p53 and p21 regulate error-prone DNA repair to yield a lower mutation load

Regulation of mutation rates is critical for maintaining genome stability and controlling cancer risk. A special challenge to this regulation is the presence of multiple mutagenic DNA polymerases in mammals. These polymerases function in translesion DNA synthesis (TLS), an error-prone DNA repair process that involves DNA synthesis across DNA lesions. We found that in mammalian cells TLS is controlled by the tumor suppressor p53, and by the cell cycle inhibitor p21 via its PCNA-interacting domain, to maintain a low mutagenic load at the price of reduced repair efficiency. This regulation may be mediated by binding of p21 to PCNA and via DNA damage-induced ubiquitination of PCNA, which is stimulated by p53 and p21. Loss of this regulation by inactivation of p53 or p21 causes an out of control lesion-bypass activity, which increases the mutational load and might therefore play a role in pathogenic processes caused by genetic instability.     

Ubiquitination of p53 and p21 is differentially affected by ionizing and UV radiation.

Levels of the tumor suppressor protein p53 are normally quite low due in part to its short half-life. p53 levels increase in cells exposed to DNA-damaging agents, such as radiation, and this increase is thought to be responsible for the radiation-induced G1 cell cycle arrest or delay. The mechanisms by which radiation causes an increase in p53 are currently unknown. The purpose of this study was to compare the effects of gamma and UV radiation on the stability and ubiquitination of p53 in vivo. Ubiquitin-p53 conjugates could be detected in nonirradiated and gamma-irradiated cells but not in cells which were UV treated, despite the fact that both treatments resulted in the stabilization of the p53 protein. These results demonstrate that UV and gamma radiation have different effects on ubiquitinated p53 and suggest that the UV-induced stabilization of p53 results from a loss of p53 ubiquitination. Ubiquitinated forms of p21, an inhibitor of cyclin-dependent kinases, were detected in vivo, demonstrating that p21 is also a target for degradation by the ubiquitin-dependent proteolytic pathway. However, UV and gamma radiation had no effect on the stability or in vivo ubiquitination of p21, indicating that the radiation effects on p53 are specific.     

Zinc status affects p53, gadd45, and c-fos expression and caspase-3 activity in human bronchial epithelial cells

This study was designed to examine theinfluence of zinc depletion and supplementation on the expression ofp53 gene, target genes of p53, andcaspase-3 activity in normal human bronchial epithelial (NHBE) cells. Aserum-free, low-zinc medium containing 0.4 µmol/l of zinc [zincdeficient (ZD)] was used to deplete cellular zinc over one passage. Inaddition, cells were cultured for one passage in media containing 4.0 µmol/l of zinc [zinc normal (ZN)], which represents normal cultureconcentrations (Clonetics); 16 µmol/l of zinc [zinc adequate (ZA)],which represents normal human plasma zinc levels; or 32 µmol/l ofzinc [zinc supplemented (ZS)], which represents the high end ofplasma zinc levels attainable by oral supplementation in humans.Compared with ZN cells, cellular zinc levels were 76% lower in ZDcells but 3.5-fold and 6-fold higher in ZA and ZS cells, respectively.Abundances of p53 mRNA and nuclear p53 protein were elevatedin treatment groups compared with controls (ZN). For p53mRNA abundance, the highest increase (3-fold) was observed in ZD cells.In contrast, the highest increase (17-fold) in p53 nuclearprotein levels was detected in ZS cells. Moreover, gadd45mRNA abundance was moderately elevated in ZD and ZA cells and was notaltered in ZS cells compared with ZN cells. Furthermore, the onlyalteration in c-fos mRNA and caspase-3 activity was thetwofold increase and the 25% reduction, respectively, detected in ZScompared with ZN cells. Thus p53, gadd45, andc-fos and caspase-3 activity appeared to be modulated bycellular zinc status in NHBE cells.

     

Mechanism of p53 downstream effectors p21 and Gadd45 in DNA damage surveillance

Both p21 (WAF1/CIP1) and Gadd45 were activated in a p53-dependent manner in MCF-7 cells after being exposed to ionizing radiation. In order to investigate their roles in DNA damage surveillance, p21~(as)/MCF-7 cells stably transfected by p21 antisense expression plasmid pC-WAF1-AS and Gadd45~(as)/MCF-7 stably transfected by Gadd45 antisense expression plasmid pCMVas45 were established. It was observed that G_1 arrest induced by radiation was significantly reduced in Gadd45~(as)/MCF-7 cells as well as in p21~(as)/MCF-7 cells. Repair of radiation damaged report gene greatly reduced in Gadd45~(as)/MCF-7 and p21~(as)/MCF-7 cells. Apoptosis significantly increased in p21~(as)/MCF-7 after exposure to radiation. These results suggest that both p21 and Gadd45 support cellular survival by taking roles in G_1 arrest and DNA repair, furthermore, p21 protects cells from death by inhibiting apoptosis after exposure to ionizing radiation.     

