Shengliang Zhang

Targeting tumor suppressor p53 for cancer therapy: strategies, challenges and opportunities.

p53 is one of the most important tumor suppressor genes that is frequently mutated in human cancers. Generally, p53 functions as a transcription factor that is stabilized and activated by various genotoxic and cellular stress signals, such as DNA damage, hypoxia, oncogene activation and nutrient deprivation, consequently leading to cell cycle arrest, apoptosis, senescence and metabolic adaptation. p53 not only becomes functionally deficient in most cancers, but not infrequently mutant p53 also acquires dominant negative activity and oncogenic properties. p53 has remained an attractive target for cancer therapy. Strategies targeting p53 have been developed including gene therapy to restore p53 function, inhibition of p53-MDM2 interaction, restoration of mutant p53 to wild-type p53, targeting p53 family proteins, eliminating mutant p53, as well as p53-based vaccines. Some of these p53-targeted therapies have entered clinical trials. We discuss the therapeutic potential of p53, with particular focus on the therapeutic strategies to rescue p53 inactivation in human cancers. In addition, we discuss the challenges of p53-targeted therapy and new opportunities for the future.

Prodigiosin Rescues Deficient p53 Signaling and Antitumor Effects via Upregulating p73 and Disrupting Its Interaction with Mutant p53

p53 reactivation offers a broad-based strategy for cancer therapy. In this study, we report the identification of prodigiosin that can reactivate p53 family-dependent transcriptional activity in p53-deficient human colon cancer cells. Prodigiosin and its structural analogue (compound R) induced the expression of p53 target genes accompanied by cell-cycle arrest and apoptosis in p53-deficient cancer cells. Prodigiosin restored p53 signaling in cancer cells harboring hotspot TP53 mutations, with little to no detectable cytotoxicity in normal human fibroblasts and with no genotoxicity. Prodigiosin induced the expression of p73 and disrupted its interaction with mutant p53, thereby rescuing p53 pathway deficiency and promoting antitumor effects. The disruption of mutant p53/p73 interaction was specific to prodigiosin and not related to mTOR inhibition. Our findings suggest that mutant p53 needs to be targeted in the context of p73 stimulation to allow efficient restoration of the p53 pathway. In exhibiting this capability, prodigiosin and its analogue provide lead compounds to rescue deficiencies in the p53 pathway in cancer cells by upregulating p73 and targeting mutant p53/p73 interaction there.

Small-Molecule NSC59984 Restores p53 Pathway Signaling and Antitumor Effects against Colorectal Cancer via p73 Activation and Degradation of Mutant p53

The tumor-suppressor p53 prevents cancer development via initiating cell-cycle arrest, cell death, repair, or antiangiogenesis processes. Over 50% of human cancers harbor cancer-causing mutant p53. p53 mutations not only abrogate its tumor-suppressor function, but also endow mutant p53 with a gain of function (GOF), creating a proto-oncogene that contributes to tumorigenesis, tumor progression, and chemo- or radiotherapy resistance. Thus, targeting mutant p53 to restore a wild-type p53 signaling pathway provides an attractive strategy for cancer therapy. We demonstrate that small-molecule NSC59984 not only restores wild-type p53 signaling, but also depletes mutant p53 GOF. NSC59984 induces mutant p53 protein degradation via MDM2 and the ubiquitin-proteasome pathway. NSC59984 restores wild-type p53 signaling via p73 activation, specifically in mutant p53-expressing colorectal cancer cells. At therapeutic doses, NSC59984 induces p73-dependent cell death in cancer cells with minimal genotoxicity and without evident toxicity toward normal cells. NSC59984 synergizes with CPT11 to induce cell death in mutant p53-expressing colorectal cancer cells and inhibits mutant p53-associated colon tumor xenograft growth in a p73-dependent manner in vivo. We hypothesize that specific targeting of mutant p53 may be essential for anticancer strategies that involve the stimulation of p73 in order to efficiently restore tumor suppression. Taken together, our data identify NSC59984 as a promising lead compound for anticancer therapy that acts by targeting GOF-mutant p53 and stimulates p73 to restore the p53 pathway signaling.

