Over half of colorectal cancers (CRCs) harbor TP53 missense mutations (mutp53). We show that the most common mutp53 allele R248Q (p53) exerts gain of function (GOF) and creates tumor dependence in mouse CRC models. mutp53 protein binds Stat3 and enhances activating Stat3 phosphorylation by displacing the phosphatase SHP2. Ablation of the p53 allele suppressed Jak2/Stat3 signaling, growth, and invasiveness of established, mutp53-driven tumors. Treating tumor-bearing mice with an HSP90 inhibitor suppressed mutp53 levels and tumor growth. Importantly, human CRCs with stabilized mutp53 exhibit enhanced Jak2/Stat3 signaling and are associated with poorer patient survival. Cancers with TP53 are associated with a higher patient death risk than are those having nonR248 mutp53. These findings identify GOF mutp53 as a therapeutic target in CRC.
p53 induces cell death upon DNA damage, but this may not confer all of its tumor suppressor activity. We report that p53 activation enhances the processivity of DNA replication, as monitored by multi-label fiber assays, whereas removal of p53 reduces fork progression. This is observed in tumor-derived U2OS cells but also in murine embryonic fibroblasts with heterozygous or homozygous p53 deletion and in freshly isolated thymocytes from mice with differential p53 status. Mdm2, a p53-inducible gene product, similarly supports DNA replication even in p53-deficient cells, suggesting that sustained Mdm2-expression is at least one of the mechanisms allowing p53 to prevent replicative stress. Thus, p53 helps to protect the genome during S phase, by preventing the occurrence of stalled or collapsed replication forks. These results expand p53's tumor-suppressive functions, adding to the ex-post model (elimination of damaged cells) an ex-ante activity; i.e., the prevention of DNA damage during replication.
p53 missense mutant alleles are present in nearly 40% of all human tumors. Such mutated alleles generate aberrant proteins that not only lose their tumor-suppressive functions but also frequently act as driver oncogenes, which promote malignant progression, invasion, metastasis, and chemoresistance, leading to reduced survival in patients and mice. Notably, these oncogenic gain-of-function (GOF) missense mutant p53 proteins (mutp53) are constitutively and tumor-specific stabilised. This stabilisation is one key pre-requisite for their GOF and is largely due to mutp53 protection from the E3 ubiquitin ligases Mdm2 and CHIP by the HSP90/HDAC6 chaperone machinery. Recent mouse models provide convincing evidence that tumors with highly stabilized GOF mutp53 proteins depend on them for growth, maintenance, and metastasis, thus creating exploitable tumor-specific vulnerabilities that markedly increase lifespan if intercepted. This identifies mutp53 as a promising cancer-specific drug target. This review discusses direct mutp53 protein-targeting drug strategies that are currently being developed at various preclinical levels.
Missense mutations in TP53 comprise >75% of all p53 alterations in cancer, resulting in highly stabilized mutant p53 proteins that not only lose their tumor-suppressor activity, but often acquire oncogenic gain-of-functions (GOFs). GOF manifests itself in accelerated tumor onset, increased metastasis, increased drug resistance and shortened survival in patients and mice. A known prerequisite for GOF is mutant p53 protein stabilization, which itself is linked to aberrant protein conformation. However, additional determinants for mutant p53 stabilization likely exist. Here we show that in initially heterozygous mouse tumors carrying the hotspot GOF allele R248Q (p53Q/+), another necessary prerequisite for mutant p53 stabilization and GOF in vivo is loss of the remaining wild-type p53 allele, termed loss-of-heterozygosity (LOH). Thus, in mouse tumors with high frequency of p53 LOH (osteosarcomas and fibrosarcomas), we find that mutant p53 protein is stabilized (16/17 cases, 94%) and tumor onset is significantly accelerated compared with p53+/− tumors (GOF). In contrast, in mouse tumors with low frequency of p53 LOH (MMTV-Neu breast carcinomas), mutant p53 protein is not stabilized (16/20 cases, 80%) and GOF is not observed. Of note, human genomic databases (TCGA, METABRIC etc.) show a high degree of p53 LOH in all examined tumor types that carry missense p53 mutations, including sarcomas and breast carcinomas (with and without HER2 amplification). These data – while cautioning that not all genetic mouse models faithfully represent the human situation – demonstrate for the first time that p53 LOH is a critical prerequisite for missense mutant p53 stabilization and GOF in vivo.