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 20J/m2 UVC (LD50=5.6J/m2). 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 6h and from the non-transcribed strand was 73% complete in 24h. 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.     

UV irradiation triggers ubiquitin-dependent degradation of p21(WAF1) to promote DNA repair

p53-mediated increase in cyclin-dependent kinase inhibitor p21(WAF1) protein is thought to be the major mediator of cell cycle arrest after DNA damage. Previously p21 protein levels have been reported to increase or to decrease after UV irradiation. We show that p21 protein is degraded after irradiation of a variety of cell types with low but not high doses of UV. Cell cycle arrest occurs despite p21 degradation via Tyr(15) inhibitory phosphorylation of cdk2 and differs from the classical p21-dependent checkpoint elicited by ionizing radiation. In contrast to the basal turnover of p21, degradation of p21 switches to ubiquitin/Skp2-dependent proteasome pathway following UV irradiation. ATR activation after UV irradiation is essential for signaling p21 degradation. Finally, UV-induced p21 degradation is essential for optimal DNA repair. These results provide novel insight into regulation of p21 protein and its role in the cellular response to DNA damage.     

p53 Ser15 phosphorylation disrupts the p53-RPA70 complex and induces RPA70-mediated DNA repair in hypoxia

Cellular stressors are known to inhibit the p53-RPA70 (replication protein A, 70 kDa subunit) complex, and RPA70 increases cellular DNA repair in cancer cells. We hypothesized that regulation of RPA70-mediated DNA repair might be responsible for the inhibition of apoptosis in hypoxic tumours. We have shown that, in cancer cells, hypoxia disrupts the p53-RPA70 complex, thereby enhancing RPA70-mediated NER (nucleotide excision repair)/NHEJ (non-homologous end-joining) repair. In normal cells, RPA70 binds to the p53-NTD (N-terminal domain), whereas this binding is disrupted in hypoxia. Phosphorylation of p53-NTD is a crucial event in dissociating both NTD-RPA70 and p53-RPA70 complexes. Serial mutations at serine and threonine residues in the NTD confirm that p53(Ser15) phosphorylation induces dissociation of the p53-RPA70 complex in hypoxia. DNA-PK (DNA-dependent protein kinase) is shown to induce p53(Ser15) phosphorylation, thus enhancing RPA70-mediated NER/NHEJ repair. Furthermore, RPA70 gene silencing induces significant increases in cellular apoptosis in the resistant hypoxic cancer cells. We have thus elucidated a novel pathway showing how DNA-PK-mediated p53(Ser15) phosphorylation dissociates the p53-RPA70 complex, thus enhancing NER/NHEJ repair, which causes resistance to apoptosis in hypoxic cancer cells. This novel finding may open new strategies in developing cancer therapeutics on the basis of the regulation of RPA70-mediated NER/NHEJ repair.     

Nuclear translocation of p21 protein prior to its cytosolic degradation by UV enhances DNA repair and survival

We previously reported that UV induced rapid proteasomal degradation of p21 protein in an ubiquitination-independent manner. Here, UV-induced p21 proteolysis was found to occur in the cytosol. Before cytosolic degradation, however, p21 protein translocated to and transiently accumulated in the nucleus. Nuclear translocation of p21 was not required for its degradation, but rather promoted DNA repair and cell survival. Overexpression of the wild type p21, but not the one with defective nuclear localization signal (NLS), reduced UV-induced DNA damage and cell death. Some of p21 protein translocated to the nucleus were associated with chromatin-bound PCNA and saved from UV-induced proteolysis. These data together show that p21 translocates to the nucleus to participate in DNA repair, while the rest is rapidly degraded in the cytosol. We propose that our findings reflect a mechanism to facilitate removal of damaged cells, enhancing DNA repair at the same time.     

