Long Term Effect of Curcumin in Restoration of Tumour Suppressor p53 and Phase-II Antioxidant Enzymes via Activation of Nrf2 Signalling and Modulation of Inflammation in Prevention of Cancer

Inhibition of carcinogenesis may be a consequence of attenuation of oxidative stress via activation of antioxidant defence system, restoration and stabilization of tumour suppressor proteins along with modulation of inflammatory mediators. Previously we have delineated significant role of curcumin during its long term effect in regulation of glycolytic pathway and angiogenesis, which in turn results in prevention of cancer via modulation of stress activated genes. Present study was designed to investigate long term effect of curcumin in regulation of Nrf2 mediated phase-II antioxidant enzymes, tumour suppressor p53 and inflammation under oxidative tumour microenvironment in liver of T-cell lymphoma bearing mice. Inhibition of Nrf2 signalling observed during lymphoma progression, resulted in down regulation of phase II antioxidant enzymes, p53 as well as activation of inflammatory signals. Curcumin potentiated significant increase in Nrf2 activation. It restored activity of phase-II antioxidant enzymes like GST, GR, NQO1, and tumour suppressor p53 level. In addition, curcumin modulated inflammation via upregulation of TGF-β and reciprocal regulation of iNOS and COX2. The study suggests that during long term effect, curcumin leads to prevention of cancer by inducing phase-II antioxidant enzymes via activation of Nrf2 signalling, restoration of tumour suppressor p53 and modulation of inflammatory mediators like iNOS and COX2 in liver of lymphoma bearing mice.     

Mdm2 regulates p53 independently of p19(ARF) in homeostatic tissues

Tumor suppressor proteins must be exquisitely regulated since they can induce cell death while preventing cancer. For example, the p19(ARF) tumor suppressor (p14(ARF) in humans) appears to stimulate the apoptotic function of the p53 tumor suppressor to prevent lymphomagenesis and carcinogenesis induced by oncogene overexpression. Here we present a genetic approach to defining the role of p19(ARF) in regulating the apoptotic function of p53 in highly proliferating, homeostatic tissues. In contrast to our expectation, p19(ARF) did not activate the apoptotic function of p53 in lymphocytes or epithelial cells. These results demonstrate that the mechanisms that control p53 function during homeostasis differ from those that are critical for tumor suppression. Moreover, the Mdm2/p53/p19(ARF) pathway appears to exist only under very restricted conditions.     

Autophagy signaling and the cogwheels of cancer

The downregulation of macroautophagy observed in cancer cells is associated with tumor progression. The regulation of macroautophagy by signaling pathways overlaps with the control of cell growth, proliferation, cell survival and death. Several tumor suppressor genes (PTEN, TSC2 and p53) involved in the mTOR signaling network have been shown to stimulate autophagy. In contrast, the oncoproteins involved in this network have the opposite effect. These findings, together with the discovery that haploinsufficiency of the tumor suppressor beclin 1 promotes tumorigenesis in various tissues in transgenic mice, give credibility to the idea that autophagy is a tumor suppressor mechanism. The induction of macroautophagy by cancer treatments may also contribute to cell eradication. However, cancer cells sometimes mobilize autophagic capacities in response to various stimuli without a fatal outcome, suggesting that they can also exploit macroautophagy for their own benefit.     

Autophagy Signaling and the Cogwheels of Cancer

The downregulation of macroautophagy observed in cancer cells is associated with tumor progression. The regulation of macroautophagy by signaling pathways overlaps with the control of cell growth, proliferation, cell survival, and death. Several tumor suppressor genes (PTEN, TSC2 and p53) involved in the mTOR signaling network have been shown to stimulate autophagy. In contrast, the oncoproteins involved in this network have the opposite effect. These findings, together with the discovery that haplo-insufficiency of the tumor suppressor beclin 1 promotes tumorigenesis in various tissues in transgenic mice, give credibility to the idea that autophagy is a tumor suppressor mechanism. The induction of macroautophagy by cancer treatments may also contribute to cell eradication. However, cancer cells sometimes mobilize autophagic capacities in response to various stimuli without a fatal outcome, suggesting that they can also exploit macroautophagy for their own benefit.     