Macrophage migration inhibitory factor (MIF) is an upstream regulator of innate immunity, but its expression is increased in some cancers via stabilization with HSP90-associated chaperones. Here, we show that MIF stabilization is tumor-specific in an acute colitis-associated colorectal cancer (CRC) mouse model, leading to tumor-specific functions and selective therapeutic vulnerabilities. Therefore, we demonstrate that a Mif deletion reduced CRC tumor growth. Further, we define a dual role for MIF in CRC tumor progression. Mif deletion protects mice from inflammation-associated tumor initiation, confirming the action of MIF on host inflammatory pathways; however, macrophage recruitment, neoangiogenesis, and proliferative responses are reduced in Mif-deficient tumors once the tumors are established. Thus, during neoplastic transformation, the function of MIF switches from a proinflammatory cytokine to an angiogenesis promoting factor within our experimental model. Mechanistically, Mif-containing tumor cells regulate angiogenic gene expression via a MIF/CD74/MAPK axis in vitro. Clinical correlation studies of CRC patients show the shortest overall survival for patients with high MIF levels in combination with CD74 expression. Pharmacological inhibition of HSP90 to reduce MIF levels decreased tumor growth in vivo, and selectively reduced the growth of organoids derived from murine and human tumors without affecting organoids derived from healthy epithelial cells. Therefore, novel, clinically relevant Hsp90 inhibitors provide therapeutic selectivity by interfering with tumorigenic MIF in tumor epithelial cells but not in normal cells. Furthermore, Mif-depleted colonic tumor organoids showed growth defects compared to wild-type organoids and were less susceptible toward HSP90 inhibitor treatment. Our data support that tumor-specific stabilization of MIF promotes CRC progression and allows MIF to become a potential and selective therapeutic target in CRC.
All current regimens for treating ovarian cancer center around carboplatin as standard first line. The HSP90 inhibitor ganetespib is currently being assessed in advanced clinical oncology trials. Thus, we tested the combined effects of ganetespib and carboplatin on a panel of 15 human ovarian cancer lines. Strikingly, the two drugs strongly synergized in cytotoxicity in tumor cells lacking wild-type p53. Mechanistically, ganetespib and carboplatin in combination, but not individually, induced persistent DNA damage causing massive global chromosome fragmentation. Live-cell microscopy revealed chromosome fragmentation occurring to a dramatic degree when cells condensed their chromatin in preparation for mitosis, followed by cell death in mitosis or upon aberrant exit from mitosis. HSP90 inhibition caused the rapid decay of key components of the Fanconi anemia pathway required for repair of carboplatin-induced interstrand crosslinks (ICLs), as well as of cell cycle checkpoint mediators. Overexpressing FancA rescued the DNA damage induced by the drug combination, indicating that FancA is indeed a key client of Hsp90 that enables cancer cell survival in the presence of ICLs. Conversely, depletion of nuclease DNA2 prevented chromosomal fragmentation, pointing to an imbalance of defective repair in the face of uncontrolled nuclease activity as mechanistic basis for the observed premitotic DNA fragmentation. Importantly, the drug combination induced robust antitumor activity in xenograft models, again accompanied with depletion of FancA. In sum, our findings indicate that ganetespib strongly potentiates the antitumor efficacy of carboplatin by causing combined inhibition of DNA repair and cell cycle control mechanisms, thus triggering global chromosome disruption, aberrant mitosis and cell death. 6 This provides a strong rationale for HSP90 inhibitors in cancer therapy 7 and raises the possibility that HSP90 inhibitors can be used in combination with DNAdamaging chemotherapeutics. 8 Ovarian cancer is among the most common gynecological tumor types and carries the worst prognosis. HSP90 is highly expressed in advanced ovarian carcinoma 9 and thus constitutes a potential therapeutic drug target. 10 In support, HSP90 inhibitors were found effective against ovarian cancer in preclinical models, 11-14 alone or in combination with conventional chemotherapy. 15,16 Carboplatin is the key component of all current first-line therapies for ovarian carcinoma. However, while initially often responding with regression, most tumors relapse and develop resistance within less than a year. 17,18 Like other platinum compounds, carboplatin acts by forming crosslinks within DNA. 17 Platinum compounds form intrastrand DNA lesions but also interstrand crosslinks (ICLs) by covalently linking opposite DNA strands. Such ICLs represent major obstacles to the DNA replication fork 19 and are therefore considered the principal toxic lesion of carboplatin's mode of action. The ICLs can only be removed by a sophisticated DNA repair systemthe Fanconi ...
