Syngeneic Murine Tumor Models Research Articles

Tumor Radiosensitization by Gene Electrotransfer-Mediated Double Targeting of Tumor Vasculature.

Targeting the tumor vasculature through specific endothelial cell markers involved in different signaling pathways represents a promising tool for tumor radiosensitization. Two prominent targets are endoglin (CD105), a transforming growth factor β co-receptor, and the melanoma cell adhesion molecule (CD1046), present also on many tumors. In our recent in vitro study, we constructed and evaluated a plasmid for simultaneous silencing of these two targets. In the current study, our aim was to explore the therapeutic potential of gene electrotransfer-mediated delivery of this new plasmid in vivo, and to elucidate the effects of combined therapy with tumor irradiation. The antitumor effect was evaluated by determination of tumor growth delay and proportion of tumor free mice in the syngeneic murine mammary adenocarcinoma tumor model TS/A. Histological analysis of tumors (vascularization, proliferation, hypoxia, necrosis, apoptosis and infiltration of immune cells) was performed to evaluate the therapeutic mechanisms. Additionally, potential activation of the immune response was evaluated by determining the induction of DNA sensor STING and selected pro-inflammatory cytokines using qRT-PCR. The results point to a significant radiosensitization and a good therapeutic potential of this gene therapy approach in an otherwise radioresistant and immunologically cold TS/A tumor model, making it a promising novel treatment modality for a wide range of tumors.

1,2,4-Amino-triazine derivatives as pyruvate dehydrogenase kinase inhibitors: Synthesis and pharmacological evaluation

Among the different hallmarks of cancer, deregulation of cellular metabolism turned out to be an essential mechanism in promoting cancer resistance and progression. The pyruvate dehydrogenase kinases (PDKs) are well known as key regulators in cells metabolic process and their activity was found to be overexpressed in different metabolic alerted types of cancer, including the high aggressive pancreatic ductal adenocarcinoma (PDAC). To date few PDK inhibitors have been reported, and the different molecules developed are characterized by structural chemical diversity. In an attempt to find novel classes of potential PDK inhibitors, the molecular hybridization approach, which combine two or more active scaffolds in a single structure, was employed. Herein we report the synthesis and the pharmacological evaluation of the novel hybrid molecules, characterized by the fusion of three different pharmacophoric sub-units such as 1,2,4-amino triazines, 7-azaindoles and indoles, in a single structure. The synthesized derivatives demonstrated a promising ability in hampering the enzymatic activity of PDK1 and 4, further confirmed by docking studies. Interestingly, these derivatives retained a strong antiproliferative activity against pancreatic cancer cells either in 2D and 3D models. Mechanistic studies in highly aggressive PDAC cells confirmed their ability to hamper PDK axis and to induce cancer cell death by apoptosis. Moreover, in vivo translational studies in a murine syngeneic solid tumor model confirmed the ability of the most representative compounds to target the PDK system and highlight the ability to reduce the tumor growth without inducing substantial body weight changes in the treated mice.

Tumoral CD105 promotes immunosuppression, metastasis, and angiogenesis in renal cell carcinoma.

CD105 (endoglin) is a transmembrane protein that functions as a TGF-beta coreceptor and is highly expressed on endothelial cells. Unsurprisingly, preclinical and clinical evidence strongly suggests that CD105 is an important contributor to tumor angiogenesis and tumor progression. Emerging evidence suggests that CD105 is also expressed by tumor cells themselves in certain cancers such as renal cell carcinoma (RCC). In human RCC tumor cells, CD105 expression is associated with stem cell-like properties and contributes to the malignant phenotype in vitro and in xenograft models. However, as a regulator of TGF-beta signaling, there is a striking lack of evidence for the role of tumor-expressed CD105 in the anti-tumor immune response and the tumor microenvironment. In this study, we report that tumor cell-expressed CD105 potentiates both the in vitro and in vivo tumorigenic potential of RCC in a syngeneic murine RCC tumor model. Importantly, we find that tumor cell-expressed CD105 sculpts the tumor microenvironment by enhancing the recruitment of immunosuppressive cell types and inhibiting the polyfunctionality of tumor-infiltrating CD4+ and CD8+ T cells. Finally, while CD105 expression by endothelial cells is a well-established contributor to tumor angiogenesis, we also find that tumor cell-expressed CD105 significantly contributes to tumor angiogenesis in RCC.

Derazantinib, a fibroblast growth factor receptor inhibitor, inhibits colony-stimulating factor receptor-1 in macrophages and tumor cells and in combination with a murine programmed cell death ligand-1-antibody activates the immune environment of murine syngeneic tumor models.

