Patient-derived Orthotopic Xenograft Research Articles

An annotated biobank of triple negative breast cancer patient-derived xenografts featuring treatment-naïve and longitudinal samples throughout neoadjuvant chemotherapy.

Triple negative breast cancer (TNBC) that fails to respond to neoadjuvant chemotherapy (NACT) can be lethal. Developing effective strategies to eradicate chemoresistant disease requires experimental models that recapitulate the heterogeneity characteristic of TNBC. To that end, we established a biobank of 92 orthotopic patient-derived xenograft (PDX) models of TNBC from the tumors of 75 patients enrolled in the ARTEMIS clinical trial ( NCT02276443 ) at MD Anderson Cancer Center, including 12 longitudinal sets generated from serial patient biopsies collected throughout NACT and from metastatic disease. Models were established from both chemosensitive and chemoresistant tumors, and nearly 30% of PDX models were capable of lung metastasis. Comprehensive molecular profiling demonstrated conservation of genomes and transcriptomes between patient and corresponding PDX tumors, with representation of all major transcriptional subtypes. Transcriptional changes observed in the longitudinal PDX models highlight dysregulation in pathways associated with DNA integrity, extracellular matrix interactions, the ubiquitin-proteasome system, epigenetics, and inflammatory signaling. These alterations reveal a complex network of adaptations associated with chemoresistance. This PDX biobank provides a valuable resource for tackling the most pressing issues facing the clinical management of TNBC, namely chemoresistance and metastasis.

OrthologAL: A Shiny application for quality-aware humanization of non-human pre-clinical high-dimensional gene expression data.

Single-cell and spatial transcriptomics provide unprecedented insight into the inner workings of disease. Pharmacotranscriptomic approaches are powerful tools that leverage gene expression data for drug repurposing and treatment discovery in many diseases. Multiple databases attempt to connect human cellular transcriptional responses to small molecules for use in transcriptome-based drug discovery efforts. However, pre-clinical research often requires in vivo experiments in non-human species, which makes capitalizing on such valuable resources difficult. To facilitate the application of pharmacotranscriptomic databases to pre-clinical research models and to facilitate human orthologous conversion of non-human transcriptomes, we introduce OrthologAL. OrthologAL leverages the BioMart database to access different gene sets from Ensembl, facilitating the interaction between these servers without needing user-generated code. Researchers can input their single-cell or other high-dimensional gene expression data from any species, and OrthologAL will output a human ortholog-converted dataset for download and use. To demonstrate the utility of this application, we characterized orthologous conversion in single-cell, single-nuclei, and spatial transcriptomic data derived from common pre-clinical models, including patient-derived orthotopic xenografts of medulloblastoma, and mouse and rat models of spinal cord injury. We show that OrthologAL can convert these data types efficiently to that of corresponding orthologs while preserving the dimensional architecture of the original non-human expression data. OrthologAL will be broadly useful for applying pre-clinical, high-dimensional transcriptomics data in functional small molecule predictions using existing human-annotated databases.

Gliocidin is a nicotinamide-mimetic prodrug that targets glioblastoma.

Glioblastoma is incurable and in urgent need of improved therapeutics1. Here we identify a small compound, gliocidin, that kills glioblastoma cells while sparing non-tumour replicative cells. Gliocidin activity targets a de novo purine synthesis vulnerability in glioblastoma through indirect inhibition of inosine monophosphate dehydrogenase 2 (IMPDH2). IMPDH2 blockade reduces intracellular guanine nucleotide levels, causing nucleotide imbalance, replication stress and tumour cell death2. Gliocidin is a prodrug that is anabolized into its tumoricidal metabolite, gliocidin-adenine dinucleotide (GAD), by the enzyme nicotinamide nucleotide adenylyltransferase 1 (NMNAT1) of the NAD+ salvage pathway. The cryo-electron microscopy structure of GAD together with IMPDH2 demonstrates its entry, deformation and blockade of the NAD+ pocket3. In vivo, gliocidin penetrates the blood-brain barrier and extends the survival of mice with orthotopic glioblastoma. The DNA alkylating agent temozolomide induces Nmnat1 expression, causing synergistic tumour cell killing and additional survival benefit in orthotopic patient-derived xenograft models. This study brings gliocidin to light as a prodrug with the potential to improve the survival of patients with glioblastoma.

