Enhanced Tumor Growth Research Articles

TMIC-18. ROLE OF NEUROTRANSMITTERS IN GLIOBLASTOMA PATHOPHYSIOLOGY: EMERGING INSIGHTS

Abstract INTRODUCTION Glioblastoma (GBM) are the most common primary brain tumor in adults associated with a dismal patient outcome. While it is well-known that glutamatergic neurons can form functional synapses with glioblastoma cells to enhance tumor growth, lesser is known about the effects of activity of other neuronal types on glioblastoma biology, especially among different glioblastoma molecular subtypes. Here, we examined the effects of various neurotransmitters on the growth of glioblastoma cells characterized as classical, proneural and mesenchymal subtypes. METHODS Patient-derived glioblastoma cell lines were exposed to varying concentrations of different neurotransmitters and assessed for cell viability using CCK-8 assay. Transcriptomic data from TCGA (The Cancer Genome Atlas) database was analyzed for correlation of expression of neurotransmitter receptors (NTRs) with patient survival. Using IVY-GAP database, we compared the expression of NTRs at leading-edge versus tumor core of tumors to assess their possible involvement in cell migration and microenvironmental interactions. RESULTS Consistent with previous findings, we observed an increase in cell viability in all GBM cell lines after being incubated with L-glutamate. The classical subtype has a stronger growth response to L-glutamate compared to the other two subtypes. TCGA data revealed the expression of GRIK4 (glutamate ionotropic receptor kainate type subunit 4) as highest in the classical subtype as well as inversely correlated with worse patient survival in this GBM subtype, as opposed to proneural or mesenchymal patient groups. CCK8 assay also suggested that acetylcholine and dopamine increase glioblastoma cell growth. A subset of cholinergic and glutamatergic receptors (CHRM1, GRM2) was found upregulated in infiltrating/leading-edge regions of glioblastoma tumors compared to the tumor core, suggesting possible involvement in glioblastoma-neuron interactions. CONCLUSION Our findings suggest that GBM subtypes may differentially leverage neuro-modulatory mechanisms to support their growth. Future studies will investigate the differential neuronal responses in GBM subtypes using pharmacological/genetic approaches.

The role of mesenchymal cells in cholangiocarcinoma.

The tumour microenvironment (TME) significantly influences tumour formation and progression through dynamic interactions. Cholangiocarcinoma (CCA), a highly desmoplastic tumour, lacks early diagnostic biomarkers and has limited effective treatments due to an incomplete understanding of its molecular pathogenesis. Investigating the TME's role in CCA progression could lead to better therapies. RNA sequencing was performed on seven CCA PDXs and their corresponding patient samples. Differential expression analysis was conducted, and Qiagen Ingenuity Pathway Analysis (IPA) was used to predict dysregulated pathways and upstream regulators. PDX and cell line-derived spheroids, with and without immortalised mesenchymal stem cells, were grown and analysed for morphology, growth, and viability. Histological analysis confirmed biliary phenotypes. RNA sequencing indicated upregulation of ECM-receptor interaction and PI3K-Akt pathways in the presence of MSCs, with several genes linked to poor survival. MSCs restored the activity of inhibited cancer-associated kinases (ICAKs). This study shows that adding MSCs to CCA spheroid models restores key paracrine signalling pathways lost in PDXs, enhancing tumour growth and viability. These findings highlight the importance of including stromal components in cancer models to improve pre-clinical studies.

Nuclear imaging of PD-L1 expression promotes the synergistic antitumor efficacy of targeted radionuclide therapy and immune checkpoint blockade.

In order to maximize synergistic effect of targeted radionuclide therapy (TRT) and immune checkpoint blockade (ICB) as well as reduce the toxicity, we pioneered a strategy guided by PD-L1-targeted nuclear medicine imaging for the combination of TRT and ICB towards precision cancer therapy. As a novel targeted radiotherapeutic agent, 177Lu-AB-3PRGD2 targeting integrin αvβ3 was developed to achieve sustained antitumor effect by introducing an albumin binder (AB) into the structure of 3PRGD2. The 177Lu-AB-3PRGD2 TRT as well as different types of combination therapies of 177Lu-AB-3PRGD2 TRT and anti-PD-L1 ICB were performed in animal models. The changes of PD-L1 expression in tumors after TRT were evaluated in vitro and in vivo by PD-L1-specific SPECT/CT imaging of 99mTc-MY1523. 177Lu-AB-3PRGD2 showed improved tumor uptake and prolonged tumor retention, leading to significantly enhanced tumor growth suppression. Moreover, 177Lu-AB-3PRGD2 TRT remodeled the tumor immune microenvironment by upregulating PD-L1 expression and increasing tumor-infiltrating CD8+ T cells, facilitating immunotherapy. We found that the anti-PD-L1 treatment was more effective during the upregulation of tumor PD-L1 expression, and the time window could be determined by 99mTc-MY1523 SPECT/CT. We developed a novel and long-acting radiotherapeutic agent 177Lu-AB-3PRGD2, and pioneered a strategy guided by PD-L1-targeted nuclear medicine imaging for the combination of TRT and ICB towards precision cancer therapy, optimizing the therapeutic efficacy and reducing the cost and potential toxicity risks. This strategy could also be adapted for clinical practice, combining conventional radiotherapy or chemotherapy with ICB to enhance therapeutic efficacy.

