Mark W. Zimmerman

Targeted Deletion of the Metastasis-Associated Phosphatase Ptp4a3 (PRL-3) Suppresses Murine Colon Cancer

Ptp4a3 (commonly known as PRL-3) is an enigmatic member of the Ptp4a family of prenylated protein tyrosine phosphatases that are highly expressed in many human cancers. Despite strong correlations with tumor metastasis and poor patient prognosis, there is very limited understanding of this gene familys role in malignancy. Therefore, we created a gene-targeted murine knockout model for Ptp4a3, the most widely studied Ptp4a family member. Mice deficient for Ptp4a3 were grossly normal. Fewer homozygous-null males were observed at weaning, however, and they maintained a decreased body mass. Although Ptp4a3 is normally associated with late-stage cancer and metastasis, we observed increased Ptp4a3 expression in the colon of wildtype mice immediately following treatment with the carcinogen azoxymethane. To investigate the role of Ptp4a3 in malignancy, we used the most commonly studied murine colitis-associated colon cancer model. Wildtype mice treated with azoxymethane and dextran sodium sulfate developed approximately 7–10 tumors per mouse in the distal colon. The resulting tumor tissue had 4-fold more Ptp4a3 mRNA relative to normal colon epithelium and increased PTP4A3 protein. Ptp4a3-null mice developed 50% fewer colon tumors than wildtype mice after exposure to azoxymethane and dextran sodium sulfate. Tumors from the Ptp4a3-null mice had elevated levels of both IGF1Rβ and c-MYC compared to tumors replete with Ptp4a3, suggesting an enhanced cell signaling pathway engagement in the absence of the phosphatase. These results provide the first definitive evidence implicating Ptp4a3 in colon tumorigenesis and highlight the potential value of the phosphatase as a therapeutic target for early stage malignant disease.

Protein-tyrosine Phosphatase 4A3 (PTP4A3) Promotes Vascular Endothelial Growth Factor Signaling and Enables Endothelial Cell Motility

Background: The Ptp4a gene family encodes cancer-associated phosphatases with poorly understood in vivo functions. Results: Mice deficient for PTP4A3 exhibit reduced tumor angiogenesis and decreased VEGF-mediated endothelial cell motility and vascular permeability. Conclusion: PTP4A3 has an important role in endothelial cell response to proangiogenic VEGF signaling. Significance: PTP4A3 appears to be an attractive molecular target for impeding angiogenesis in addition to tumor progression. Protein-tyrosine phosphatase 4A3 (PTP4A3) is highly expressed in multiple human cancers and is hypothesized to have a critical, albeit poorly defined, role in the formation of experimental tumors in mice. PTP4A3 is broadly expressed in many tissues so the cellular basis of its etiological contributions to carcinogenesis may involve both tumor and stromal cells. In particular, PTP4A3 is expressed in the tumor vasculature and has been proposed to be a direct target of vascular endothelial growth factor (VEGF) signaling in endothelial cells. We now provide the first in vivo experimental evidence that PTP4A3 participates in VEGF signaling and contributes to the process of pathological angiogenesis. Colon tumor tissue isolated from Ptp4a3-null mice revealed reduced tumor microvessel density compared with wild type controls. Additionally, vascular cells derived from Ptp4a3-null tissues exhibited decreased invasiveness in an ex vivo wound healing assay. When primary endothelial cells were isolated and cultured in vitro, Ptp4a3-null cells displayed greatly reduced migration compared with wild type cells. Exposure to VEGF led to an increase in Src phosphorylation in wild type endothelial cells, a response that was completely ablated in Ptp4a3-null cells. In loss-of-function studies, reduced VEGF-mediated migration was also observed when human endothelial cells were treated with a small molecule inhibitor of PTP4A3. VEGF-mediated in vivo vascular permeability was significantly attenuated in PTP4A3-deficient mice. These findings strongly support a role for PTP4A3 as an important contributor to endothelial cell function and as a multimodal target for cancer therapy and mitigating VEGF-regulated angiogenesis.

