Melanoma Model Research Articles

Abstract B035: Reciprocal macrophage - T cell interactions regulate anti-tumor immunity

Abstract Cancer immunotherapy (including immune checkpoint blockade (ICB)) has shown great promise in the treatment of some solid cancers, but responses in breast cancer patients are limited. While breast cancer is generally considered poorly immunogenic, the abundance of CD8+ T cells correlates with clinical response. CD8+ T cells are critical mediators of anti-tumor immunity and the main target for ICB. However, the onset of terminal functional T cell exhaustion poses a major challenge. Although T cell exhaustion has been linked to persistent antigen exposure, it remains unclear how the immune composition of the breast tumor microenvironment (TME) contributes to this dysfunctional T cell state. Breast cancers are heavily infiltrated with tumor-associated macrophages (TAMs) and their abundance correlates with T cell exhaustion and poor prognosis. Previously, we discovered a spatiotemporal co-dependency between exhausted T cells (TEX) and TAMs in mouse models of melanoma and breast cancer. We showed that TEX actively recruit monocytes to the TME and shape their differentiation trajectory into TAMs. Reciprocally, these TAMs ‘capture’ T cells in long-lived synaptic interactions that contribute to functional T cell exhaustion. Our current work is focused on studying the TEX-derived chemokines that regulate these TAM – T cell interactions in the breast TME with the ultimate goal to alleviate immune evasion and improve responsiveness of breast cancer to immunotherapy. Citation Format: Meenakshi Sudhakaran, Sofia Lombardi, Sophie Ayma, Matthew F. Krummel, Kelly Kersten. Reciprocal macrophage - T cell interactions regulate anti-tumor immunity [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr B035.

Abstract A023: Arachidonic acid metabolism promoting cross resistance in melanoma cells

Abstract Melanoma patients initially respond well to first line immunotherapy. However, cross resistance to immunotherapy and BRAF/MEK inhibitor is a clinical challenge for melanoma care. To investigate drug tolerant and resistant mechanisms promoting cross resistance, we analyzed RNA-sequencing and gene set enrichment targeted therapy resistant melanoma cells revealing an enriched arachidonic acid gene signature. Intracellular arachidonic acid levels were increased in drug resistant and drug tolerant melanoma models. Arachidonic acid is enzymatically converted by COX1 and COX2 to prostaglandins, which is subsequently secreted into the microenvironment. Drug tolerant and resistant cells had increased protein expression of COX1 and COX2 concurrently with increased secretion of prostaglandin E2. COX1/2 inhibition and COX2 knockdown in vitro had no effect on cell growth in drug tolerant or resistant cells compared to parental cells. However, secreted prostaglandins are known immunomodulators, thus we explored how COX1/2 inhibition in combination with BRAF inhibitor plus MEK inhibitor affected immune cell infiltration. COX1/2 inhibition increased CD4+ and CD8+ T cell infiltration as compared to BRAF inhibitor plus MEK inhibitor alone. Under constant BRAF inhibitor plus MEK inhibitor treatment, we found that COX1/2 inhibition upon reaching MRD status prevented tumor relapse in vivo and increased survival dependent on an immune system. Future studies will evaluate the importance of arachidonic acid metabolism in promoting cross resistance to immune checkpoint blockade and whether T cell depletion prevents the delayed tumor relapse. Overall, COX1/2 inhibition delayed tumor relapse and survival in an immune-dependent manner and demonstrated a potential cross resistant mechanism. Citation Format: Casey D. Stefanski, Daniel A. Erkes, Timothy J. Purwin, Glenn L. Mersky, Erica L. Kitterman, Manal Mustafa, Jelan Haj, Diana Melissaratos, Andrew E. Aplin. Arachidonic acid metabolism promoting cross resistance in melanoma cells [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr A023.

The HDAC6 inhibitor AVS100 (SS208) induces a pro-inflammatory tumor microenvironment and potentiates immunotherapy.

