Overall Survival Of Mice Research Articles

GNG2 inhibits brain metastases from colorectal cancer via PI3K/AKT/mTOR signaling pathway

G-protein gamma subunit 2 (GNG2) plays a vital role in various cellular processes, yet its specific function in colorectal cancer (CRC), particularly in highly invasive cases and brain metastasis, remains unclear. This study identifies GNG2 as a key regulator in metastatic colorectal cancer (mCRC) through bioinformatics analysis and experimental validation. Functional enrichment analyses reveal that GNG2 is related to the PI3K/AKT/mTOR signaling pathway and cell cycle regulation. These findings were further confirmed by in vitro and in vivo experiments. The overexpression of GNG2 significantly induced G0/G1 arrest and further inhibited the PI3K/AKT/mTOR axis in CRC cell lines, including suppressed proliferation, migration, and invasion and metastasis ability. In vivo studies using an orthotopic xenograft model demonstrated that GNG2 overexpression reduced brain metastasis and extended overall survival in mice. Immunohistochemistry and multiplex immunofluorescence confirmed the association between GNG2 overexpression, the PI3K/AKT/mTOR signaling pathway, and G0/G1 arrest. Our study suggests that GNG2 contributes to tumor suppression in CRC, particularly in preventing brain metastasis, and could serve as a promising biomarker and treatment target for mCRC, offering fresh insights into the molecular processes driving cancer progression and metastasis.

ENPP1 induces blood-brain barrier dysfunction and promotes brain metastasis formation in human epidermal growth factor receptor 2-positive breast cancer.

Brain metastasis (BrM) is a devastating end-stage neurological complication that occurs in up to 50% of human epidermal growth factor receptor 2-positive (HER2+) breast cancer (BC) patients. Understanding how disseminating tumor cells manage to cross the blood-brain barrier (BBB) is essential for developing effective preventive strategies. We identified the ecto-nucleotidase ENPP1 (ectonucleotide pyrophosphatase/phosphodiesterase 1) as specifically enriched in the secretome of HER2+ brain metastatic cells, prompting us to explore its impact on BBB dysfunction and BrM formation. We used in vitro BBB and in vivo premetastatic mouse models to evaluate the effect of tumor-secreted ENPP1 on brain vascular permeability. BBB integrity was analyzed by real-time fluorescence imaging of 20 kDa Cy7.5-dextran extravasation and immunofluorescence staining of adherens and tight junction proteins. Pro-metastatic effects of ENPP1 were evaluated in an experimental brain metastatic model. Systemically secreted ENPP1 from primary breast tumors impaired the integrity of BBB with loss of tight and adherens junction proteins early before the onset of BrM. Mechanistically, ENPP1 induced endothelial cell dysfunction by impairing insulin signaling and its downstream AKT/GSK3β/β-catenin pathway. Genetic ablation of ENPP1 from HER2+ brain metastatic cells prevented endothelial cell dysfunction and reduced metastatic burden while prolonging the overall and metastasis-free survival of mice. Furthermore, plasmatic ENPP1 levels correlate with brain metastatic burden and inversely with overall survival. We demonstrated that metastatic BC cells exploit the ENPP1 signaling for cell transmigration across the BBB and brain colonization. Our data implicate ENPP1 as a potential biomarker for poor prognosis and early detection of BrM in HER2+ BC.

Efficient gene delivery admitted by small metabolites specifically targeting astrocytes in the mouse brain.

The development of efficient and targeted methods for delivering DNA invivo has long been a major focus of research. In this study, we introduce a gene delivery approach admitted by small metabolites (gDAM) for the efficient and targeted delivery of naked DNA into astrocytes in the adult brains of mice. gDAM uses a straightforward combination of DNA and small metabolites, including glycine, L-proline, L-serine, L-histidine, D-alanine, Gly-Gly, and Gly-Gly-Gly, to achieve astrocyte-specific delivery of naked DNA, resulting in transient and robust gene expression in these cells. Using gDAM, we successfully co-deliver the PiggyBac transposon and the CRISPR-Cas9 system to induce long-term overexpression of the oncogene EGFRvIII and knockout of tumor suppressor genes Nf1, Pten, and Trp53 in astrocytes, leading to the development of astrocyte-derived gliomas in immunocompetent mice. Furthermore, gDAM facilitates the delivery of naked DNA to peripheral glioma astrocytes. The overexpression of interferon-β and granulocyte-macrophage colony-stimulating factor in these peripheral glioma astrocytes significantly prolongs the overall survival of mice bearing 73C glioma cells. This approach offers a new perspective on developing gene delivery systems that specifically target astrocytes to meet the varied needs of both research and gene therapy. The innovative strategy behind gDAM is expected to provide fresh inspiration in the quest for DNA delivery to other tissues, such as skeletal muscle and skin.

