Anticancer Immune Response Research Articles

Exosomes as carriers to stimulate an anti-cancer immune response in immunotherapy and as predictive markers.

During this era of rapid advancements in cancer immunotherapy, the application of cell-released small vesicles that activate the immune system is of considerable interest. Exosomes are cell-derived nanovesicles that show great promise for the immunological treatment of cancer because of their immunogenicity and molecular transfer capacity. Recent technological advancements have enabled the identification of functional functions that exosome cargoes perform in controlling immune responses. Exosomes are originated specifically from immune cells and tumor cells and they show unique composition patterns directly related to the immunotherapy against cancer. Exosomes can also deliver their cargo to particular cells, which can affect the phenotypic and immune-regulatory functions of those cells. Exosomes can influence the course of cancer and have therapeutic benefits by taking part in several cellular processes; as a result, they have the dual properties of activating and restraining cancer. Exosomes have tremendous potential for cancer immunotherapy; they may develop into the most powerful cancer vaccines and carriers of targeted antigens and drugs. Comprehending the potential applications of exosomes in immune therapy is significant for regulating cancer progression. This review offers an analysis of the function of exosomes in immunotherapy, specifically as carriers that function as diagnostic indicators for immunological activation and trigger an anti-cancer immune response. Moreover, it summarizes the fundamental mechanism and possible therapeutic applications of exosome-based immunotherapy for human cancer.

Combined delivery of IL12 and an IL18 mutant without IL18BP-binding activity by an adenoviral vector enhances tumor specific immunity

Cytokines play pivotal roles in anticancer immune response. We previously reported that adenovirus armed with an IL18 variant (DR18) that overcomes IL18BP neutralizing effect displayed powerful therapeutic effects in local and distant tumors when delivered intratumorally. Here, we tested a combined delivery of IL12 and DR18 in tumor models since IL12 and IL18 are known to act synergistically in potentiating IFNγ production and antitumor immunity. To minimize adverse effects associated with systemic delivery, we constructed oncolytic adenoviruses (oAd) harboring DR18 and IL12 (oAd.DR18/IL12). IL12 was expressed as a single chain IL12 (scIL12) peptide composed of the IL12/p40 and IL12/p35 subunits. Intratumoral administration of oAd.DR18/IL12, oAd-expressing DR18 (oAd.DR18), or oAd-expressing IL12 (oAd.IL12) showed antitumor effect in syngeneic colorectal tumor models. Compared to oAd.DR18 or oAd.IL12, administration of oAd.DR18/IL12 improved the antitumor effects as well as increased survival rate in these models. We detected enhanced tumor infiltrating T lymphocytes and NK cells in oAd.DR18/IL12-treated mice than those from mock-treated or individually treated groups. Moreover, mice received oAd.DR18/IL12 had more robust tumor-specific cytotoxicity. Importantly, mice that had tumor regression after oAd.DR18/IL12 treatment established anti-tumor specific immune memory. These results show that adenovirus armed with engineered cytokines boosts tumor specific immunity and antitumor effect.

The Detection of Lung Cancer Cell Profiles in Mediastinal Lymph Nodes Using a Hematological Analyzer and Flow Cytometry Method

The presence of metastases in mediastinal lymph nodes (LNs) is essential for planning lung cancer treatment and assessing anticancer immune responses. The aim of the study was to assess LNs for the presence of neoplastic cells and evaluate lung cancer-selected antigen expression. LN aspirates were obtained during an EBUS/TBNA procedure. The cells were analyzed using a hematological analyzer and flow cytometry. It was possible to indicate the presence of cells characterized by high fluorescence connected with high metabolic activity using a hematological analyzer and to determine their non-hematopoietic origin using flow cytometry. Using these methods together, we detected very quickly a high proportion of cancer cells in LNs. We noticed that it was possible to determine a high expression of EpCAM, TTF-1, Ki67, cytokeratin, HER, and differences between non-small-cell (NSCLC) and small-cell lung cancer (SCLC) for the antigens MUC-1, CD56, HLA-DR, CD39, CD184, PD-L1, PD-L2 and CTLA-4 on tumor cells. We report, for the first time, that the detection of tumor cells in LNs with the expression of specific antigens is easy to evaluate using a hematological analyzer and flow cytometry in EBUS/TBNA samples. Such precise characteristics of non-hematopoietic cells in LNs may be of great diagnostic importance in the detection of micrometastases.