Histone deacetylase 6 (HDAC6) inhibition is associated with an increased pro-inflammatory tumor microenvironment and antitumoral immune responses. Here, we show that the HDAC6 inhibitor AVS100 (SS208) had an antitumoral effect in SM1 melanoma and CT26 colon cancer models and increased the efficacy of anti-programmed cell death protein 1 treatment, leading to complete remission in melanoma and increased response in colon cancer. AVS100 treatment increased pro-inflammatory tumor-infiltrating macrophages and CD8 effector T cells with an inflammatory and T cell effector gene signature. Acquired T cell immunity and long-term protection were evidenced as increased immunodominant T cell clones after AVS100 treatment. Last, AVS100 showed no mutagenicity, toxicity, or adverse effects in preclinical good laboratory practice studies, part of the package that has led to US Food and Drug Administration clearance of an investigational new drug application for initiating clinical trials. This would be a first-in-human combination therapy of pembrolizumab with HDAC6 inhibition for locally advanced or metastatic solid tumors.

H2S-Prdx4 axis mitigates Golgi stress to bolster tumor-reactive T cell immunotherapeutic response.

The role of tumor microenvironment (TME)-associated inadequate protein modification and trafficking due to insufficiency in Golgi function, leading to Golgi stress, in the regulation of T cell function is largely unknown. Here, we show that disruption of Golgi architecture under TME stress, identified by the decreased expression of GM130, was reverted upon treatment with hydrogen sulfide (H2S) donor GYY4137 or overexpressing cystathionine β-synthase (CBS), an enzyme involved in the biosynthesis of endogenous H2S, which also promoted stemness, antioxidant capacity, and increased protein translation, mediated in part by endoplasmic reticulum-Golgi shuttling of Peroxiredoxin-4. In in vivo models of melanoma and lymphoma, antitumor T cells conditioned ex vivo with exogenous H2S or overexpressing CBS demonstrated superior tumor control upon adoptive transfer. Further, T cells with high Golgi content exhibited unique metabolic and glycation signatures with enhanced antitumor capacity. These data suggest that strategies to mitigate Golgi network stress or using Golgihi tumor-reactive T cells can improve tumor control upon adoptive transfer.

Inflammasome-Activating Nanovaccine for Cancer Immunotherapy.

A range of advanced nanovaccines (NV) combined with immunotherapies has recently emerged for treating malignant tumors and has demonstrated promising tumor-suppressive effects. Nevertheless, their effectiveness is often limited by immunosuppression within the tumor microenvironment. To overcome this challenge, new approaches for NV development are required to improve antigen cross-presentation and to remodel the tumor microenvironment. In this issue of Cancer Research, Zhou and colleagues have developed a photo-enhanceable inflammasome-activating nanovaccine (PIN) designed for precise, in situ delivery of a tumor antigen and a hydrophobic small molecule that activates the NLRP3 inflammasome pathway. Near infrared light exposure enables the accumulation of PINs at tumor sites by inducing a photo-triggered charge reversal in the BODIPY-modified PAMAM nanocarrier. Systemic administration of PINs resulted in effective intratumoral activation of the NLRP3 inflammasome and antigen cross-presentation in antigen-presenting cells upon light exposure, leading to enhanced immune responses through increased proinflammatory cytokine production without significant systemic toxicity. Importantly, PINs also enhanced the efficacy of immune checkpoint blockade and promoted the development of long-term immune memory in mouse models of melanoma and hepatocellular carcinoma. Overall, inflammasome-activating NVs represent a cancer immunotherapy strategy by harnessing the innate immune system to achieve robust responses against tumors. Ongoing research and development are crucial to addressing current limitations and advancing this innovative technology toward clinical application. See related article by Zhou et al., p. 3834.