Analysis of SLC genes alternative splicing identifies the SLC7A6 RI isoform as a therapeutic target for colorectal cancer.

Alternative splicing (AS), a crucial mechanism in post-transcriptional regulation, has been implicated in diverse cancer processes. Several splicing variants of solute carrier (SLC) transporters reportedly play pivotal roles in tumorigenesis and tumor development. However, an in-depth analysis of AS landscapes of SLCs in colon adenocarcinoma (COAD) is lacking. Herein, we analyzed data from The Cancer Genome Atlas and identified 1215 AS events across 243 SLC genes, including 109 differentially expressed AS (DEAS) events involving 62 SLC genes in COAD. Differentially spliced SLCs were enriched in biological processes, including transmembrane transporter activity, transporter activity, ferroptosis, and choline metabolism. In patients with COAD, tumor tissues exhibited higher expression of longer mitochondrial carrier SLC25A16 isoforms than adjacent normal tissues, consistent with bioinformatics analysis. Protein-coding sequences and transmembrane helices of survival-related DEAS were predicted, revealing that shifts in splicing sites altered the number and structure of their transmembrane proteins. We developed a prognostic risk model based on the screened 6-SLC-AS (SLC7A6_RI_37208 (SLC7A6-RI), SLC11A2_AP_21724, SLC2A8_ES_87631, SLC35B1_AA_42317, SLC39A11_AD_43204, and SLC7A8_AP_26712). Knockdown of the intronic region of SLC7A6-RI isoform enhanced colon cancer cell proliferation. Invivo, knockdown of the intronic region of SLC7A6-RI isoform enhanced tumor growth in colon cancer. Mechanistically, si-SLC7A6-RI isoform exerted oncogenic effects by activating the PI3K-Akt-mTOR signaling pathway and promoting cell proliferation, evidenced by increased expression of key regulators Phosphorylated Mammalian Target of Rapamycin (p-mTOR) and a cell proliferation marker Proliferating Cell Nuclear Antigen (PCNA) using western blotting. Our study elucidated SLC-AS in COAD, highlighting its potential as a prognostic and therapeutic target and emphasizing the suppressive influence of SLC7A6-RI in colon cancer progression.

Tumor cell-intrinsic Piezo2 drives radioresistance by impairing CD8+ T cell stemness maintenance.

Changes in mechanosensitive ion channels following radiation have seldom been linked to therapeutic sensitivity or specific factors involved in antitumor immunity. Here, in this study, we found that the mechanical force sensor, Piezo2, was significantly upregulated in tumor cells after radiation, and Piezo2 knockout in tumor cells enhanced tumor growth suppression by radiotherapy. Specifically, loss of Piezo2 in tumor cells induced their IL-15 expression via unleashing JAK2/STAT1/IRF-1 axis after radiation. This increase in IL-15 activates IL-15Rα on tumor-infiltrating CD8+ T cells, thereby leading to their augmented effector and stem cell-like properties, along with reduced terminal exhausted feature. Importantly, Piezo2 expression was negatively correlated with CD8 infiltration, as well as with radiosensitivity of patients with rectum adenocarcinoma receiving radiotherapy treatment. Together, our findings reveal that tumor cell-intrinsic Piezo2 induces radioresistance by dampening the IRF-1/IL-15 axis, thus leading to impaired CD8+ T cell-dependent antitumor responses, providing insights into the further development of combination strategies to treat radioresistant cancers.

Copper homeostasis and cuproptosis in gynecological cancers.