TMOD-08. DETAILED GENERATION OF AN ORTHOTOPIC INTRACRANIAL GLIOBLASTOMA (GBM) PATIENT-DERIVED XENOGRAFT (PDX) MODEL FOR PRECLINICAL IMMUNOTHERAPEUTIC STUDIES

Abstract PURPOSE This study aimed to establish an orthotopic intracranial PDX mouse model using cryopreserved GBM tissues expanded in a heterotopic subcutaneous PDX model for immunotherapeutic studies. The model is designed to closely replicate human GBM, enabling the exploration of its pathophysiology and the development of effective immunotherapies for this type of cancer. METHODS Glioblastoma tissues from 16 fresh and cryopreserved samples were used to establish a heterotopic subcutaneous PDX mouse model for tumor expansion. Successful engraftments were then used to create an orthotopic intracranial PDX mouse model. The tumor formation rates and durations were estimated in both models. Tumor fidelity to the original GBM tumors was confirmed through immunohistology (GFAP, P53, and Ki67) and genetic analysis (whole exome sequencing, RNA sequencing, and methylome analysis). The therapeutic effects of immunotherapy (allogenic NK cells) in combination with Avastin and Irinotecan were tested in the orthotopic intracranial PDX model. RESULTS The orthotopic intracranial GBM mouse model achieved 100% engraftment from successful tumor growth in the subcutaneous PDX model. The overall success rate was 81.25% (85.71% for cryopreserved tissues), with a median process duration of 26.5 weeks (19 weeks for the subcutaneous and 7.5 weeks for intracranial establishment). No significant differences in tumor formation were observed within one year for cryopreserved tissue in the subcutaneous model. Molecular and genetic analysis confirmed similar tumor characteristics between the intracranial PDX tumors and the original patient tumors. Additionally, NK cells combined with Avastin and Irinotecan demonstrated efficacy in this model. CONCLUSIONS We successfully established an orthotopic intracranial PDX mouse model using cryopreserved GBM tissues, with no observed differences within one year. These models accurately mirror patients’ tumor characteristics, promising advancements in glioblastoma research and treatment, particularly for immunotherapy studies. Keywords: Glioblastoma (GBM), cryopreserved GBM tissues, patient-derived xenograft (PDX) model, NOD/SCID IL-12Rγnull (NSG) mice

EXTH-82. TUMOR ORGANOID PREDICTED THERAPEUTIC RESPONSES TO NOVEL EPIGENETIC DRUGS VIA HIGH-THROUGHPUT SCREENING

Abstract INTRODUCTION The treatment choices for pediatric brain tumors are still very limited. Epigenetic therapy emerges as a promising option recently. The lack of in vitro models that represent tumors in vivo and can be scalable for large scale drug screening is major barrier. We have developed tumor organoids from patient-derived orthotopic xenograft and performed a multi-stage high throughput screening for single or combined epigenetic agents and radiation therapy in tumor organoids. METHOD Primary xenograft tumor cells were cultured in matrix and cancer stem cell culture medium in 384-well plates. Radiation sensitivity was examined at 5 different doses. Epigen40 (40 drugs/compounds) targeting various epigenetic modifications was used alone to identify agents with the most cell killing (4 doses for up to 19 days). The drugs that showed partial activity were combined with radiation (at 5 doses) to evaluate additive or synergistic effects. The anti-tumor efficacy of selected drug was then evaluated in vivo. RESULTS The conditions of organoid growth and screen variability were optimized. 7 tumor organoids including 4 glioblastomas and 3 medulloblastomas were successfully established and characterized. The different radio-sensitivities were observed among these models. 7 compounds (JIB-04, SP2509, AS-8351, GSK J4 HCI, 3-Deazaneplanocin A HCL, Chaetocin, TC-E-5003) were shown to effectively suppress organoid growth. Chaetocin, methyltransferase SUV39H inhibitor, demonstrated broadly active and highly potent inhibition across all 7 tested organoids. In addition, bioinformatic analysis identified a subset of epigenetic inhibitors combined with radiation that produced additive anti-tumor activities in vitro. Unfortunately, in vivo treatment of Chaetocin (0.25mg/kg) didn’t convey consistent anti-tumor effects as shown in vitro whereas a high risk of drug toxicity to the mice. CONCLUSION Tumor organoids were successfully developed from primary tumors. With our optimized assay using primary tumor organoids and a multi-stage high throughput drug screening, a novel panel of epigenetic drugs that effective alone or additively with radiation was identified.