Abstract A012: g3bp1-mediated stress granule formation drives melanoma initiation in zebrafish

Abstract Stress granules confer cancer cells the ability to withstand harsh biological conditions and impart tumorigenic translational states through mRNA sequestration. Despite advances in in vitro knowledge, mechanistic understanding of the endogenous influence of stress granules during tumorigenesis in vivo remains understudied. To address this, we use a zebrafish melanoma model where oncogenic human BRAF V600E is driven by the melanocyte master regulator mitfa in a p53 -/- background. Through vector-based genetic engineering, endogenous melanoma induction in these zebrafish can be developmentally staged from single cell to tumor. BRAF V600E ::p53 -/- melanocytes form a cancerized field (CF), from which a subset upregulate the melanocyte master regulator mitfa, creating a cancer precursor zone (CPZ). Transformation of CPZ cells to an embryonic, neural crest-like state facilitates their formation of an early tumor patch that inevitable develops into an overt tumor. Single cell RNAseq analysis of cells representing each melanoma stage showed that CPZ cells upregulate core stress granule markers, including g3bp1, tia1, tia1l, and nufip2. Immunostaining of g3bp1 in CF, CPZ, patch, and tumor cells revealed a significant induction of stress granules from the CF to CPZ transition (2 vs 10 stress granules/cell; N=3; p=0.034) that persists during the patch and tumor stage, indicating cell stress accompanies melanoma initiation and progression. Genetic disruption of g3bp1 through cell autonomous, melanocyte-specific CRISPR editing in zebrafish (N=10-13) causes delayed CPZ onset (P=0.012) and fewer CPZs to form (P=0.021). In turn, g3bp1-edited zebrafish have delayed tumor formation (P=0.026) and develop fewer tumors (P=0.006). To decipher the RNAs sequestered by stress granules during melanomagenesis, we performed RIPseq for G3BP1 in human A375 melanoma cells stressed with sodium arsenite. RNAs significantly bound to G3BP1 upon stress induction include major tumor suppressors, such as CDKN2A, RBM5, BIK, and RHOB. Together, these results suggest that endogenous g3bp1-mediated stress granule formation in melanoma initiating cells is tumorigenic in vivo and operates through the sequestration of tumor suppressive RNAs. Citation Format: Kyle D Drake, Emily Formato, Leonard Zon. g3bp1-mediated stress granule formation drives melanoma initiation in zebrafish [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: RNAs as Drivers, Targets, and Therapeutics in Cancer; 2024 Nov 14-17; Bellevue, Washington. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(11_Suppl):Abstract nr A012.

Combination of gold nanoparticles with near-infrared light as an alternative approach for melanoma management.

Melanoma is the most aggressive type of skin cancer and recently approved drugs are often associated with resistance and significant adverse effects. Therefore, the design of more effective and safe options remains imperative. Photothermal therapy (PTT) using gold nanoparticles (AuNPs) presents a promising and innovative approach. In this work, the efficacy of combining a previously optimized formulation of AuNPs coated with a mixture of hyaluronic and oleic acids (HAOA-AuNPs) with near-infrared (NIR) laser irradiation in melanoma cell lines was explored. Coated and uncoated AuNPs formulations were characterized in physicochemical, morphological and elemental terms. Next, the cellular uptake efficiency as well as antiproliferative activity of the combination of each formulation with laser irradiation was evaluated. Subsequently, HAOA-AuNPs were selected to assess the underlying mechanism of combined therapy by cell cycle and Annexin V/PI assays. An in vivo syngeneic murine melanoma model was also conducted. In vitro studies demonstrated that 24 h after incubation and in the absence of laser, HAOA-AuNPs did not exhibit cytotoxic effects on the melanoma cell lines tested, similar to the laser alone. On the contrary, the combination therapy resulted in a large reduction in cell viability. Furthermore, it has been shown to promote S-phase cell cycle arrest and increase in the percentage of late apoptotic cells. Finally, the in vivo proof-of-concept showed that the intratumoral administration of HAOA-AuNPs followed by three laser irradiations impaired tumor progression. Collectively, AuNP-based PTT holds significant potential to improve treatment efficacy and safety, offering a versatile and potent tool against cancer.

