P53-mediated DNA Damage Response Research Articles

Telomerase-immortalized human fibroblasts retain UV-induced mutagenesis and p53-mediated DNA damage responses

Immortalized cells frequently have disruptions of p53 activity and lack p53-dependent nucleotide excision repair (NER). We hypothesized that telomerase immortalization would not alter p53-mediated ultraviolet light (UV)-induced DNA damage responses. DNA repair proficient primary diploid human fibroblasts (GM00024) were immortalized by transduction with a telomerase expressing retrovirus. Empty retrovirus transduced cells senesced after a few doublings. Telomerase transduced GM00024 cells (tGM24) were cultured continuously for 6 months (>60 doublings). Colony forming ability after UV irradiation was dose-dependent between 0 and 20 J/m 2 UVC (LD50 = 5.6 J/m 2). p53 accumulation was UV dose- and time-dependent as was induction of p48(XPE/DDB2), p21 CIP1/WAF1, and phosphorylation on p53-S15. UV dose-dependent apoptosis was measured by nuclear condensation. UV exposure induced UV-damaged DNA binding as monitored by electrophoretic mobility shift assays using UV irradiated radiolabeled DNA probe was inhibited by p53-specific siRNA transfection. p53-Specific siRNA transfection also prevented UV induction of p48 and improved UV survival measured by colony forming ability. Strand-specific NER of cyclobutane pyrimidine dimers (CPD) within DHFR was identical in tGM24 and GM00024 cells. CPD removal from the transcribed strand was nearly complete in 6 h and from the non-transcribed strand was 73% complete in 24 h. UV-induced HPRT mutagenesis in tGM24 was indistinguishable from primary human fibroblasts. These wide-ranging findings indicate that the UV-induced DNA damage response remains intact in telomerase-immortalized cells. Furthermore, telomerase immortalization provides permanent cell lines for testing the immediate impact on NER and mutagenesis of selective genetic manipulation without propagation to establish mutant lines.

C-Myc Can Induce DNA Damage, Increase Reactive Oxygen Species, and Mitigate p53 Function: A Mechanism for Oncogene-Induced Genetic Instability

Oncogene overexpression activates p53 by a mechanism posited to involve uncharacterized hyperproliferative signals. We determined whether such signals produce metabolic perturbations that generate DNA damage, a known p53 inducer. Biochemical, cytological, cell cycle, and global gene expression analyses revealed that brief c-Myc activation can induce DNA damage prior to S phase in normal human fibroblasts. Damage correlated with induction of reactive oxygen species (ROS) without induction of apoptosis. Deregulated c-Myc partially disabled the p53-mediated DNA damage response, enabling cells with damaged genomes to enter the cycle, resulting in poor clonogenic survival. An antioxidant reduced ROS, decreased DNA damage and p53 activation, and improved survival. We propose that oncogene activation can induce DNA damage and override damage controls, thereby accelerating tumor progression via genetic instability.

PARP-1 modifies the effectiveness of p53-mediated DNA damage response.

The tumour suppressor protein p53 plays a key role in the cell's decision to arrest the cell cycle or undergo apoptosis following a genotoxic insult. p53 is stabilized and activated after DNA damage, however the cascade of events signalling from DNA lesions to p53 stabilization and activation is still controversial. Poly (ADP-ribosylation) of different nuclear acceptors by PARP-1 is an early event when a single strand DNA lesion is produced. We present here evidences that interplay between PARP-1 and p53 is dependent on the type of damage induced to DNA. Primary mouse embryonic fibroblasts derived from parp-1 -/- mice exhibited decreased p53 accumulation and activation following gamma-irradiation compared to parp-1 proficient cells. On the other hand, treatment with the single alkylating agent 2'-methyl-2'-nitrose-urea (MNU), resulted in the rapid and sustained accumulation and activation of p53 in parp-1-deficient cells, while very little accumulation was observed in parp-1 +/+ cells. After IR, the turnover of the p53 inhibitory protein MDM-2 is perturbed and the level of phosphorylation of p53 at serine-15 is blunted in parp-1 -/- cells. PARP-1 is determinant in the cytotoxic response to alkylating agents but only partially contributes to radiation-induced cell killing, as determined by colony forming assay. Altogether, these results suggest that PARP-1 participates in the p53 response following irradiation, resides upstream of p53 and indirectly modulates the level of phosphorylation of key substrates in this pathway while treatment with MNU results in an enhanced p53-mediated response in parp-1-null cells.

Immortalization of primary human keratinocytes by the helix-loop-helix protein, Id-1.