An Iron‐Polyphenol Decorated siRNA‐Encapsulated Nanomedicine Multifacetedly Promoted Macrophage Phagocytosis for Synergistic Ferroptosis‐Immunotherapy

AbstractMacrophages are vital components of the innate immune system, capable of directly engulfing tumor cells. However, tumor cells can cunningly evade recognition and phagocytosis by macrophages. In light of this, an iron‐polyphenol‐decorated poly(ethylene glycol)‐poly(lactic‐co‐glycolic acid (PEG‐PLGA) nanoparticle has been developed with efficient siRNA encapsulation (NPsiCD47@Fe‐TA) to trigger the ferroptosis in tumor cell and also elicit the macrophage‐mediated immunotherapy. The Fe‐TA (Tannic acid) shell of NPsiCD47@Fe‐TA induces the ferroptosis in tumor cell, which consequently produces oxygenated phosphatidylethanolamine 1‐steaoryl‐2‐15‐HpETE‐sn‐glycero‐3‐phosphatidylethanolamine (SAPE‐OOH) in the cell membrane and achieve the surface exposure of calreticulin (CRT). Meanwhile, the encapsulated siCD47 of NPsiCD47@Fe‐TA efficiently down‐regulates the CD47 receptor in the tumor cell membrane. The exposure of SAPE‐OOH and CRT in the cell membrane and down‐regulation of CD47 receptor remarkably promoted the phagocytosis of tumor cells by macrophage and elicited the systemic anticancer immune response. Eventually, the NPsiCD47@Fe‐TA can efficiently suppress the tumor growth. Moreover, after combination with immune checkpoint blockade (ICB) antibody, NPsiCD47@Fe‐TA remarkably inhibits tumor progress and metastasis in the cold triple‐negative 4T1 breast cancer model.

Cathepsins: Novel opportunities for antibody therapeutics in cancer.

Cathepsins, the most abundant lysosomal proteases, have key functions in cell maintenance and homeostasis. They are overexpressed and hypersecreted in cancer and associated with poor prognosis. Secreted cathepsins display pro-tumour activities in the tumour microenvironment and thus represent interesting molecular targets in oncology. Recently, several antibody-based cancer therapies have targeted the pro-tumour activity of the extracellular cathepsin pool, altering several cancer hallmarks, but not the intracellular cathepsin levels that are often crucial for cell homeostasis. In this mini-review, we describe advances in antibodies against extracellular cathepsins in cancer, and their effect on the proteolytic cascade, matrix remodelling, proliferation, and modulation of the anti-cancer immune response. We also discuss the add-on value of combination strategies (anti-cathepsin antibodies with chemotherapy and/or biologics) that make anti-cathepsin antibodies a new opportunity for disease management.

Efficacy of Anti-Cancer Immune Responses Elicited Using Tumor-Targeted IL-2 Cytokine and Its Derivatives in Combined Preclinical Therapies.

