA contained trans-(7R)-N2-[10-(7 beta,8 alpha,9 alpha-trihydroxy-7,8,9,10-tetrahydrobenzo[alpha]pyrene)-yl]- deoxyguanosine; other adducts were not detected by liquid chromatography. In this study, DNA replication forks with antibodies bound to B[alpha]P diol epoxide-I adducts were detected by electron microscopy. The frequency of replication forks containing carcinogen adducts associated with the fork junction was found to be 8-fold higher than expected for an average distribution. The proportion of replication forks that were apparently blocked at the site of the DNA damage increased when replication was allowed to occur after carcinogen exposure. These results support the conclusions that the fork junction is particularly vulnerable to adduction by B[alpha]P diol epoxide-I and that B[alpha]P diol epoxide-I adducts block the displacement of replication forks during DNA synthesis in intact cells.

Effects of carcinogen treatment on rat liver DNA synthesis in vivo and on nascent DNA synthesis and elongation in cultured hepatocytes

One objective of this study was to determine the effects of N-hydroxy-2-acetylaminofluorene (N-OH-AAF) treatment on DNA synthesis in regenerating rat liver. Rats were subjected to a two-thirds hepatectomy followed 20 h later by i.p. injection of N-OH-AAF. 4 h after carcinogen injection, it was found that N-OH-AAF caused a dose-dependent inhibition of [3H]thymidine incorporation into liver DNA. This inhibition was followed by a gradual, but incomplete recovery beginning 28 h after carcinogen treatment. Radioimmunoassay of deoxyguanine-C8 adducts remaining in liver DNA indicated that the recovery began prior to detection of adduct removal. The second objective of the study was to determine the effects of DNA damage on the size distribution and elongation of nascent hepatocyte DNA. Hepatocytes, which have been shown to demonstrate a pattern of inhibition and subsequent recovery of DNA synthesis following UV irradiation similar to that seen in vivo upon treatment with N-OH-AAF (Zurlo and Yager, 1984), were cultured under conditions that promote replicative DNA synthesis. The size distribution of nascent DNA after UV irradiation was determined by pH step gradient alkaline elution analysis. [3H]Thymidine pulse times and subsequent chase times were adjusted to equalize amounts of DNA synthesis in control and UV-irradiated cells. The results show that UV irradiation caused a dose-dependent decrease in the size distribution of nascent DNA suggesting an inhibition of elongation. Pulse-chase studies revealed that subsequent joining of nascent chains in UV-irradiated hepatocytes occurred at a rate comparable to or faster than controls and that this could be inhibited by caffeine. The results obtained from both the in vivo and in vitro studies show that resumption of DNA synthesis and nascent strand elongation occur on damaged templates. These observations along with our previous studies demonstrating the ability of UV-irradiated hepatocytes to carry out enhanced reactivation of UV-irradiated herpes virus lend support to the idea that DNA damage leading to inhibition of DNA synthesis may induce SOS-type processes which if mutagenic may play a role in the initiation of carcinogenesis.

Excision repair in xeroderma pigmentosum group C but not group D is clustered in a small fraction of the total genome

DNA repair in xeroderma pigmentosum complementation groups C and D occurs at a low level. Measurements of pyrimidine dimers remaining in bulk DNA from the whole genome indicated very little excision in either complementation group. The repair sites in group C cells were, however, clustered together in small regions of the genome which appeared to be mended nearly as efficiently as the whole genome is mended in normal cells, while repair in group D cells was randomly distributed. Growth of normal cells in cycloheximide or 3-aminobenzamide neither inhibited repair nor altered the distribution of repair sites. Growth of normal cells in novobiocin or aphidicolin inhibited excision but repair remained randomly distributed. On the basis of these observations, and consideration of other cellular features of group C and D, we suggest that group C may represent a mutation which results in a low level of repair enzymes with normal function. Group D, on the other hand, may represent a mutation resulting in functionally defective repair enzymes.

Effect of ultraviolet light on thymidine incorporation, DNA chain elongation and replicon initiation in wild-type and excision-deficient Chinese hamster ovary cells

Wild-type Chinese hamster ovary cells (AA8) and five excision-deficient clones derived from the AA8 line (UV-4, UV-5, UV-20, UV-24 and UV-41) were exposed to ultraviolet light and then analyzed for their ability to incorporate [3H]thymidine and to initiate as well as elongate replicon-sized DNA fragments. After exposure to ultraviolet light, all cell lines exhibited a depression in the rate of thymidine incorporation. For exposures of 4.0 J/m2 or higher the wild-type cells recovered normal rates of thymidine incorporation within a few hours, while none of the excision-deficient lines exhibited complete recovery. For fluences below 4.0 J/m2 all but the UV-5 line exhibited at least some recovery. The ability to elongate DNA chains appeared to correlate with the thymidine incorporation data, with the UV-5 line exhibiting the strongest blockage of DNA chain elongation, the AA8 line exhibiting the least blockage, and the UV-20 line exhibiting an intermediate response. All cell lines exhibited a decrease in the distance between replication origins, thus supporting models which propose that exposure to ultraviolet light results in the use of alternative sites for the initiation of replication.