EXTH-66. ONCOLYTIC ADENOVIRAL INFECTION SYNERGIZES WITH IMMUNE CHECKPOINT INHIBITION TO MEDIATE INTRACRANIAL TUMOR CONTROL IN DISPARATE MODELS OF MELANOMA BRAIN METASTASES

Abstract Amongst all solid cancers, melanoma brain metastases (MBM) have the highest likelihood of metastasizing to the brain. The emergence of immune checkpoint inhibitors (ICI) for metastatic melanoma have demonstrated increasingly promising results; however, intracranial progression remains a challenging obstacle. Oncolytic viral (OV) therapy leverages tumor cell replication machinery to selectively replicate and kill tumor cells and promote anti-tumor immunity. We propose this OV strategy can be applied to MBM through direct tumor infection that simultaneously sustains a distant antitumor immune response. To counteract immunosuppressive features of the tumor microenvironment (TME), a third-generation oncolytic adenovirus (Delta-24-RGDOX) has been developed which expresses the immune stimulatory OX40 ligand (OX40L). We quantified the cytotoxic capacity of Delta-24-RGDOX and its ability to achieve immunogenic cell death (ICD) in vitro along with cerebral organoid co-culture models. Additionally, we used a series of syngeneic murine melanoma models to explore local and systemic antitumor immunity following Delta-24-RGDOX infection. Delta-24-RGDOX inoculation achieved viral infection, OX40L cell surface expression, tumor cell cytotoxicity, and ICD in vitro. Viral oncolysis was recapitulated in a cerebral organoid melanoma co-culture model with concomitant alterations in microglia activation and detection of viral transcripts within microglia using single cell RNA sequencing, suggesting a viral-clearing role of microglia within the TME. Local tumor clearance was achieved in orthotopic intracranial models following direct intracranial viral inoculation alone, and in combination with ICI. Lastly, we demonstrated improvement in overall survival in a synchronous subcutaneous/intracranial B16F10 model where the subcutaneous tumor was treated with Delta-24-RGDOX in combination with ICI. In summary, Delta-24-RGDOX achieves viral infection, oncolysis, and ICD following infection of melanoma cell lines. These findings translated in multiple in vivo models including immune cell activation and systemic antitumor immunity against uninfected MBM. Future studies are needed to explore the role of immune cell trafficking, myeloid cell modulation, T cell priming, and clonal expansion withing locally infected and the distant melanoma TME.

DDDR-04. PRECLINICAL INVESTIGATION OF A NOVEL BRAIN PENETRANT COMBINATION THERAPY TARGETING RAF AND MEK FOR MELANOMA BRAIN METASTASIS

Abstract INTRODUCTION Up to 75% of patients with advanced melanoma develop brain metastases. BRAF mutations are found in 50-55% of melanoma brain metastases. Current BRAF/MEK inhibitors, such as dabrafenib and vemurafenib, have shown responses on the order of 50-60% in patients with BRAF-mutant melanoma; however, responses are not durable. Better therapies are needed with improved penetration of the blood brain barrier. This study aims to evaluate the efficacy of two novel brain-penetrant inhibitors, KIN-7136 (MEK inhibitor) and KIN-8391 (RAF inhibitor), in preclinical mouse models of melanoma brain metastases driven by aberrant BRAF-MEK signaling. METHODS CellTiter-Glo® 2.0 Cell Viability Assay (Promega) was used for in vitro cell viability assays. Intracranial A375 melanoma models were generated in athymic nude mice to assess the pharmacodynamics, safety, and efficacy of combination therapy of KIN-7136 and KIN-8391. RESULTS In mice, the brain-to-plasma unbound partition coefficients (Kpuu) of KIN-7136 and KIN-8391 were 0.67 and 0.7 respectively, higher than the comparators binimetinib and belvarafenib, demonstrating improved brain exposure. The IC50s of KIN-7136/ KIN-8391 in melanoma cell lines were 27.0/36.5 nM in A375 (BRAF V600E), 78.6/35.4 nM in HMV2 (BRAF G469V), 183.0/699.0 nM in SK-MEL-2 (NRAS Q61R), and 53.9/110.0 nM in SK-MEL30 (BRAF D287H and E275K), respectively. KIN-7136 and KIN-8391 synergistically inhibited HMV2, SK-MEL-2, and SK-MEL-30 cells. Pharmacodynamic studies showed that both KIN-7136 and KIN-8391 suppressed phospho-ERK, a downstream component of BRAF-MEK signaling, in A375 xenografts in mice. Daily oral treatment with a combination of KIN-7136 and KIN-8391 was well-tolerated and extended overall survival to 64 days (median survival), compared to the vehicle control and monotherapies with KIN-7136 or KIN-8391 (28, 58, and 46.5, respectively) in the A375 intracranial tumor model. CONCLUSION These preclinical data confirm the synergistic effect of KIN-7136 and KIN-8391 in BRAF-mutant melanoma brain metastases models, supporting further research to advance its clinical translation.