Derazantinib (DZB) is an inhibitor of the fibroblast growth factor receptors 1-3 (FGFRi) with similar potency against colony-stimulating factor receptor-1 (CSF1R), a protein important in the recruitment and function of tumor-associated macrophages. DZB inhibited pCSF1R in the macrophage cell line RAW264.7, and tumor cells GDM-1 and DEL, and had the same potency in HeLa cells transiently over-expressing FGFR2. DZB exhibited similar potency against pCSF1R expressed by isolated murine macrophages, but as in the cell lines, specific FGFRi were without significant CSF1R activity. DZB inhibited growth of three tumor xenograft models with reported expression or amplification of CSF1R, whereas the specific FGFRi, pemigatinib, had no efficacy. In the FGFR-driven syngeneic breast tumor-model, 4T1, DZB was highly efficacious causing tumor stasis. A murine PD-L1 antibody was without efficacy in this model, but combined with DZB, increased efficacy against the primary tumor and further reduced liver, spine and lung metastases. Immunohistochemistry of primary 4T1 tumors showed that the combination favored an antitumor immune infiltrate by strongly increasing cytotoxic T, natural killer and T-helper cells. Similar modulation of the tumor microenvironment was observed in an FGFR-insensitive syngeneic bladder model, MBT-2. These data confirm CSF1R as an important oncology target for DZB and provide mechanistic insight for the ongoing clinical trials, in which DZB is combined with the PD-L1 antibody, atezolizumab.

Evaluation of the clinical molecule anti-human-PD-L1/IL-15 KD033 in the human-PD-1/PD-L1-expressing murine model demonstrates PD-L1 targeting of IL-15 in vivo

KD033 is a clinical-stage immunocytokine composed of a high-affinity anti-human-PD-L1 antibody and the human IL-15/ IL-15 receptor sushi-domain complex. We have previously shown that KD033-surrogate, the anti-mouse-PD-L1/IL-15 immunocytokine, was efficacious in several syngeneic murine tumor models including those that were refractory to anti-PD-1/PD-L1 checkpoint blockers. KD033-surrogate showed better efficacy than the combination treatment of its component, anti-PD-L1 antibody with the non-targeting IL-15. KD033-surrogate was also efficacious in both low and high PD-L1-expressing tumors. In this study, we have utilized double knock-in mice expressing functional human PD-1/PD-L1 to show that the clinical molecule, KD033, reproduced the anti-tumor efficacy observed with KD033-surrogate in the syngeneic models. KD033 was equally efficacious in reducing the growth of human-PD-L1 positive (hPDL1+) and negative (hPDL1-) MC38 murine tumors. We observed similar peripheral pharmacodynamics changes in KD033-treated mice bearing either hPDL1+ or hPDL1- MC38 tumors. However, different transcriptomic profiles were observed between KD033-treated hPDL1+ and hPDL1- MC38 tumors with marked changes involving mostly downregulated genes in hPDL1- tumors in addition to the immune-related genes changes observed in both hPDL1+ and hPDL1- MC38 tumors. Cytotoxic and myeloid cell signatures were upregulated in both tumors with relatively greater increases observed in hPDL1- MC38 tumors. These effects of KD033 treatment in PD-L1 positive and negative tumors demonstrate the role of PD-L1 in targeting of IL-15 cytokine in vivo.

RAD21 amplification epigenetically suppresses interferon signaling to promote immune evasion in ovarian cancer.

Prevalent copy number alteration is the most prominent genetic characteristic associated with ovarian cancer (OV) development, but its role in immune evasion has not been fully elucidated. In this study, we identified RAD21, a key component of the cohesin complex, as a frequently amplified oncogene that could modulate immune response in OV. Through interrogating the RAD21-regulated transcriptional program, we found that RAD21 directly interacts with YAP/TEAD4 transcriptional corepressors and recruits the NuRD complex to suppress interferon (IFN) signaling. In multiple clinical cohorts, RAD21 overexpression is inversely correlated with IFN signature gene expression in OV. We further demonstrated in murine syngeneic tumor models that RAD21 ablation potentiated anti-PD-1 efficacy with increased intratumoral CD8+ T cell effector activity. Our study identifies a RAD21-YAP/TEAD4-NuRD corepressor complex in immune modulation, and thus provides a potential target and biomarker for precision immunotherapy in OV.