Missense p53 mutations (mutp53) occur in approx. 70% of pancreatic ductal adenocarcinomas (PDAC). Typically, mutp53 proteins are aberrantly stabilized by Hsp90/Hsp70/Hsp40 chaperone complexes. Notably, stabilization is a precondition for specific mutp53 alleles to acquire powerful neomorphic oncogenic gain-of-functions (GOFs) that promote tumor progression in solid cancers mainly by increasing invasion and metastasis. In colorectal cancer (CRC), we recently established that the common hotspot mutants mutp53R248Q and mutp53R248W exert GOF activities by constitutively binding to and hyperactivating STAT3. This results in increased proliferation and invasion in an autochthonous CRC mouse model and correlates with poor survival in patients. Comparing a panel of p53 missense mutations in a series of homozygous human PDAC cell lines, we show here that, similar to CRC, the mutp53R248W protein again undergoes a strong Hsp90-mediated stabilization and selectively promotes migration. Highly stabilized mutp53 is degradable by the Hsp90 inhibitors Onalespib and Ganetespib, and correlates with growth suppression, possibly suggesting therapeutic vulnerabilities to target GOF mutp53 proteins in PDAC. In response to mutp53 depletion, only mutp53R248W harboring PDAC cells show STAT3 de-phosphorylation and reduced migration, again suggesting an allele-specific GOF in this cancer entity, similar to CRC. Moreover, mutp53R248W also exhibits the strongest constitutive complex formation with phosphorylated STAT3. The selective mutp53R248W GOF signals through enhancing the STAT3 axis, which was confirmed since targeting STAT3 by knockdown or pharmacological inhibition phenocopied mutp53 depletion and reduced cell viability and migration preferentially in mutp53R248W-containing PDAC cells. Our results confirm that mutp53 GOF activities are allele specific and can span across tumor entities.
Pure erythroleukemia (PEL) is a very aggressive, but poorly understood form of acute myeloid leukemia characterized by malignant accumulation of erythroid progenitor cells. A novel t(1;16)(p31;q24) chromosomal translocation leading to expression of a fusion between the nuclear factor I A (NFIA) and the ETO2 transcriptional co-regulator (a.k.a. CBFA2T3 or MTG16) has been identified in pediatric patients with PEL. Based on the function of the fusion partners, we hypothesized that NFIA-ETO2 (N-E) might initiate PEL by interfering with erythroid differentiation. To investigate its function, we cloned a full-length ORF and retrovirally expressed N-E in primary mouse bone marrow (BM)- and fetal liver (FL)-derived erythroblasts (EB). N-E expression significantly increased proliferation and blocked differentiation of EB. N-E expressing BM-derived hematopoietic stem and progenitor cells (HSPC) could be plated in erythropoietin (EPO)-containing methylcellulose (MC) for up to 3 rounds. Expression of N-E deletion mutants lacking the NFIA DNA-binding, the ETO2 NHR2 or NHR4 (ΔNHR4) transcriptional repression domains were unable to block erythroid differentiation. Notably, interfering with the ETO2-NHR2 oligomerization domain by overexpressing a competing peptide overcame the N-E-mediated differentiation block. Transplantation of N-E-expressing BM-derived HSPC into irradiated syngenic mice did not induce any disease suggesting the need of genetic cooperation. As TP53 gain-of-function (GOF) mutations are molecular hallmarks of PEL, we explored functional cooperation by using a conditional TP53R248Q allele. Interestingly, the TP53 status did not affect EB in vitro proliferation or differentiation. However, N-E expression increased proliferation of TP53R248Q+ EB and resulted in the formation of abnormal round and dense colonies in MC that could be serially propagated. In addition, transplantation of N-E-expressing TP53R248Q+ EB into irradiated recipients induced a transplantable PEL-like disease after a median latency of 4 months. Symptomatic mice presented with anemia, thrombocytopenia, multi-organ tumor cell infiltration and increased white blood cell counts. To better understand the molecular mechanism, we compared the gene expression signatures before and 24 hours after induced differentiation of FL-derived EB expressing WT or the inactive ΔNHR4 N-E mutant, in presence or absence of TP53R248Q. Principal component analysis (PCA) revealed a clear separation between the transcriptomes of WT EB expressing either the active or the inactive ΔNHR4 N-E (PC1:54.7%) and by their erythroid differentiation stage (PC2:9.07%). Overall, we observed 3753 (FDR<0.05, logFC>1.5) differentially expressed genes. Many of the significantly higher expressed genes (2313/3753) were related to hematopoietic stemness (GSEAs, p<0.001). Almost 10% of the significantly lower expressed genes (92/1440) were linked to the erythroid lineage development and to erythropoietic targets of NFIA or the erythroid master regulator GATA1. Interestingly, we also found reduced expression of genes encoding for ETO2-interacting transcription factors including TAL1 and KLF1. Despite a critical role on disease progression, PCA showed only minimal changes in the N-E expression signature in presence or absence of TP53R248Q with only 12 genes differently expressed (FDR<0.05, logFC>1). These genes were previously shown to be oncogenic mediators of TP53-GOF mutations, related to metabolism and transcriptional regulation. Interestingly, the signature of differentially expressed genes in N-E transformed FL-derived EB were significantly differentially expressed in tumor cells from pediatric but not adult PEL patients (p=0.00045), indicating the pediatric origin of the fusion. Collectively, we found that the PEL-associated N-E fusion blocks erythroid differentiation, and cooperates with a TP53-GOF mutation to induce a PEL-like disease in mice that phenocopies the human disease. Mechanistically, its activity seems to correlate with repression of erythroid regulatory genes controlled by the fusion partners NFIA, ETO2, and the erythroid master regulator GATA1. Disclosures No relevant conflicts of interest to declare.
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