Copper (Cu) is an essential trace element involved in a variety of biological processes, such as antioxidant defense, mitochondrial respiration, and bio-compound synthesis. In recent years, a novel theory called cuproptosis has emerged to explain how Cu induces programmed cell death. Cu targets lipoylated enzymes in the tricarboxylic acid cycle and subsequently triggers the oligomerization of lipoylated dihydrolipoamide S-acetyltransferase, leading to the loss of Fe-S clusters and induction of heat shock protein 70. Gynecological malignancies including cervical cancer, ovarian cancer and uterine corpus endometrial carcinoma significantly impact women's quality of life and even pose a threat to their lives. Excessive Cu can promote cancer progression by enhancing tumor growth, proliferation, angiogenesis and metastasis through multiple signaling pathways. However, there are few studies investigating gynecological cancers in relation to cuproptosis. Therefore, this review discusses Cu homeostasis and cuproptosis while exploring the potential use of cuproptosis for prognosis prediction as well as its implications in the progression and treatment of gynecological cancers. Additionally, we explore the application of Cu ionophore therapy in treating gynecological malignancies.

Impaired mitochondrial oxidative phosphorylation induces CD8+ T cell exhaustion

CD8+ T cells play a crucial role in anti-tumor immunity, but their function can be impaired by exhaustion induced by prolonged antigen stimulation. Mitochondrial dysfunction, a hallmark of the tumor microenvironment (TME), has been linked to various pathologies, but its specific role in CD8+ T cell exhaustion remains underexplored. Here, we established an in vitro model of CD8+ T cell exhaustion by co-culturing OVA-specific OT1 CD8+ T cells with OVA-expressing MC38 tumor cells. Next, we investigated the impact of mitochondrial dysfunction on exhaustion using pharmacological inhibitors targeting the electron transport chain. The role of the mitochondrial complex I component NDUFA10 was further examined through genetic knockout in CD8+ T cells using CRISPR-Cas9. Inhibition of the mitochondrial electron transport chain significantly accelerated CD8+ T cell exhaustion in vitro. Knockout of NDUFA10 in CD8+ T cells led to enhanced tumor growth and increased exhaustion of tumor-infiltrating CD8+ T cells in a Rag1−/− tumor-bearing transfer model. This study highlights the critical role of mitochondrial function in regulating CD8+ T cell exhaustion and anti-tumor activity, providing new insights into the metabolic underpinnings of immune dysfunction in cancer.

Investigating MATN3 and ASPN as novel drivers of gastric cancer progression via EMT pathways

Abstract Gastric cancer (GC) is a leading cause of cancer-related deaths globally, necessitating the identification of novel therapeutic targets. This study investigates the roles of MATN3 and ASPN in GC progression via the epithelial-mesenchymal transition (EMT) pathway. Analysis of the Cancer Genome Atlas—Stomach Adenocarcinoma (TCGA-STAD) dataset revealed that both MATN3 and ASPN are significantly upregulated in GC tissues and correlate with poor patient survival. Protein–protein interaction and co-expression analyses confirmed a direct interaction between MATN3 and ASPN, suggesting their synergistic role in EMT activation. Functional assays demonstrated that MATN3 promotes GC cell proliferation, migration, and invasion, while its knockdown inhibits these malignant behaviors and induces apoptosis. ASPN overexpression further amplified these oncogenic effects. In vivo, studies in a mouse model corroborated that co-overexpression of MATN3 and ASPN enhances tumor growth and metastasis. These findings highlight the MATN3-ASPN axis as a potential therapeutic target in GC, offering new insights into the molecular mechanisms driving GC progression.

C-FOS inhibition promotes pancreatic cancer cell ferroptosis by transcriptionally regulating the expression of SLC7A11.

Cellular proto-oncogene C-Fos forms the AP-1 transcription factor by dimerizing with proto-oncogene c-Jun; this factor upregulates the transcription of genes associated with different malignancies. However, its functions in pancreatic adenocarcinoma (PAAD) remain poorly understood. In this study, the c-Fos was increased in PAAD cells and tissues through bioinformatic analysis, RT-PCR, and WB. In two PAAD cell lines, PANC-1 and BxPC-3, we performed c-Fos knockdown studies using short hairpin RNA (shRNA). Functional analysis indicated that c-Fos depletion in PAAD cells inhibits cell proliferation and promotes ferroptosis. Chromatin Immunoprecipitation (ChIP) and Dual-luciferase experiments showed that c-Fos coupled to the promoter region of SLC7A11 stimulated its transcription, providing mechanistic insight into the process. Moreover, SLC7A11 blocked the decline of proliferation and ferroptosis by c-Fos knockdown in PAAD cells. Furthermore, a xenograft nude mouse model was established to study the impact of c-Fos on tumorigenesis in vivo. Depletion of c-Fos could suppress PC tumor growth and the expressions of SLC7A11, ki-67, and 4HNE, but overexpression of SLC7A11 reversed this process. In summary, our investigation has shown that c-Fos acts as a transcriptional regulator of SLC7A11, which may enhance tumour growth in pancreatic cancer by inhibiting ferroptosis. These results indicate that c-Fos might be a promising target for treating ferroptosis in PAAD.