Tumor-derived CCL2 drives tumor growth and immunosuppression in IDH1- mutant cholangiocarcinoma.

Isocitrate dehydrogenase 1 ( IDH1 )-mutant cholangiocarcinoma (CCA) is a highly lethal subtype of hepatobiliary cancer that is often resistant to immune checkpoint inhibitor therapies. We evaluated the effects of IDH1 mutations in CCA cells on the tumor immune microenvironment and identified opportunities for therapeutic intervention. Analysis of 2606 human CCA tumors using deconvolution of RNA-sequencing data identified decreased CD8+ T cell and increased M2-like tumor-associated macrophage (TAM) infiltration in IDH1 -mutant compared to IDH1 wild-type tumors. To model the tumor immune microenvironment of IDH1 -mutant CCA in vivo, we generated an isogenic cell line panel of mouse SB1 CCA cells containing a heterozygous IDH1 R132C (SB1 mIDH1 ) or control (SB1 WT ) mutation using CRISPR-mediated homology-directed repair. SB1 mIDH1 cells recapitulated features of human IDH1 -mutant CCA including D-2-hydroxyglutarate production and increased M2-like TAM infiltration. SB1 mIDH1 cells and tumors produced increased levels of CCL2, a chemokine involved in the recruitment and polarization of M2-like TAMs, compared to wild-type controls. In vivo neutralization of CCL2 led to decreased M2-like TAM infiltration, reduced tumor size, and improved overall survival in mice harboring SB1 mIDH1 tumors. IDH1- mutant CCA is characterized by an increased abundance of M2-like TAMs. Targeting CCL2 remodels the tumor immune microenvironment and improves outcomes in preclinical models of IDH1 -mutant CCA, highlighting the role of myeloid-targeted immunotherapies in the treatment of this cancer.

High iASPP (PPP1R13L) expression is an independent predictor of adverse clinical outcome in acute myeloid leukemia (AML)

Apoptosis-stimulating proteins of p53 (ASPPs) are a family of proteins that modulate key tumor suppressor pathways via direct interaction with p53. Deregulation of these proteins promotes cancer development and impairs sensitivity to systemic (chemo)therapy and radiation. In this study, we describe that the inhibitor of ASPP (iASPP) is frequently highly expressed in acute myeloid leukemia (AML) and that overexpression correlates with a poor clinical outcome. Four independent patient cohorts comprising about 1500 patient samples were analysed and consistently confirm an association of high iASPP expression with unfavourable clinical characteristics and shorter survival. Notably, the predictive role of iASPP is independent of, and adds information to, the European LeukemiaNET (ELN) risk classification. iASPP-interference cell models were developed to investigate the underlying functional aspects of iASPP in AML biology. Attenuation of iASPP expression resulted in reduced proliferation rates of leukemic blasts and rendered cells more susceptible towards induction of apoptosis in response to cytotoxic therapy. In line, independent NSG xenograft mouse experiments demonstrate that attenuation of iASPP results in a significant delay of disease onset and tumor burden and this translates to longer overall survival of mice. In conclusion, deregulation of iASPP has direct functional consequences in AML. Determination of iASPP expression levels provides valuable additional information as a predictive marker in AML and may guide treatment decisions.

Tumor-Specific Protein Induced in Situ Self-Assembly of Peptide Drugs for Synergistic Mitochondria Disruption.

Mitochondria-targeted cancer therapy is an effective method for controlling tumor growth. However, the presence of repair mechanisms in tumor cells in response to mitochondrial damage poses significant challenges for treatment. By taking advantage of intracellular self-assembly technology, a peptide nanomaterial, RC-K-FX, that enters tumor cells in a monomeric form is designed. After binding to MUC1-C inside the cell membrane, RC-K-FX assembles into a spherical structure that stably encapsulates MUC1-C, inhibiting its dimerization and blocking the repair of stress-induced mitochondrial damage in tumor cells. Moreover, the self-assembled mitochondrial toxic peptide effectively destroys the mitochondria, and the loss of mitochondrial repair significantly increases tumor cytotoxicity by disrupting the redox balance, enhancing reactive oxygen species (ROS), inhibiting the nuclear factor (NF)-κB pathway, and suppressing the epithelial-mesenchymal transition (EMT) process. After intravenous administration, RC-G-FX accumulated at the tumor site, exhibiting improved anti-tumor effects and extending the overall survival of tumor-bearing mice. Therefore, the integration of the in situ self-assembly of peptide drugs and damage to mitochondrial repair mechanisms provides effective therapeutic options for malignancy.