CAF Specific Expression of Podoplanin May Be Dispensable for the Malignancy of Malignant Melanoma.

Within the tumor microenvironment (TME), cancer-associated fibroblasts (CAFs) were shown to be an active and pivotal cell population, supporting many protumorigenic mechanisms. Podoplanin (PDPN)-positive CAFs are of special interest since their abundance correlated with a worse prognosis for patients of different cancer entities, including malignant melanoma. In this study, we applied a loss-of-function approach in an in vivo mouse melanoma model to evaluate the contribution of CAF-specific PDPN expression to melanoma formation and progression. Surprisingly, despite its prominent expression in CAFs deletion of PDPN in this cell type did neither affect the onset, nor growth of MM tumors. These data imply that PDPN expression in CAFs represents a biomarker for poor prognosis but does not serve as a useful target for stroma-directed therapy of malignant melanoma.

Intratumoral Injectable Redox-Responsive Immune Niche Improves the Abscopal Effect in Radiotherapy.

Radiotherapy (XRT) is often utilized to improve the immune checkpoint blockade response in cancer management. Such combination treatment can enhance the abscopal effect, facilitating a prolonged and durable systemic response. However, despite intense research efforts, only a minority of patients respond to this approach, and novel strategies to increase the abscopal effect are urgently needed. Here, the development of an intratumoral (i.t.) injectable nanofiber (NF)-based tumor immune niche (TIN) that converts XRT-treated tumors into an in situ cancer vaccine, eliciting robust systemic antitumor immunity, is reported. This NF-based immune niche incorporates redox-degradable anti-CTLA-4 (α-CTLA-4) nanogels (NGs) and interleukin-2 (IL-2) NGs for controlled release in hypoxic irradiated tumors, reversing the immunosuppressive tumor microenvironment into a pro-inflammatory microenvironment, and expanding the tumor-infiltrating CD8+ T cell population. Additionally, it is functionalized with polyinosinic-polycytidylic acid (poly(I:C)) to promote antigen-presenting cell maturation and prime neoantigen-specific CD8+ T cells. In vitro studies demonstrate TIN's ability to prime antigen-specific CD8+ T cells and increase antigen-specific cell-killing efficiency under in vitro immunosuppressive conditions. In vivo studies confirm TIN's ability to elicit robust systemic anticancer activity in mouse melanoma and colorectal cancer models without inducing severe immune-related adverse events.

PHGDH Induction by MAPK is Essential for Melanoma Formation and Creates an Actionable Metabolic Vulnerability.

Overexpression of PHGDH, the rate-limiting enzyme in the serine synthesis pathway, promotes melanomagenesis, melanoma cell proliferation, and survival of metastases in serine-low environments such as the brain. Here, we found that PHGDH is universally increased in melanoma cells and required for melanomagenesis. While PHGDH amplification explained PHGDH overexpression in a subset of melanomas, oncogenic BRAFV600E also promoted PHGDH transcription through mTORC1-mediated translation of ATF4. Importantly, depletion of PHGDH in genetic mouse melanoma models blocked tumor formation. In addition to BRAFV600E-mediated upregulation, PHGDH was further induced by exogenous serine restriction. Surprisingly, BRAFV600E inhibition diminished serine restriction-mediated PHGDH expression by preventing ATF4 induction. Consequently, melanoma cells could be specifically starved of serine by combining BRAFV600E inhibition with exogenous serine restriction, which promoted cell death in vitro and attenuated melanoma growth in vivo. In summary, this study identified that PHGDH is essential for melanomagenesis and regulated by BRAFV600E, revealing a targetable vulnerability in BRAFV600E-mutant melanoma.

