Sarah Injac

Concurrent Inhibition of Neurosphere and Monolayer Cells of Pediatric Glioblastoma by Aurora A Inhibitor MLN8237 Predicted Survival Extension in PDOX Models

Purpose: Pediatric glioblastoma multiforme (pGBM) is a highly aggressive tumor in need of novel therapies. Our objective was to demonstrate the therapeutic efficacy of MLN8237 (alisertib), an orally available selective inhibitor of Aurora A kinase (AURKA), and to evaluate which in vitro model system (monolayer or neurosphere) can predict therapeutic efficacy in vivo. Experimental Design: AURKA mRNA expressions were screened with qRT-PCR. In vitro antitumor effects were examined in three matching pairs of monolayer and neurosphere lines established from patient-derived orthotopic xenograft (PDOX) models of the untreated (IC-4687GBM), recurrent (IC-3752GBM), and terminal (IC-R0315GBM) tumors, and in vivo therapeutic efficacy through log rank analysis of survival times in two models (IC-4687GBM and IC-R0315GBM) following MLN8237 treatment (30 mg/kg/day, orally, 12 days). Drug concentrations in vivo and mechanism of action and resistance were also investigated. Results: AURKA mRNA overexpression was detected in 14 pGBM tumors, 10 PDOX models, and 6 cultured pGBM lines as compared with 11 low-grade gliomas and normal brains. MLN8237 penetrated into pGBM xenografts in mouse brains. Significant extension of survival times were achieved in IC-4687GBM of which both neurosphere and monolayer were inhibited in vitro, but not in IC-R0315GBM of which only neurosphere cells responded (similar to IC-3752GBM). Apoptosis-mediated MLN8237 induced cell death, and the presence of AURKA-negative and CD133+ cells appears to have contributed to in vivo therapy resistance. Conclusions: MLN8237 successfully targeted AURKA in a subset of pGBMs. Our data suggest that combination therapy should aim at AURKA-negative and/or CD133+ pGBM cells to prevent tumor recurrence. Clin Cancer Res; 24(9); 2159–70. ©2018 AACR.

Xenotransplantation of pediatric low grade gliomas confirms the enrichment of BRAF V600E mutation and preservation of CDKN2A deletion in a novel orthotopic xenograft mouse model of progressive pleomorphic xanthoastrocytoma

To identify cellular and molecular changes that driver pediatric low grade glioma (PLGG) progression, we analyzed putative cancer stem cells (CSCs) and evaluated key biological changes in a novel and progressive patient-derived orthotopic xenograft (PDOX) mouse model. Flow cytometric analysis of 22 PLGGs detected CD133+ (<1.5%) and CD15+ (20.7 ± 28.9%) cells, and direct intra-cranial implantation of 25 PLGGs led to the development of 1 PDOX model from a grade II pleomorphic xanthoastrocytoma (PXA). While CSC levels did not correlate with patient tumor progression, neurosphere formation and in vivo tumorigenicity, the PDOX model, IC-3635PXA, reproduced key histological features of the original tumor. Similar to the patient tumor that progressed and recurred, IC-3635PXA also progressed during serial in vivo subtransplantations (4 passages), exhibiting increased tumor take rate, elevated proliferation, loss of mature glial marker (GFAP), accumulation of GFAP−/Vimentin+ cells, enhanced local invasion, distant perivascular migration, and prominent reactive gliosis in normal mouse brains. Molecularly, xenograft cells with homozygous deletion of CDKN2A shifted from disomy chromosome 9 to trisomy chromosome 9; and BRAF V600E mutation allele frequency increased (from 28% in patient tumor to 67% in passage III xenografts). In vitro drug screening identified 2/7 BRAF V600E inhibitors and 2/9 BRAF inhibitors that suppressed cell proliferation. In summary, we showed that PLGG tumorigenicity was low despite the presence of putative CSCs, and our data supported GFAP−/Vimentin+ cells, CDKN2A homozygous deletion in trisomy chromosome 9 cells, and BRAF V600E mutation as candidate drivers of tumor progression in the PXA xenografts.