TMOD-10. ESTABLISHMENT OF ADULT AND PEDIATRIC BRAZILIAN PRE-CLINICAL MODELS FOR HIGH-GRADE GLIOMAS

Abstract High-grade gliomas (HGG) are the most aggressive brain tumors, necessitating robust and representative preclinical models for therapeutic research. We established primary cultures and patient-derived xenograft models from three pediatric high-grade gliomas (pHGG) and one adult IDH wild-type glioblastoma (GBM IDHwt) Brazilian patients. The first pHGG case, from an 11-year-old with PDGFRA (c.1977C>G) and TP53 (c.637C>T) mutations, led to the development of the HCB570 primary culture, PDX and patient-derived orthotopic xenograft (PDOX) OXP9. The second pHGG, from an 11-year-old with CMMRD syndrome and MSH6 germline mutation, resulted in the HCB589 primary culture, PDX and PDOX OXP22. The third pHGG case, from a 14-year-old with diffuse midline glioma harboring an H3F3A mutation, established the HCB604 primary culture and PDX OXP32. The HCB612 primary culture and PDX GBM1, were established from an adult patient with GBM IDHwt, TERT mutated, with no MGMT promoter methylated. The primary cultures showed varied proliferative rates, with an average doubling time of 55 hours. All cultures demonstrated colony-formating capability, with an average IC50 of 750µM for temozolomide (TMZ) exposure. Immunohistochemical and EPIC methylation profiles confirmed that the PDX models closely resemble the patient features. Our establishment of diverse preclinical models, including those derived from patients with rare genetic conditions such as CMMRD, provides valuable insights into HGG pathogenesis and potential therapeutic strategies. The present Brazilian patient-derived models enrich glioma research inclusion diversity and foster future personalized treatment approaches.

CSIG-24. BRAIN MICROENVIRONMENT-DEPENDENT NEURODEVELOPMENTAL LINEAGE PLASTICITY PROMOTES ADAPTATION TO ONCOGENE INHIBITION IN MALIGNANT GLIOMAS

Abstract Phenotypic plasticity drives non-genetic tumor adaptation in response to various microenvironmental and therapeutic pressures, consequently promoting tumor heterogeneity and progression. In malignant gliomas, the intrinsic and extrinsic mechanisms underlying phenotypic lineage plasticity and its contribution to drug resistance remain unclear. The epidermal growth factor receptor (EGFR) is frequently altered in glioma and serves as a critical regulator of normal radial glia (RG) cells – multipotent progenitors that give rise to cortical neurons and glia in the developing brain. Here, through interrogation of a large panel of diverse glioblastoma (GBM) patient-derived gliomaspheres and orthotopic xenografts, we find that enrichment of RG-like cells is significantly correlated with responses to pharmacological ablation of EGFR, highlighting EGFR as a crucial lineage survival factor for a population of malignant RG-like cells in GBM. Single-cell RNA sequencing and quantitative proteomics reveal that adaptation to EGFR inhibition is linked to a temporal contraction in RG-like cells and concomitant increase in lineage-restricted neuronal and oligodendrocyte progenitor (NPC/OPC)-like states exclusively in the orthotopic brain environment. This lineage transition is coupled to heightened RAS signaling gene expression programs and sustained activation of MAPK signaling, despite robust and durable inhibition of EGFR activation. Furthermore, constitutively active MEK – but not AKT – is sufficient to rescue tumor proliferation under EGFRi, suggesting that the brain microenvironment modulates RAS-MAPK oncogenic signaling to drive lineage transitions following EGFR blockade. Collectively, these results highlight a critical link between oncogenic signaling and neurodevelopmental lineage plasticity in malignant gliomas, presenting a compelling therapeutic opportunity to block tumor cell state transitions for more durable tumor responses in the native glioma tumor microenvironment.

Preclinical Multi-Omic Assessment of Pioglitazone in Skeletal Muscles of Mice Implanted with Human HER2/neu Overexpressing Breast Cancer Xenografts.