Altered DNA repair and recombination responses in mouse cells expressing wildtype or mutant forms of RAD51

Rad51, a homolog of Esherichia coli RecA, is a DNA-dependent ATPase that binds cooperatively to single-stranded DNA forming a nucleoprotein filament, which functions in the strand invasion step of homologous recombination. In this study, we examined DNA repair and recombination responses in mouse hybridoma cells stably expressing wildtype Rad51, or Walker box lysine variants, Rad51-K133A or Rad51-K133R, deficient in ATP binding and ATP hydrolysis, respectively. A unique feature is the recovery of stable transformants expressing Rad51-K133A. Augmentation of the endogenous pool of Rad51 by over-expression of transgene-encoded wildtype Rad51 enhances cell growth and gene targeting, but has minimal effects on cell survival to DNA damage induced by ionizing radiation (IR) or mitomycin C (MMC). Whereas expression of Rad51-K133A impedes growth, in general, neither Rad51-K133A nor Rad51-K133R significantly affected survival to IR- or MMC-induced damage, but did significantly reduce gene targeting. Expression of wildtype Rad51, Rad51-K133A or Rad51-K133R did not affect the frequency of intrachromosomal homologous recombination. However, in both gene targeting and intrachromosomal homologous recombination, wildtype and mutant Rad51 transgene expression altered the recombination mechanism: in gene targeting, wildtype Rad51 expression stimulates crossing over, while expression of Rad51-K133A or Rad51-K133R perturbs gene conversion; in intrachromosomal homologous recombination, cell lines expressing wildtype Rad51, Rad51-K133A or Rad51-K133R display increased deletion formation by intrachromosomal homologous recombination. The results suggest that ATP hydrolysis by Rad51 is more important for some homologous recombination functions than it is for other aspects of DNA repair.     

The p53 status of Chinese hamster V79 cells frequently used for studies on DNA damage and DNA repair.

Chinese hamster lung fibroblast V79 cells have been widely used in studies of DNA damage and DNA repair. Since the p53 gene is involved in normal responses to DNA damage, we have analyzed the molecular genetics and functional status of p53 in V79 cells and primary Chinese hamster embryonic fibroblast (CHEF) cells. The coding product of the p53 gene in CHEF cells was 76 and 75% homologous to human and mouse p53 respectively, and was 95% homologous to the Syrian hamster cells. The V79 p53 sequence contained two point mutations located within a presumed DNA binding domain, as compared with the CHEF cells. Additional immunocytochemical and molecular studies confirmed that the p53 protein in V79 cells was mutated and nonfunctional. Our results indicate that caution should be used in interpreting studies of DNA damage, DNA repair and apoptosis in V79 cells.     

Mismatch repair protein MSH2 regulates translesion DNA synthesis following exposure of cells to UV radiation

Translesion DNA synthesis (TLS) can use specialized DNA polymerases to insert and/or extend nucleotides across lesions, thereby limiting stalled replication fork collapse and the potential for cell death. Recent studies have shown that monoubiquitinated proliferating cell nuclear antigen (PCNA) plays an important role in recruitment of Y-family TLS polymerases to stalled replication forks after DNA damage treatment. To explore the possible roles of other factors that regulate the ultraviolet (UV)-induced assembly of specialized DNA polymerases at arrested replication forks, we performed immunoprecipitation experiments combined with mass spectrometry and established that DNA polymerase kappa (Polκ) can partner with MSH2, an important mismatch repair protein associated with hereditary non-polyposis colorectal cancer. We found that depletion of MSH2 impairs PCNA monoubiquitination and the formation of foci containing Polκ and other TLS polymerases after UV irradiation of cells. Interestingly, expression of MSH2 in Rad18-deficient cells increased UV-induced Polκ and REV1 focus formation without detectable changes in PCNA monoubiquitination, indicating that MSH2 can regulate post-UV focus formation by specialized DNA polymerases in both PCNA monoubiquitination-dependent and -independent fashions. Moreover, we observed that MSH2 can facilitate TLS across cyclobutane pyrimidine dimers photoproducts in living cells, presenting a novel role of MSH2 in post-UV cellular responses.     

Inhibition of the Jun kinase pathway blocks DNA repair, enhances p53-mediated apoptosis and promotes gene amplification.

We have previously shown, by expression of a nonphosphorylatable dominant inhibitor mutant of c-Jun [cJun(S63A,S73A)], that activation of the NH2-terminal Jun kinase/stress-activated protein kinase by genotoxic damage is required for DNA repair. Here, we examine the consequences of inhibition of DNA repair on p53-induced apoptosis in T98G cells, which are devoid of endogenous wild-type p53. Relative to parental or wild-type c-Jun-expressing control cells, mutant Jun-expressing T98G clones show similar growth rates and plating efficiencies. However, these cells are unable to repair DNA (PCR-stop assays) and exhibit up to an 80-fold increased methotrexate-induced colony formation due to amplification of the dihydrofolate reductase gene. Moreover, the mutant c-Jun clones exhibit increased apoptosis and elevated bax:bcl2 ratios on expression of wild-type p53. These results indicate that inhibition of DNA repair leads to accumulation of DNA damage in tumor cells with unstable genomes and this, in turn, enhances p53mediated apoptosis.