Therapeutic targeting of the p53 pathway in cancer stem cells

Introduction: Cancer stem cells (CSCs) are a high profile drug target for cancer therapeutics due to their indispensable role in cancer progression, maintenance and therapeutic resistance. Restoring wild-type (WT) p53 function is an attractive new therapeutic approach for the treatment of cancer due to the well-described powerful tumor suppressor function of p53. As emerging evidence intimately links p53 and stem cell biology, this approach also provides an opportunity to target CSCs. Areas covered: This review covers the therapeutic approaches to restore the function of WT p53, cancer and normal stem cell biology in relation to p53 and the downstream effects of p53 on CSCs. Expert opinion: The restoration of WT p53 function by targeting p53 directly, its interacting proteins or its family members holds promise as a new class of cancer therapies. This review examines the impact that such therapies may have on normal and CSCs based on the current evidence linking p53 signaling with these populations.

Small-Molecule Prodigiosin Restores p53 Tumor Suppressor Activity in Chemoresistant Colorectal Cancer Stem Cells via c-Jun-Mediated ΔNp73 Inhibition and p73 Activation

Tumor suppressor p53 is frequently mutated or inactivated in colorectal cancer. In contrast, p53 family member p73 is rarely mutated in colorectal cancer and p73 activation elicits p53-like tumor suppression. Colorectal cancer stem cells (CRCSC) comprise a rare self-renewing subpopulation that contributes to tumor maintenance and chemoresistance. p53 restoration is known to target CRCSCs, but p73 restoration in CRCSCs has not been examined. In this study, we investigated the effects of the small-molecule prodigiosin, which restores the p53 pathway in tumor cells via p73 activation, on CRCSCs in vitro and in vivo Prodigiosin prevented colonosphere formation independent of p53 status and reduced the viability of self-renewing, 5-fluorouracil-resistant Aldefluor positive [Aldefluor(+)] CRCSCs in vitro Furthermore, prodigiosin inhibited the growth of xenograft tumors initiated with Aldefluor+ cells without toxic effects and limited the tumorigenic potential of these cells. Consistently, prodigiosin induced activation of a p53-responsive luciferase reporter in colonospheres, Aldefluor(+) cells, and tumor xenografts. Mechanistic studies revealed that prodigiosin increased the levels of p73 and reduced levels of the oncogenic N-terminally truncated isoform ΔNp73 in Aldefluor(+) cells. Accordingly, p73 knockdown or ΔNp73 overexpression suppressed prodigiosin-mediated inhibition of colonosphere formation. Moreover, prodigiosin increased levels of the transcription factor c-Jun, a regulator of p73 and ΔNp73, in both the cytoplasm and nucleus. c-Jun knockdown attenuated prodigiosin-mediated p53-reporter activation, ΔNp73 downregulation, p73 activation, and cell death. Collectively, our findings highlight the previously uncharacterized use of p73-activating therapeutics to target CRCSCs. Cancer Res; 76(7); 1989-99. ©2016 AACR.

Targeting of Chk2 as a countermeasure to dose-limiting toxicity triggered by topoisomerase-II (TOP2) poisons

The DNA damage response (DDR) gene cell cycle checkpoint kinase 2 (Chk2) triggers programmed cell death and lethal radiation-induced toxicity in mice in vivo. However, it is not well established to what extent targeting of Chk2 may protect from dose-limiting toxicities (DLT) inflicted by mainstay cancer chemotherapy. We screened different classes of chemotherapy in wild type and Chk2-deficient cells. Here we show that loss of Chk2 protect from cell death in vitro and lethal toxicity in vivo following treatment with topoisomerase II (TOP2)–inhibitors whereas no such protection was observed following treatment with topoisomerase I (TOP1) inhibitors. Furthermore, through combined in silico and functional screens of the Diversity Set II (NCI/NTP) chemical library we identified the carbanilide-derivative NSC105171, also known as ptu-23, as a novel Chk2 inhibitor (Chk2i). Indeed, NSC105171 can be administered safely to mice to countermeasure etoposide-induced toxicity. Incorporation of Chk2i into chemotherapy protocols employing TOP2-inhibitors may be an effective strategy to prevent DLTs without interfering with treatment.