Dendrimer‐Cu(II) Complexes Mediate Enzyme Delivery for Lactate Depletion‐Enhanced Combinational Treatment of Leukemia and Glioma

AbstractCancer cells engage in active aerobic glycolysis to meet their bioenergetic synthesis needs, which is known as the Warburg effect. Such a process leads to lactate accumulation in the tumor microenvironment (TME), further promoting cancer progression and inducing immunosuppression. Herein, functionalized dendrimer‐Cu(II) complexes (for short, D‐Cu(II)) as a nanocarrier, which enables a Fenton‐like reaction is developed to generate a large amount of hydroxyl radicals and shows a T1‐weighted magnetic resonance (MR) imaging performance. Importantly, the D‐Cu(II) allows efficient delivery of lactate oxidase (LOx) to cancer cells, directly downregulating the lactate levels. When combining with an immune activator of leukadherin‐1, the developed D‐Cu(II)/LOx complexes alleviate the symptoms of mouse leukemia. With a further coating of macrophage membranes, the generated D‐Cu(II)/LOx@M allows for effective blood‐brain barrier crossing to treat an orthotopic murine glioma model under the guidance of Cu(II)‐facilitated MR imaging. By integrating the LOx‐mediated lactate depletion with Cu(II)‐mediated chemodynamic therapy, the developed dendrimer nanomedicines improve the overall survival and antitumor immune responses of mice, and help to remodel the immunosuppressive TME in both cancer models, greatly sensitizing the treatment efficacy of immune activator. Such dendrimer technology may further be used for theranostics of other cancer types through lactate depletion‐enhanced combinational therapy.

Pretargeted alpha therapy in MUC16-positive high-grade serous ovarian cancer

BackgroundPeritoneal metastasis with micrometastatic cell clusters is a common feature of advanced ovarian cancer. Targeted alpha therapy (TAT) is an attractive approach for treating micrometastatic diseases as alpha particles release enormous amounts of energy within a short distance. A pretargeting approach — leveraging the inverse-electron-demand Diels-Alder reaction between tetrazines (Tz) and trans-cyclooctene (TCO) — can minimize off-target toxicity related to TAT, often associated with full-length antibodies. We hypothesized that a pretargeting strategy could effectively treat high-grade serous (HGS) ovarian tumors while minimizing toxicity. MethodsWe utilized the humanized antibody, AR9.6, labeled with actinium-225 (225Ac). AR9.6 targets fully glycosylated and hypoglycosylated isoforms of MUC16. For biodistribution and radioimmunotherapy studies, AR9.6-TCO was injected into OVCAR3-bearing mice 72 h before administering [225Ac]Ac-mcp-PEG8-Tz, e.g. using a 1,2,4,5-tetrazine conjugated to the macropa chelator via a polyethylene glycol (PEG) linker. ResultsBiodistribution data revealed that the pretargeting approach achieved substantial tumor uptake. Cerenkov luminescence imaging confirmed successful in vivo pretargeting during TAT studies. Compared to the control groups, TAT with AR9.6-TCO and [225Ac]Ac-mcp-PEG8-Tz significantly suppressed tumor growth and improved overall survival in OVCAR3 tumor-bearing mice. Renal and ovarian pathology compatible with toxicity was observed in mice in addition to transient hematologic toxicity. ConclusionWe confirmed that pretargeting with AR9.6-TCO and [225Ac]Ac-mcp-PEG8-Tz has durable antitumor effects in high MUC16-expressing tumors. These findings demonstrate great potential for using pretargeting in combination with TAT for the treatment of ovarian cancer. ClassificationBiological Sciences; Applied Biological Sciences.