Background/Objectives: Breast cancer (BC) is the second most commonly diagnosed cancer worldwide and is accompanied by fatigue during both active disease and remission in the majority of cases. Our lab has measured fatigue in isolated muscles from treatment-naive BC patient-derived orthotopic xenograft (BC-PDOX) mice. Here, we conducted a preclinical trial of pioglitazone in BC-PDOX mice to determine its efficacy in ameliorating BC-induced muscle fatigue, as well as its effects on transcriptomic, metabolomic, and lipidomic profiles in skeletal muscle. Methods: The pioglitazone and vehicle groups were treated orally for 4 weeks upon reaching a tumor volume of 600 mm3. Whole-animal indirect calorimetry was used to evaluate systemic metabolic states. The transcriptome was profiled using short-read bulk RNA sequencing (RNA-seq). Liquid chromatography-tandem mass spectrometry (LC-MS/MS) was used to profile the metabolome and lipidome. Fast and slow skeletal muscle function were evaluated using isolated ex vivo testing. Results: Pioglitazone was associated with a 16.634% lower average O2 consumption (mL∙h-1, p = 0.035), 16.309% lower average CO2 production (mL∙h-1, p = 0.022), and 16.4% lower cumulative energy expenditure (EE) (kcal∙h-1, p = 0.035), with no changes in substrate utilization. RNA-seq supported the downstream effects of pioglitazone on target genes and displayed considerable upregulation of mitochondrial bioenergetic pathways. K-means cluster 5 showed enrichment of the PPAR signaling pathway (adj. p < 0.05, Log2FC = 2.58). Skeletal muscle metabolomic and lipidomic profiles exhibited dysregulation in response to BC, which was partially restored in pioglitazone-treated mice compared to vehicle-treated BC-PDOX mice. In particular, the overall abundance of total ceramide levels was significantly lower in the PioTx group (-46.327%, p = 0.048). Despite molecular support for pioglitazone's efficacy, isolated muscle function was not affected by pioglitazone treatment. No significant difference in the area under the fatigue curve (AUC) was found between the pioglitazone and vehicle groups (p = 0.596). Conclusions: BC induces multi-omic dysregulation in skeletal muscle, which pioglitazone partially ameliorates. Future research should focus on profiling systemic metabolic dysfunction, identifying molecular biomarkers of fatigue, and testing alternative pioglitazone treatment regimens.

DNA-PK inhibition shows differential radiosensitization in orthotopic GBM PDX models based on DDR pathway deficits.

Glioblastoma (GBM) remains one of the most therapy-resistant malignancies with frequent local failures despite aggressive surgery, chemotherapy, and ionizing radiation (IR). Small molecule inhibitors of DNA-dependent protein kinase (DNA-PKi's) are potent radiosensitizers currently in clinical trials. Determining which patients may benefit from radiosensitization with DNA-PKi's is critical to avoid unnecessary increased risk of normal tissue toxicity. In this study we used GBM patient derived xenografts (PDXs) in orthotopic murine models to study the relationship between molecular features, pharmacokinetics, and the radiosensitizing potential of the DNA-PKi peposertib. We show that peposertib radiosensitizes established and PDX GBM lines in vitro at 300nM and above, with significant increase in radiosensitization by maintaining post-IR exposure for >12 hours. Radiosensitization by peposertib is mediated by catalytic inhibition of DNA-PK, and knock-down of DNA-PK by short hairpin RNA (shRNA) largely abolished the radiosensitizing effect. Peposertib decreased auto-phosphorylation of DNA-PKcs after IR in a dose-dependent manner with delay in resolution of γH2AX foci at 24 hours. The addition of peposertib to IR significantly increased survival in GBM120 orthotopic xenografts, but not in GBM10. There was no difference in plasma or average tumor concentrations of peposertib in the two cohorts. While the mechanism underpinning this discordant effect in vitro vs. in vivo is not clear, there was an association for greater sensitization in TP53 mutant lines. Transfection of a dominant-negative TP53 mutant in baseline TP53 wildtype GBM lines significantly delayed growth and decreased NHEJ efficiency (but not Homologous Recombination), after peposertib exposure.

EZH2 functional dichotomy in reactive oxygen species-stratified glioblastoma.

EZH2, well-known for its canonical methyltransferase activity in transcriptional repression in many cancers including glioblastoma (GBM), has an understudied non-canonical function critical for sustained tumor growth. Recent GBM consortial efforts reveal complex molecular heterogeneity for which therapeutic vulnerabilities correlated with subtype stratification remain relatively unexplored. Current enzymatic EZH2 inhibitors (EZH2inh) targeting its canonical SET domain show limited efficacy and lack durable response, suggesting that underlying differences in the non-canonical pathway may yield new knowledge. Here, we unveiled dual roles of the EZH2 CXC domain in therapeutically-distinct, reactive oxygen species (ROS)-stratified tumors. We analyzed differentially expressed genes between ROS classes by examining cis-regulatory elements as well as clustering of activities and pathways to identify EZH2 as the key mediator in ROS-stratified cohorts. Pull-down assays and CRISPR knockout of EZH2 domains were used to dissect the distinct functions of EZH2 in ROS-stratified GBM cells. The efficacy of NF-κB-inducing kinase inhibitor (NIKinh) and standard-of-care temozolomide was evaluated using orthotopic patient-derived GBM xenografts. In ROS(+) tumors, CXC-mediated co-interaction with RelB drives constitutive activation of non-canonical NF-κB2 signaling, sustaining the ROS(+) chemoresistant phenotype. In contrast, in ROS(-) subtypes, PRC2 methyltransferase activity represses canonical NF-κB. Addressing the lack of EZH2inh targeting its non-methyltransferase roles, we utilized a brain-penetrant NIKinh that disrupts EZH2-RelB binding, consequently prolonging survival in orthotopic ROS(+)-implanted mice. Our findings highlight the functional dichotomy of the EZH2 CXC domain in governing ROS-stratified therapeutic resistance, thereby advocating for the development of therapeutic approaches targeting its non-canonical activities and underscoring the significance of patient stratification methodologies.