Combination of oral STING agonist MSA-2 and anti-TGF-β/PD-L1 bispecific antibody YM101: a novel immune cocktail therapy for non-inflamed tumors

BackgroundNon-inflamed tumors, including immune-excluded and immune-desert tumors, are commonly resistant to anti-PD-1/PD-L1 (α-PD-1/PD-L1) therapy. Our previous study reported the potent antitumor activity of anti-TGF-β/PD-L1 bispecific antibody YM101 in immune-excluded tumors. However, YM101 had limited antitumor activity in immune-desert models. MSA-2 is a novel oral stimulator of interferon genes (STING) agonist, which activates the innate immune system and may synergize with YM101 in overcoming immunotherapy resistance.MethodsThe dose-dependent effect of MSA-2 on STING signaling was determined by interferon-β level. The maturation and function of dendritic cell (DC) were measured by flow cytometry, RNA-seq, one-way mixed lymphocyte reaction (MLR), OVA peptide pulse, and cytokine/chemokine detection. The synergistic effect between MSA-2 and YM101 was assessed by one-way MLR. The macrophage activation was measured by flow cytometry and cytokine/chemokine detection. The in vivo antitumor activity of MSA-2 combined with YM101 was explored in syngeneic murine tumor models. After treatments, the alterations in the tumor microenvironment (TME) were detected by flow cytometry, immunohistochemistry staining, immunofluorescence staining, RNA-seq, and single-cell RNA-seq (scRNA-seq).ResultsMSA-2 could promote the maturation and antigen presentation capability of murine DC. In the one-way MLR assay, MSA-2 synergized with YM101 in enhancing naive T cell activation. Moreover, MSA-2 stimulated the classical activation of macrophage, without significant influence on alternative activation. Further in vivo explorations showed that MSA-2 increased multiple proinflammatory cytokines and chemokines in the TME. MSA-2 combined with YM101 remarkedly retarded tumor growth in immune-excluded and immune-desert models, with superior antitumor activity to monotherapies. Flow cytometry, bulk RNA-seq, and scRNA-seq assays indicated that the combination therapy simultaneously boosted the innate and adaptive immunity, promoted antigen presentation, improved T cell migration and chemotaxis, and upregulated the numbers and activities of tumor-infiltrating lymphocytes.ConclusionOur results demonstrate that MSA-2 synergizes with YM101 in boosting antitumor immunity. This immune cocktail therapy effectively overcomes immunotherapy resistance in immune-excluded and immune-desert models.

155 (PB035) - Derazantinib, an inhibitor of fibroblast growth factor receptors 1–3, increases the efficacy of paclitaxel combined with a VEGFR2-antibody in murine syngeneic tumor models

Background: Derazantinib (DZB) is an oral fibroblast growth factor receptor (FGFR) inhibitor with clinical activity in intrahepatic cholangiocarcinoma. DZB is also in a phase-2 trial for gastric cancer (GC), where it is combined with the current standard-of-care (SoC) paclitaxel and the VEGFR2-antibody (Ab), ramucirumab. Kinase assays and cellular and in vivo data indicate significant activity of DZB against two other important targets in oncology, CSF1R and VEGFR2. Here, using three different syngeneic tumor models grown orthotopically or subcutaneously in mice, we have explored the efficacy and tolerability of combining DZB with paclitaxel and a murine VEGFR2-Ab.

Patient-derived head and neck tumor slice cultures: a versatile tool to study oncolytic virus action

Head and neck cancer etiology and architecture is quite diverse and complex, impeding the prediction whether a patient could respond to a particular cancer immunotherapy or combination treatment. A concomitantly arising caveat is obviously the translation from pre-clinical, cell based in vitro systems as well as syngeneic murine tumor models towards the heterogeneous architecture of the human tumor ecosystems. To bridge this gap, we have established and employed a patient-derived HNSCC (head and neck squamous cell carcinoma) slice culturing system to assess immunomodulatory effects as well as permissivity and oncolytic virus (OV) action. The heterogeneous contexture of the human tumor ecosystem including tumor cells, cancer-associated fibroblasts and immune cells was preserved in our HNSCC slice culturing approach. Importantly, the immune cell compartment remained to be functional and cytotoxic T-cells could be activated by immunostimulatory antibodies. In addition, we uncovered that a high proportion of the patient-derived HNSCC slice cultures were susceptible to the OV VSV-GP. More specifically, VSV-GP infects a broad spectrum of tumor-associated lineages including epithelial and stromal cells and can induce apoptosis. In sum, this human tumor ex vivo platform might complement pre-clinical studies to eventually propel cancer immune-related drug discovery and ease the translation to the clinics.