Long-term mutagenic effects of ionising radiation on mice which vary in their p53 status

The tumor suppressor gene p53 plays a major role in the maintenance of genomic integrity. The impact that variations in cellular turnover rates and sensitivity to DNA damage will have on the effectiveness of p53 in this role was examined by following the induction and persistence of mutations in the brain and small intestine of mice after exposure to ionising radiation (IR). The examination of mutagenesis was carried out using the pUR288 LacZ plasmid-based mouse model-consisting of mice containing a target gene for mutation analysis integrated into every cell. In addition the mice varied in their p53 status. The tissues were compared at post-irradiation time-points from 24h to 3 months. The mutation frequencies (MFs) in the p53 wildtype and heterozygous brains peaked at 24h post-irradiation, and then returned to background or close to background levels, respectively. The p53 nullizygous brain showed a more fluctuating MF pattern, but returned to background levels by 3 months, indicating that the effect of the loss of p53 did not result in lasting differences in the response to mutation induction in the brain. In the intestine, there was a different pattern; in the wildtype and heterozygous animals, the MFs increased from 24h to a peak at 4 weeks post-irradiation, before decreasing towards background levels at 3 months. The MFs in the intestine from the nullizygous animals did not decrease significantly between 4 weeks and 3 months, illustrating that the loss of p53 had a greater impact in this tissue than the brain. The variation in mutation frequencies and the type of mutations generated after DNA damage suggests that while p53 plays a significant role in the maintenance of genomic integrity, other mechanisms, such as the drive to replicate in progenitor cells, can reduce its effectiveness as the "guardian of the genome".     

Crucial Role of TSC-22 in Preventing the Proteasomal Degradation of p53 in Cervical Cancer

The p53 tumor suppressor function can be compromised in many tumors by the cellular antagonist HDM2 and human papillomavirus oncogene E6 that induce p53 degradation. Restoration of p53 activity has strong therapeutic potential. Here, we identified TSC-22 as a novel p53-interacting protein and show its novel function as a positive regulator of p53. We found that TSC-22 level was significantly down-regulated in cervical cancer tissues. Moreover, over-expression of TSC-22 was sufficient to inhibit cell proliferation, promote cellular apoptosis in cervical cancer cells and suppress growth of xenograft tumors in mice. Expression of also TSC-22 enhanced the protein level of p53 by protecting it from poly-ubiquitination. When bound to the motif between amino acids 100 and 200 of p53, TSC-22 inhibited the HDM2- and E6-mediated p53 poly-ubiquitination and degradation. Consequently, ectopic over-expression of TSC-22 activated the function of p53, followed by increased expression of p21(Waf1/Cip1) and PUMA in human cervical cancer cell lines. Interestingly, TSC-22 did not affect the interaction between p53 and HDM2. Knock-down of TSC-22 by small interfering RNA clearly enhanced the poly-ubiquitination of p53, leading to the degradation of p53. These results suggest that TSC-22 acts as a tumor suppressor by safeguarding p53 from poly-ubiquitination mediated-degradation.     

Chromosome missegregation causes colon cancer by APC loss of heterozygosity

A longstanding hypothesis in the field of cancer biology is that aneuploidy causes cancer by promoting loss of chromosomes that contain tumor suppressor genes. By crossing aneuploidy-prone Bub1 hypomorphic mice onto a heterozygous null background for p53, we provided conclusive evidence for this idea.1 Surprisingly, the tumors that developed in this model had not just lost the chromosome 11 copy harboring wildtype p53, but had also gained an extra copy of chromosome 11 bearing the p53 null allele. Here we report that a similar chromosome-reshuffling blueprint drives colonic tumorigenesis in Bub1 hypomorphic mice that are heterozygous for ApcMin, but now involving chromosome 18. These extended studies highlight that in order for whole chromosome instability to drive tumorigenesis, it needs to establish tumor suppressor gene loss of heterozygosity while retaining two copies of the other genes on the chromosome. Additional restrictions seem to apply to whole chromosome instability as a cancer causing mechanism, which will be discussed in this paper.     

Tumor suppression by p53 in the absence of Atm

Oncogenes can induce p53 through a signaling pathway involving p19/Arf. It was recently proposed that oncogenes can also induce DNA damage, and this can induce p53 through the Atm DNA damage pathway. To assess the relative roles of Atm, Arf, and p53 in the suppression of Ras-driven tumors, we examined susceptibility to skin carcinogenesis in 7,12-dimethylbenz(a)anthracene/12-O-tetradecanoylphorbol-13-acetate (TPA)-treated Atm- and p53-deficient mice and compared these results to previous studies on Arf-deficient mice. Mice with epidermal-specific deletion of p53 showed increased papilloma number and progression to malignant invasive carcinomas compared with wild-type littermates. In contrast, Atm-deficient mice showed no increase in papilloma number, growth, or malignant progression. gamma-H2AX and p53 levels were increased in both Atm(+/+) and Atm(-/-) papillomas, whereas Arf(-/-) papillomas showed much lower p53 expression. Thus, although there is evidence of DNA damage, signaling through Arf seems to regulate p53 in these Ras-driven tumors. In spontaneous and radiation-induced lymphoma models, tumor latency was accelerated in Atm(-/-)p53(-/-) compound mutant mice compared with the single mutant Atm(-/-) or p53(-/-) mice, indicating cooperation between loss of Atm and loss of p53. Although p53-mediated apoptosis was impaired in irradiated Atm(-/-) lymphocytes, p53 loss was still selected for during lymphomagenesis in Atm(-/-) mice. In conclusion, in these models of oncogene- or DNA damage-induced tumors, p53 retains tumor suppressor activity in the absence of Atm.     