Basic helix-loop-helix (bHLH) DNA-binding proteins have been demonstrated to regulate tissue-specific transcription within multiple cell lineages. The Id family of helix-loop-helix proteins does not possess a basic DNA-binding domain and functions as a negative regulator of bHLH proteins. Overexpression of Id proteins within a variety of cell types has been shown to inhibit their ability to differentiate under appropriate conditions. We demonstrate that ectopic expression of Id-1 leads to activation of telomerase activity and immortalization of primary human keratinocytes. These immortalized cells have a decreased capacity to differentiate as well as activate phosphorylation of the retinoblastoma protein. Additionally, these cells acquire an impaired p53-mediated DNA-damage response as a late event in immortalization. We conclude that bHLH proteins play a pivotal role in regulating normal keratinocyte growth and differentiation, which can be disrupted by the immortalizing functions of Id-1 through activation of telomerase activity and inactivation of the retinoblastoma protein.

Impaired p53-mediated DNA damage response, cell-cycle disturbance and chromosome aberrations in Nijmegen breakage syndrome lymphoblastoid cell lines

Purpose : To investigate the p53 ionizing radiation-induced response, G1/S cell-cycle block and cytogenetic damage in Nijmegen breakage syndrome (NBS) cells characterized by different haplotypes. Material and methods : Lymphoblastoid cell lines derived from three normals, five NBS and two ataxia telangiectasia (AT) individuals were treated with moderate doses of X-rays and changes in the p53 response were studied by dose-response and time-course experiments. Multiparametric flow cytometry analysis of bromodesoxyuridine-incorporated cells was carried out to analyse G1/S checkpoint alterations. Cytogenetic damage induced by 2Gy radiation was assessed in cells harvested 28h later. Results : Comparison of mean values of p53 accumulation in NBS, AT and control cells indicated that protein induction in NBS cells was between normal and AT cells. Cell-cycle experiments showed a markedly reduced S-phase fraction in irradiated samples of normal cell lines, while NBS, and particularly AT cells, showed less reduction in S-phase fraction. Irrespective of differences in p53 induction and G1/S block, chromatid-type aberrations were induced at a comparable level in both syndromes, while being almost absent in normal cells. Conclusions: The data suggested that failure of NBS cells to initiate cell-cycle delay cannot account alone for their extreme sensitivity to radiation.

Cleavage of CDK Inhibitor p21Cip1/Waf1 by Caspases Is an Early Event during DNA Damage-induced Apoptosis

Activation of the p53-mediated DNA damage response induces either G1 cell cycle arrest or apoptosis. The G1 cell cycle arrest is in part caused by the p53-dependent transcriptional activation of the CDK inhibitor, p21(Cip1/Waf1). We report here that human p21 protein is rapidly induced but selectively cleaved during the apoptotic response to gamma-irradiation. Such an event occurred early, well before the morphological appearance of apoptosis. Ectopical expression of p53 in tumor cells alone could induce p21 expression, followed by p21 cleavage and apoptosis. The cleavage of p21 could be reproduced in extracts prepared from irradiated cells or by recombinant caspase-3, suggesting that a caspase-like activity is responsible for this cleavage. p21 binds independently to both CDK2 and proliferation cell nuclear antigen (PCNA). Our studies indicated that p21 cleavage by the caspase-like activity specifically abolished its interaction with PCNA, suggesting that p21 cleavage may interfere with normal PCNA-dependent repair. Our data suggest that p21 may serve as a critical checkpoint regulator for both cell cycle arrest and apoptosis during the p53-mediated DNA damage response. Manipulation of the checkpoint regulators involved in cell cycle arrest and apoptosis may thus provide a novel strategy to cancer therapy.

The p53-mediated DNA damage response to ionizing radiation in fibroblasts from ataxia-without-telangiectasia patients

Purpose: To assess the functionality of the p53-mediated pathway, activated by the ataxia-telangiectasia gene product (ATM) in response to ionizing radiation, in cells derived from four ataxiawithout-telangiectasia patients. These patients exhibit cerebellar ataxia and cellular abnormalities that are compatible with the diagnosis of ataxia-telangiectasia (AT), but the telangiectasias normally seen in AT patients are absent. Materials and method: Protein and RNA extracts were prepared from primary fibroblast cultures non- or exposed to 5Gy of ionizing radiation in order to monitor the modulation in p53 and ATM protein levels by immunologic techniques and WAF1/Cip1 (p21) mRNA by Northern blotting. Results: A sub-optimal response in terms of increased levels of p53 and the transcriptional activation of WAF1/Cip1 (p21) was seen in the ataxia-without-telangiectasia fibroblast cultures examined over a 4h period post-irradiation when compared with normal fibroblast cultures. The ATM protein was expressed at much reduced levels in the ataxia-without-telangiectasia and the classical AT fibroblast cultures examined when compared with normal fibroblast cultures. Conclusions: Despite the milder clinical phenotypes observed in these ataxia-without-telangiectasia patients and the presence of low levels of ATM protein in the fibroblast cultures, their response to ionizing radiation quantitatively resembles that reported in fibroblast cultures established from classical AT patients.