Systems biology–based drug repositioning identifies digoxin as a potential therapy for groups 3 and 4 medulloblastoma

Systematic drug repositioning identifies digoxin as a potential treatment for groups 3 and 4 medulloblastoma. Digoxin on the brain Groups 3 and 4 medulloblastoma (MB) are highly heterogeneous in nature and have therefore proven difficult to target, resulting in corresponding meagre survival rates. Using a sophisticated systematic drug repositioning approach, Huang et al. identified the already-approved drug digoxin as a possible treatment for these MB subtypes. Application of digoxin to orthotopic patient-derived xenograft models produced an increase in survival; this increase in survival was further extended upon combining digoxin treatment with radiation, and, importantly, occurred at blood concentrations of digoxin that might be feasible in patients. These findings could mean a possible inroads in improving outcome for patients with these hard-to-treat cancers. Medulloblastoma (MB) is the most common malignant brain tumor of childhood. Although outcomes have improved in recent decades, new treatments are still needed to improve survival and reduce treatment-related complications. The MB subtypes groups 3 and 4 represent a particular challenge due to their intragroup heterogeneity, which limits the options for “rational” targeted therapies. Here, we report a systems biology approach to drug repositioning that integrates a nonparametric, bootstrapping-based simulated annealing algorithm and a 3D drug functional network to characterize dysregulated driver signaling networks, thereby identifying potential drug candidates. From more than 1300 drug candidates studied, we identified five members of the cardiac glycoside family as potentially inhibiting the growth of groups 3 and 4 MB and subsequently confirmed this in vitro. Systemic in vivo treatment of orthotopic patient-derived xenograft (PDX) models of groups 3 and 4 MB with digoxin, a member of the cardiac glycoside family approved for the treatment of heart failure, prolonged animal survival at plasma concentrations known to be tolerated in humans. These results demonstrate the power of a systematic drug repositioning method in identifying a potential treatment for MB. Our strategy could potentially be used to accelerate the repositioning of treatments for other human cancers that lack clearly defined rational targets.

Abstract 3214: Systematic drug repurposing for faster cures of pediatric cancer identifies that Digoxin prolongs survival in a PDOX model of group 4 medulloblastoma

Background: Medulloblastoma (MB) is the most common malignant brain tumor of childhood. While the current standard care for MB leads to long term survival in approximately 75 % of patients; recurrent and refractory MB continues to have dismal outcomes. In addition, long term survivors face significant treatment-related sequelae especially poor neurocognitive outcomes. Drug repositioning for known drugs is a promising potential strategy not only for drug discovery but also for accelerated translation into the clinical setting. To systematically explore thousands of known drugs available, we integrated computational biology and empirical biology methods to find old drugs for new indications in MB. Results: A non-parametric, bootstrapping based simulated annealing (NPBSA) algorithm was employed to identify driver signaling pathways for over 1,800 patients with Group 3 and Group 4 MB through an integrative analysis on their mRNA expression, DNA-copy number, DNA-methylation and DNA-seq profiles. Then, drug functional networks were constructed based on gene expression profiles under drug treatment as well as chemical structures and were clustered into drug modules with potential mechanisms of action. By evaluating targeted effects of 1,309 drugs from connectivity map database within each drug module in driver signaling pathways, we identified a group of known cardiac glycosides that top ranked among the total drug candidates for the Group 3 and 4 MB subtypes. In addition to traditional chemotherapeutic agents, members of the cardiac aminoglycoside family were repeatedly identified as potential therapeutic agents for MB. These findings were validated in multiple MB-derived cell lines which showed high rates of growth inhibition by cardiac aminoglycosides compared to controls. To evaluate if this growth inhibition in vitro correlated to prolonged survival in vivo, an extensively characterized patient-derived orthotopic-xenograft (PDOX) model of Group 4 MB (ICb-1078MB) was treated with digoxin (2 mg/kg i.p.) for 2 cycles of 14 days. Digoxin treatment significantly prolonged survival to 113 days from a median of 92 days in untreated controls (p=0.001). Histological evaluation of recurrent tumors following digoxin treatment demonstrated changes in the pattern of tumor spread, vascularity and necrosis compared to untreated controls. Conclusions: Leveraging big data in the domains of pharmacogenomics and the notion of drug functional networks and driver signaling pathways represents a powerful tool to repurpose known drugs for new indications in pediatric cancers. Using this integrative biology approach, we identified the cardiac aminoglycosides family generally and Digoxin, specifically, as potential novel agents in the treatment of pediatric medulloblastoma Citation Format: Lei Huang, Sarah G. Injac, Hong Zhao, Qi Lin, Mari Kogiso, Chris T. Man, Xiao-Nan Li, Ching C. Lau, Stephen T. Wong. Systematic drug repurposing for faster cures of pediatric cancer identifies that Digoxin prolongs survival in a PDOX model of group 4 medulloblastoma [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 3214. doi:10.1158/1538-7445.AM2017-3214

