Differentiation-dependent p53 regulation of nucleotide excision repair in keratinocytes.

The role of the tumor suppressor p53 in repair of ultraviolet light (UV)-induced DNA damage was evaluated using a host-cell reactivation (HCR) assay. HCR determines a cell's ability to repair UV-damaged DNA through reactivation of a transfected CAT reported plasmid. Most UV damage is removed through nucleotide excision repair (NER). Primary murine keratinocytes isolated from p53-deficient and wild-type p53 mice were used in the HCR assay. The NER was reduced in p53-/- keratinocytes as compared with p53+/+ keratinocytes. The reduced DNA repair in p53-/- mice was confirmed with a radioimmunoassay comparing cyclobutane dimers (CPDs) and (6-4) photoproducts in p53+/+ and p53-/- keratinocytes after the cells were exposed to UV irradiation. Our results demonstrate that wildtype p53 plays a significant role in regulating NER. Furthermore, as there is evidence that p53 protein levels decrease after keratinocytes become differentiated, we sought to determine whether p53 plays a role in NER in differentiated keratinocytes. Differentiation of the keratinocytes by increasing the Ca2+ concentration in the culture media resulted in a marked reduction in NER equally in both p53+/+ and p53-/- groups. This finding suggests that reduced DNA repair after differentiation is p53 independent. A similar reduction in HCR was confirmed in differentiated human keratinocytes. These data, taken together, indicate that p53 or p53-regulated proteins enhance NER in basal undifferentiated keratinocytes but not in differentiated cells. As nonmelanoma skin cancers originate from the basal keratinocytes, our findings suggest that loss of p53 may contribute to the pathogenesis of this common skin cancer.     

Dmap1 plays an essential role in the maintenance of genome integrity through the DNA repair process

Faithful control of cell cycle checkpoint and DNA repair contributes to prevent the cells from chromosomal instability and tumorigenesis. Dnmt1-associated protein 1 (Dmap1), a component of the NuA4 histone acetyltransferase complex, was originally identified as an interacting molecule with DNMT1 which co-localizes with PCNA at DNA replication foci. However, its role in cellular functions remains largely unknown. Here we show that Dmap1 knockdown in mouse embryonic fibroblasts (MEFs) lead to spontaneous double-strand breaks (DSBs), resulting in growth arrest because of p53-dependent cell cycle checkpoint activation. Deletion of both Dmap1 and p53 in MEFs synergized towards enhanced generation of DSBs, chromosomal abnormalities and tumor development in mice. Notably, we found that, on DNA damage, Dmap1 was recruited to the damaged sites to form complexes with γ-H2AX and replication factors, including Pcna. Depletion of Dmap1 in MEFs abrogated the stable accumulation of Pcna at the DNA damaged sites. Furthermore, the re-introduction of Dmap1 mutants with a reduced capacity to bind Pcna failed to ameliorate the impaired DNA repair in Dmap1-depleted cells. These findings indicate that Dmap1 is required to involve Pcna in DNA repair. Together, Dmap1 plays a crucial role in DNA repair, and is indispensable for the maintenance of chromosomal integrity.     

The role of DNA repair in resistance of L1210 cells to isomeric 1,2-diaminocyclohexaneplatinum complexes and ultraviolet irradiation

Resistance to cisplatin in several murine leukemia L1210 cell lines is due to enhanced DNA repair. Other platinum complexes, particularly those containing 1,2-diaminocyclohexane (DACH) are of interest as they effectively kill both sensitive (L1210/0) and cisplatin-resistant (L1210/DDP) cell lines. An L1210/DACH cell line has been developed that is preferentially resistant to DACH-Pt complexes. In the current experiments, we investigated the role that DNA repair has in resistance to DACH-Pt compounds. The DACH ligand exists in 3 isomeric forms which exhibit markedly different activities in the various resistant cell lines. Generally, R,R-DACH-Pt was the most effective isomer. DNA repair was assayed by host-cell reactivation of platinated pRSV cat. DNA damage induced by all the isomeric DACH-Pt-SO₄ complexes markedly reduced CAT expression in sensitive L1210/0 cells. One adduct per transcribed strand of the cat gene inhibited CAT expression demonstrating that the sensitive cells exhibited no detectable DNA repair. All the resistant cell lines reactivated the plasmid DNA whether damaged with cisplatin or any of the 3 DACH-Pt isomers. Therefore, resistance to both cisplatin and DACH-Pt appears to be mediated by enhanced DNA repair, but the level of reactivation of the transfected plasmid did not correlate with the toxicity of each analogue. These results suggest that some additional event(s) is responsible for the substrate specificity of repair of genomic DNA. These resistant cell lines also exhibited resistance to UV irradiation but this was much less than, and did not correlate with the degree of resistance to either cisplatin or DACH-Pt. However, there was a good correlation between resistance to UV irradiation and reactivation of UV-damaged plasmid DNA. This enhanced reactivation suggests that enhanced repair may be the sole reason for the resistance to UV irradiation.     