Preclinical characterization and clinical translation of pharmacodynamic markers for MK-5890: a human CD27 activating antibody for cancer immunotherapy

BackgroundImmune checkpoint inhibitors (ICI) have radically changed cancer therapy, but most patients with cancer are unresponsive or relapse after treatment. MK-5890 is a CD27 agonist antibody intended to complement ICI...

A multi-omic single cell sequencing approach to develop a CD8 T cell specific gene signature for anti-PD1 response in solid tumors.

Immune checkpoint blockade (ICB) has led to durable clinical responses in multiple cancer types. However, biomarkers that identify which patients are most likely to respond to ICB are not well defined. Many putative biomarkers developed from a small number of samples often fail to maintain their predictive status in larger validation cohorts. We show across multiple human malignancies and syngeneic murine tumor models that neither pretreatment T cell receptor (TCR) clonality nor changes in clonality after ICB correlate with response. Dissection of tumor infiltrating lymphocytes pre- and post-ICB by paired single-cell RNA sequencing and single-cell TCR sequencing reveals conserved and distinct transcriptomic features in expanded TCR clonotypes between anti-PD1 responder and nonresponder murine tumor models. Overall, our results indicate a productive anti-tumor response is agnostic of TCR clonal expansion. Further, we used single-cell transcriptomics to develop a CD8+ T cell specific gene signature for a productive anti-tumor response and show the response signature to be associated with overall survival (OS) on nivolumab monotherapy in CheckMate-067, a phase 3 clinical trial in metastatic melanoma. These results highlight the value of leveraging single-cell assays to dissect heterogeneous tumor and immune subsets and define cell-type specific transcriptomic biomarkers of ICB response.

Cell-penetrating peptides enhance peptide vaccine accumulation and persistence in lymph nodes to drive immunogenicity

Peptide-based cancer vaccines are widely investigated in the clinic but exhibit modest immunogenicity. One approach that has been explored to enhance peptide vaccine potency is covalent conjugation of antigens with cell-penetrating peptides (CPPs), linear cationic and amphiphilic peptide sequences designed to promote intracellular delivery of associated cargos. Antigen-CPPs have been reported to exhibit enhanced immunogenicity compared to free peptides, but their mechanisms of action invivo are poorly understood. We tested eight previously described CPPs conjugated to antigens from multiple syngeneic murine tumor models and found that linkage to CPPs enhanced peptide vaccine potency invivo by as much as 25-fold. Linkage of antigens to CPPs did not impact dendritic cell activation but did promote uptake of linked antigens by dendritic cells both invitro and invivo. However, T cell priming invivo required Batf3-dependent dendritic cells, suggesting that antigens delivered by CPP peptides were predominantly presented via the process of cross-presentation and not through CPP-mediated cytosolic delivery of peptide to the classical MHC class I antigen processing pathway. Unexpectedly, we observed that many CPPs significantly enhanced antigen accumulation in draining lymph nodes. This effect was associated with the ability of CPPs to bind to lymph-trafficking lipoproteins and protection of CPP-antigens from proteolytic degradation in serum. These two effects resulted in prolonged presentation of CPP-peptides in draining lymph nodes, leading to robust T cell priming and expansion. Thus, CPPs can act through multiple unappreciated mechanisms to enhance T cell priming that can be exploited for cancer vaccines with enhanced potency.

Novel Donor-Acceptor Conjugated Polymer-Based Nanomicelles for Photothermal Therapy in the NIR Window.

In this study, a novel donor-acceptor conjugated polymer PDPPDTP was designed and synthesized by D-A polymerization using 2,6-di(trimethyltin)-N-dithieno[3,2-b:20,30-d]pyrrole as the electron-donating (D) unit and 3,6-bis(5-bromothiophen-2-yl)-2,5-dihexadecylpyrrolo[3,4-c]pyrrole-1,4-dione as the electron-accepting (A) unit. The prepared polymer has strong absorption in the near-infrared (NIR) range of 700-900 nm. Moreover, it shows excellent photothermal performance under irradiation at 808 nm. Next, the biodegradable amphiphilic polymer polyethylene glycol-polycaprolactone was used to encapsulate the new conjugated polymer into nanomicelles by the microemulsion method. The obtained PDPPDTP-loaded micelles exhibited a regular spherical structure, and their hydrodynamic diameter was about 78 nm, characterized by transmission electron microscopy and dynamic light scattering. Notably, the micelles exhibited good stability, and the encapsulation efficiency of the conjugated polymer in the micelles was ∼80%. In vitro cell experiments demonstrated that the nanomicelles not only showed good biocompatibility and low toxicity but also could effectively inhibit the proliferation of breast cancer cells 4T1 under the NIR light irradiation of 808 nm. Furthermore, in vivo studies of photothermal therapy (PTT) efficacy showed that the PDPPDTP-loaded micelles exhibited a remarkable tumor growth inhibition in a syngeneic murine tumor model, indicating that the nanomicelles loaded with this novel conjugated polymer could be further explored as a new type of theranostic agent and applied in the PTT of tumors.