Natural diterpene carrier-free hydrogel enhances antigen presentation and intensifies T cell activation for tumor immunotherapy

Although immunotherapy has revolutionized cancer treatment, the low immunogenicity, insufficient T cells intratumoral infiltration and defective antigen presentation in the “cold” tumor microenvironment limit its clinical application. To address this challenge, enlightened by the clinical combined application of antitumor herb medicines, we developed a carrier-free hydrogel KEEM by integrating multiple natural active lipophilic components with manganese ions into a natural co-assembled ternary system. The KEEM hydrogel induced the formation of hydroxyl radicals by Fenton-like reactions, leading to apoptosis, while simultaneously inducing tumor cell ferroptosis through the system xc−-GSH-GPX4 axis. Subsequent release of damage-associated molecular patterns (DAMPs) proved the emergence of immunogenic cell death (ICD). Additionally, manganese ions could directly activate the cGAS-STING pathway, further amplifying the immunostimulatory effects. This synergistic effect promoted dendritic cell maturation thus enhancing antigen presentation, and mediating the change of tumor microenvironment (TME) from “cold” to “hot”. In hepatoma ascites and melanoma models, KEEM combined with immune checkpoint blockade and adoptive T cell therapy respectively demonstrated promising anti-tumor effects in vivo, meanwhile showing excellent biocompatibility and biosafety. Thus, the combination of this multi-diterpenoids carrier-free hydrogel with immunotherapy offers a new strategy for clinical immune-refractory tumor treatment.

Characterization of Human Melanoma Skin Cancer Models: A step towards Model-Based Melanoma Research.

Advancing 3D in vitro human tissue models is crucial for biomedical research and drug development to address the ethical and biological limitations of animal testing. Recently, 3D skin models have proven to be effective for studying serious skin conditions, such as melanoma. For these advanced models to be applicable in preclinical studies, thorough characterization is essential to understand their applicability and limitations. In this study, we used bioimaging and RNA sequencing to assess the architecture and transcriptomic profiles of skin models, including models with melanoma. Our results indicated that these models closely mimicked skin morphology and gene expression patterns. The full-thickness (FT) model shows a superior resemblance to the human skin, particularly in basement membrane formation and cellular interactions. The integrity of the skin-like properties and gene expression signatures of both skin and melanoma cells were preserved upon the integration of melanoma cells, establishing these models as robust platforms for cancer research. The responsiveness of the FT melanoma models to vemurafenib treatment was successfully monitored, demonstrating their validity as a reliable, reproducible, and humane tool for pharmacological testing and drug development. Furthermore, the transcriptomic data showed that skin models with cancer spheroids had upregulated genes linked to aggressive and resilient cancer behavior compared to spheroids alone. This emphasizes the importance of the microenvironment in cancer progression and suggests that 3D skin models can serve to uncover mechanisms and therapeutic targets that are not detectable in simpler systems. STATEMENT OF SIGNIFICANCE: This study introduces advanced, ethically sound skin and melanoma models as alternatives to animal testing in drug discovery. By thoroughly characterizing these models using bioimaging and RNA sequencing, we demonstrate their close resemblance to human skin, particularly in full-thickness models. These models not only replicate the complex cellular interactions and gene expression patterns of human tissue but also maintain robustness after melanoma integration. Our findings highlight the potential of these models in revealing cancer mechanisms and therapeutic targets, offering a significant impact on melanoma research and preclinical testing.

Homeostatic self-MHC-I recognition regulates anti-metastatic function of mature lung natural killer cells

Natural killer (NK) cells are important innate immune effector cells for controlling tumor growth and metastasis. Differentiated mature NK cells preferentially reside in the peripheral tissues and express higher levels of self-major histocompatibility complex class I (MHC-I)-recognizing inhibitory receptors. MHC-I recognition by NK cells are known to be important for their development and maturation processes, however, the role of homeostatic MHC-I recognition in maintaining effector functions of mature NK cells in the peripheral tissues needs to be elucidated. In this study, we utilized a pan anti-MHC-I blocking monoclonal antibody (anti-MHC-I) to examine the role of homeostatic MHC-I recognition in the response of pulmonary mature NK cells in an experimental lung metastasis model of B16F10 melanoma. Anti-MHC-I treatment showed significant inhibition of the lung metastasis of B16F10 melanoma in NK cell- and IFN-γ-dependent mechanisms. The blockade of homeostatic MHC-I recognition increased mature lung NK cell responsiveness, such as direct cytotoxicity and IFN-γ production, rather than the number of lung NK cells. Mechanistically, the gene expression of activating receptors including DNAX accessory molecule-1 (DNAM-1) was upregulated in NK cells treated with anti-MHC-I, and further the enhanced NK cell cytotoxicity against B16F10 cells was DNAM-1-dependent. Collectively, homeostatic self-MHC-I recognition regulates anti-metastatic function of mature lung NK cells by restraining the expression of activating receptors.