Genomic convergence and suppression of centrosome hyperamplification in primary p53-/- cells in prolonged culture

Chromosome instability, a major property of cancer cells, is believed to promote mutations that establish malignant phenotypes. Centrosome hyperamplification and the consequential increase in the frequency of aberrant mitoses are the major causes of chromosome instability in cancer cells that lack the functional p53 tumor suppressor protein. Here, we examined dynamic changes of chromosome and centrosome behaviors during long-term culturing of primary epithelial cells derived from p53-null mice. The heterogeneity in the number of chromosomes per cell in the early to mid passage cell population diminished in late passage cells, giving rise to distinct subpopulations of cells. Concomitantly, centrosome hyperamplification that was observed at a high frequency in early to mid passage cells was suppressed in late passage cells. These results provide an explanation for the frequent observations that some cancer cell lines and tissues that lack functional p53 show normal centrosome behaviors and altered, yet relatively stable, chromosomes. Moreover, our in vitro findings may provide a model for possible genomic convergence in cultured cells. This may be analogous to the genomic convergence model proposed for in vivo tumor progression in which chromosome instability initially imposed during tumorigenesis becomes suppressed when neoplastic cells have acquired chromosome compositions that promise an optimal growth in a given environment.     

Inhibitory Effect of Tumor Suppressor p53 on Proinflammatory Chemokine Expression in Ovarian Cancer Cells by Reducing Proteasomal Degradation of IκB

Ovarian cancer, one of inflammation-associated cancers, is the fifth leading cause of cancer deaths among women. Inflammation in the tumor microenvironment is associated with peritoneal tumor dissemination and massive ascites, which contribute to high mortality in ovarian cancer. Tumor suppressor p53 is frequently deleted or mutated in aggressive and high-grade ovarian cancer, probably aggravating cancer progression and increasing mortality. We therefore investigated the influence of p53 on proinflammatory chemokines in ovarian cancer cells. A PCR array of the chemokine network revealed that ovarian cancer cells with low or mutated p53 expression expressed high levels of proinflammatory chemokines such as CXCL1, 2, 3 and 8. Transient transfection of p53 into p53-null ovarian cancer cells downregulated proinflammatory chemokines induced by tumor necrosis factor-α (TNF), a proinflammatory cytokine abundantly expressed in ovarian cancer. Furthermore, p53 restoration or stabilization blocked TNF-induced NF-κB promoter activity and reduced TNF-activated IκB. Restoration of p53 increased ubiquitination of IκB, resulting from concurrently reduced proteasome activity followed by stability of IκB. A ubiquitination PCR array on restoration of p53 did not reveal any significant change in expression except for Mdm2, indicating that the balance between p53 and Mdm2 is more important in regulating NF-κB signaling rather than the direct effect of p53 on ubiquitin-related genes or IκB kinases. In addition, nutlin-3, a specific inducer of p53 stabilization, inhibited proinflammatory chemokines by reducing TNF-activated IκB through p53 stabilization. Taken together, these results suggest that p53 inhibits proinflammatory chemokines in ovarian cancer cells by reducing proteasomal degradation of IκB. Thus, frequent loss or mutation of p53 may promote tumor progression by enhancing inflammation in the tumor microenvironment.     

Wip1 phosphatase regulates p53-dependent apoptosis of stem cells and tumorigenesis in the mouse intestine

Colorectal cancer is one of the major causes of cancer-related deaths. To gain further insights into the mechanisms underlying its development, we investigated the role of Wip1 phosphatase, which is highly expressed in intestinal stem cells, in the mouse model of APC(Min)-driven polyposis. We found that Wip1 removal increased the life span of APC(Min) mice through a significant suppression of polyp formation. This protection was dependent on the p53 tumor suppressor, which plays a putative role in the regulation of apoptosis of intestinal stem cells. Activation of apoptosis in stem cells of Wip1-deficient mice, but not wild-type APC(Min) mice, increased when the Wnt pathway was constitutively activated. We propose, therefore, that the Wip1 phosphatase regulates homeostasis of intestinal stem cells. In turn, Wip1 loss suppresses APC(Min)-driven polyposis by lowering the threshold for p53-dependent apoptosis of stem cells, thus preventing their conversion into tumor-initiating stem cells.     