EXTH-79. BREAKING THE BARRIER: ADOPTIVE CELLULAR THERAPY HALTS GLIOMA IMMUNOSUPPRESSION BY TARGETING MYELOID-DERIVED SUPPRESSOR CELL MIGRATION AND CELL CYCLE MECHANISMS

Abstract INTRODUCTION Our group previously demonstrated that adoptive cellular therapy (ACT) significantly increased overall survival in mice across several brain cancer models. ACT remodels the tumor microenvironment (TME) in a pleiotropic manner, and specifically depletes immunosuppressive cells like myeloid-derived suppressor cells (MDSCs) which are a significant barrier to efficacious immunotherapy responses. This led us to hypothesize that ACT depletes MDSCs from the glioma microenvironment by inhibiting MDSC proliferation and migration, thereby overcoming glioma immunosuppression. METHODS We quantified MDSC cell cycle, apoptosis, and localization in the TME and peripheral lymphoid tissues using flow cytometry as well as chemokines in the TME from glioma-bearing mice treated with ACT. C57BL/6J mice intracranially received KR158b-luciferase glioma and were treated with ACT. After treatment, MDSC cell cycle was quantified using bromodeoxyuridine and 7-aminoactinomycin to define cell cycle phases. MDSC apoptosis and cell death states were quantified by measuring annexin-V and propidium iodide. Anatomic localization of MDSCs was measured by comparing host (CD45.2) and transferred HSC-derived cell markers (CD45.1) in the TME and spleen. A multiplex array was performed using tumor lysates to quantify cytokine and chemokine levels within the TME. RESULTS We observed that MDSCs in the TME were significantly less proliferative and exhibited significantly increased levels of apoptosis and cell death after ACT. HSC-derived MDSCs were significantly enriched in the spleen of ACT-treated mice, but both transferred HSC-derived MDSCs and host MDSCs were depleted in the TME. Finally, ACT significantly decreased several chemokines in the TME, including interleukin-16 and monocyte chemoattractant protein-5. CONCLUSION These results indicate that ACT shifts MDSC cell cycle states away from proliferation towards cell death, and inhibits peripheral recruitment to the TME. Our investigation revealed novel, myeloproliferative chemokines that are decreased by ACT, representing a novel mechanism underlying disrupted MDSC migration to the glioma microenvironment and ultimately to overcoming glioma-mediated immunosuppression.

CCRG-01. MYT1 BLOCKADE AS A NOVEL GLIOMA THERAPEUTICS THROUGH ABROGATIING OF THE G2/M CELL CYCLE CHECKPOINT

Abstract BACKGROUND The cell cycle is tightly regulated by checkpoints, which play a vital role in controlling its progression and timing. Cancer cells exploit the G2/M checkpoint, which serves as a resistance mechanism against genotoxic anticancer treatments, allowing for DNA repair prior to cell division. Manipulating cell cycle timing has emerged as a potential strategy to augment the effectiveness of DNA damage-based therapies. METHODS In this study, we conducted a forward genome-wide CRISPR/Cas9 screening with repeated exposure to the alkylating agent temozolomide (TMZ) to investigate the mechanisms underlying tumor cell survival under genotoxic stress. The screening hits were validated through in patient derived glioma cells and xenografts. RESULTS Our findings revealed that canonical DNA repair pathways, including the Ataxia–telangiectasia mutated (ATM)/Fanconi and mismatch repair, determine cell fate under genotoxic stress. Notably, we identified the critical role of PKMYT1, in ensuring cell survival. Depletion of PKMYT1 led to overwhelming TMZ-induced cytotoxicity in cancer cells. Isobologram analysis demonstrated potent drug synergy between alkylating agents and a Myt1 kinase inhibitor, RP-6306. Mechanistically, inhibiting Myt1 forced G2/M-arrested cells into an unscheduled transition to the mitotic phase without complete resolution of DNA damage. This forced entry into mitosis, along with persistent DNA damage, resulted in severe mitotic abnormalities. Ultimately, these aberrations led to mitotic exit with substantial apoptosis. Preclinical animal studies demonstrated that the combination regimen involving TMZ and RP-6306 prolonged the overall survival of glioma-bearing mice.