Effective cancer therapies must address the tumor microenvironment (TME), a complex network of tumor cells and stromal components, including endothelial, immune, and mesenchymal cells. Durable outcomes require targeting both tumor cells and the TME while minimizing systemic toxicity. Interleukin-2 (IL-2)-based therapies have shown efficacy in cancers such as metastatic melanoma and renal cell carcinoma but are limited by severe side effects. Innovative IL-2-based immunotherapeutic approaches include immunotoxins, such as antibody-drug conjugates, immunocytokines, and antibody-cytokine fusion proteins that enhance tumor-specific delivery. These strategies activate cytotoxic CD8+ T lymphocytes and natural killer (NK) cells, eliciting a potent Th1-mediated anti-tumor response. Modified IL-2 variants with reduced Treg cell activity further improve specificity and reduce immunosuppression. Additionally, IL-2 conjugates with peptides or anti-angiogenic agents offer improved therapeutic profiles. Combining IL-2-based therapies with immune checkpoint inhibitors (ICIs), anti-angiogenic agents, or radiotherapy has demonstrated synergistic potential. Preclinical and clinical studies highlight reduced toxicity and enhanced anti-tumor efficacy, overcoming TME-driven immune suppression. These approaches mitigate the limitations of high-dose soluble IL-2 therapy, promoting immune activation and minimizing adverse effects. This review critically explores advances in IL-2-based therapies, focusing on immunotoxins, immunocytokines, and IL-2 derivatives. Emphasis is placed on their role in combination strategies, showcasing their potential to target the TME and improve clinical outcomes effectively. Also, the use of IL-2 immunocytokines in "in situ" vaccination to relieve the immunosuppression of the TME is discussed.

Immune Biomarkers on Tissue Microarray Cores Support the Presence of Adjacent Tertiary Lymphoid Structures in Soft Tissue Sarcoma.

Immunotherapy has emerged as a new treatment modality in some soft tissue sarcomas, particularly for tumors associated with tertiary lymphoid structures (TLS). These structures are functional lymphoid aggregates, and their presence is indicative of an active anticancer immune response in the tumor microenvironment. The assessment of TLS as a predictive biomarker at scale on patient specimens remains challenging. While tissue microarrays could facilitate this assessment, it is unclear whether small microarray cores can represent and identify associated TLS responses. We sought to use multiplex immunohistochemistry to identify key components of TLS: T cells, B cells, and dendritic cells. The multiplex panels (CD3, CD20, CD208 and PNAd) were applied onto 80 cases both on tissue microarrays and on their cognate available full-faced sections from epithelioid sarcoma and dedifferentiated/well-differentiated liposarcoma case series. Tissue microarrays were digitally scored for the number of immune cells using the HALO image analysis platform, and cognate full-faced sections were visually evaluated for the presence of TLS. An independent validation set of soft tissue sarcomas (N=49) was stained with the CD3, CD20, and CD208, and scored by QuPath. A Combined Immune Marker (defined as the presence of more than more than 24% CD3+T cell, or 0.51% CD20+B cell, or more than 0.14% CD208+mature dendritic cell on tissue microarray core) is highly specific (100%) and moderately sensitive (61%) to predict the existence of TLS on full-faced sections. The Combined Immune Marker showed a sensitivity of 25% and specificity of 91% on the validation set. The Combined Immune Marker assessed on tissue microarrays is highly specific to infer the presence of TLS present on cognate full-faced sections. Therefore, despite the small area sampled, tissue microarrays may be utilized to assess the clinical value of TLS on datasets where specificity is critical and large sample size can mitigate low to moderate sensitivity.

Antagonists of CD39 and CD73 potentiate doxycycline repositioning to induce a potent antitumor immune response.