Inactivated tumor suppressor Rb by nitric oxide promotes mitosis in human breast cancer cells

Inactivation of tumor suppressor protein retinoblastoma (Rb) is important mechanism for the G1/S transition during cell cycle progression. Human breast cancer cells T47D release great amount of nitric oxide (NO), but its relation to tumor suppressor Rb is unknown. In this study, it is shown that NO induces phosphorylation and inactivation of Rb tumor suppressor protein, increasing G2/M phase and cell proliferation of breast cancer cells T47D. NO did not induce changes in p53 ser-15 phosphorylation, the most phosphorylated site of p53 during its activation. These data indicate that NO induces cell proliferation through the Rb pathway. NO phosphorylates and inactivates tumor suppressor protein Rb inducing mitosis by the p53 independent pathway in breast cancer cell.     

Inactivation of the p19(ARF) tumor suppressor affects intestinal epithelial cell proliferation and integrity

p19(ARF) is a tumor suppressor that is frequently deleted in human cancer. It lies at chromosome 9p21 and shares exons 2 and 3 with p16(ink4a), which is also inactivated by these cancer-associated deletions. The "canonical pathway" by which p19(ARF) is thought to suppress tumorigenesis through activation of the p53 tumor suppressor. In response to hyperproliferative signals, such as expression of oncogenes, p19(ARF) is induced and binds to the MDM2 ubiquitin ligase, sequestering it in the nucleolus to allow the accumulation of p53. However, p19(ARF) also has MDM2 and p53 independent functions. In human colon cancer, p19(ARF) is only rarely deleted, but it is more frequently silenced by DNA promoter methylation. Here we show that inactivation of p19(ARF) in mice increases the number of cycling cells in the crypts of the colonic epithelium. Moreover, inactivation of p19(ARF) exacerbated the ulceration of the colonic epithelium caused by dextran sodium sulfate (DSS). These effects were similar to those observed in mice lacking myeloid translocation gene-related-1 (Mtgr1), and mice lacking both of these genes showed an even greater sensitivity to DSS. Surprisingly, inactivation of p19(ARF) restored the loss of the secretory lineage in mice deficient in Mtgr1, suggesting an additional role for p19(ARF) in the small intestinal epithelium.     

Specific apoptosis induction in human papillomavirus-positive cervical carcinoma cells by photodynamic antisense regulation

Human papillomavirus type 18 (HPV18) is frequently detected in cervical cancer cells. The viral proteins E6 and E7 are expressed consistently and have oncogenic activities. The E7 protein binds to a tumor suppressor, the retinoblastoma gene product (pRB), however, leading to the stabilization of tumor suppressor, p53 protein. On the other hand, another viral product, E6, forms complexes with p53 and abrogates its function, resulting in tumor progression. These facts imply that the E6 oncogene is one of the ideal targets for directed gene therapy in HPV-positive cervical cancer. In this study, we tried photodynamic antisense regulation of the antiapoptotic E6 expression using a photocross-linking reagent, 4,5',8-trimethylpsoralen, conjugated oligo(nucleoside phosphorothioate) (Ps-S-Oligo). This photodynamic antisense strategy effectively elicited the apoptotic death of HPV18-positive cervical cancer cells through the selective repression of E6 mRNA and consequent stabilization of p53 protein. E7-mediated signals potentially activated the p53 function and mobilized the p53 pathway to deliver pro-apoptotic signals to the cancer cells, leading to the suppression of in vivo tumorigenesis. An extremely low concentration of cisplatin in addition to Ps-S-Oligos further up-regulated p53 activity, provoking massive apoptotic induction. These results suggest that the photodynamic antisense strategy has the great therapeutic potential in HPV-positive cervical cancers.     

Lymphoma development in Bax transgenic mice is inhibited by Bcl-2 and associated with chromosomal instability

Bax is a Bcl-2 family member that promotes apoptosis but has paradoxical effects on lymphoma development in p53-deficient mice. To better understand the mechanism of Bax-induced lymphoma development, the effect of Bax levels, p53 status and Bcl-2 coexpression on lymphoma development were determined. In addition, DNA content and cytogenetics were performed on young (premalignant) Lck-Bax mice as measures of genetic instability. Bax promoted lymphoma development in p53-deficient mice in a dose-dependent manner. Bax expression also led to lymphoma development in both p53 +/- and +/+ animals. Ploidy analysis in mice prior to the onset of overt thymic lymphomas demonstrated that Lck-Bax transgenic mice were more likely to be aneuploid and demonstrate increased chromosome instability. With tumor progression, aneuploidy increased and Bax expression was maintained. Importantly, coexpression of Bcl-2 delayed lymphoma development in Lck-Bax transgenic mice. These data support a model in which increased sensitivity to apoptosis leads directly to chromosome instability in developing T cells and may explain a number of paradoxical observations regarding Bcl-2 family members and the regulation of cancer.