Abstract A049: Collagen-driven kinome reprogramming reveals unique, actionable DDR1-signaling dependencies in pancreatic cancer cells

Abstract Introduction: Pancreatic ductal adenocarcinoma (PDA) is the 3rd most common cause of cancer death in the United States, with a 5-year survival rate of only 13%, in part due to late detection and metastatic dissemination at early stages of progression. Most PDA tumors exhibit a dense fibro-inflammatory stroma consisting of fibroblasts, immune cells, and a dense collagen-rich extracellular matrix (ECM) that regulate disease progression. How distinct collagens (COLs) influence PDA progression remains unclear. COLs signal via specific cell surface receptors, of which the Discoidin Domain Receptors (DDRs) constitute a unique family of collagen-binding receptor tyrosine kinases (RTKs). DDR1 is expressed by PDA cancer cells, while DDR2 is expressed by mesenchymal cells. DDR1 is activated by both basement membrane COL (e.g. COL4) and fibrillar COLs (e.g. COLs 1, 2, 11). Compared to most RTKs, relatively little is understood about differential ligand activation and signaling downstream of DDRs. Our working hypothesis is that switches in ECM collagen composition over the course of PDA progression induce changes in DDR1-intracellular signaling cascades, which may reveal unexplored therapeutic susceptibilities to target and eliminate PDA cancer cells. Methods and Recent Advances: Using genetically engineered mouse models of PDA, we previously found that genetic ablation of Ddr1 impedes tumor progression, blocking the transition from well-differentiated to poorly-differentiated adenocarcinoma and, as a result, metastasis. Moreover, we showed that xenografts of DDR1-expressing human PDA cell lines display enhanced tumor growth exclusively when implanted within a COL1 scaffold. Leveraging an innovative high-throughput kinase-activity mapping (HT-KAM) platform and kinase network resource database (PhosphoAtlas), we started investigating mechanisms of differential activation of DDR1 by distinct COLs, including COL1 and COL11, which is an understudied fibrillar collagen that is prominent in the stroma of late-stage, metastatic PDA. New, Unpublished Findings: Using several PDA cell line models with or without DDR1 expression, our results indicate that DDR1 activates two distinct signaling networks: (1) a conserved, coordinated response that is modestly activated by COL1 but is hyperactivated by COL11 (e.g., ERBB, AKT, MEK/ERK, SRC), and (2) a unique set of phospho-signaling nodes that are only induced by COL11 –and not COL1 (e.g., specific RTKs and PKCs). Several of these kinases are associated with cancer cell proliferation and survival, as well as EMT induction, in part illuminating the malignancy-promoting effects of DDR1 in late-stage PDA in response to changes in COL composition. Conclusion: Differential activation of DDR1 represents a new paradigm on how distinct fibrillar COLs within the TME may drive PDA cell signaling. We are actively exploring how distinct COLs differentially regulate PDA tumor growth and metastatic behavior via DDR1, and how specific kinase-targeting interventions may prevent malignant phenotypes or induce tumor cell death. Citation Format: Anjum Sohail, Yeonjoo Hwang, Denise P Munoz, Yoshihiro Ishikawa, Rafael Fridman, Howard Crawford, Jean-Philippe Coppe. Collagen-driven kinome reprogramming reveals unique, actionable DDR1-signaling dependencies in pancreatic cancer cells [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 A049.

Abstract B079: Disassembly of embryonic keratin filaments promotes pancreatic cancer metastases

Abstract Keratin 17 (K17), an intermediate filament protein typically expressed during embryonic development, is a hallmark of one of the most aggressive pancreatic ductal adenocarcinoma (PDAC) subtypes. Its expression is also associated with poor patient survival and resistance to first-line therapies. However, the mechanistic roles of K17 in malignancy remain largely unexplored. Here, we demonstrate that K17 expression and disassembly enhance tumor growth, increase metastatic potential, and shorten overall survival. Using the Clinical Proteomic Tumor Analysis Consortium (CPTAC) stratified by K17 phosphorylation status, we found that increased K17 phosphorylation correlated with worse survival. Mass spectrometry of untreated PDAC patient samples identified a phosphorylation hotspot at serines 10-13, which is conserved across species and type I keratin proteins. We found that K17 phosphorylation, mediated by the PKC/MEK/RSK pathway, led to increased disassembly and nuclear translocation in pancreatic cancer cells. Mice with phosphomimetic mutations at the serine hotspot showed increased metastases and decreased survival compared to wild-type and phosphorylation-resistant K17. Lastly, detergent-soluble nuclear K17 promoted metastasis- related genes in both patient and murine tumors. These findings suggest that disassembly of K17 mediated by phosphorylation at serines 10-13 is sufficient to promote metastases and decrease overall survival in PDAC. This opens the door for further investigation into K17 phosphorylation as a novel therapeutic target to enhance PDAC patient survival, especially in those with more aggressive, chemoresistant subtypes. Citation Format: Deanne E Yugawa, Ryan Kawalerski, Mariana Torrente Gonçalves, Chun-Hao Pan, Robert Tseng, Lucia Roa-Pena, Cindy V Leiton, Luke A Torre-Healy, Taryn Boyle, Sumedha Chowdhury, Natasha T Snider, Kenneth R Shroyer, Luisa F Escobar-Hoyos. Disassembly of embryonic keratin filaments promotes pancreatic cancer metastases [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 B079.