Decreased DNA repair but normal apoptosis in ultraviolet-irradiated skin of p53-transgenic mice.

p53 tumor suppressor plays a vital role in the cellular responses to genotoxic stress. It is believed that p53 regulates the cell cycle by activating the G1 checkpoint after exposure to agents like ionizing radiation, ultraviolet (UV) radiation, or genotoxic chemicals. Recently, it is conjectured that p53 may have additional functions in DNA repair and apoptosis. Previously, we demonstrated that p53-transgenic mice that carry mutant alleles of a p53 gene developed twice as many skin tumors as control mice after UV exposure. To elucidate the molecular mechanisms of mutant p53 in skin cancers, we studied DNA repair efficiency and the rate of apoptosis in murine keratinocytes after UV irradiation. In this report, we show that mutant p53-transgenic mouse skin has reduced repair of UV-induced DNA damage in both in vivo and in vitro radioimmunoassays. In control mice, DNA repair is associated with increased amounts of wild-type P53 protein. Unexpectedly, mutant p53-transgenic mice had slightly increased apoptosis after UV irradiation, suggesting that the wild-type p53 protein in the cells still functions in inducing apoptosis, or that this cell death results from p53-independent mechanisms. These results suggest that mutant p53 interferes with wild-type p53 in the repair of UV-induced DNA damage but not in apoptosis.     

Demonstration of DNA damage/repair in individual cells using in situ end labelling: Association of p53 with sites of DNA damage

We describe the development and application of in situ end labelling (ISEL) to identity sites of damaged DNA in the nuclei of individual cells. In cell culture, exposure to a variety of genotoxic agents induced a dose and time-dependent increase in nuclear labelling. In addition, examination of histological sections of human skin exposed to solar-simulated UV light showed ISEL in both keratinocytes and superficial dermal cells, with the same spatial and temporal distribution as that of a marker of DNA repair, PCNA (proliferating cell nuclear antigen). Using co-localization techniques and confocal microscopy, we found increased levels of p53 in many ISEL-positive cells in vitro, with a similar distribution of labelling in the nucleus. This observation provides further evidence for a direct role of p53 in the recognition of damaged DNA. Thus, ISEL should prove a convenient method for demonstrating genotoxic insult in individual cells and in histological material, and may have value in toxicological screening. This high-resolution microscopy technique can also be used to compare the spatial distribution of various proteins implicated in the response to DNA damage with the sites of the lesion.     

Enhanced expression of Ki-67, topoisomerase IIα, PCNA, p53 and p21 reflecting proliferation and repair activity in UV-irradiated melanocytic nevi

To investigate the effect of ultraviolet (UV) irradiation on the expression of cell cycle-associated proteins, melanocytic nevi from healthy volunteers were partially covered, irradiated with a defined UV dose, and excised 1 week thereafter. The irradiated and the protected parts were examined separately by conventional microscopy and immunohistochemistry using the antibodies Ki-S11 (Ki-67), Ki-S7 (topoisomerase IIα), PC10 (proliferating cell nuclear antigen [PCna]), DO-7 (p53), 6B6 (p21^WAF1/Cip1), and the melanocytic marker HMB-45. DNA nick-end labeling was used as a marker of apoptosis. Irradiation resulted in morphological changes and increased HMB-45 reactivity. Proliferation, as assessed by Ki-67 and topoisomerase IIα expression, was also clearly enhanced in the UV-exposed areas. This was confirmed by the appearance of occasional mitotic figures. PCNA expression levels markedly exceeded those of the proliferation markers and did not correlate with the latter in most cases. p21 immunolabeling indices were also consistently augmented after UV exposure; hence it is likely that growth-inhibitory mechanisms partly compensate for the proliferative impulse, and the disproportional rise in PCNA expression probably reflects DNA repair activity. Enhanced p53 immunostaining in four cases suggests that the induction of p21 after irradiation may be p53 mediated, whereas no concomitant apoptotic events were observed. We conclude that UV light can stimulate the proliferative activity of melanocytes in melanocytic nevi, but that simultaneously cell cycle inhibitors are activated to permit DNA repair.     