EXTH-21. WINNING THE TUG OF WAR BETWEEN VIRUS AND TUMOR IMMUNODOMINANCE IN GLIOMAS TREATED WITH ONCOLYTIC ADENOVIRUSES USING TOLEROGENIC STRATEGIES

Abstract Phase 1 and 2 clinical trials of our oncolytic adenovirus Delta-24-RGD for patients with recurrent malignant gliomas have demonstrated its safety and efficacy, and showed that 20% of the patients experienced long-term tumor remissions often associated with inflammatory responses and tumor infiltration of lymphocytes. Based on our preliminary data, we expected that the most frequent tumor-infiltrating CD8+ T cell clones will target adenoviral hexon, with a single virus-specific clone representing up to 5% of the total population. Competition between T cells for resources may limit the expansion of subdominant clones recognizing tumor antigens. We hypothesized that mitigating virus-specific immunity allows the expansion of tumor-specific T cells and results in better therapeutic efficacy. In mice, intravenously injected nanoparticles encapsulating adenoviral antigens preferentially accumulated in the liver (P<0.0001), where self-reactive immune cells are deleted through peripheral tolerance. RNA-sequencing of antigen-specific T cells isolated after nanoparticle injection revealed enriched expression of gene sets involved in immune tolerance through clonal deletion and T cell anergy, including increased expression of immune checkpoint molecules (P<0.001). In glioma-bearing mice treated with virotherapy in combination with nanoparticle administration, tumor infiltrating lymphocytes exhibited decreased IFNγ secretion against viral antigens and increased secretion against tumor antigens, suggesting a redirection of the immunity from anti-viral to anti-tumoral (P<0.05). Importantly, virotherapy with nanoparticles increased the overall survival of tumor-bearing mice compared to virus treatment alone (P<0.001). To further characterize the roles of virus- and tumor-specific immune cells during virotherapy we are analyzing the T cell receptor repertoire of surgical specimens from nine glioma patients treated with Delta-24-RGD in a phase 1 clinical trial. In summary, our data provide the basis for a future clinical trial using tolerogenic strategies to redirect immunodominance of the viral to the glioma antigens, and represent a novel strategy to enhance anti-tumor immunity during virotherapy of brain tumors.

CNSC-47. SENOLYTICS ERADICATE SENESCENT MICROGLIA IN THE BRAIN PARENCHYMA AND IMPROVE SURVIVAL IN OLDER ADULT MICE WITH GLIOBLASTOMA

Abstract BACKGROUND Glioblastoma (GBM) is the most common aggressive primary malignant brain tumor in adults with a poor median survival rate. Despite the aggressive standard of care treatment combining surgical resection, chemo-, and radio-therapy, the median overall survival (OS) is only ~15-18 months. Progressively increasing subject age is inversely associated with GBM patient OS such that older adults tend to have significantly worse survival outcomes compared to younger counterparts. Senescent cells accumulate in the body during progressive aging and contribute to worse outcomes in older adult mice with GBM. Senolytics are pharmacologics that cause senescent cells to undergo cell death. OBJECTIVE To comprehensively profile the treatment effect of senolytics combined with or without immunotherapy in mice with GBM across the lifespan. METHODS Young 7-9- and older adult 97-104-week-old wild-type (WT; C57BL/6) and 110-130-week-old INK-ATTAC mice with or without intracranial SB28 cells were treated with or without brain radiation (RT), PD-1 mAb, and an IDO enzyme inhibitor with the senolytics, dasatinib + quercetin, or the AP compound that induces p16INK4A+ senescent cell death in INK-ATTAC mice (n=5/group). The quantification of beta-galactosidase positive cells by flow cytometry was performed on brain-resident neurons, astrocytes, oligodendrocytes, microglia, as well as dendritic cells, macrophages, neutrophils, T cells in the tumor and non-tumor bulk mass. Overall survival was also evaluated. RESULTS Senolytics or AP compound treatment both decrease beta-galactosidase positive microglia in the older adult brain with GBM (p<0.05). Combining radio- and immuno-therapy with senolytics improves overall survival of older adult mice with intracranial GBM (p<0.05). CONCLUSIONS Our ongoing work aims to understand how senescent microglia affect neuronal health and function in the older adult brain with GBM. KEYWORDS Glioma, senescence, senolytic.