Molecular Imaging of Melanoma VEGF-expressing Tumors through [99mTc]Tc-HYNIC-Fab(Bevacizumab).

Angiogenesis is a process that many tumors depend on for growth, development, and metastasis. Vascular endothelial growth factor (VEGF) is one of the major players in tumor angiogenesis in several tumor types, including melanoma. VEGF inhibition is achieved by bevacizumab, a humanized monoclonal antibody that binds with high affinity to VEGF and prevents its function. In order to successfully enable in vivo VEGF expression imaging in a murine melanoma model, we previously labeled bevacizumab with [99mTc]Tc. We observed that this was feasible, but it had prolonged blood circulation and delayed tumor uptake. The aim of this study was to develop a radiolabeled Fab bevacizumab fragment, [99mTc]Tc-HYNICFab( bevacizumab), for non-invasive in vivo VEGF expression molecular imaging. Flow cytometry was used to examine VEGF presence in the murine melanoma cell line (B16-F10). Bevacizumab was digested with papain for six hours at 37°C to produce Fab(bevacizumab), which was then conjugated to NHS-HYNIC-Tfa for radiolabeling with [99mTc]Tc. Stability and binding affinity assays were also evaluated. Biodistribution and single photon emission computed tomography/computed tomography (SPECT/CT) were performed at 1, 3, and 6 h (n = 4) after injection of [99mTc]Tc-HYNIC-Fab(Bevacizumab) in normal and B16-F10 tumor-bearing C57Bl/6J mice. Using flow cytometry, it was shown that the B16-F10 murine melanoma cell line has intracellular VEGF expression. Papain incubation resulted in the complete digestion of bevacizumab with good purity and homogeneity. The radiolabeling yield of [99mTc]Tc-HYNIC-Fab(bevacizumab) was 85.00 ± 6.06%, with a specific activity of 291.87 ± 18.84 MBq/mg (n=3), showing in vitro stability. Binding assays demonstrated significant intracellular in vitro VEGF expression. Fast blood clearance and high kidney and tumor uptake were observed in biodistribution and SPECT/CT studies. We present the development and evaluation of [99mTc]Tc-HYNIC-Fab(bevacizumab), a novel molecular VEGF expression imaging agent that may be used for precision medicine in melanoma and potentially in other VEGF-expressing tumors.

Extracellular vesicles powered cancer immunotherapy: Targeted delivery of adenovirus-based cancer vaccine in humanized melanoma model.

Malignant melanoma, a rapidly spreading form of skin cancer, is becoming more prevalent worldwide. While surgery is successful in treating early-stage melanoma, patients with advanced disease have only a 20% chance of surviving beyond five years. Melanomas with mutations in the NRAS gene are characterized for a more aggressive tumor biology, poorer prognosis and shorter survival. Hence, new therapeutic strategies are needed, especially for this specific group of patients. Novel approaches, such as cancer vaccines, offer promising solutions by stimulating the anti-tumor immune response. Nevertheless, their clinical efficacy is still modest and more effective approaches are required. Herein, we propose the systemic administration of the adenovirus-based cancer vaccine complexed in extracellular vesicles (EVs) with the aim of achieving a targeted therapeutic effect. The vaccine was based on previously tested oncolytic adenovirus Ad5/3-D24-ICOSL-CD40L in combination with melanoma-specific antigens targeting NRAS mutations to enhance the anticancer effect. The antineoplastic properties of the oncolytic vaccine were evaluated in xenograft MUG Mel-2 melanoma BALB/c nude mice. Moreover, to mimic the tumor microenvironment, while investigating at the same time immune cell infiltration and drug penetration, we established a 3D co-culture model based on human NRAS mutated MUG Mel-2 spheroids and PBMCs (HLA matched), which displayed a synergistic effect when treated with the cancer vaccine compared to relative controls. Subsequently, we investigated the systemic delivery of the vaccine in EV formulations in a humanized NSG MUG Mel-2 melanoma mouse model. Our study provides a promising strategy for a tumor-targeted vaccine delivery by EVs, resulting in improved anticancer efficacy and increased infiltration of tumor-infiltrating lymphocytes. This study explores the potential of EVs for the selective delivery of cancer vaccines against malignancies, such as NRAS melanoma. Overall, this research could pave the way for applying autologous EVs as a safe and efficacious tool for targeted cancer therapy.

