Human papillomavirus 16 E6 expression disrupts the p53-mediated cellular response to DNA damage.

Infection with certain types of human papillomaviruses (HPV) is highly associated with carcinomas of the human uterine cervix. However, HPV infection alone does not appear to be sufficient for the process of malignant transformation, suggesting the requirement of additional cellular events. After DNA damage, normal mammalian cells exhibit G1 cell-cycle arrest and inhibition of replicative DNA synthesis. This mechanism, which requires wild-type p53, presumably allows cells to undertake DNA repair and avoid the fixation of mutations. We directly tested whether the normal response of cervical epithelial cells to DNA damage may be undermined by interactions between the E6 protein expressed by oncogenic HPV types and wild-type p53. We treated primary keratinocytes with the DNA-damaging agent actinomycin D and demonstrated inhibition of replicative DNA synthesis and a significant increase in p53 protein levels. In contrast, inhibition of DNA synthesis and increases in p53 protein did not occur after actinomycin D treatment of keratinocytes immortalized with HPV16 E6/E7 or in cervical carcinoma cell lines containing HPV16, HPV18, or mutant p53 alone. To test the effects of E6 alone on the cellular response to DNA damage, HPV16 E6 was expressed in the carcinoma cell line RKO, resulting in undetectable baseline levels of p53 protein and loss of the G1 arrest that normally occurs in these cells after DNA damage. These findings demonstrate that oncogenic E6 can disrupt an important cellular response to DNA damage mediated by p53 and may contribute to the subsequent accumulation of genetic changes associated with cervical tumorigenesis.     

Nitric oxide-induced p53 accumulation and regulation of inducible nitric oxide synthase expression by wild-type p53.

The tumor suppressor gene product p53 plays an important role in the cellular response to DNA damage from exogenous chemical and physical mutagens. Therefore, we hypothesized that p53 performs a similar role in response to putative endogenous mutagens, such as nitric oxide (NO). We report here that exposure of human cells to NO generated from an NO donor or from overexpression of inducible nitric oxide synthase (NOS2) results in p53 protein accumulation. In addition, expression of wild-type (WT) p53 in a variety of human tumor cell lines, as well as murine fibroblasts, results in down-regulation of NOS2 expression through inhibition of the NOS2 promoter. These data are consistent with the hypothesis of a negative feedback loop in which endogenous NO-induced DNA damage results in WT p53 accumulation and provides a novel mechanism by which p53 safeguards against DNA damage through p53-mediated transrepression of NOS2 gene expression, thus reducing the potential for NO-induced DNA damage.     

Human papillomavirus type 16 E6 and E7 oncogenes abrogate radiation-induced DNA damage responses in vivo through p53-dependent and p53-independent pathways

E6 and E7 oncoproteins from high risk human papillomaviruses (HPVs) transform cells in tissue culture and induce tumors in vivo. Both E6, which inhibits p53 functions, and E7, which inhibits pRb, can also abrogate growth arrest induced by DNA-damaging agents in cultured cells. In this study, we have used transgenic mice that express HPV-16 E6 or E7 in the epidermis to determine how these two proteins modulate DNA damage responses in vivo. Our results demonstrate that both E6 and E7 abrogate the inhibition of DNA synthesis in the epidermis after treatment with ionizing radiation. Increases in the levels of p53 and p21 proteins after irradiation were suppressed by E6 but not by E7. Through the study of p53-null mice, we found that radiation-induced growth arrest in the epidermis is mediated through both p53-dependent and p53-independent pathways. The abrogation of radiation responses in both E6 and E7 transgenic mice was more complete than was seen in the p53-null epidermis. We conclude that E6 and E7 each have the capacity to modulate p53-dependent as well as p53-independent cellular responses to radiation. Additionally, we found that the conserved region (CR) 1 and CR2 domains in E7 protein, which are involved in the inactivation of pRb function and required for E7’s transforming function, were also required for E7 to modulate DNA damage responses in vivo. Thus pRb and/or pRb-like proteins likely mediate both p53-dependent and p53-independent responses to radiation.     

Growth arrest by induction of p53 in DNA damaged keratinocytes is bypassed by human papillomavirus 16 E7.