Studies have reported that cellular metabolism at the tumor-immune microenvironment (TiME) serves as a critical checkpoint and perturbs/supports anti-cancer immunity. Extra cellular ATP (eATP) may mediate anti-cancer immune response; however, its catabolism by ectonucleotidase generates immunosuppressive adenosine. In the presented work, we have tried to repurpose doxycycline with or without an antagonist of ectonucleotidase for mitigating ATP metabolism and immunosuppression. In this methodology eATP and adenosine levels were quantified. Bone marrow-derived M1 and M2 polarized macrophages were maintained in tumor mimicking condition (TMC). Total/CD4+Tcells were co-cultured with macrophages to understand the impact of doxycycline and/or antagonist of ectonucleotidase on T cell/subset differentiation. Preclinical efficacy of doxycycline and/or ectonucleotidase antagonist and their synergy was scored in 4 T1-induced breast carcinoma. We found that Doxycycline manipulated macrophage polarization by decreasing the frequency of CD206+M2 macrophages, which resulted in enhanced CD4+ directed CD8+ T cell response. Doxycycline alleviated the expression of CD39 and CD73, rescuing ATP catabolism. Doxycycline delayed tumor growth by enhancing F4/80+ CD86+ M1 macrophages and subsequently anti-tumor Tbet+ CD4+Tcells, attenuating the frequency of FOXP3+ regulatory T cells, which was cooperatively supported by ARL67156 and AMPCP (CD39 and CD73 antagonist).A synergy was observed with ARL67156 and AMPC Pensuring a possibility of using doxycycline alone or in combination with an antagonist of ectonucleotidase to present adenosine-mediated immunosuppression. Subsequently, our finding indicated that prospective usage of doxycycline as a novel metabolic checkpoint blocker (IMB) against ectonucleotidase and may be modified/delivered appropriately as a monotherapy or in combination with antagonists of ectonucleotidases as an IMB.

Role of immune-checkpoint LAG3 as a biomarker finding tool in patient-derived organoid cultures of breast cancer

LAG3 plays a regulatory role in immunity and emerged as an inhibitory immune checkpoint molecule comparable to PD-L1 and CTLA-4 and a potential target for enhancing anti-cancer immune responses. We generated 3D cancer cultures as a model to identify novel molecular biomarkers for the selection of patients suitable for α-LAG3 treatment and simultaneously the possibility to perform an early diagnosis due to its higher presence in breast cancer, also to achieve a theragnostic approach. Our data confirm the extreme dysregulation of LAG3 in breast cancer with significantly higher expression in tumor tissue specimens, compared to non-cancerous tissue controls. LAG3 blockade inhibited proliferation of in vitro and ex vivo 3D human organoids and immune micro-environment through both a decrease of PD-L1, TIM-3 and CTLA4 expression and an increased production of several pro-inflammatory cytokines (IFNγ, IL-12, IL-6, IL-1β, TNFα) and EMT markers. These effects trigger a more permissive anti-tumor immune reaction, recruiting immune cells to the tumor sites, boosting the anti-tumor response. LAG3 acts as an immunosuppressive molecule in breast cancer, inhibiting T CD8 + cell proliferation and cytokine production by T cells. We proposed the modulation of a novel checkpoint molecule, such as LAG3, as potential biomarkers associated to a rapid diagnosis.

Modification of Fc-fusion protein structures to enhance efficacy of cancer vaccine in plant expression system.

Epithelial cell adhesion molecule (EpCAM) fused to IgG, IgA and IgM Fc domains was expressed to create IgG, IgA and IgM-like structures as anti-cancer vaccines in Nicotiana tabacum. High-mannose glycan structures were generated by adding a C-terminal endoplasmic reticulum (ER) retention motif (KDEL) to the Fc domain (FcK) to produce EpCAM-Fc and EpCAM-FcK proteins in transgenic plants via Agrobacterium-mediated transformation. Cross-fertilization of EpCAM-Fc (FcK) transgenic plants with Joining chain (J-chain, J and JK) transgenic plants led to stable expression of large quaternary EpCAM-IgA Fc (EpCAM-A) and IgM-like (EpCAM-M) proteins. Immunoblotting, SDS-PAGE and ELISA analyses demonstrated that proteins with KDEL had higher expression levels and binding activity to anti-EpCAM IgGs. IgM showed the strongest binding among the fusion proteins, followed by IgA and IgG. Sera from BALB/c mice immunized with these vaccines produced anti-EpCAM IgGs. Flow cytometry indicated that the EpCAM-Fc fusion proteins significantly activated CD8+ cytotoxic Tcells, CD4+ helper Tcells and B cells, particularly with EpCAM-FcKP and EpCAM-FcP (FcKP) × JP (JKP). The induced anti-EpCAM IgGs captured human prostate cancer PC-3 and colorectal cancer SW620 cells. Sera from immunized mice inhibited cancer cell proliferation, migration and invasion; down-regulated proliferation markers (PCNA, Ki-67) and epithelial-mesenchymal transition markers (Vimentin); and up-regulated E-cadherin. These findings suggest that N. tabacum can produce effective vaccine candidates to induce anti-cancer immune responses.