Treatment with a VEGFR-2 antibody results in intra-tumor immune modulation and enhances anti-tumor efficacy of PD-L1 blockade in syngeneic murine tumor models.

Prolonged activation of vascular endothelial growth factor receptor-2 (VEGFR-2) due to mis-regulation of the VEGF pathway induces aberrant blood vessel expansion, which supports growth and survival of solid tumors. Therapeutic interventions that inhibit the VEGFR-2 pathway have therefore become a mainstay of cancer treatment. Non-clinical studies have recently revealed that blockade of angiogenesis can modulate the tumor microenvironment and enhance the efficacy of concurrent immune therapies. Ramucirumab is an FDA-approved anti-angiogenic antibody that inhibits VEGFR-2 and is currently being evaluated in clinical studies in combination with anti-programmed cell death (PD-1) axis checkpoint inhibitors (pembrolizumab, durvalumab, or sintilimab) across several cancer types. The purpose of this study is to establish a mechanistic basis for the enhanced activity observed in the combined blockade of VEGFR-2 and PD-1-axis pathways. Pre-clinical studies were conducted in murine tumor models known to be responsive to anti-PD-1 axis therapy, using monoclonal antibodies that block mouse VEGFR-2 and programmed death-ligand 1 (PD-L1). Combination therapy resulted in enhanced anti-tumor activity compared to anti-PD-L1 monotherapy. VEGFR-2 blockade at early timepoints post-anti-PD-L1 therapy resulted in a dose-dependent and transient enhanced infiltration of T cells, and establishment of immunological memory. VEGFR-2 blockade at later timepoints resulted in enhancement of anti-PD-L1-driven immune cell infiltration. VEGFR-2 and PD-L1 monotherapies induced both unique and overlapping patterns of immune gene expression, and combination therapy resulted in an enhanced immune activation signature. Collectively, these results provide new and actionable insights into the mechanisms by which concurrent VEGFR-2 and PD-L1 antibody therapy leads to enhanced anti-tumor efficacy.

Avian Paramyxovirus 4 Antitumor Activity Leads to Complete Remissions and Long-term Protective Memory in Preclinical Melanoma and Colon Carcinoma Models.

Avulaviruses represent a diverse subfamily of non-segmented negative strand RNA viruses infecting avian species worldwide. To date, 22 different serotypes have been identified in a variety of avian hosts, including wild and domestic birds. APMV-1, also known as Newcastle disease virus (NDV), is the only avulavirus that has been extensively characterized due to its relevance for the poultry industry and, more recently, its inherent oncolytic activity and potential as a cancer therapeutic. An array of both naturally-occurring and recombinant APMV-1 strains has been tested in different preclinical models and clinical trials, highlighting NDV as a promising viral agent for human cancer therapy. To date, the oncolytic potential of other closely related avulaviruses remains unknown. Here, we have examined the in vivo anti-tumor capability of prototype strains of APMV serotypes -2, -3, -4, -6, -7, -8 and -9 in syngeneic murine colon carcinoma and melanoma tumor models. Our studies have identified APMV-4 Duck/Hong Kong/D3/1975 virus as a novel oncolytic agent with greater therapeutic potential than one of the NDV clinical candidate strains, La Sota. Intratumoral administration of the naturally-occurring APMV-4 virus significantly extends survival, promotes complete remission, and confers protection against re-challenge in both murine colon carcinoma and melanoma tumor models. Furthermore, we have designed a plasmid rescue strategy that allows us to develop recombinant APMV-4-based viruses. The infectious clone rAPMV-4 preserves the extraordinary antitumor capacity of its natural counterpart, paving the way to a promising next generation of viral therapeutics.