IMMU-44. EXTRINSIC ELECTRICAL MODULATION OF THE GLIOBLASTOMA TUMOR MICROENVIRONMENT

Abstract BACKGROUND Approximately 30 to 50% of patients with glioblastoma (GBM) present with glioma-related epilepsy (GRE). Despite morbidity associated with seizures, GRE constitutes an independent positive predictive predictor for survival in GBM. Our prior results showed that repeated seizure induction through extrinsic electrical modulation (EEM, a technique in which an electrical stimulus sufficient to produce a therapeutic seizure is applied) slows intracranial tumor growth and prolongs overall survival in immunocompetent CT-2A glioma-bearing mice. However, the overall survival advantage following EEM treatment was diminished in immunocompromised mice bearing human patient derived xenografts. We hypothesized that EEM induces immune-related tumor microenvironment (TME) changes that prolong survival in mice. METHODS C57BL/6J mice were orthotopically implanted with CT-2A xenografts and subjected to EEM of 2.0 millicoulombs or sham treatment. Quantitative reverse transcription polymerase chain reaction (RT-qPCR) was performed at 3 and 24 hours to determine mRNA level of inflammatory cytokines. Immunohistochemistry (IHC) and bulk RNA sequencing analysis were utilized to assess CD3+ T-cell infiltration and identify immune-related secreted genes, respectively. Flow cytometry at 3 and 96 hours was utilized to characterize tumor-infiltrating immune cell populations. Samples were subjected to Percoll gradient enrichment of immune cell populations and stained for extracellular (CD45, CD4, CD8, CD11b, F4/80, CD80, Ly6G, Ly6C, and CX3CR1) and intracellular (TNF-a, Il-1b, CCL2, and Arg1) antigens. RESULTS RT-qPCR showed an increase in pro-inflammatory cytokines TNF-α (P = 0.0087) and IL-1β (P = 0.000349). IHC analysis demonstrated an increase in intratumoral CD3+ T-cells in EEM-treated samples (P = 0.0171). From 1855 upregulated genes, 3 immune-related secreted genes (C1QTNF4, FAM19A4, and GREM2) were identified. Flow cytometric analysis showed a significant increase in CD11b+, CX3RC1+ microglia (P = 0.0306) and CD45+, CD11b+ tumor-associated myeloid cells (TAMCs) (P = 0.0192) at 3 hours post-EEM. CONCLUSIONS EEM treatment promotes an inflammatory TME with increased intratumoral microglia, TAMCs and T-cell infiltration. These inflammatory changes may prolong survival of CT-2A glioma-bearing mice.

Tumor-intrinsic PRMT5 upregulates FGL1 via methylating TCF12 to inhibit CD8+ T-cell-mediated antitumor immunity in liver cancer

Protein arginine methyltransferase 5 (PRMT5) acts as an oncogene in liver cancer, yet its roles and in-depth molecular mechanisms within the liver cancer immune microenvironment remain mostly undefined. Here, we demonstrated that disruption of tumor-intrinsic PRMT5 enhances CD8+ T-cell-mediated antitumor immunity both in vivo and in vitro. Further experiments verified that this effect is achieved through downregulation of the inhibitory immune checkpoint molecule, fibrinogen-like protein 1 (FGL1). Mechanistically, PRMT5 catalyzed symmetric dimethylation of transcription factor 12 (TCF12) at arginine 554 (R554), prompting the binding of TCF12 to FGL1 promoter region, which transcriptionally activated FGL1 in tumor cells. Methylation deficiency at TCF12-R554 residue downregulated FGL1 expression, which promoted CD8+ T-cell-mediated antitumor immunity. Notably, combining the PRMT5 methyltransferase inhibitor GSK591 with PD-L1 blockade efficiently inhibited liver cancer growth and improved overall survival in mice. Collectively, our findings reveal the immunosuppressive role and mechanism of PRMT5 in liver cancer and highlight that targeting PRMT5 could boost checkpoint immunotherapy efficacy.

Compound #41 Targets Acute Myelogenous Leukemia by Inhibiting the Wnt/β-catenin Signaling Pathway.