Deletion of Ptp4a3 reduces clonogenicity and tumor-initiation ability of colitis-associated cancer cells in mice

The PTP4A3 gene is highly expressed in human colon cancer and often associates with enhanced metastatic potential. Genetic disruption of the mouse Ptp4a3 gene reduces the frequency of colon tumor formation in mice treated in a colitis-associated cancer model. In the current study, we have examined the role of Ptp4a3 in the tumor-initiating cell population of mouse colon tumors using an in vitro culture system. Tumors generated in vivo following AOM/DSS treatment were isolated, dissociated, and expanded on a feeder layer resulting in a CD133(+) cell population, which expressed high levels of Ptp4a3. Tumor cells deficient for Ptp4a3 exhibited reduced clonogenicity and growth potential relative to WT cells as determined by limiting dilution analysis. Importantly, expanded tumor cells from WT mice readily formed secondary tumors when transplanted into nude mice, while tumor cells without Ptp4a3 expression failed to form secondary tumors and thus were not tumorigenic. These results demonstrate that Ptp4a3 contributes to the malignant phenotype of tumor-initiating cells and supports its role as a potential therapeutic target to inhibit tumor self-renewal and metastasis.

Synergy between loss of NF1 and overexpression of MYCN in neuroblastoma is mediated by the GAP-related domain

Earlier reports showed that hyperplasia of sympathoadrenal cell precursors during embryogenesis in Nf1-deficient mice is independent of Nf1’s role in down-modulating RAS-MAPK signaling. We demonstrate in zebrafish that nf1 loss leads to aberrant activation of RAS signaling in MYCN-induced neuroblastomas that arise in these precursors, and that the GTPase-activating protein (GAP)-related domain (GRD) is sufficient to suppress the acceleration of neuroblastoma in nf1-deficient fish, but not the hypertrophy of sympathoadrenal cells in nf1 mutant embryos. Thus, even though neuroblastoma is a classical “developmental tumor”, NF1 relies on a very different mechanism to suppress malignant transformation than it does to modulate normal neural crest cell growth. We also show marked synergy in tumor cell killing between MEK inhibitors (trametinib) and retinoids (isotretinoin) in primary nf1a-/- zebrafish neuroblastomas. Thus, our model system has considerable translational potential for investigating new strategies to improve the treatment of very high-risk neuroblastomas with aberrant RAS-MAPK activation. DOI: http://dx.doi.org/10.7554/eLife.14713.001

MYC Drives a Subset of High-Risk Pediatric Neuroblastomas and Is Activated through Mechanisms Including Enhancer Hijacking and Focal Enhancer Amplification

The amplified MYCN gene serves as an oncogenic driver in approximately 20% of high-risk pediatric neuroblastomas. Here, we show that the family member MYC is a potent transforming gene in a separate subset of high-risk neuroblastoma cases (∼10%), based on (i) its upregulation by focal enhancer amplification or genomic rearrangements leading to enhancer hijacking, and (ii) its ability to transform neuroblastoma precursor cells in a transgenic animal model. The aberrant regulatory elements associated with oncogenic MYC activation include focally amplified distal enhancers and translocation of highly active enhancers from other genes to within topologically associating domains containing the MYC gene locus. The clinical outcome for patients with high levels of MYC expression is virtually identical to that of patients with amplification of the MYCN gene, a known high-risk feature of this disease. Together, these findings establish MYC as a bona fide oncogene in a clinically significant group of high-risk childhood neuroblastomas.Significance: Amplification of the MYCN oncogene is a recognized hallmark of high-risk pediatric neuroblastoma. Here, we demonstrate that MYC is also activated as a potent oncogene in a distinct subset of neuroblastoma cases through either focal amplification of distal enhancers or enhancer hijacking mediated by chromosomal translocation. Cancer Discov; 8(3); 320-35. ©2017 AACR.This article is highlighted in the In This Issue feature, p. 253.

Selective gene dependencies in MYCN -amplified neuroblastoma include the core transcriptional regulatory circuitry

Childhood high-risk neuroblastomas with MYCN gene amplification are difficult to treat effectively1. This has focused attention on tumor-specific gene dependencies that underlie tumorigenesis and thus provide valuable targets for the development of novel therapeutics. Using unbiased genome-scale CRISPR–Cas9 approaches to detect genes involved in tumor cell growth and survival2–6, we identified 147 candidate gene dependencies selective for MYCN-amplified neuroblastoma cell lines, compared to over 300 other human cancer cell lines. We then used genome-wide chromatin-immunoprecipitation coupled to high-throughput sequencing analysis to demonstrate that a small number of essential transcription factors—MYCN, HAND2, ISL1, PHOX2B, GATA3, and TBX2—are members of the transcriptional core regulatory circuitry (CRC) that maintains cell state in MYCN-amplified neuroblastoma. To disable the CRC, we tested a combination of BRD4 and CDK7 inhibitors, which act synergistically, in vitro and in vivo, with rapid downregulation of CRC transcription factor gene expression. This study defines a set of critical dependency genes in MYCN-amplified neuroblastoma that are essential for cell state and survival in this tumor.This study identifies a set of critical dependency genes in MYCN-amplified neuroblastoma that make up the oncogenic transcriptional regulatory circuitry underlying cell state and tumor survival.