Abstract 5058: Lysine specific demethylase-1 (LSD-1) Inhibitor SYC-836 in combination with radiation prolongs animal survival in patient-derived posterior fossa ependymoma xenograft mouse models

Background: Ependymoma (EPN) is the third most common malignant pediatric brain tumor. Current standard therapy include maximally safe surgical resection followed by radiation and lead to a 5-year overall survival of 50-71%. Recent molecular subgrouping of EPN has identified one group, posterior fossa A (PFA), which accounts for 45% of all EPN cases, to have one of the worst prognosis and it is driven by epigenetic changes, suggesting targeting epigenetic changes in PFA EPN can potentially be effective. In this study, we examined the therapeutic efficacy of SYC-836, a novel LSD-1 inhibitor compound developed at Baylor College of Medicine, both in vitro and in vivo in PDOX models of posterior fossa EPN. Methods: To examine in vitro anti-tumor activities, paired primary cultured cells (both as attached cells and neurospheres) from an established PDOX model of posterior fossa EPN (ICb-4423EPN) were subjected to SYC-836 at various concentrations (0-25uM). Cell viability and proliferation were measured using Cell Counting Kit-8 assay at 5 different time points over 14 days. To validate the drug’s in vivo efficacy, two established posterior fossa EPN PDOX models, ICb-4423EPN and ICb-2002EPN, were utilized. 40 eight weeks old SCID mice per model were implanted with tumor cells. They were divided into 4 treatment groups (10 mice/group) each: 1) control (DPBS, 10uL/kg IP daily x 28 days), 2) radiation/standard therapy (2 Gy focal XRT daily x 5 days), 3) SYC-836 only (15mg/kg IP daily x 28 days), and 4) combination (radiation + SYC-836 per regimen above). Animal survival times were analyzed using log rank analysis. Changes of histone lysine methylation were examined through western hybridization. Results: SYC-836 demonstrated effective cell killing in vitro against both attached and neurosphere cultured cells in both time- and dose-dependent manner. IC50 was ~7.5uM. In vivo experiment was completed in 1 of the 2 EPN PDOX models (ICb-2002EPN) with the second model ongoing. Median survival times for each group is as followed: control 136 days, radiation 148 days, SYC-836 only 136 days, combination 180 days. There were no survival benefit with either XRT only (P=0.205) or SYC-836 only (P=0.186) when compared to the control group; however, when used in combination, the treatment strategy lead to significant improvement in animal survival (P=0.004). SYC-836 was well tolerated in mice. Conclusion: Our data showed that combining SYC-836 with current standard therapy of radiation synergistically prolongs animal survival significantly, although as a single agent SYC-836 was not effective against posterior fossa ependymoma. Our data suggest that SYC-836 may have a role in the clinical setting by either reducing radiation dosages, or be a potential adjuvant agent to other chemotherapy drugs in our treatment approach for ependymoma. Citation Format: Sibo Zhao, Huiyuan Zhang, Lin Qi, Holly Lindsay, Yuchen Du, Mari Kogiso, Frank Braun, Sarah Injac, Laszlo Perlaky, Donald W. Parsons, Murali Chintagumpala, Adekunle Adesina, Yongcheng Song, Xiao-Nan Li. Lysine specific demethylase-1 (LSD-1) Inhibitor SYC-836 in combination with radiation prolongs animal survival in patient-derived posterior fossa ependymoma xenograft mouse models [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 5058. doi:10.1158/1538-7445.AM2017-5058