Genetic complementation of UV-induced DNA repair in Chinese hamster ovary cells by the denV gene of phage T4

The denV gene of phage T4, encoding the pyrimidine dimer-specific DNA repair enzyme endonuclease V, has been introduced by DNA transfection into the UV-sensitive DNA repair-deficient Chinese hamster ovary (CHO) cell line UV5. Transformants were first selected for resistance to the antibiotic G418 conferred by the neo gene from Tn5 carried by the same plasmid. A majority of the isolated G418-resistant UV5 clones also showed an increased resistance to 254-nm UV light. One clone, designated I-A1, was found to have an intermediate level of colony-forming ability after UV irradiation when compared to UV5 and wild-type AA8 cells. A Southern blot showed that I-A1 carries a single integrated intact copy of the denV gene. Alkaline sucrose gradients revealed a dose-dependent appearance of breaks in the DNA of I-A1 cells following UV-irradiation, while unirradiated cells did not exhibit any significant breaks. Analysis of DNA repair by isopycnic sedimentation showed that DNA excision repair by I-A1 was at least equal to the level of repair in AA8 cells. These results show that the prokaryotic denV gene can restore UV repair capabilities in vivo to CHO UV5 cells defective in repair of UV-induced damage.

Deoxynucleoside triphosphate pool changes and UV-induced depression of DNA synthesis

It has been reported that changes in deoxynucleotide pool levels following exposure to UV might lead to an overestimation of the UV-induced depression in DNA synthesis as analyzed by incorporation of 3H-thymidine (1). We attempted to determine the importance of such pool effects in two ways. First, we examined the grain density along DNA fiber autoradiographs obtained from CHO AA8, and CHO UV-5 cells exposed or sham exposed to UV. Exposure to UV did not alter the grain density immediately or 5 hours after exposure to UV in these cell lines. Second, we examined the kinetics of incorporation of 3H-dTTP in permeabilized AA8 cells under conditions of increased dCTP or increased exogenous dTTP levels. The extent of the depression of 3H-dTTP was identical under all incubation conditions.

Effect of ultraviolet light on DNA replication in excision-deficient mammalian cells

DNA replication after exposure to 254-nm ultraviolet light was examined in wild-type (AA8) and excision-deficient (UV-5) Chinese hamster ovary (CHO) cells. DNA replication was examined by measuring the incorporation of [3H]thymidine into acid-precipitable form and by DNA fiber autoradiography. Following exposure to UV both cell lines exhibited a fluence-dependent reduction in the rate of incorporation of thymidine. For exposures of 3.25 and 6.5 J/m2 the response was quantitatively similar in both cell lines for the first hour or two following exposure, with thymidine incorporation dropping to less than 50% of the control rate within the first 1-2 h. For the AA8 cells the depression was only temporary with the rate of thymidine incorporation eventually recovering to control levels. UV-5 cells, on the other hand, never exhibited a recovery in the rate of thymidine incorporation, even at a fluence as low as 0.8 J/m2. DNA fiber-autoradiographic analysis revealed that for both AA8 and UV-5 lines there were about a 40% reduction in the rate of chain growth in the first 40 min after exposure to 6.5 J/m2. The rate of DNA chain elongation recovered to normal rates in less than 5 h in AA8 cells while little or no recovery in the rate of DNA chain elongation was observed for up to 5 h in the UV-5 cells. From these results it appears that the steps of excision repair that are missing in the UV-5 cells are required not only for excision repair, but also for the ability of cells to recover normal rates of DNA replication following exposure to UV.

Repair of psoralen adducts in human DNA: differences among xeroderma pigmentosum complementation groups

Angelicin and 5-methylangelicin formed photoadducts in DNA after illumination with 360-nm radiation that were excised rapidly from normal cells; 80-90% of the initial angelicin adducts and 65% of the initial 5-methylangelicin adducts were excised within 24 h. Xeroderma pigmentosum group A cells excised about 20% of the angelicin adducts, group D cells excised 55-60%, and group E, 80%. This extent of excision resembles that reported for pyrimidine dimers in these complementation groups, except for group D. Repair of psoralen adducts may not, therefore, be identical in every respect to repair of pyrimidine dimers. Group D cells seem exceptionally able to repair angelicin adducts in comparison to their repair of pyrimidine dimers, suggesting that these cells lack a gene product that is required to a greater extent for the repair of pyrimidine dimers than for the repair of angelicin adducts.