JDP2: An oncogenic bZIP transcription factor in T cell acute lymphoblastic leukemia

A substantial subset of patients with T cell acute lymphoblastic leukemia (T-ALL) develops resistance to steroids and succumbs to their disease. JDP2 encodes a bZIP protein that has been implicated as a T-ALL oncogene from insertional mutagenesis studies in mice, but its role in human T-ALL pathogenesis has remained obscure. Here we show that JDP2 is aberrantly expressed in a subset of T-ALL patients and is associated with poor survival. JDP2 is required for T-ALL cell survival, as its depletion by short hairpin RNA knockdown leads to apoptosis. Mechanistically, JDP2 regulates prosurvival signaling through direct transcriptional regulation of MCL1. Furthermore, JDP2 is one of few oncogenes capable of initiating T-ALL in transgenic zebrafish. Notably, thymocytes from rag2:jdp2 transgenic zebrafish express high levels of mcl1 and demonstrate resistance to steroids in vivo. These studies establish JDP2 as a novel oncogene in high-risk T-ALL and implicate overexpression of MCL1 as a mechanism of steroid resistance in JDP2-overexpressing cells.

Abstract 1957: Molecular pathogenesis and drug synergism in a zebrafish model of high risk neuroblastoma

We have developed a transgenic zebrafish model that overexpresses MYCN and harbors loss-of-function mutations of the nf1 tumor suppressor. In this model, loss of nf1 leads to aberrant activation of RAS-MAPK signaling, promoting both increased tumor cell survival and rapid tumor cell proliferation. These neuroblastomas are very aggressive in that almost all of the fish develop neuroblastoma by 3 weeks of age. Three-week old juvenile fish are very small, making it feasible to test the effectiveness of many drugs and drug combinations in vivo for activity against the primary tumors. We demonstrate these advantages of the model by showing marked synergistic anti-tumor effects of a MEK inhibitor (trametinib) and a retinoid (isotretinoin) in vivo at several different dosage combinations by in vivo isobologram analysis. Thus, inhibition of RAS-MAPK signaling can significantly improve the treatment of this very aggressive form of neuroblastoma when it is combined with the inhibition of other key pathways. Because of the very high penetrance and rapid onset of neuroblastoma in our nf1-deficient, MYCN-transgenic zebrafish model, it is one of the only model systems in which extensive analysis of the synergistic activity of two or more drugs can be evaluated in primary tumors in vivo. This capability is especially valuable given that mutations causing RAS-MAPK pathway hyperactivation have been shown to arise frequently at the time of relapse of childhood neuroblastomas, indicating the need to eliminate these mutated tumor cells as a component of the primary treatment. Note: This abstract was not presented at the meeting. Citation Format: Shuning He, Marc R. Mansour, Mark W. Zimmerman, Hillary M. Layden, A. Thomas Look. Molecular pathogenesis and drug synergism in a zebrafish model of high risk neuroblastoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 1957. doi:10.1158/1538-7445.AM2017-1957

Abstract 1540: Creating faithful genetic zebrafish models of pediatric high grade gliomas and MPNSTs