Cellular tumor suppressors p53 and Rb play an important role in controlling cell proliferation. Inactivation of these tumor suppressor proteins can occur by gene mutation or by association with oncoproteins from the small DNA tumor viruses. One function of p53 is in regulating cell cycle check-point control after DNA damage. To dissect the pathways by which p53 and Rb may act, the E6 and E7 oncogenes of human papillomavirus (HPV) types 6 and 16 were introduced into primary human epithelial cells by retroviral transfer vector, and cells were assayed for growth arrest after DNA damage induced by actinomycin D. The E6 or E7 oncogenes from the low-risk HPV6 had no affect on growth arrest, p53 protein levels increased, Rb protein levels decreased, and Rb was predominantly in the hypophosphorylated state similar to vector-infected cells. Either the E6 or the E7 oncogene from the high-risk HPV16 abrogated growth arrest. Cells expressing HPV16 E6 (16E6) were severely reduced in p53 protein levels that did not increase detectably after DNA damage, Rb protein levels did not decrease, and hyperphosphorylated Rb was present. After DNA damage in cells expressing 16E7 p53 levels increased, and Rb protein levels decreased; however, Rb was predominantly in the hyperphosphorylated state. Even though p53 protein levels increased in response to DNA damage in cells expressing 16E7, G1 growth arrest was bypassed. This suggests that the circuitry controlling the growth arrest signal after DNA damage may be interconnected between the p53 and Rb pathways.     

BCR-ABL-mediated inhibition of apoptosis with delay of G2/M transition after DNA damage: a mechanism of resistance to multiple anticancer agents

A critical determinant of the efficacy of antineoplastic therapy is the response of malignant cells to DNA damage induced by anticancer agents. The p53 tumor-suppressor gene is a critical component of two distinct cellular responses to DNA damage, the induction of a reversible arrest at the G1/S cell cycle checkpoint, and the activation of apoptosis, a genetic program of autonomous cell death. Expression of the BCR-ABL chimeric gene produced by a balanced translocation in chronic myeloid leukemia, confers resistance to multiple genotoxic anticancer agents. BCR-ABL expression inhibits the apoptotic response to DNA damage without altering either the p53-dependent WAF1/CIP1-mediated G1 arrest or DNA repair. BCR-ABL-mediated inhibition of DNA damage-induced apoptosis is associated with a prolongation of cell cycle arrest at the G2/M restriction point; the delay of G2/M transition may allow time to repair and complete DNA replication and chromosomal segregation, thereby preventing a mitotic catastrophe. The inherent resistance of human cancers to genotoxic agents may result not only by the loss or inactivation of the wild-type p53 gene, but also by genetic alterations such as BCR-ABL that can delay G2/M transition after DNA damage.     

Immunoreactivity evaluation of mutant p53 gene product with DNA ploidy pattern in colorectal carcinoma

BACKGROUND/AIMS: Studying p53 protein expression in tumor cells is one of the effective methods for detecting p53 gene mutations. This study attempted simultaneous monitoring of p53 overexpression in colon cancer using immunohistochemical and immunoblotting techniques and also to compare abnormalities of p53 with DNA ploidy and clinicopathological variables. METHODOLOGY: The occurrence of p53 protein expression was analyzed in forty-nine fresh colorectal cancer specimens by immunohistochemical and p53 protein expression also demonstrated by Western immunoblotting technique in 28 colorectal cancer specimens, using an anti-human p53 monoclonal antibody (Do-7), and 25 normal colon mucosa as a negative control. DNA ploidy in 36 specimens of colon cancer tissues was determined by Flow cytometry. RESULTS: Overexpression of p53 protein was detected immunohistochemically in 53.1% (26 of 49) of the tumor specimens. DNA ploidy was performed in 36 cases, 55.6% (20 of 36) of colon cancer specimens were DNA aneuploidy, p53 immunostaining was positive in 60% of cases with DNA aneuploidy compared to 31.3% in diploid tumors (p<0.001). There was no significant association between p53 immunostaining and clinicopathological variables. Overexpression of p53 protein was demonstrated in nuclear protein extract by immunoblotting in 75% (21 of 28) of colorectal carcinoma. Aneuploidy carcinomas were more frequently p53 positive by immunoblotting than DNA diploidy carcinomas; 76.5% (13 of 17) vs. 72.7% (8 of 11) (p<0.2). P53 expression by immunoblotting was more frequently found in good lymphocytic infiltration than moderate and poor lymphocytic infiltration (p<0.001). Also, p53 expression in right colon was significant with rectum (p<0.009). The incidence of p53 expression in Duke's stage B was significant if compared with Duke's stage C (p<0.005). Immuno-reactivity of p53 expression was detected by immunostaining and immunoblotting in 89.3% (25 of 28) of colorectal cancer. P53 immunoreactivity by immunostaining and immunoblotting were closely related to the clinicopathological variables such as pathological type (p<0.01), lymphocytic infiltration (p<0.0001), tumor grade, and tumor site (p<0.001). DNA aneuploidy was more frequently p53 positive than DNA diploid tumor by immunostaining and immunoblotting (p<0.001). CONCLUSIONS: Immunohistochemistry confirmed by immunoblotting assay is a sensitive method for detecting the trace amount of p53 protein and provides valuable information for the understanding of colorectal cancer biology.     