Three-dimensional analysis of mitochondria in a patient-derived xenograft model of triple negative breast cancer reveals mitochondrial network remodeling following chemotherapy treatments.

Mitochondria are hubs of metabolism and signaling and play an important role in tumorigenesis, therapeutic resistance, and metastasis in many cancer types. Various laboratory models of cancer demonstrate the extraordinary dynamics of mitochondrial structure, but little is known about the role of mitochondrial structure in resistance to anticancer therapy. We previously demonstrated the importance of mitochondrial structure and oxidative phosphorylation in the survival of chemotherapy-refractory triple negative breast cancer (TNBC) cells. As TNBC is a highly aggressive breast cancer subtype with few targeted therapy options, conventional chemotherapies remain the backbone of early TNBC treatment. Unfortunately, approximately 45% of TNBC patients retain substantial residual tumor burden following chemotherapy, associated with abysmal prognoses. Using an orthotopic patient-derived xenograft mouse model of human TNBC, we compared mitochondrial structures between treatment-naïve tumors and residual tumors after conventional chemotherapeutics were administered singly or in combination. We reconstructed 1,750 mitochondria in three dimensions from serial block-face scanning electron micrographs, providing unprecedented insights into the complexity and intra-tumoral heterogeneity of mitochondria in TNBC. Following exposure to carboplatin or docetaxel given individually, residual tumor mitochondria exhibited significant increases in mitochondrial complexity index, area, volume, perimeter, width, and length relative to treatment-naïve tumor mitochondria. In contrast, residual tumors exposed to those chemotherapies given in combination exhibited diminished mitochondrial structure changes. Further, we document extensive intra-tumoral heterogeneity of mitochondrial structure, especially prior to chemotherapeutic exposure. These results highlight the potential for structure-based monitoring of chemotherapeutic responses and reveal potential molecular mechanisms that underlie chemotherapeutic resistance in TNBC.

Prediction of the response to antiangiogenic sunitinib therapy by non-invasive hybrid diffuse optics in renal cell carcinoma.

In this work, broadband diffuse reflectance spectroscopy (DRS) and diffuse correlation spectroscopy (DCS) were used to quantify deep tissue hemodynamics in a patient-derived orthotopic xenograft mouse model of clear cell renal cancer undergoing antiangiogenic treatment. A cohort of twenty-two mice were treated with sunitinib and compared to thirteen control untreated mice, and monitored by DRS/DCS. A reduction in total hemoglobin concentration (THC, p = 0.03), oxygen saturation (SO2, p = 0.03) and blood flow index (BFI, p = 0.02) was observed over the treatment course. Early changes in tumor microvascular blood flow and total hemoglobin concentration were correlated with the final microvessel density (p = 0.014) and tumor weight (p = 0.024), respectively. Higher pre-treatment tumor microvascular blood flow was observed in non-responder mice with respect to responder mice, which was statistically predictive of the tumor intrinsic resistance (p = 0.01). This hybrid diffuse optical technique provides a method for predicting tumor intrinsic resistance to antiangiogenic therapy and could be used as predictive biomarker of response to antiangiogenic therapies in pre-clinical models.

Osteosarcoma patient-derived orthotopic xenograft (PDOX) models for identification of novel and effective therapeutics.