p53-Degradation by HPV-16 E6 preferentially affects the removal of cyclobutane pyrimidine dimers from non-transcribed strand and sensitizes mammary epithelial cells to UV-irradiation

Nucleotide excision repair (NER), the most versatile and ubiquitous mechanism for DNA repair, operates to remove many types of DNA base lesions. We have studied the role of p53 function in modulating the repair of DNA damage following UV irradiation in normal and p53-compromised human mammary epithelial cells (HMEC). The effect of UV-induced DNA damage on cellular cytotoxicity and apoptosis was determined in conjunction with global, gene- and strand-specific repair. Cytotoxicity studies, using clonogenic survival and MTT assays, showed that HPV-16 E6-expressing HMEC were more UV sensitive than p53-WT cell lines. High apoptotic index obtained with p53-compromised cells was in conformity to both the low clonogenic survival and the low cellular viability. No discernible differences in the formation of initial UV-induced cyclobutane pyrimidine dimers (CPD) were observed in the cell lines of varying p53 functional status. However, the extent and the rate of damage removal from genome overall were highest for p53-WT cells. Further examination of strand-specific repair in the p53 gene revealed that the removal of CPD in the non-transcribed strand (NTS) was slower in p53-compromised cells compared to the normal p53-WT cell lines. These results suggest that loss of p53 function, in the absence of other genetic alterations, decreased both overall amount of CPD repaired and their removal rate from the genome. Additionally, normal function of p53 is required for the repair of the NTS, but not of the transcribed strand (TS) in genomic DNA in human epithelial cells. Thus, failure of quantitative removal of CPD by global genomic repair (GGR), due to loss of p53 function, causes the enhanced UV sensitivity and increased damage-induced apoptosis via a p53-independent pathway. Nevertheless, recovery of cells from UV damage requires normal p53 function and efficient GGR.     

Role of apoptosis in basal cell and squamous cell carcinoma formation

Long-term ultraviolet-light (UV) exposure of human skin epidermis is associated with an increased risk for the development of skin cancers, such as melanoma, basal cell carcinoma (BCC) and squamous cell carcinoma (SCC). UV radiation not only induces DNA damage in epidermal cells, it also interferes with skin homeostasis, which is maintained by a unique distribution pattern of apoptosis-inducing and -preventing molecules. If the DNA damage is not repaired or the damaged cells are not eliminated by apoptosis, the consequence can be cell transformation, uncontrolled proliferation and eventually skin tumor formation. An important "repair" gene is the p53 suppressor gene. Excessive UV exposure can mutate the p53 gene leading to the loss of its repair function and thus apoptosis resistance of the DNA-damaged cell. For BCC formation an additional pathway has been identified. Mutation of genes of the Hedgehog signaling pathway evokes the downregulation of apoptotic genes and upregulation of anti-apoptotic genes preventing the elimination of damaged cells. In addition, BCC and SCC strongly express the apoptosis-inducing Fas-ligand (FasL) which may help the tumor to escape the attack of immune effector cells. Silencing the genes involved in tumor formation by RNA interference might become a promising new approach to treat skin tumors.     

Induced cellular resistance to ultraviolet light in Saccharomyces cerevisiae is not accompanied by increased repair of plasmid DNA

Summary Many reports show that resistance of Saccharomyces cerevisiae to a large UV dose can be enhanced by pre-induction with a smaller one given some hours before. This work tests if such increased cell survival is associated with increased DNA repair on UV damaged plasmid transformed into yeast. There was no change in transformation efficiency of UV-damaged plasmid DNA under conditions where RAD cell survival increased 5-fold, and where rad1-1 and rad6-1 survival increased 2-fold. It is concluded that DNA repair activity involving the RAD6 and RAD3 pathways is either not inducible or is unable to work on plasmid DNA. It is suggested that the enhancement of cellular survival detected may be based on changes in cell-cycle behaviour which permit cells generally proficient in repair a greater chance to recover.     