MG53 suppresses tumor growth via transcriptional inhibition of KIF11 in pancreatic cancer

Pancreatic ductal adenocarcinoma (PDAC) poses a formidable challenge in oncology due to its limited treatment options and poor long-term survival rates. Our previous work identified MG53, a member of the tripartite motif family protein (TRIM72), as a key player in tissue repair with potential applications in regenerative medicine. Despite the focus on MG53’s cytosolic functions, its nuclear role in suppressing pancreatic cancer remains unknown. Through orthotopic and subcutaneous transplantation studies in mice, we observed enhanced tumor growth in MG53-deficient mice compared to wild-type counterparts. The overexpression of KIF11, a motor protein crucial for cell mitosis regulation, has been linked to the aggressive proliferation of pancreatic cancer cells. Confocal imaging confirmed MG53′s presence in the nucleus of human pancreatic cancer cells, while functional assays demonstrated its impact on KIF11 expression and subsequent cell proliferation. Mechanistically, we revealed MG53′s transcriptional control over KIF11, leading to cell cycle arrest. Our findings position MG53 as a promising tumor suppressor in PDAC, offering a novel avenue for therapeutic intervention by regulating KIF11 expression.

Telotristat ethyl, a tryptophan hydroxylase inhibitor, enhances antitumor efficacy of standard chemotherapy in preclinical cholangiocarcinoma models.

Cholangiocarcinoma (CCA), an aggressive biliary tract cancer, carries a grim prognosis with a 5-year survival rate of 5%-15%. Standard chemotherapy regimens for CCA, gemcitabine plus cisplatin (GemCis) or its recently approved combination with durvalumab demonstrate dismal clinical activity, yielding a median survival of 12-14 months. Increased serotonin accumulation and secretion have been implicated in the oncogenic activity of CCA. This study investigated the therapeutic efficacy of telotristat ethyl (TE), a tryptophan hydroxylase inhibitor blocking serotonin biosynthesis, in combination with standard chemotherapies in preclinical CCA models. Nab-paclitaxel (NPT) significantly enhanced animal survival (60%), surpassing the marginal effects of TE (11%) or GemCis (9%) in peritoneal dissemination xenografts. Combining TE with GemCis (26%) or NPT (68%) further increased survival rates. In intrahepatic (iCCA), distal (dCCA) and perihilar (pCCA) subcutaneous xenografts, TE exhibited substantial tumour growth inhibition (41%-53%) compared to NPT (56%-69%) or GemCis (37%-58%). The combination of TE with chemotherapy demonstrated enhanced tumour growth inhibition in all three cell-derived xenografts (67%-90%). PDX studies revealed TE's marked inhibition of tumour growth (40%-73%) compared to GemCis (80%-86%) or NPT (57%-76%). Again, combining TE with chemotherapy exhibited an additive effect. Tumour cell proliferation reduction aligned with tumour growth inhibition in all CDX and PDX tumours. Furthermore, TE treatment consistently decreased serotonin levels in all tumours under all therapeutic conditions. This investigation decisively demonstrated the antitumor efficacy of TE across a spectrum of CCA preclinical models, suggesting that combination therapies involving TE, particularly for patients exhibiting serotonin overexpression, hold the promise of improving clinical CCA therapy.

Gliomedin drives gastric cancer cell proliferation and migration, correlating with a poor prognosis

Gastric cancer (GC) is a prevalent global malignancy, often diagnosed at advanced stage due to a lack of early symptoms and reliable markers. Previous research has identified gliomedin (GLDN) as a potential predictive marker for poor prognosis in cancer patients. However, the specific relationship between GLDN expression and GC prognosis has been unclear. Using the Tumor-Immune System Interaction Database (TISIDB), we examined GLDN expression in GC tissues and found a positive correlation with advanced clinical stages. Kaplan-Meier Plotter analysis further demonstrated that elevated GLDN levels were closely associated with poor prognosis in GC patients. To explore the functional significance of GLDN in GC, we conducted experiments involving GLDN overexpression and knockdown in GC cell lines, as well as subcutaneous tumor formation in nude mice. Our findings provided compelling evidence that GLDN promotes GC cell proliferation, viability, and migration, significantly enhancing tumor growth in vivo. Mechanistically, RNA-sequencing (RNA-seq) combined with bioinformatics analysis revealed that GLDN influences genes enriched in the p53 signaling pathway. Our data suggest that GLDN likely regulates cell proliferation through the p53-p21-CyclinD/CDK4 signaling axis. In conclusion, our study underscores GLDN's critical role in regulating GC cell proliferation and migration, and proposes its potential as a prognostic marker for GC patients.