The human papilloma virus 16E6 gene sensitizes human mammary epithelial cells to apoptosis induced by DNA damage.

Programmed cell death (apoptosis) is a normal physiological process, which could in principle be manipulated to play an important role in cancer therapy. The key importance of p53 expression in the apoptotic response to DNA-damaging agents has been stressed because mutant or deleted p53 is so common in most kinds of cancer. An important strategy, therefore, is to find ways to induce apoptosis in the absence of wild-type p53. In this paper, we compare apoptosis in normal human mammary epithelial cells, in cells immortalized with human papilloma virus (HPV), and in mammary carcinoma cell lines expressing wild-type p53, mutant p53, or no p53 protein. Apoptosis was induced with mitomycin C (MMC), a DNA cross-linking and damaging agent, or with staurosporine (SSP), a protein kinase inhibitor. The normal and HPV-transfected cells responded more strongly to SSP than did the tumor cells. After exposure to MMC, cells expressing wild-type p53 underwent extensive apoptosis, whereas cells carrying mutated p53 responded weakly. Primary breast cancer cell lines null for p53 protein were resistant to MMC. In contrast, two HPV immortalized cell lines in which p53 protein was destroyed by E6-modulated ubiquitinylation were highly sensitive to apoptosis induced by MMC. Neither p53 mRNA nor protein was induced in the HPV immortalized cells after MMC treatment, although p53 protein was elevated by MMC in cells with wild-type p53. Importantly, MMC induced p21 mRNA but not p21 protein expression in the HPV immortalized cells. Thus, HPV 16E6 can sensitize mammary epithelial cells to MMC-induced apoptosis via a p53- and p21-independent pathway. We propose that the HPV 16E6 protein modulates ubiquitin-mediated degradation not only of p53 but also of p21 and perhaps other proteins involved in apoptosis.     

A role for p300/CREB binding protein genes in promoting cancer progression in colon cancer cell lines with microsatellite instability

Our manipulation of the nonsense-mediated decay pathway in microsatellite unstable colon cancer cell lines identified the p300 gene as a potential tumor suppressor in this subtype of cancer. Here, we have demonstrated that not only the p300 gene but also the highly homologous cAMP-response element-binding protein (CREB) binding protein (CBP) gene together are mutated in >85% of microsatellite instability (MSI)+ colon cancer cell lines. A limited survey of primary tumors with MSI+ shows that p300 is also frequently mutated in these cancers, demonstrating that these mutations are not consequences of in vitro growth. The mutations in both genes occur frequently in mononucleotide repeats that generate premature stop codons. Reintroduction of p300 into MSI colon cancer cells could only be supported in the presence of an inactivated CBP gene, suggesting the idea that one or the other function must be inactivated for cancer cell viability. p300 is known to acetylate p53 in response to DNA damage, and when MSI+ cells null for p300 activity are forced to reexpress exogenous p300 cells show slower growth and a flatter morphology. p53 acetylation is increased upon reexpression of p300, suggesting that MSI+ cells constitutively activate the DNA damage response pathway in the absence of DNA-damaging agents. In support of this hypothesis, c-ABL kinase, which is also activated in response to DNA damage, shows higher levels of basal kinase activity in MSI+ cells. These observations suggest that there is a selective growth/survival advantage to mutational inactivation of p300/CBP in cells with inactivated mismatch repair capabilities.     