Aberrant activation of the Wnt/β-catenin signaling pathway contributes to the pathogenesis of acute myelogenous leukemia (AML). Thus, targeting this pathway offers a promising therapeutic strategy against AML. Here, we synthesized a novel dipeptide-type inhibitor of the Wnt/β-catenin signaling pathway, compound #41, and explored its anti-tumor effects on AML cells. We evaluated the inhibitory effect of compound #41 on T cell factor (TCF)/β-catenin transcriptional activity using a luciferase (Luc) reporter assay. The anti-tumor effects were assessed on KG1a and MV4;11 human AML cells using RT-qPCR, western blotting, and WST-8, cell cycle, and apoptosis assays. Differentially expressed genes were analyzed by RNA-sequencing (RNA-seq). Additionally, we investigated the in vivo effects of compound #41 using KG1a-Luc/GFP cells in an orthotopic mouse model. The Luc reporter assay showed that compound #41 decreased the TCF/β-catenin transcriptional activity. Compound #41 blocked the cell cycle progression, inhibited cell proliferation, and induced apoptosis in AML cells. Treatment with compound #41 down-regulated the expression of β-catenin, Survivin, and β-catenin-specific target genes, as demonstrated by RNA-seq. In vivo analysis showed that compound #41 blocked the expansion of KG1a-Luc/GFP cells in the bone marrow and prolonged the overall survival of KG1a-Luc/GFP-transplanted mice. Compound #41 suppressed the Wnt/β-catenin signaling pathway by reducing CTNNB1 levels and induced apoptosis in AML cells. Furthermore, compound #41 inhibited the proliferation of KG1a-Luc/GFP cells in the bone marrow and extended the overall survival of mice. Thus, compound #41 is an attractive Wnt/β-catenin signaling pathway inhibitor of AML.

Spleen-Targeted mRNA Vaccine Doped with Manganese Adjuvant for Robust Anticancer Immunity In Vivo.

The successful application of mRNA vaccines in preventing and treating infectious diseases highlights their potential as therapeutic vaccines for cancer treatment. However, unlike infectious diseases, effective antitumor therapy, particularly for solid tumors, necessitates the activation of more powerful cellular and humoral immunity to achieve clinical efficacy. Here, we report a spleen-targeted mRNA vaccine (Mn@mRNA-LNP) designed to deliver tumor antigen-encoding mRNA and manganese adjuvant (Mn2+) simultaneously to dendritic cells (DCs) in the spleen. This delivery system promotes DC maturation and surface antigen presentation and stimulates the production of cytotoxic T cells. Additionally, Mn2+ codelivered in the system serves as a safe and effective immune adjuvant, activating the stimulator of interferon genes (STING) signaling pathway and promoting the secretion of type I interferon, further enhancing the antigen-specific T cell responses. Mn@mRNA-LNP effectively inhibits tumor progression in established melanoma and colon tumor models as well as in a model of tumor recurrence after resection. Notably, the combination of Mn@mRNA-LNP with immune checkpoint inhibitors further enhances complete tumor suppression and prolonged the overall survival in mice. Overall, this "All-in-One" mRNA vaccine significantly boosts antitumor immunity responses by improving spleen targeting and immune activation, providing an attractive strategy for the future clinical translation of therapeutic mRNA vaccines.

Broad applicability of the Goldspire™ platform for the treatment of solid tumors

Goldspire™ is a personalized immunotherapy platform that combines whole tumor-derived cells with antisense oligonucleotide (IMV-001) against Insulin-Like Growth Factor-1 Receptor (IGF-1R) in biodiffusion chambers (BDCs; 0.1 μm pore). BDCs are exposed to 5–6 Gy and implanted at abdominal sites for ∼48 h to deliver an antigenic payload and immunostimulatory factors to train the immune system. Lead product IGV-001 was evaluated in newly diagnosed glioblastoma (ndGBM) patients in Phase 1a and 1b trials (NCT02507583). A Phase 2b study (NCT04485949) recently completed enrollment.Preventative treatment with tumor-specific products manufactured with Goldspire limited tumor progression and extended overall survival in mice challenged with bladder, pancreatic, ovarian, colorectal, or renal carcinomas. The benefit of this immunotherapy was enhanced with anti-PD-1; combination treatment was superior to either monotherapy in orthotopic GBM and melanoma models. Lastly, Goldspire elicited immune T cell activation and memory phenotypes against patient-derived endometrial tumor-derived products in co-cultures with matching immune cells.

Directed protein engineering identifies a human TIM-4 blocking antibody that enhances anti-tumor response to checkpoint inhibition in murine colon carcinoma.