Lomitapide, a cholesterol-lowering drug, is an anticancer agent that induces autophagic cell death via inhibiting mTOR

Autophagy is a biological process that maintains cellular homeostasis and regulates the internal cellular environment. Hyperactivating autophagy to trigger cell death has been a suggested therapeutic strategy for cancer treatment. Mechanistic target of rapamycin (mTOR) is a crucial protein kinase that regulates autophagy; therefore, using a structure-based virtual screen analysis, we identified lomitapide, a cholesterol-lowering drug, as a potential mTOR complex 1 (mTORC1) inhibitor. Our results showed that lomitapide directly inhibits mTORC1 in vitro and induces autophagy-dependent cancer cell death by decreasing mTOR signaling, thereby inhibiting the downstream events associated with increased LC3 conversion in various cancer cells (e.g., HCT116 colorectal cancer cells) and tumor xenografts. Lomitapide also significantly suppresses the growth and viability along with elevated autophagy in patient-derived colorectal cancer organoids. Furthermore, a combination of lomitapide and immune checkpoint blocking antibodies synergistically inhibits tumor growth in murine MC38 or B16-F10 preclinical syngeneic tumor models. These results elucidate the direct, tumor-relevant immune-potentiating benefits of mTORC1 inhibition by lomitapide, which complement the current immune checkpoint blockade. This study highlights the potential repurposing of lomitapide as a new therapeutic option for cancer treatment.

Abstract 4234: ONM-501: A polyvalent STING agonist for oncology immunotherapy

Abstract Background: The stimulator of interferon genes (STING) plays a central role in innate immune response against infection and cancer. Several cyclic di-nucleotide (CDN) and non-CDN small molecule STING agonists have demonstrated effectiveness against cancer in preclinical animal models, however their clinical trials showed limited therapeutic efficacy. ONM-501, a dual-activating STING agonist employs PC7A, a synthetic polymer that induces polyvalent STING condensation and prolongs innate immune activation has been recently developed. ONM-501 encapsulates the endogenous STING agonist cGAMP with the PC7A micelles offering dual ‘burst’ and ‘sustained’ STING activation. The mechanism and effectiveness of intratumorally delivered ONM-501 as an immunotherapy against solid tumors has been demonstrated in preclinical models. Methods: ONM-501 was recently evaluated for STING activation across different species: STING related IFNB1 and CXCL10 gene expression after ONM-501 treatment was measured by RT-qPCR in PBMCs from rat, cynomolgus monkey, and human. ONM-501 antitumor efficacy was evaluated in murine syngeneic tumor models. Abscopal effect was demonstrated by studying antitumor efficacy using both a primary/distal model and a lung metastatic model. STING knockout mice and STING knockout cancer cells were used to clarify the dependence of STING status to the ONM-501 antitumor immunity. Immune cell dependence was further elucidated by depletion of specific immune cell populations. Pilot safety studies including major organ function and systemic cytokine levels were performed in immunocompetent mice. Results: STING activation was observed across different species by measuring IFNB1 and CXCL10 mRNA in PBMCs from rat, cynomolgus monkey, and human after ONM-501 treatment. Antitumor efficacy was demonstrated both as a monotherapy and in combination with anti-PD1 in six different syngeneic tumor models. ONM-501 also induced an abscopal effect - tumor inhibition was observed in both primary and distal MC38 tumors in the same animal. Reduction of lung metastasis in an immune “cold” triple negative orthotopic breast cancer 4T1 model further confirmed the systemic antitumor immunity. Knocking out host STING (i.e. STING KO mice) rather than cancer cell STING KO resulted in abrogation of tumor inhibition suggesting that the host STING status is responsible for ONM-501-mediated anti-tumor immunity. Immune cell depletion studies further clarified that the antitumor immunity is dependent on CD8+ T cell and dendritic cells (DCs). No alteration of main organ function or systemic cytokine storm were observed in the pilot safety study. Conclusions: ONM-501 demonstrated marked anti-tumor efficacy in a panel of syngeneic tumor models. The anti-tumor effect was mediated by host STING and dependent on CD8+ T cells and DCs. These results support further evaluation of ONM-501 as a clinical candidate for the potential treatment of solid tumors. Citation Format: Suxin Li, Jian Wang, Jonathan Wilhelm, Qingtai Su, Gaurav Bharadwaj, Jason Miller, Wei Li, Katy Torres, Ruolan Han, Tian Zhao, Jinming Gao. ONM-501: A polyvalent STING agonist for oncology immunotherapy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 4234.