Sphingosine-1-phosphate lyase potentiates apoptosis via p53- and p38-dependent pathways and is down-regulated in colon cancer

Sphingolipid metabolites such as sphingosine-1-phosphate (S1P) and ceramide modulate apoptosis during development and in response to stress. In general, ceramide promotes apoptosis, whereas S1P stimulates cell proliferation and protects against apoptosis. S1P is irreversibly degraded by the enzyme S1P lyase (SPL). In this study, we show a crucial role for SPL in mediating cellular responses to stress. SPL expression in HEK293 cells potentiated apoptosis in response to stressful stimuli including DNA damage. This effect seemed to be independent of ceramide generation but required SPL enzymatic activity and the actions of p38 MAP kinase, p53, p53-inducible death domain protein (PIDD), and caspase-2 as shown by molecular and chemical inhibition of each of these targets. Further, SPL expression led to constitutive activation of p38. Endogenous SPL expression was induced by DNA damage in WT cells, whereas SPL knockdown diminished apoptotic responses. Importantly, SPL expression was significantly down-regulated in human colon cancer tissues in comparison with normal adjacent tissues, as determined by quantitative real-time PCR (Q-PCR) and immunohistochemical analysis. Down-regulation of S1P phosphatases was also observed, suggesting that colon cancer cells manifest a block in S1P catabolism. In addition, SPL expression and activity were down-regulated in adenomatous lesions of the Min mouse model of intestinal tumorigenesis. Taken together, these results indicate that endogenous SPL may play a physiological role in stress-induced apoptosis and provide an example of altered SPL expression in a human tumor. Our findings suggest that genetic or epigenetic changes affecting intestinal S1P metabolism may correlate with and potentially contribute to carcinogenesis.     

p53-mediated cellular response to DNA damage in cells with replicative hepatitis B virus.

Wild-type p53 acts as a tumor suppressor gene by protecting cells from deleterious effects of genotoxic agents through the induction of a G1/S arrest or apoptosis as a response to DNA damage. Transforming proteins of several oncogenic DNA viruses inactivate tumor suppressor activity of p53 by blocking this cellular response. To test whether hepatitis B virus displays a similar effect, we studied the p53-mediated cellular response to DNA damage in 2215 hepatoma cells with replicative hepatitis B virus. We demonstrate that hepatitis B virus replication does not interfere with known cellular functions of p53 protein.     

HCV NS5A abrogates p53 protein function by interfering with p53-DNA binding

AIM: To evaluate the inhibition effect of HCV NS5A on p53 transactivation on p21 promoter and explore its possible mechanism for influencing p53 function. METHODS: p53 function of transactivation on p21 promoter was studied with a luciferase reporter system in which the luciferase gene is driven by p21 promoter, and the p53-DNA binding ability was observed with the use of electrophoretic mobility-shift assay (EMSA). Lipofectin mediated p53 or HCV NS5A expression vectors were used to transfect hepatoma cell lines to observe whether HCV NS5A could abrogate the binding ability of p53 to its specific DNA sequence and p53 transactivation on p21 promoter. Western blot experiment was used for detection of HCV NS5A and p53 proteins expression. RESULTS: Relative luciferase activity driven by p21 promoter increased significantly in the presence of endogenous p53 protein. Compared to the control group, exogenous p53 protein also stimulated p21 promoter driven luciferase gene expression in a dose-dependent way. HCV NS5A protein gradually inhibited both endogenous and exogenous p53 transactivation on p21 promoter with increase of the dose of HCV NS5A expression plasmid. By the experiment of EMSA, we could find p53 binding to its specific DNA sequence and, when co-transfected with increased dose of HCV NS5A expression vector, the p53 binding affinity to its DNA gradually decreased and finally disappeared. Between the Huh 7 cells transfected with p53 expression vector alone or co-transfected with HCV NS5A expression vector, there was no difference in the p53 protein expression. CONCLUSION: HCV NS5A inhibits p53 transactivation on p21 promoter through abrogating p53 binding affinity to its specific DNA sequence. It does not affect p53 protein expression.     