T-cell immunoglobulin and mucin domain containing molecule-4 (TIM-4) is a scavenger receptor best known for its role in recognizing dying cells. TIM-4 orchestrates phagocytosis allowing for cellular clearance of apoptotic cells, termed efferocytosis. It was previously shown that TIM-4 directly interacts with AMPKα1, activating the autophagy pathway, leading to degradation of ingested tumors, and effectively reducing antigen presentation. This study sought to identify a novel human TIM-4 antibody that can prevent phagocytosis of tumor cells thereby allowing for more antigen presentation resulting in anti-tumor immunological response. Using phage display panning directed against human TIM-4, we engineered a novel human TIM-4 antibody (SKWX301). Combination of in vitro phagocytosis assays and cell viability assays were used to test functionality of SKWX301. To examine the effect of SKWX301 in mouse models, we employed a syngeneic mouse model. CT26 cells were subcutaneously injected into BALB/c mice and tumor growth and mouse survival were analyzed. SKWX301 can prevent human macrophage phagocytosis of cancer cells in vitro. Combination of low dose SKWX301 and anti-PD1 antibody significantly inhibited tumor growth and increased overall survival in mice. This demonstrates that SKWX301 is effective in both human in vitro models and mouse in vivo models. Our study has demonstrated a rapid antibody discovery approach and identified a novel human TIM-4 antibody that can serve as a therapeutic for antitumor immunity to improve cancer therapy.

Abstract B057: The circadian master regulator BMAL1 blocks immune cell recognition of pancreatic ductal adenocarcinomas via tumor-derived interleukin-1 receptor antagonist

Abstract Many tumor types, including pancreatic adenocarcinomas, have dysregulated circadian rhythms. Previous work in our lab has shown that disseminated dormant tumor cells have increased expression of Dec2, a circadian rhythm gene, and knocking out Dec2 leads to increased overall survival in our murine resectable PDAC model. To see whether the effect of Dec2 is due to a circadian effect, we deleted the master regulator circadian gene, BMAL1. Using CRISPR-generated knockout (KO) cell lines, we saw that loss of Bmal1 completely abrogated metastasis in immunocompetent mice, but not in immunocompromised mice indicating an immune mediated mechanism. Similarly in our murine resectable PDAC model, loss of BMAL1 led to an increase in overall survival in immunocompetent mice only. Looking at the tumor microenvironment, we saw an increase in CD4+ and CD8+ T cell infiltration in the tumors derived from the BMAL KO cells. We then evaluated the BMAL KO cells for their cytokine secretion and saw that loss of BMAL1 led to decreased interleukin-1 receptor antagonist both in vitro and in vivo. IL-Ra has been shown in literature to suppress the immunogenic anti-tumor response by impairing the activities of APCs, CD4+ and CD8+ T cells and disruption of IL-1Ra can reverse the TME towards more immunogenic leading to an antitumor effect. Taken together these studies implicate Bmal1 in regulating anti-tumor immunity in PDAC through its regulation of IL-1Ra secretion. This is a novel function for a circadian rhythm gene in PDAC biology. Citation Format: Orjola Prela, Lan Wang, Chris Harris, Darren Carpizo. The circadian master regulator BMAL1 blocks immune cell recognition of pancreatic ductal adenocarcinomas via tumor-derived interleukin-1 receptor antagonist [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr B057.

Intermittent fasting boosts antitumor immunity by restricting CD11b+Ly6ClowLy6Glow cell viability through glucose metabolism in murine breast tumor model

Intermittent fasting can benefit breast cancer patients undergoing chemotherapy or immunotherapy. However, it is still uncertain how to select immunotherapy drugs to combine with intermittent fasting. Herein we observed that two cycles of fasting treatment significantly inhibited breast tumor growth and lung tissue metastasis, as well as prolonged overall survival in mice bearing 4T1 and 4T07 breast cancer. During this process, both the immunosuppressive monocytic- (M-) and granulocytic- (G-) myeloid-derived suppressor cell (MDSC) decreased, accompanied by an increase in interleukin (IL) 7R+ and granzyme B+ T cells in the tumor microenvironment. Interestingly, we observed that Ly6Glow G-MDSC sharply decreased after fasting treatment, and the cell surface markers and protein mass spectrometry data showed potential therapeutic targets. Mechanistic investigation revealed that glucose metabolism restriction suppressed the splenic granulocyte-monocyte progenitor and the generation of colony-stimulating factors and IL-6, which both contributed to the accumulation of G-MDSC. On the other hand, glucose metabolism restriction can directly induce the apoptosis of Ly6Glow G-MDSC, but not Ly6Ghigh subsets. In summary, these results suggest that glucose metabolism restriction induced by fasting treatment attenuates the immune-suppressive milieu and enhances the activation of CD3+ T cells, providing potential solutions for enhancing immune-based cancer interventions.