Butyrate modulates DNA-damage-induced p53 response by induction of p53-independent differentiation and apoptosis.

Butyrate, a physiologically occurring agent, has been reported to decrease constitutively high expressed p53 levels in transformed cells. To elucidate whether butyrate also inhibits DNA-damage-induced p53 response we investigated the effects of butyrate and the anticancer drug mitomycin C in normal C3H10T1/2 cells harbouring wild-type p53. In comparison with p53-deficient fibroblasts we examined p53 protein level, cell cycle arrest, differentiation, and apoptosis. Butyrate induced G1 phase arrest, differentiation, and p53-independent increase in p21(waf1/cip1) protein. Moreover, butyrate induced p53-independent apoptosis, which was, as well as p53-mediated apoptosis, associated with a dose-dependent increase in Bax and c-Myc protein. Pretreatment with butyrate repressed dose-dependently mitomycin-C-induced p53 accumulation and interfered with p53-dependent cell cycle arrest. Butyrate further partially inhibited p53-mediated apoptosis, but low doses of butyrate were more effective than higher concentrations. This was reflected in an enhanced decrease in c-Myc and Bax protein in response to mitomycin C with low concentrations of butyrate. Our data indicate that the differentiation stimulus of butyrate, in association with p21(waf1/cip1) induction, and apoptosis, may explain antineoplastic effects of butyrate. Co-carcinogenic features of butyrate may result from inhibition of p53-mediated DNA damage response.

Nijmegen breakage syndrome cells fail to induce the p53-mediated DNA damage response following exposure to ionizing radiation.

The functionality of the p53-mediated pathway, activated in response to DNA damage, has been assessed in primary fibroblast cell cultures and Epstein-Barr virus-transformed lymphoblastoid cell lines derived from Nijmegen breakage syndrome (NBS) patients. This autosomal recessive disease is characterized by microcephaly, growth and mental retardation, chromosomal instability, radiosensitivity, and high cancer incidence. The recent mapping of the NBS gene to chromosome 8q21 demonstrates that NBS is genetically distinct from ataxia telangiectasia (AT). Changes in p53 protein levels were significantly reduced and delayed in all the NBS fibroblast cell cultures and lymphoblastoid cell lines examined compared to normal cultures over a 4-h period postirradiation (5 Gy). The transcriptional activation of p21(WAF1/CIP1) mRNA was also lower in 12 NBS fibroblast cultures examined. In agreement with an abrogated p53 function, NBS cells exposed to ionizing radiation show an abnormal cell cycle arrest at G1-S and a prolonged accumulation of cells in the G2 phase. In contrast, exposure to the alkylating agent methyl methanesulfonate results in similar increases of p53 and p21(WAF1/CIP1) mRNA in both cell types. The ATM gene transcript was found to be expressed at similar levels in NBS and normal cells, whereas it was strongly reduced in the AT homozygote cells examined. These results suggest that the ATM gene product cannot substitute for that of the NBS gene in the signaling of cellular damage produced by ionizing radiation and that both are involved in the activation of p53. The suboptimal p53-mediated response could contribute to the high cancer risk and radiosensitivity seen in NBS patients.

Analysis of the p53-mediated G1 growth arrest pathway in cells expressing the human papillomavirus type 16 E7 oncoprotein.

Cells expressing human papillomavirus type 16 (HPV-16) E7, similar to those which express HPV-16 E6, are resistant to a p53-mediated G1 growth arrest. We examined the p53-mediated DNA damage response pathway in E7-expressing cells to determine the mechanism by which E7-containing cells continue to cycle. In response to DNA damage, no dramatic difference was detected in G1- or S-phase cyclin or cyclin-dependent kinase (Cdk) levels when E7-expressing cells were compared to the parental cell line, RKO. Furthermore, Cdk2 kinase activity was inhibited in both RKO cells and E7-expressing cells, while Cdk2 remained active in E6-expressing cells. However, the steady-state levels of pRB and p107 protein were substantially lower in E7-expressing cells than in the parental RKO cells or E6-expressing cells. There was no reduction in pRB mRNA levels, but the half-life of pRB in E7-expressing cells was markedly shorter. Infection of primary human foreskin keratinocytes with recombinant retroviruses expressing HPV-16 E7 resulted in a decrease in pRB protein levels, indicating this phenomenon is a consequence of E7 expression, not of immortalization or transformation. These data strongly suggest E7 interferes with the stability of pRB and p107 protein. We propose that the removal of these components of the p53-mediated G1 growth arrest pathway in E7-expressing cells contributes to the ability of E7 to overcome a p53-mediated G1 growth arrest.