Abstract 2055: WTX-330 is a conditionally activated IL-12 prodrug that fundamentally reprograms tumor infiltrating CD8+ T cells and drives tumor regression

Abstract Immune checkpoint inhibition (ICI) has established immunotherapy as the first line of treatment in a subset of cancers. However, there are still many patients and cancer types where ICI is not effective, representing a significant unmet clinical need for novel immunotherapies to expand the clinical options for patients. Interleukin 12 (IL-12) is a pleiotropic cytokine that drives naïve T cells towards a TH1 phenotype, activates NK cells and cytotoxic T cells, and strongly induces the expression of IFNγ by multiple cell types, making it an attractive pro-inflammatory cytokine for cancer immunotherapy. However, despite its demonstrated clinical benefits, poor pharmacokinetic properties and dose-limiting toxicities after systemic administration have greatly limited the use of IL-12 in the clinic. WTX-330 is a novel IL-12 pro-drug that is designed to harness the dysregulated protease activity of tumors to selectively deliver fully active IL-12 to the tumor microenvironment (TME). WTX-330 consists of wild-type IL-12 tethered to a high affinity antibody blockade domain and a half-life extension (HLE) domain via tumor protease-sensitive linkers. Following systemic administration, WTX-330 circulates as an inactive prodrug that is unable to bind to IL-12 receptors in normal tissues. When WTX-330 enters the tumor however, proteases found in the TME cleave the protease-sensitive linkers, releasing fully active IL-12 selectively in the tumor. WTX-330 is highly efficacious in murine syngeneic tumor models, leading to complete, CD8+ T cell dependent tumor regressions when MC38 tumor bearing mice were treated with a murine surrogate of WTX-330. Importantly, while murine WTX-330 was well tolerated by the mice, equimolar amounts of wild-type IL-12 was not, highlighting the tumor selective activity of the INDUKINE™ protein. Murine WTX-330 treatment of either MC38 or EMT6 tumor bearing mice increased the frequency of tumor infiltrating polyfunctional CD8+ T cells and activated tumor infiltrating NK cells in both models. In the EMT6 model, Geospatial NanoString analysis revealed significantly more tumor penetration by CD8+ T cells following murine WTX-330 treatment at multiple timepoints and demonstrated that systemic dosing with the IL-12 INDUKINE™ molecule resulted in IL-12 signaling by the tumor infiltrating CD8+ T cells. Furthermore, murine WTX-330 treatment fundamentally reprogrammed the metabolic program of tumor infiltrating CD8+ T cells, increasing both glycolysis and mitochondrial biogenesis, while also increasing TCR signaling and degranulation. Finally, ex vivo incubation of WTX-330 with various primary human tumors led to the release of active IL-12, while WTX-330 was stable in human serum and healthy human primary cells from various tissues. Together, these data support continued development of this innovative IL-12 therapy into clinical testing. Citation Format: Christopher J. Nirschl, Pam Alderhold, Heather R. Brodkin, Connor J. Dwyer, Daniel J. Hicklin, Nesreen Ismail, Andres Salmeron, Cynthia Seidel-Dugan, Philipp Steiner, Zoe Steuert, Jenna Sullivan, William M. Winston. WTX-330 is a conditionally activated IL-12 prodrug that fundamentally reprograms tumor infiltrating CD8+ T cells and drives tumor regression [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2055.

Abstract 6218: Oncolytic Seneca Valley virus (SVV-001) overcomes checkpoint inhibitor resistance and demonstrates a systemic anti-tumor immune response in a syngeneic pancreatic cancer murine model

Abstract Here we evaluated the efficacy of Seneca Valley Virus (SVV), an oncolytic virus in the Picornaviridae family, in combination with checkpoint inhibitors (CPI) using the CPI-resistant murine syngeneic pancreatic tumor model Pan02. SVV, serendipitously identified in 2001, is an extremely tumor selective and potent oncolytic virus for a variety of solid human cancers, primarily due to the expression of the receptor of SVV, TEM8, being selectively expressed on the surface of malignant cancer cells and cancer stem cells within a variety of solid tumors. SVV has been tested in three clinical trials of patients having neuroendocrine neoplasms as a single intravenous dose monotherapy. Despite this, the results were encouraging with patients having evidence of clinical benefit and only one DLT was reported in the 76 patients treated. Recent data have demonstrated that some oncolytic viruses can enhance efficacy in preclinical models and in clinical trials when the oncolytic virus was injected intratumorally in combination with systemic administration of a CPI(s). The mechanism is primarily believed to be due to the oncolytic virus enhancing T cell infiltration and fostering an anti-tumor immune response. SVV was injected intra-tumorally in Pan02 tumors along with aPD1and/or aCTLA4. SVV reversed any resistance to CPIs and enhanced efficacy over CPI(s) alone resulting in complete cures in >83% of mice with primary and abscopal tumors. SVV plus aPD1+aCTLA4 resulted in 5 of 6 mice cured of their primary tumor. The animals were challenged on their contralateral flank with Pan02 to evaluate systemic and abscopal immune effects. All mice (5/5) that cleared the primary Pan02 tumor also eradicated the abscopal secondary tumors. Control treated Pan02 tumor-bearing mice were all sacrificed due to tumor burden by day 70 (median survival <50 days). Control animals treated with aPD1+aCTLA4 showed transient tumor regressions but these animals all grew large tumors, requiring sacrifice. In contrast, the SVV+aPD1+aCTLA4 primary tumors were eliminated within 44 days and these animals remain tumor-free out to >110+ days. Contralateral tumors were eradicated in all 5 animals that rejected the primary tumor, demonstrating potent systemic immunity. In the control aPD1+aCTLA4 group, only one animal with contralateral tumor showed prolonged tumor regression. SVV treatment caused increases in T-cell infiltration; the combination of SVV+aPD1+aCTLA4 showing the highest infiltration. Phenotypic and gene expression analyses of infiltrating cells will be presented. These studies serve as a foundation for translating SVV oncolytic virotherapy combined with anti-PD-1 and anti-CTLA4 antibodies in patients with neuroendocrine neoplasms with a clinical trial anticipated to begin in H1, 2021. Citation Format: Paul L. Hallenbeck, Sunil Chada. Oncolytic Seneca Valley virus (SVV-001) overcomes checkpoint inhibitor resistance and demonstrates a systemic anti-tumor immune response in a syngeneic pancreatic cancer murine model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 6218.