Comparison of the expression of p53, p21, Bax and the induction of apoptosis between patients with basal cell carcinoma and normal controls in response to ultraviolet irradiation

AIM: Ultraviolet light (UV) is known to cause DNA damage in the epidermis. The damaged DNA is repaired or deleted by apoptosis to prevent the generation of cancer. It has been suggested that a deficient apoptotic mechanism may predispose individuals to skin cancer. Therefore, the response of normal controls and patients with basal cell carcinoma (BCC) to UV irradiation was investigated. METHODS: The buttock skin from normal volunteers and patients with BCC was irradiated using solar simulated radiation (SSR). SSR mimics the effect of natural sunlight. Skin biopsies were excised and examined for p53, p21, and Bax protein expression and for the induction of apoptosis. RESULTS: At 33 hours after UV irradiation, the induction of apoptosis was significantly higher (p = 0.04) in patients with BCC than in normal volunteers (Mann Whitney test). A trend towards higher p21 expression was found at 33 hours in patients with BCC (mean, 18.69 positive cells/field) than in normal volunteers (mean, 9.89), although this difference was not significant (p = 0.05 positive cells/field). CONCLUSION: These results may imply that patients with BCC have enhanced sensitivity to UV irradiation or that there is some defect in the cell arrest or repair pathways, which results in damaged cells been pushed into apoptosis rather than repair.     

Effect of p53 tumor suppressor on nucleotide excision repair in human colon carcinoma cells treated with 4-nitroquinoline 1-oxide

In probing the mechanism of nucleotide excision repair (NER) in response to 4-nitroquinoline 1-oxide (4NQO)-induced DNA damage, the effect of p53 tumor suppressor was investigated. The effect of p53 protein on the repair of damaged DNA was examined by comet assay. Expression of p53 and p21(Waf1/Cip1) proteins was measured by the Enzyme-linked immunosorbent assay (ELISA) and immunocytochemistry, respectively. Compared to RKO cells having the wild-type p53 gene, increased cytotoxicity by 4NQO was observed in RKOmp53 cells with a mutation in p53 protein. DNA single strand breaks (SSB), indicative of the DNA repair, were considerably increased in 4NQO-treated RKO cells. Also, the expression of p53 and p21 proteins was significantly increased in 4NQO-treated RKO cells. In RKOmp53 cells, no effect of 4NQO on p21 expression was observed. Our findings suggest that 4NQO-induced NER is p53-dependent and involves up-regulation of its downstream regulator, p21(Waf1/Cip1) proteins.     

Ultraviolet light-induced DNA damage in transcribed sequences: No change in repair with age

We studied the repair of a plasmid vector containing the chloramhenicol acetyltransferase (CAT) gene by treating the plasmid with UV light and then transfecting this plasmid into fibroblasts from human fetal lung (in vitro aging) and into primary cultured fibroblasts from rat lung and skin. This methodology allows us to examine the repair of specific transcribed DNA sequences. There was no age-related change in the repair of UV damage in these cells. Rat embryo fibroblasts at different passages transfected with the plasmid also revealed no significant alteration in UV repair as a function of passage number.     

Chromatin-associated DNA endonucleases from xeroderma pigmentosum cells are defective in interaction with damaged nucleosomal DNA

The influence of nucleosome structure on the activity of 2 chromatin-associated DNA endonucleases, pIs 4.6 and 7.6, from normal human and xeroderma pigmentosum, complementation group A (XPA), lymphoblastoid cells was examined on DNA containing either psoralen monoadducts or cross-links. As substrate a reconstituted nucleosomal system was utilized consisting of a plasmid DNA and either core (H2A, H2B, H3, H4), or total (core plus H1) histones from normal or XPA cells. Both non-nucleosomal and nucleosomal DNA were treated with 8-methoxypsoralen (8-MOP) plus long-wavelength ultraviolet radiation (UVA), which produces monoadducts and DNA interstrand cross-links, and angelicin plus UVA, which produces monoadducts. Both normal endonucleases were over 2-fold more active on both types of psoralen-plus-UVA-damaged core nucleosomal DNA than on damaged non-nucleosomal DNA. Addition of histone H1 to the system reduced but did not abolish this increase. By contrast, neither XPA endonuclease showed any increase on psoralen-treated nucleosomal DNA, with or without histone H1. Mixing the normal with the XPA endonucleases led to complementation of the XPA defect. These results indicate that interaction of these endonucleases with chromatin is of critical importance and that it is at this level that a defect exists in XPA endonucleases.     

Effect of heterozygous loss of p53 on benzo[a]pyrene-induced mutations and tumors in DNA repair-deficient XPA mice.