Genetic status of p53 and induction of apoptosis by radiation or isoflavones in human gastric carcinoma cell lines

We have shown previously that various human cancer cell lines undergo morphological changes and internucleosomal DNA fragmentation characteristic of apoptosis after exposure to ionizing radiation or isoflavones. Here, we assessed the role of p53 gene in cell cycle and apoptosis following treatment of 11 gastric carcinoma cell lines with gamma-rays, genistein, biochanin A, or daidzein. Cell survival was measured by trypan blue staining, and apoptosis was assessed by fluorochrome staining. The rate of cell survival and apoptosis of the cells by gamma-irradiation or isoflavones did not correlate with p53 gene abnormalities. Flow cytometric measurement of DNA content demonstrated that while gamma-irradiation and genistein induced G(2) arrest, biochanin A and daidzein blocked the cell cycle of all carcinoma cells at G(1) phase. At multiple time points following irradiation, G(2) arrest was observed at 12-16 h in the wild-type and mutant p53 cell lines. Induction of p53 and p21 proteins was not observed in wild-type p53 lines after exposure to gamma-irradiation or isoflavones by Western blotting. Moreover, transfection of the wild-type p53 gene into MKN-1 cells failed to induce G(1) arrest by gamma-irradiation and genistein. Based on these results, we hypothesize that gastric cancer cells may possess a signal pathway which is different from the usual mechanisms of the p53-mediated DNA damage response in normal or hematopoietic tumor cells.

Role of Retinoblastoma Gene Product in p53-Mediated DNA Damage Response

The cellular response to DNA-damaging agents involves the activation of cell cycle checkpoints. Checkpoints provide a transient delay in cell cycle progression, presumably to allow time for the cell to repair the damage. A most important checkpoint, active in the G1 phase of the cell cycle, is mediated by the p53 tumor suppressor gene product. To investigate the role of downstream components of the cell cycle machinery in p53-mediated G1 arrest, the possible involvement of the RB gene product was examined. Rb and p53 proteins were studied by immunoprecipitation and Western blotting experiments in the presence and absence of DNA-damaging treatment. The phosphorylation status of Rb was altered following DNA damage in p53 wild-type cell lines, but was not altered in p53 mutant cell lines, nor in cell lines where p53 function was abrogated by viral gene products. These findings indicate that Rb probably plays a role in the activation of the p53-mediated checkpoint.

P53-dependent G1 arrest involves pRB-related proteins and is disrupted by the human papillomavirus 16 E7 oncoprotein.

The cell cycle regulatory tumor suppressor proteins p53 and pRB are targeted for inactivation by several tumor viruses, including the high-risk types of human papillomaviruses (HPVs) via interactions of the HPV E6 and E7 oncoproteins with p53 and pRB, respectively. p53 plays a central role in a signal transduction pathway that mediates G1 arrest after DNA damage, though the mechanism by which G1 arrest occurs has not been elucidated. The cyclin-associated protein p21waf1/cip1 has recently been shown to be induced by p53 and to inhibit cyclin complex-mediated phosphorylation of pRB in vitro. Thus, we investigated a possible role for pRB in the p53-mediated DNA damage response. After gamma-irradiation, cells expressing wild-type p53 arrested in G1, contained increased levels of WAF1/CIP1 mRNA, and demonstrated accumulation of hypophosphorylated pRB. In contrast, cell lines with abnormal p53 genes or with p53 functionally inactivated by the E6 oncoprotein of HPV16 (a high-risk HPV) failed to arrest in G1, did not elevate WAF1/CIP1 mRNA, and did not accumulate hypophosphorylated pRB. Despite apparently normal elevation of p53 protein and WAF1/CIP1 mRNA after irradiation, cells expressing HPV16 E7 also failed to arrest in G1 and did not accumulate hypophosphorylated pRB. Disruption of RB genes alone did not totally abrogate this G1 arrest. Our results suggest that p53 indirectly regulates phosphorylation of pRB and that pRB and/or other pRB-like molecules that bind to HPV16 E7 participate in the DNA damage-mediated G1 arrest signal. In the process of HPV infection, the HPV E6 and E7 oncoproteins may undermine this cell cycle checkpoint, contributing to the accumulation of genetic alterations during tumorigenesis.