228 Background: Osteosarcoma is the most common malignant primary tumor of bone and mainly occurs in young generations. Due to the heterogeneity, rarity, poor response rate to systemic therapy, and metastatic potential of osteosarcoma, individualized precision medicine and novel drug discovery are greatly needed. Toward this goal, we have established the patient-derived orthotopic xenograft (PDOX) mouse model with surgical orthotopic implantation for all major cancers. The PDOX models recapitulate human tumors better than subcutaneous-transplanted xenografts including patient-derived xenograft (PDX). Metastasis is observed to a greater extent in PDOX models due to the intact histology and correct-organ tumor micro-environment of the orthotopically implanted tissue. Therefore, the PDOX model is highly predictive of drug efficacy and useful for identifying effective drugs for tumors in which new drugs are difficult to develop. Methods: We have reported 18 osteosarcoma PDOX studies evaluating approved and experimental drugs since 2017. The present report reviews our research group’s experience with the osteosarcoma-PDOX model, and the power of the PDOX models to identify effective therapeutics. Results: Effective treatment for drug-resistant osteosarcoma includes regorafenib, as monotherapy, and temozolomide-irinotecan, trabectedin-irinotecan, sorafenib-everolimus, sorafenib-palbociclib, and olaratumab-doxorubicin-cisplatin, as combinations. Experimental therapy with recombinant methioninase, tumor-targeting S. typhimurium A1-R, or combinations of these agents and other drugs have shown surprising efficacy in the recalcitrant-osteosarcoma PDOX models. Conclusions: Owing to the high concordance of drug efficacy between patients and their corresponding PDOX models, these models provide improved and personalized treatment options for patients with osteosarcoma. The patient does not need to suffer from the potential drug toxicity and morbidity of ineffective chemotherapies. In an era of growing promise of new treatment and precision medicine, PDOX models can offer a unique opportunity to provide specific and individualized therapy and novel therapeutic options for osteosarcoma patients.

Detection of Hepatocellular Carcinoma in an Orthotopic Patient-Derived Xenograft with an Epithelial Cell Adhesion Molecule-Specific Peptide.

Hepatocellular carcinoma (HCC) has emerged as a major contributor to the worldwide cancer burden. Improved methods are needed for early cancer detection and image-guided surgery. Peptides have small dimensions that can overcome delivery challenges to achieve high tumor concentrations and deep penetration. We used phage display methods to biopan against the extra-cellular domain of the purified EpCAM protein, and used IRDye800 as a near-infrared (NIR) fluorophore. The 12-mer sequence HPDMFTRTHSHN was identified, and specific binding to EpCAM was validated with HCC cells in vitro. A binding affinity of kd = 67 nM and onset of k = 0.136 min-1 (7.35 min) were determined. Serum stability was measured with a half-life of T1/2 = 2.6 h. NIR fluorescence images showed peak uptake in vivo by human HCC patient-derived xenograft (PDX) tumors at 1.5 h post-injection. Also, the peptide was able to bind to foci of local and distant metastases in liver and lung. Peptide biodistribution showed high uptake in tumor versus other organs. No signs of acute toxicity were detected during animal necropsy. Immunofluorescence staining of human liver showed specific binding to HCC compared with cirrhosis, adenoma, and normal specimens.

Dual targeting of histone deacetylases and MYC as potential treatment strategy for H3-K27M pediatric gliomas.

Diffuse midline gliomas (DMGs) are aggressive and fatal pediatric tumors of the central nervous system that are highly resistant to treatments. Lysine to methionine substitution of residue 27 on histone H3 (H3-K27M) is a driver mutation in DMGs, reshaping the epigenetic landscape of these cells to promote tumorigenesis. H3-K27M gliomas are characterized by deregulation of histone acetylation and methylation pathways, as well as the oncogenic MYC pathway. In search of effective treatment, we examined the therapeutic potential of dual targeting of histone deacetylases (HDACs) and MYC in these tumors. Treatment of H3-K27M patient-derived cells with Sulfopin, an inhibitor shown to block MYC-driven tumors in vivo, in combination with the HDAC inhibitor Vorinostat, resulted in substantial decrease in cell viability. Moreover, transcriptome and epigenome profiling revealed synergistic effect of this drug combination in downregulation of prominent oncogenic pathways such as mTOR. Finally, in vivo studies of patient-derived orthotopic xenograft models showed significant tumor growth reduction in mice treated with the drug combination. These results highlight the combined treatment with PIN1 and HDAC inhibitors as a promising therapeutic approach for these aggressive tumors.

Dual targeting of histone deacetylases and MYC as potential treatment strategy for H3-K27M pediatric gliomas

Diffuse midline gliomas (DMGs) are aggressive and fatal pediatric tumors of the central nervous system that are highly resistant to treatments. Lysine to methionine substitution of residue 27 on histone H3 (H3-K27M) is a driver mutation in DMGs, reshaping the epigenetic landscape of these cells to promote tumorigenesis. H3-K27M gliomas are characterized by deregulation of histone acetylation and methylation pathways, as well as the oncogenic MYC pathway. In search of effective treatment, we examined the therapeutic potential of dual targeting of histone deacetylases (HDACs) and MYC in these tumors. Treatment of H3-K27M patient-derived cells with Sulfopin, an inhibitor shown to block MYC-driven tumors in vivo, in combination with the HDAC inhibitor Vorinostat, resulted in substantial decrease in cell viability. Moreover, transcriptome and epigenome profiling revealed synergistic effect of this drug combination in downregulation of prominent oncogenic pathways such as mTOR. Finally, in vivo studies of patient-derived orthotopic xenograft models showed significant tumor growth reduction in mice treated with the drug combination. These results highlight the combined treatment with PIN1 and HDAC inhibitors as a promising therapeutic approach for these aggressive tumors.