Synergistic anti-tumor effects of oncolytic virus and anti-programmed cell death protein 1 antibody combination therapy: For suppression of lymph node and distant metastasis in a murine melanoma model

Synergistic anti-tumor effects of oncolytic virus and anti-programmed cell death protein 1 antibody combination therapy: For suppression of lymph node and distant metastasis in a murine melanoma model

Immunotherapy-induced reprogramming of cancer-associated fibroblasts can promote tumor progression.

Use of immune checkpoint inhibitors (ICIs) as cancer immunotherapy has advanced rapidly in the clinic; however, ICI initiation can also cause an unexpectedly rapid acceleration of cancer progression in some patients. Here, we used a murine syngeneic melanoma model to conduct mechanistic analysis of cancer-associated fibroblast (CAF) function in cancer progression in the context of immunotherapy. We found that after ICI treatment CAFs acquire inflammatory properties, which can promote tumor progression. Mechanistically, we show that T-cell-derived interferon-γ (IFN-γ) stimulates production of tumor necrosis factor-α (TNF-α) by macrophages, facilitating CAF conversion to inflammatory CAFs. Our findings suggest that CAF/immune cell crosstalk plays an essential role in ICI-associated tumor progression.

52Mn-labelled Beta-cyclodextrin for Melanoma Imaging: A Proof-of-concept Preclinical Study.

As prostaglandin E2 (PGE2) and its receptors (EP2) are over-expressed on tumor cells and microenvironment, radiolabeled cyclodextrins targeting such biomolecules are valuable vector candidates in molecular cancer diagnostics. Using experimental melanoma models, we evaluated the in vivo imaging behavior of novel Manganese-52-labeled (52Mn) randomly methylated beta-cyclodextrin ([52Mn]Mn-DOTAGA-RAMEB) and compared it with the following well-established tumor-specific probes: melanocortin-1 receptor (MC1-R)-affine [68Ga]Ga-DOTA-NAPamide and PGE2 selective [68Ga]Ga-DOTAGA-RAMEB cyclodextrin. Post-injection of [68Ga]Ga-DOTA-NAPamide, [68Ga]Ga-DOTAGA-RAMEB, and [52Mn]Mn-DOTAGA-RAMEB into MC1-R positive B16F10 melanoma-bearing mice, tumor radio-pharmaceutical uptake was quantified in vivo and ex vivo using preclinical positron emission tomography (PET) and high-performance gamma counter. Although all tracers performed well in tumor identification, the highest standardized uptake values were detected in the [68Ga]Ga-DOTA-NAPamide scans. Corresponding to the ex vivo data, meaningful [52Mn]Mn-DOTAGA-RAMEB accumulation 1 h post-injection confirmed the tumor-targeting potential of the tracer. Temporal changes in PGE2/EP2 expression of the neoplasms may explain the significant differences observed between the tumor uptake of the two cyclodextrin probes and that of the 52Mn-labelled compound measured 1 h, 4 h, and 3 days post-injection (p≤0.01, p≤0.05). Although further pharmacokinetical optimization may be required, 52Mn-labelled cyclodextrin holds potential in melanoma diagnostics and the PET-based longitudinal assessment of tumor-associated PGE2/EP2 expression.