Abstract 4182: Intratumoral treatment with VAX014 facilitates in situ immunization leading to systemic antitumor responses that enhance systemic immune checkpoint blockade

Abstract Intratumorally (i.t.) delivered immunotherapies stimulate in situ immunization by promoting local tumor inflammation, immune cell recruitment, and the generation of systemic antitumor lymphocytic responses. Clinical studies indicate combining i.t. immunotherapy with systemic immune checkpoint blockade (ICB) enhances durable complete response rates (CRR) in treated and distal untreated tumors (abscopal effect), although the number of i.t. therapies tested in this setting remains is limited. The purpose of this study was to evaluate and characterize the immunotherapeutic activity of VAX014, a novel clinical-stage bacterial minicell-based oncolytic agent, following i.t. delivery in two syngeneic murine solid tumor models. The nonimmunogenic B16F10 melanoma and immunogenic MB49 urothelial carcinoma models were used to establish single agent activity of VAX014 in mice bearing a single intradermal (i.d.) tumor, followed by an evaluation of synergy between VAX014 and ICB combinations (CTLA-4 ± PD-1) in mice bearing dual bilateral i.d. B16F10 tumors where only one tumor is treated with VAX014.Weekly i.t. treatment with VAX014 led to significant CD8+ T cell mediated antitumor activity in single i.d. tumor models. A significant reduction in tumor growth rate was observed in all mice (p< 0.0001, 38/38 for B16F10; p< 0.0001, 12/12 for MB49) which ultimately resulted in a durable CRR in 58.0% and 100% in the B16F10 and MB49 models, respectively. B16F10 tumors actively responding to i.t. treatment with VAX014 had a significant increase in CD8+ T cells (p= 0.0004) with a concomitant decrease in CD11b+ myeloid cells (p= 0.039) even after a single i.t. dose of VAX014. VAX014-mediated antitumor activity was specific to the treated tumor type as determined by cytotoxic T lymphocyte assay against the treated tumor cell line versus haplotype matched control target cells (p= 0.0015). Using a bilateral variation of each model, VAX014 exhibited a significant abscopal effect in the immunogenic MB49 model (22.0% CRR and ↓ tumor growth rate in untreated tumors, p= 0.009), an effect that was less pronounced in the nonimmunogenic B16F10 model. Addition of systemic CTLA-4 ICB significantly enhanced abscopal activity in the bilateral B16F10 model whereas PD-1 ICB did not. Remarkably, tripartite combination of VAX014 with CTLA-4/PD-1 ICB resulted in a significant reduction in treated (p< 0.0001) and distal untreated B16F10 tumors (p< 0.0012) as well as an enhanced survival advantage versus CTLA-4/PD-1 ICB combination (p= 0.03). Survival was associated with an improved CRR of both tumors (50.0% vs. 20.0%).In conclusion, these preclinical data provide scientific rationale and set the foundation for i.t. treatment with VAX014 in patients with injectable tumors refractory to standard treatment options and may be particularly effective when combined with systemic ICB. Citation Format: Shingo Tsuji, Katherine A. Reil, Kinsey L. Nelson, Kathleen L. McGuire, Matthew J. Giacalone. Intratumoral treatment with VAX014 facilitates in situ immunization leading to systemic antitumor responses that enhance systemic immune checkpoint blockade [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 4182.