Mutant p53 Exploits Enhancers to Elevate Immunosuppressive Chemokine Expression and Impair Immune Checkpoint Inhibitors in Pancreatic Cancer.

Pancreatic ductal adenocarcinoma (PDAC) is an aggressive cancer without effective treatments. It is characterized by activating KRAS mutations and p53 alterations. However, how these mutations dysregulate cancer-cell-intrinsic gene programs to influence the immune landscape of the tumor microenvironment (TME) remains poorly understood. Here, we show that p53R172H establishes an immunosuppressive TME, diminishes the efficacy of immune checkpoint inhibitors (ICIs), and enhances tumor growth. Our findings reveal that the upregulation of the immunosuppressive chemokine Cxcl1 mediates these pro-tumorigenic functions of p53R172H. Mechanistically, we show that p53R172H associates with the distal enhancers of the Cxcl1 gene, increasing enhancer activity and Cxcl1 expression. p53R172H occupies these enhancers in an NF-κB-pathway-dependent manner, suggesting NF-κB's role in recruiting p53R172H to the Cxcl1 enhancers. Our work uncovers how a common mutation in a tumor-suppressor transcription factor appropriates enhancers, stimulating chemokine expression and establishing an immunosuppressive TME that diminishes ICI efficacy in PDAC.

Cancer cell-derived exosomes promote NSCLC progression via the miR-199b-5p/HIF1AN axis

BackgroundExosomes are mediators of intercellular communication. Cancer cell-secreted exosomes allow exosome donor cells to promote cancer growth, as well as metastasis. MethodsHere, exosomes were isolated from the serum of non-small cell lung cancer (NSCLC) patients and characterized by transmission electron microscopy (TEM), nanoparticle tracking analysis (NTA) and western blot analysis. NSCLC cell proliferation and migration were assessed using CCK-8, 5-ethynyl-2′-deoxyuridine (EdU) and Transwell assays. H1299 tumor formation and pulmonary metastasis were examined in a xenograft model in nude mice. ResultsWe found that exosomes derived from NSCLC (NSCLC-Exos) promoted NSCLC cell migration and proliferation, and that NSCLC-Exo-mediated malignant progression of NSCLC was mediated by miR-199b-5p. Inhibition of miR-199b-5p decreased the effects of NSCLC-Exos on NSCLC malignant progression. HIF1AN was identified as a downstream target of miR-199b-5p. Furthermore, overexpression of HIF1AN reversed the effects of miR-199b-5p on NSCLC malignant progression. ConclusionIn summary, our findings demonstrated that exosomal-specific miR-199b-5p promoted proliferation in distant or neighboring cells via the miR-199b-5p/HIF1AN axis, resulting in enhanced tumor growth.

Unveiling the Hidden Links: Periodontal Disease, Fusobacterium Nucleatum, and Cancers.

Fusobacterium nucleatum (F. nucleatum), an anaerobic, gram-negative microbe, commonly found in human dental biofilm and the gut flora. It has long been known to have a higher concentration in periodontal disease and has recently been implicated in bothoral and distant cancers such as colorectal,gastrointestinal, esophageal, breast, pancreatic hepatocellular,and genitourinary cancers.However, the mechanism of its involvement in the development of cancer has not been fully discussed. This review aims to cover biological molecular and clinical aspects of F. nucleatumand cancers. Studies indicate F. nucleatum promotes tumor development through chronic inflammation, immune evasion, cell proliferation activation, and direct cell interactions, as in oral squamous cell carcinoma (OSCC). In colorectal cancer (CRC), F. nucleatum contributes to tumorigenesis through β-catenin signaling and NF-κB activation. It also induces autophagy, leading to chemoresistance in CRC and esophageal cancers, and enhances tumor growth and metastasis in breast cancer by reducing T-cell infiltration. F. nucleatum is linked to carcinogenesis and increased bacterial diversity in OSCC, with improved oral hygiene potentially preventing OSCC. F. nucleatum triggers cancer by causing mutations and epigenetic changes through cytokines and reactive oxygen species. It also promotes chemoresistance in CRC. F. nucleatum may potentially serve as a diagnostic tool in various cancers, with non-invasive detection methods available. Further investigation is needed to discover its potential in the diagnosis and treatment of OSCC and other cancers.