Transforming Albumin into a Trojan Horse of Immunotherapy-Resistant Colorectal Cancer with a High Microsatellite Instability.

The therapeutic response of microsatellite instability-high (MSI-H) colorectal cancer (CRC) to immune checkpoint inhibitors (ICI) is indeed surprising; however, the emergence of acquired resistance poses an even greater threat to the survival of these patients. Herein, bioinformatics analysis of MSI-H CRC samples revealed that Wnt signaling pathway represents a promising target for acquired immune reactivation, while subsequent analysis and biochemical testing substantiated the inclination of Wnt-hyperactive CRC cells to engage in macropinocytosis with human serum albumin (HSA). These findings have inspired us to develop an engineered HSA that not only possesses the ability to specifically target cancer cells but also effectively suppresses the Wnt/β-catenin cascade within these malignant cells. In pursuit of this objective, a comprehensive screening of reported Wnt small-molecule inhibitors was conducted to evaluate their affinity with HSA, and it was discovered that Carnosic acid (CA) exhibited the highest affinity while simultaneously revealing multiple binding sites. Further investigation revealed that CA HSA the capability to engineer HSA into spherical and size-tunable nanostructures known as eHSA (Engineering HSA particle), which demonstrated optimized macropinocytosis-dependent cellular internalization. As anticipated, eHSA effectively suppressed the Wnt signaling pathway and reactivated the acquired immune response in vivo. Furthermore, eHSA successfully restored sensitivity to Anti-PD1's anticancer effects in both subcutaneous and orthotopic mouse homograft models of MSI-H CRC, as well as a humanized hu-PBMC patient-derived orthotopic xenograft (PDOX) mouse model of MSI-H CRC, all while maintaining a favorable safety profile. The collective implementation of this clinically viable immune reactivation strategy not only enables the delivery of Wnt inhibitors for CRC therapy, but also serves as an exemplary demonstration of precision-medicine-guided nanopharmaceutical development that effectively harnesses specific cellular indications in pathological states.

MODL-16. CRANIOSPINAL RADIOTHERAPY IN COMBINATION WITH DNA-DAMAGE RESPONSE INHIBITORS IN PATIENT-DERIVED ORTHOTOPIC XENOGRAFT MODELS OF MEDULLOBLASTOMA

Abstract BACKGROUND Despite treatment intensification, survival for high-risk subgroups of medulloblastoma (MB) such as MYC-amplified Group 3 (Gr3-II) and p53-mutant SHH (SHH-3p53mut) have remained dismal with overall survival around 40% and 20% respectively. Our previous studies have shown that the DNA-damage response inhibitors (DDRis) prexasertib and ceralasertib enhance the effects of CSI using medulloblastoma cell line-derived orthotopic mouse models. However, patient-derived orthotopic xenografts (PDOXs) are considered superior models for preclinical testing compared to immortalised cell lines. Here, we developed a CSI protocol for multiple PDOX models of high-risk medulloblastoma and tested the optimal protocol with concurrent DDRis. METHOD For our CSI optimisation studies, MED211FH (Gr3-II) or MED813FH (SHH-3p53mut) tumour-bearing mice were monitored for clinical symptoms of tumour before commencing treatment. Multiple, fractionated CSI dosing schedules using a 5-days-on, 2-days-off treatment cycle were trialled based on our lab’s previously established CSI protocols before a schedule of 10 x 0.5 Gy fractions (5.0 Gy total) proved optimal. This schedule was then used in both PDOX models plus an additional SHH-3p53mut model (MED314mCLFH), either alone or in combination with concurrent prexasertib or ceralasertib. RESULTS MED211FH and MED813FH mice treated with 5.0 Gy CSI alone resulted in significantly improved median survival compared to control mice (p&amp;lt;0.0001 and p&amp;lt;0.005 respectively) While 5.0 Gy CSI plus concurrent prexasertib or ceralasertib showed significantly improved survival when compared to CSI alone for each model used. MED211FH: p&amp;lt;0.01 and p&amp;lt;0.001 respectively, MED813FH: p&amp;lt;0.05 and p&amp;lt;0.01 respectively and MED314mCLFH: p&amp;lt;0.05 for both DDRi combination groups. CONCLUSION Remarkably, concurrent use of prexasertib or ceralasertib with CSI significantly improved survival in fatal Gr3-II and SHH-3p53mut models. With these results, we provide robust preclinical evidence for radiosensitising use of DDRi in paediatric high-risk MB and recommend swift clinical translation.