Pediatric high-grade gliomas (HGGs) are the leading cause of cancer-related death in children. Despite a slight improvement of patient prognosis over the past decades pediatric HGGs remain largely incurable. Thus, new experimental models are needed to understand the mechanisms of the disease and find more effective treatment options. We previously reported a model of HGGs and malignant peripheral nerve sheath tumors (MPNSTs) which is based on the combined deficiencies in the tumor suppressor genes tp53 and nf1. However, HGG penetrance is very low in this line and most fish develop MPNSTs starting at about 3 months of age. On top of the existing model we used CRISPR/Cas9 to incorporate knock-out mutations in the tumor suppressor genes atrx or suz12 which are described to be involved in pediatric HGG biology. Heterozygous atrx loss-of-function (lof) did not impact tumor onset or penetrance of neither HGGs nor MPNSTs. Since a total loss of atrx was lethal in development, we re-injected effective atrx targeting gRNAs and Cas9 mRNA into the atrx+/- line to create a mosaic atrx-/- genotype. Surprisingly, despite a high mutation efficiency of the remaining atrx allele the re-injection strategy still did not alter tumor onset and penetrance in that model. This suggests that loss of atrx is only effective in HGGs in cooperation with additional hits other than tp53 and nf1. In contrast, loss of suz12 cooperated well with the tp53/nf1-deficient background. As nf1, suz12 is duplicated in zebrafish (suz12a and suz12b) resulting in 4 alleles of each gene per cell. When at least 2 out of 4 alleles of either suz12a or suz12b were lost, MPNST onset was accelerated. This effect was much stronger in tp53-/-, nf1a+/-, nf1b-/- fish (5-7 weeks) compared to tp53-/-, nf1a+/+, nf1b-/- siblings (3-4 weeks). This indicates that the tumor supporting effect of suz12 lof increases the more nf1 levels decrease. However, HGG onset still remained unchanged. We hypothesize that efficient onset of HGGs in our model requires the presence of an activated oncogene. Specific missense mutations in H3F3A are reported to be implicated in HGG progression in children and young adults. Thus, we overexpressed zebrafish h3f3a-K27M or -G34R mutant sequences in the tp53/nf1/atrx/suz12-deficient line and are currently investigating possible changes in tumor biology. Our zebrafish models of pediatric HGGs and MPNSTs will be useful to dissect the mechanisms underlying the cooperation among driver mutations and for small molecule screens to identify specific inhibitors of cell growth and survival in these malignancies. Citation Format: Felix Oppel, Ting Tao, Shuning He, Mark W. Zimmerman, Dong H. Ki, Nina Weichert, A Thomas Look. Creating faithful genetic zebrafish models of pediatric high grade gliomas and MPNSTs [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 1540. doi:10.1158/1538-7445.AM2017-1540

Abstract 2433: Loss of chd5-mediated gene repression synergizes with MYCN to accelerate neuroblastoma tumorigenesis in zebrafish

Neuroblastoma is a malignancy of the peripheral sympathetic nervous system (PSNS) and accounts for 10-15% of cancer deaths among children. For the 40% of patients presenting with high-risk disease, current therapeutic approaches are insufficient and long-term survival is less than 50%. Along with genomic amplification of the MYCN oncogene, hemizygous loss of the 1p36 chromosomal region is a major risk factor in neuroblastoma. The human CHD5 gene is a neuronal specific chromatin remodeling helicase that maps to 1p36, and is thus frequently lost in high-risk neuroblastoma. Our laboratory has previously generated a faithful model of pediatric neuroblastoma in the zebrafish driven by overexpression of the MYCN oncogene in the PSNS (dbh:MYCN). Additionally, zebrafish chd5 mutant alleles were created using the newly developed gene editing technologies TALEN and CRISPR-Cas9. The resulting chd5 mutant fish exhibit abnormal development of the PSNS in the form of expansion of the superior cervical ganglia and enlargement of the interrenal gland (adrenal medulla). Haploinsufficiency for Chd5 combined with dbh:MYCN expression accelerates the onset and increases the penetrance of neuroblastoma tumorigenesis in zebrafish, indicating a tumor suppressive function. Elevated p-ERK and PCNA+ cells in tumor tissue indicates that loss of Chd5, cooperates with MYCN overexpression to accelerate neuroblast proliferation in vivo. Chd5 (in addition to Chd3 and Chd4) is a core member of the epigenetic regulatory NuRD complex, which also contains HDAC1-2, MTA1-3, MBD2-3, GATAD2A/B and RBBP4/7. The conserved biological function of Chd5 is to silence gene expression through the maintenance of a repressed chromatin state. Tumors deficient for Chd5 expression exhibit reduced levels of the H3K27me3 histone modification, a marker of facultatively repressed genes. Future studies will further explore the mechanism and function of Chd5 so that the pathways mediating tumor suppression can be elucidated and that essential proteins in these pathways can be targeted in ways that exploit the synthetic lethal relationships that are established. Citation Format: Mark W. Zimmerman, Shuning He, Jimann Shin, Shizhen Zhu, Feng Guo, Marc Mansour, Deepak Reyon, J Keith Joung, Jinhua Quan, Timur Yusufzai, A Thomas Look. Loss of chd5-mediated gene repression synergizes with MYCN to accelerate neuroblastoma tumorigenesis in zebrafish. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2433.