Investigation of a tamoxifen-RACK7/KDM5C-IFN-I axis for ER+ breast cancer immunomodulation.

9 Background: ER+ breast cancer patients generally have good prognosis. However, significant relapse rates (i.e., hormone drugs, Tamoxifen/TMX) and the poor response to immune checkpoint blockade (ICB) remain critical issues to be addressed. Thus, exploration of anti-ICB resistant mechanisms and alternative targets is needed to improve therapeutic efficacy. Methods: To investigate potential cross-resistant mechanisms between hormone and ICB therapy, ER+ cell lines T47D and MCF7 cells were chronically-treated with TMX for 6 months, and subjected to RNA-Seq and pathway enrichment analysis. Dysregulation of identified factors were validated via western blotting, RT-qPCR, and flow cytometry. Target factors were then inhibited or depleted by shRNA knockdown (KD) or small-compound inhibition. Identified ICB resistance mechanisms were further elaborated by in vitro co-culture assays, syngeneic mouse models, and immune-profiling of tumor microenvironment (TME). Results: Chronic exposure to TMX activates Type I interferon (IFN-I) signaling, induces IFN I-stimulated gene (ISG) expression, and downregulates the H3K4 demethylase and ISG repressor complex known as RACK7/KDM5C. Chronic TMX also upregulates CEACAM1, a well-known ligand for the immune checkpoint receptor TIM3. Results prompt us to evaluate whether loss of RACK7 combined with TMX treatment may modulate a lymphocyte-attractive (via IFN-I), but T-cell exhaustive (via CEACAM1-TIM3) TME. Indeed, in vitro treatment of TMX under RACK7-KD conditions triggers STING upregulation, TBK1 hyperphosphorylation, and a more pronounced activation of ISGs and CEACAM1. In vivo, TMX combined with RACK7-KD enhances tumor growth in the TS/A (ER+) syngeneic mouse model, while immune-profiling reveal that this combination promotes lymphocyte infiltration with a higher population of terminally exhausted CD8+ T-cells in the TME. Conclusions: Our data demonstrate that the TMX-induced activation of cGAS/STING pathway and RACK7 downregulation coordinately shape the IFN-I and immune checkpoint signaling axes in ER+ breast cancer. This TMX–RACK7–IFN-I regulatory network promotes a lymphocyte-attractive TME via IFN-I signaling activation, whereas induction of inhibitory ligands renders T-cells to be terminally-exhausted and unable to kill tumors. These findings highlight the potential use of TMX’s STING-agonistic effect in re-shaping the “cold” breast cancer TME, and the use of combined TMX and anti-TIM3 or anti-CEACAM1 blockade to improve ICB therapy.

UPF1 deficiency enhances mitochondrial ROS which promotes an immunosuppressive microenvironment in pancreatic ductal adenocarcinoma

Upstream frameshift 1 (UPF1) is an RNA helicase involved in a number of mRNA regulatory processes including nonsense-mediated decay. Mutations in the UPF1 locus that reduce its expression have been associated with adenosquamous carcinoma of the pancreas, a particularly aggressive form of the disease. To determine the effect of Upf1 suppression in a murine model of pancreatic adenocarcinoma, we silenced with shRNA Upf1 in cells derived from an autochthonous tumor in an LSL-Kras G12D/+ ; Trp53 R172H/+ ; Pdx-1 Cre/+ mouse (KPC) and orthotopically implanted these cells in the pancreas of C57BL/6 mice. Tumors derived from Upf1-deficient cells were markedly larger than those derived from control cells, a difference observed only in immunocompetent mice. The immune infiltrate of Upf1-deficient tumors was enriched in myeloid-derived suppressor cells (MDSCs) and depleted of CD8 + cells compared to control KPC tumors. Upf1-deficient KPC cells secreted inflammatory cytokines including G-CSF and CXCL2, known to recruit MDSCs. Cytokine secretion from Upf1-deficient KPC cells was induced by increased levels of mitochondrial reactive oxygen species (ROS), which in turn were due to an increase in complex I activity in the electron transport chain. Thus, Upf1 helicase deficiency leads to increased mitochondrial complex I activity which produces ROS that signals for cytokine release that drives immune suppression and enhanced tumor growth.