CB002, a novel p53 tumor suppressor pathway-restoring small molecule induces tumor cell death through the pro-apoptotic protein NOXA

ABSTRACT P53 tumor suppressor gene mutations occur in the majority of human cancers and contribute to tumor development, progression and therapy resistance. Direct functional restoration of p53 as a transcription factor has been difficult to achieve in the clinic. We performed a functional screen using a bioluminescence-based transcriptional read-out to identify small molecules that restore the p53 pathway in mutant p53-bearing cancer cells. We identified CB002, as a candidate that restores p53 function in mutant p53-expressing colorectal cancer cells and without toxicity to normal human fibroblasts. Cells exposed to CB002 show increased expression of endogenous p53 target genes NOXA, DR5, and p21 and cell death which occurs by 16 hours, as measured by cleaved caspases or PARP. Stable knockdown of NOXA completely abrogates PARP cleavage and reduces sub-G1 content, implicating NOXA as the key mediator of cell death induction by CB002. Moreover, CB002 decreases the stability of mutant p53 in RXF393 cancer cells and an exogenously expressed R175H p53 mutant in HCT116 p53-null cells. R175H p53 expression was rescued by addition of proteasome inhibitor MG132 to CB002, suggesting a role for ubiquitin-mediated degradation of the mutant protein. In summary, CB002, a p53 pathway-restoring compound that targets mutant p53 for degradation and induces tumor cell death through NOXA, may be further developed as a cancer therapeutic.

Bcl-2 Protein Targeting by the p53/p21 Complex—Letter

Kim and colleagues reported a p53/p21 complex regulates cancer cell invasion and apoptosis by targeting the Bcl-2 family ([1][1]). Interaction of overexpressed p53 and p21 proteins in p53-null H1299 cells correlated with decreased cell invasion. No coimmunoprecipitation experiments documenting

Abstract 3950: Small molecule NSC59984 synergizes with ROS-generating agents to induce cell death via reduced GSH in cancer cells

NSC59984 is a small molecule with a duel capability to induce mutant p53 degradation and restore p53 pathway signaling in cancer cells. NSC59984 requires reactive oxygen species (ROS) to induce mutant p53 degradation via ERK2. ROS regulates cell growth and death with tumor cells having higher ROS levels than normal cells. Increasing ROS level is a promising therapeutic strategy applied in cancer clinical trials. However, the toxicity of high ROS levels is a limitation that needs to be solved urgently. We investigated the synergy between NSC59984 and ROS in cancer cells. To increase ROS, cells were treated with BSO, an ROS-generating agent. Our data reveal that ROS sensitizes cells to NSC59984 treatment including enhanced-p53 restoration and mutant p53 degradation induced by NSC59984. Combination of NSC59984 and BSO shows a synergy to induce cell death in cancer cells with an antagonism observed in normal cells at the tested doses. Consistent with the in vitro experiments, our in vivo experiments show that the combination of NSC59984 and BSO significantly suppresses tumor growth. Immunohistochemical staining shows a decrease in Ki67 and an increase in cleaved caspase 3 in xenografted tumors following combination treatment, suggesting that the tumor suppression is due to the induction of cell death and the inhibition of cell growth. Furthermore, the combination of NSC59984 and BSO shows a significant reduction in glutathione (GSH) levels in cancer cells, suggesting that the synergy between NSC59984 and BSO is due to the inhibition of the antioxidant system in mutant p53-expressing cancer cells. Our data indicate that a high level of ROS can be considered as a biomarker for NSC59984 administration in cancer therapy and supports further evaluation of the combination of NSC59984 and ROS-generating agents. Citation Format: Shengliang Zhang, Lanlan Zhou, Wafik S. El-Deiry. Small molecule NSC59984 synergizes with ROS-generating agents to induce cell death via reduced GSH in cancer cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 3950.

Small-molecule CB002 restores p53 pathway signaling and represses colorectal cancer cell growth

ABSTRACT Much effort is currently focused on the p53 pathway. p53 is a key tumor suppressor, which is mutated or lost in many human cancers. Restoration of the p53 pathway holds the potential to induce selective cell death in tumor cells without harming normal cells that have intact p53 pathways. Most tumor cells express mutated p53 or suppress p53 by overexpression of MDM2. In this study, a compound referred to as CB002 with one closely related compound from the Chembridge library were evaluated for tumor cytotoxicity without affecting normal cells by restoration of the p53 pathway. A decrease of mutant p53 protein expression, restoration of inactivated p53, or some activation of p73 are candidate mechanisms this agent could cause tumor cell apoptosis and growth arrest. We further show that CB002 activates p53 pathway signaling in part via p73 in p53 mutant cancer cell lines. However, it is important to note that we have not established a role for p73 in the anti-tumor effect of CB002 or R1. CB002 causes tumor cell death with synergistic effects with traditional chemotherapeutics CPT-11 and 5-FU.