XPA-deficient mice have a complete deficiency in nucleotide excision repair, and as such they display a cancer predisposition after exposure to several carcinogens. Besides being sensitive to genotoxic agents applied to the skin, they are also susceptible to human carcinogens given orally, like benzo[a]pyrene (B[a]P). To study the role of the tumor suppressor gene p53 in DNA repair, gene mutation, and tumor induction, we crossed XPA-deficient mice with p53 knockout mice and lacZ (pUR288) gene marker mice. When treated orally (by gavage) with B[a]P, the XPA(-/-)/p53(+/-) double transgenic mice developed tumors much earlier and with higher frequency compared to their single transgenic counterparts. The major tumor type found in all genotypes was generalized lymphoma mainly residing in the spleen; several sarcomas were observed in p53(+/-) and XPA(-/-)/p53(+/-) mice. Next, we determined lacZ mutation frequencies in several (non)target tissues. It appeared that in the spleen (the major tumor target tissue) of XPA(-/-) and XPA(-/-)/p53(+/-) mice the lacZ mutation frequency was significantly elevated (80-100 x 10(-5)), and was two times higher as found in spleens of B[a]P-treated WT and p53(+/-) mice (P = 0.003). In nontumor target tissues like liver and lung, we found a moderate increase in the lacZ gene mutation frequency (30-40 x 10(-5)), which was independent of the genotype. The results obtained with the DNA-repair deficient XPA mice indicate that a significantly increased lacZ mutation frequency in a particular organ/tissue is an early marker for tumor development at later stages at the same site. However, the synergistic effect of a XPA(-/-)- and a p53(+/-)-deficiency in tumor development is not reflected by an absolute increase in the lacZ mutation frequency in the major tumor target tissue of XPA(-/-)/p53(+/-) or p53(+/-) mice compared to that of XPA(-/-) and WT mice, respectively.     

Chromatid exchanges may be induced by damage in sites of transcriptional activity

A conditional expression system has allowed us to vary the expressionlevel of the xeroderma pigmentosum group A (XPA) photoproduct-specificDNA-binding protein in human cells and so control the responseof cells to damage by UV light. Using a form of XPA that containsa single missense mutation (R207G) enabled us to study a lowerrange of function than that obtained with the wild-type sequence.This form of XPA has been previously shown to stimulate pyrimidinedimer excision preferentially in actively transcribed genes.We found that UV resistance increased as a linear function ofXPA expression levels. Excision of (6–4) pyrimidine-pyrimidonephotoproducts in the whole genome increased to a maximum atabout the haploid level of XPA expression, but there was littlepyrimidine dimer excision from the whole genome. SCE frequencyinduced by UV light was high in cells with no XPA expressionand fell rapidly with increasing levels of XPA expression within0–50% of the haploid level of expression. No further reductionin SCE frequency was produced at the highest levels of XPA expression,when repair replication extended to the overall genome. We speculatethat a low level of repair, especially that occurring in activelytranscribed genes, may selectively eliminate photoproducts thatare particularly important in causing cell killing and SCEs. ³To whom correspondence should be addressed     

The effect of methyl methanesulfonate (MMS)-induced excision repair on p53-dependent apoptosis in human lymphoid cells.

The tumor suppressor p53 product has been shown to play an important role in preventing carcinogenesis by at least two different mechanisms, by evoking cell cycle arrest and eliciting DNA repair on one hand, or by eliminating damaged cells by induction of apoptosis on the other hand. As a first step toward understanding the relationship between protective responses and apoptosis after genotoxic stress, we examined the effect of DNA strand breaks generated from repair processes in respect to acute cellular responses against DNA damage, and on p53-dependent apoptosis in human lymphoid cells. We used two isogenic cell lines, TK6 harboring wild-type p53, and WI-L2-NS, which carries a mutant p53. A significant difference in sensitivity was observed at 50 microg/ml methyl methane-sulfonate (MMS) between the two cell lines used. In addition, a clear p53-mediated contribution to apoptosis in MMS-induced cell death was observed. However, we did not observe any differences in repair of MMS-lesions, as determined by comet assay, between the two cell lines. These data suggest that the differences in apoptosis induction in the two lines are not a reflection of differences in strand-break frequency or repair capacity.     

Different regulation of p53 stability in UV-irradiated normal and DNA repair deficient human cells

The stabilization of p53 protein was studied after UV exposure of normal human skin fibroblasts and cells derived from patients suffering from xeroderma pigmentosum (XP) and trichothiodystrophy (TTD). The data show that p53 is transiently stabilized both in UV-irradiated normal and repair deficient cells. However, particularly at later times after UV irradiation, stabilization of p53 persists much longer in repair deficient XP and TTD cells than in normal cells. The stabilization of p53 was found to be dose-dependent in normal and XP cells. These results indicate that unremoved DNA damage could possibly be responsible for the induction of transient stabilization of p53.