Targeting Patient-Derived Orthotopic Gastric Cancers with a Fluorescent Humanized Anti-CEA Antibody

BackgroundGastric cancer poses a major diagnostic and therapeutic challenge as surgical resection provides the only opportunity for a cure. Specific labeling of gastric cancer could distinguish resectable and nonresectable disease and facilitate an R0 resection, which could improve survival.MethodsTwo patient-derived gastric cancer lines, KG8 and KG10, were established from surgical specimens of two patients who underwent gastrectomy for gastric adenocarcinoma. Harvested tumor fragments were implanted into the greater curvature of the stomach to establish patient-derived orthotopic xenograft (PDOX) models. M5A (humanized anti-CEA antibody) or IgG control antibodies were conjugated with the near-infrared dye IRDye800CW. Mice received 50 µg of M5A-IR800 or 50 µg of IgG-IR800 intravenously and were imaged after 72 hr. Fluorescence imaging was performed by using the LI-COR Pearl Imaging System. A tumor-to-background ratio (TBR) was calculated by dividing the mean fluorescence intensity of the tumor versus adjacent stomach tissue.ResultsM5A-IR800 administration resulted in bright labeling of both KG8 and K10 tumors. In the KG8 PDOX models, the TBR for M5A-IR800 was 5.85 (SE ± 1.64) compared with IgG-IR800 at 0.70 (SE ± 0.17). The K10 PDOX models had a TBR of 3.71 (SE ± 0.73) for M5A-IR800 compared with 0.66 (SE ± 0.12) for IgG-IR800.ConclusionsHumanized anti-CEA (M5A) antibodies conjugated to fluorescent dyes provide bright and specific labeling of gastric cancer PDOX models. This tumor-specific fluorescent antibody is a promising potential clinical tool to detect the extent of disease for the determination of resectability as well as to visualize tumor margins during gastric cancer resection.

IMMU-18. ENHANCING GD2.CAR T CELL THERAPY FOR DIFFUSE MIDLINE GLIOMA WITH LSD1 AND HDAC INHIBITORS

Abstract BACKGROUND Chimeric antigen receptor T cells against the glycolipid GD2 (GD2.CARTs) have shown promise against Diffuse Midline Glioma (DMG) in clinical trials but are not yet curative. Previous studies in neuroblastoma demonstrate that histone deacetylase inhibitor (HDACi) treatment can increase GD2 on tumor cells and improve targeting by GD2.CARTs. Our lab previously found that simultaneous HDACi and lysine-demethylase 1 inhibitor (LSD1i) treatment in DMG cells causes synergistic alterations in gene expression and reduces DMG growth. Here, we find that treating GD2-low DMG cell lines with combinations of LSD1i and HDACi improves DMG response to GD2.CARTs. METHODS Surface expression of GD2 before and after LSD1i/HDACi treatment were analyzed using immunofluorescence microscopy and flow cytometry. The cytotoxicity of GD2.CARTs against DMG cells was determined from co-culture experiments and in patient-derived orthotopic xenograft models using flow cytometry and bioluminescent imaging. RESULTS Since low target antigen expression is one mechanism by which tumor cells can escape CAR T cell therapy, we profiled GD2 expression on 9 different H3K27M-mutant DMG cell lines. This analysis shows that only 5 of the 9 cell lines exhibit high GD2 expression while the remaining 4 lines have low GD2 expression. When treating these cell lines with GD2.CARTs, we find that low GD2 expression on DMG cells correlates with tumor cell escape and resistance to GD2.CARTs. Treating GD2-low DMG cells with LSD1i+HDACi increases GD2 expression and enhances tumor cell targeting by GD2.CARTs in subsequent co-culture assays. Further studies in mice bearing GD2-low DMG tumors were initially GD2.CART-insensitive but showed reduced tumor growth when pre-treated with LSD1i+HDACi before intravenous GD2.CART infusion. CONCLUSIONS These studies suggest that variable GD2 expression is a major driver of DMG resistance to GD2.CARTs and that LSD1i+HDACi pre-treatment may improve DMG patient responses to GD2.CART therapy by increasing target antigen expression.