67 Preclinical evaluation of PSMA-based68Ga-/225Ac-labeled radiotheranostic pair in a syngeneic mouse model of renal cell carcinoma

Abstract Background Despite the significant progress achieved with PD-1/PD-L1 inhibitors in the treatment of metastatic renal cell carcinoma (mRCC), most patients ultimately progress. Targeted radiotheranostics offer a new potential approach. Although a radiotheranostic platform targeting the prostate-specific membrane antigen (PSMA) has been tested in mRCC in patients preliminarily, thorough preclinical optimization has not been reported. Prostate-specific membrane antigen (PSMA) is overexpressed in tumor-associated neovascular endothelial cells of many solid tumors, including metastatic RCC. Furthermore, radiopharmaceutical therapy using β- and α-particle emitting agents causes immunomodulation by inducing immunogenic cell death, and release of tumor-associated antigens, potentially enhancing inflammatory phenotype. Here, we investigated whether PSMA-based radiotheranostics can be utilized to improve the efficacy of PD-1 therapy. Methods The PSMA+ RENCA model was developed by lentiviral transduction of RENCA (wt) cells and then characterized for basal and IFN-g induced PD-L1 expression. 68Ga-L1 and 225Ac-L1 were synthesized in high radiochemical yield and purity following our reported methods. Male and female BALB/c mice were used for tumor inoculation. 68Ga-L1 was evaluated in small animal PET/CT imaging in flank and PET/MR imaging in orthotopic implantation. A treatment study was conducted to assess the effect of combination therapy in seven groups in the flank tumors at 2 weeks post-inoculation: Control (saline); PD-1 (10 mg/kg); Anti-PD-1 (10 mg/kg)+axitinib (tyrosine kinase inhibitor, 5 mg/kg, oral gavage, for five days/wk); 225Ac-L1 (37 kBq); 225Ac-L1 (2×37 kBq, 1 wk apart); [225Ac-L1 (37 kBq)+PD-1 (10 mg/kg) and [225Ac-L1 2×37 kBq)+PD-1 (10 mg/kg)]. Therapeutic efficacy was assessed by tumor weight and time to progression of tumor volume doubling (TVD). To determine the mechanism of action of the 225Ac-L1/anti-PD-1 combination treatment, tumor-infiltrating lymphoid populations from tumor samples were collected at day 30, and Fluorescence-Activated Cell Sorting analysis was done with fluorochrome-labeled antibodies against CD45, CD3, CD8, IL10, and IL12. Results 68Ga-L1 and 225Ac-L1 confirmed 10-fold and 2-fold higher uptake, respectively, in the PSMA+ RENCA cells compared to RENCA (wt) cells. PET imaging in the flank model displayed ~7-fold higher accumulation of 68Ga-L1 in PSMA+ RENCA than the RENCA (wt). Two-fold higher accumulation of 68Ga-L1 was observed in orthotopic tumors than the normal kidneys during 1-3 h post-injection. Significant lung metastases were detected with 68Ga-L1 PET at 3 weeks in mice with orthotopic tumors. A combination therapy study was conducted using anti-PD-1 and anti-PD-1+axitinib and compared the efficacy with 225Ac-L1 as a single agent (37 kBq and 2×37 kBq, 1 wk apart) and in combination with PD-1. Median TVD increased from 12 d (control) to 16 d (anti-PD-1), 16 d (anti-PD-1+axitinib), 24 d [225Ac-L1 (37 kBq) P<0.001], 24 d [225Ac-L1 (2 × 37 kBq) P<0.0001}, 30 d [anti-PD-1+225Ac-L1 (1×37 kBq) P<0.0001], and undefined, [anti-PD-1+225Ac-L1 2×37 kBq), P<0.0001], respectively. Furthermore, treatment with 225Ac-L1 (2×37 kBq, 1 wk) resulted in a significant lowering of tumor growth (P< 0.01) compared to control, whereas anti-PD-1 (vs. control) alone moderately reduced tumor growth. The combination of the treatment of [PD-1+225Ac-L1 (2×37 kBq), P=0.0001] was the most effective in enhancing tumor growth inhibition compared with the PD-1+axitinib group. Flow cytometry of tumor-infiltrating immune cells of the treatment groups PD-1+225Ac-L1(37 kBq) and PD-1+225Ac-L1 (2×37 kBq) revealed a higher proportion of effector CD3+CD8+ T cells, accompanied by a significant decline in the proportion of immunosuppressive and pro-tumoral CD8+IL10+ T cells and increase in antitumor CD8+IL12+ T cells compared to untreated and treatment control groups (PD-1 or PD-1+axitinib groups). Conclusions Combining radiotheranostic platform, 68Ga-L1/225Ac-L1 with PD-1 therapy reduces tumor burden and improves TVD in a syngeic model of RCC. This is a promising option for metastatic RCC patients with low and heterogeneous PSMA expression. Translation of this method will be pursued actively. DOD CDMRP Funding: yes