Role of AXL in invasion and drug resistance of colon and breast cancer cells and its association with p53 alterations

AIM To characterize AXL receptor tyrosine kinase(AXL)expression in relationship to tumor protein P53(TP53gene,p53 protein)and its role in tumor invasion and response to therapy.METHODS We used 14 cell lines,including 3 isogenic pairs carrying mutant/knockout p53,to gain insight into the relationship between AXL and TP53.These included HCT116,HCT116.p53 mutant,RKO,and RKO.p53-/-lines(all from colon cancers)as well as breast cancer cell lines MCF7 and 1001(MCF7-p53 mutant clone).He La cell line was used as a positive control for epithelial to mesenchymal transition(EMT).AXL expression was determined by Western blotting using rabbit monoclonal antibody clone C89E7.AXL si RNA silencing was performed and followed by collagen invasion assay.Cell viability analysis using the sulforhodamine B assay and the invasion assay were performed after exposure to chemotherapeutic agents(doxorubicin for breast cancer cells;5FU or irinotecan for colon cancer cells).RESULTS We showed that the introduction of p53 mutations or knockout increased expression levels of AXL in isogenic cells compared to the matching p53 wild-type parental cells.Overall,we found a trend for correlation between the potential EMT candidate AXL,p53 alterations,and EMT markers in colorectal and breast cancers.The expression of AXL in RKO cells,a rare colon cancer cell line with inactive Wnt signaling,suggests that the AXL oncogene might provide an alternative genetic pathway for colorectal carcinogenesis in the absence of Wnt signaling activation and TP53 mutation.AXL silencing in the TP53 mutant isogenic cell lines 1001,HCT116.p53 mutant and RKO.P53-/-was95%efficient and the silenced cells were less invasive compared to the parental TP53 wild-type cells.AXL silencing showed a subtle trend to restore colon cancer cell sensitivity to5FU or irinotecan.Importantly,AXL expressing cells developed more invasive potential after exposure to chemotherapy compared to the AXL-silenced cells.CONCLUSION AXL is influenced by p53 status and could cause the emergence of aggressive clones after exposure to chemotherapy.These findings could have applications in cancer management.     

IGFBP-rP1 induces p21 expression through a p53-independent pathway, leading to cellular senescence of MCF-7 breast cancer cells

Objectives

Insulin-like growth factor-binding protein (IGFBP)-related protein 1 (IGFBP-rP1), a member of the IGFBP super family, was identified as a potent tumor suppressor in several carcinomas. IGFBP-rP1 was down-regulated in primary breast cancer tissues and several breast cancer cell lines but overexpressed in senescent human mammary epithelial cells (HMECs), suggesting that IGFBP-rP1 might be a tumor suppressor in breast cancer and the tumor suppressor role of IGFBP-rP1 might be associated with cellular senescence. The aim of the study was to observe the effect of IGFBP-rP1 on cellular senescence and the molecular events mediating this biological effect in MCF-7 breast cancer cells.

Methods

DNA fragment-encoding IGFBP-rP1 was cloned in-frame N-terminally to EGFP gene to generate IGFBP-rP1-EGFP fusion protein expression plasmid (pEGFP-IGFBP-rP1). The plasmid pEGFP-IGFBP-rP1 was then transfected into MCF-7 cells, and the proliferation, cell cycle distribution, cellular senescence, and cell cycle-related protein expression of MCF-7 cells were examined by trypan blue exclusion, flow cytometry, senescence-associated galactosidase (SA-β-gal) staining, and Western blot analysis, respectively. Two shRNA plasmid vectors against p21 or p53 gene were constructed and stably transfected into the MCF-7 cells to determine the involvement of p21 or p53 in cellular senescence induced by IGFBP-rP1.

Results

Transfection of IGFBP-rP1 or addition of condition medium (CM) from IGFBP-rP1-transfected cells in MCF-7 cells caused induction of a variety of senescent phenotypes, such as decrease in cell proliferation, increase in G0/G1 cell cycle arrest cells, change in cell morphology, and increase in senescence-associated galactosidase (SA-β-gal) activity. IGFBP-rP1-induced growth arrest is associated with enhanced expression of the cyclin-dependent kinase inhibitor p21 and dephosphorylation of the retinoblastoma protein (pRB). Cell proliferation block and cellular senescence induction in response to IGFBP-rP1 were partially reversed by p21 knockdown in MCF-7 cells. Knockdown of p53 in MCF-7 cells did not influence the growth inhibition, cellular senescence, and p21 expression of the cells in response to IGFBP-rP1 transfection.

Conclusions

Results from this study suggest that cellular senescence induced by IGFBP-rP1 is mediated at least in part by p21 enhanced expression, which regulated through the p53-independent pathway. IGFBP-rP1 might be one of the key molecules that trigger cellular senescence in breast cancer. Restoration of IGFBP-rP1 function might have therapeutic significance in breast cancer.