The C5a/C5aR1 axis promotes migration of tolerogenic dendritic cells to lymph nodes, impairing the anticancer immune response.

The precise mechanisms by which the complement system contributes to the establishment of an immunosuppressive tumor microenvironment (TME) and promotes tumor progression remain unclear. In this study, we investigated the expression and function of complement C5a receptor 1 (C5aR1) in human and mouse cancer-associated dendritic cells (DCs). First, we observed an overexpression of C5aR1 in tumor-infiltrating DCs, compared to DCs from blood or spleen. C5aR1 expression was restricted to type 2 conventional DCs (cDC2) and monocyte-derived DCs (moDCs), which displayed a tolerogenic phenotype capable of inhibiting T-cell activation and promoting tumor growth. C5aR1 engagement in DCs drove their migration from tumors to tumor-draining lymph nodes, where C5a levels were higher. We used this knowledge to optimize an anticancer therapy aimed at enhancing DC activity. In three syngeneic tumor models, C5aR1 inhibition significantly enhanced the efficacy of poly I:C, a Toll-like receptor 3 (TLR3) agonist, in combination with PD-1/PD-L1 blockade. The contribution of C5aR1 inhibition to the antitumor activity of the combination treatment relied on type 1 conventional DCs (cDC1s) and antigen-specific CD8+ T cells, required lymphocyte egress from secondary lymphoid organs, and was associated with an increase in interferon gamma (IFNγ) signaling. In conclusion, our study highlights the importance of the C5a/C5aR1 axis in the biology of cancer-associated DCs and provides compelling evidence for the therapeutic potential of modulating the complement system to enhance DC-mediated immune responses against tumors.

Biochemical and cellular mechanisms of immunogenic cell death

Immunogenic cell death (ICD) is a mode of programmed cell death that leads to the activation of anticancer immune response and determines the long-term success of anticancer therapies. Here, we provide a review of the known molecular and cellular mechanisms of ICD. Usually, solid tumor experimental models have been used in ICD studies. However, ascites tumor models may possess some advantages over them. The results of our investigation on the approbation of murine Nemeth-Kellner lymphoma as an experimental ascites tumor model for ICD studies are presented. Keywords: ascites tumor model, biochemical mechanisms, doxorubicin, immunogenic cell death, murine Nemeth-Kellner lymphoma, oxaliplatin

Targeting EZH2 in Cancer: Mechanisms, Pathways, and Therapeutic Potential.

Enhancer of zeste homolog 2 (EZH2) is a methyltransferase involved in cell cycle regulation, cell differentiation, and cell death and plays a role in modulating the immune response. Although it mainly functions by catalyzing the tri-methylation of H3 histone on K27 (H3K27), to inhibit the transcription of target genes, EZH2 can directly methylate several transcription factors or form complexes with them, regulating their functions. EZH2 expression/activity is often dysregulated in cancer, contributing to carcinogenesis and immune escape, thereby representing an important target in anti-cancer therapy. This review summarizes some of the mechanisms through which EZH2 regulates the expression and function of tumor suppressor genes and oncogenic molecules such as STAT3, mutant p53, and c-Myc and how it modulates the anti-cancer immune response. The influence of posttranslational modifications on EZH2 activity and stability and the possible strategies leading to its inhibition are also reviewed.

Leucine zipper-based SAIM imaging identifies therapeutic agents to disrupt the cancer cell glycocalyx for enhanced immunotherapy.

The abnormally thick glycocalyx of cancer cells can provide a physical barrier to immune cell recognition and effective immunotherapy. Here, we demonstrate an optical method based on Scanning Angle Interference Microscopy (SAIM) for the screening of therapeutic agents that can disrupt the glycocalyx layer as a strategy to improve anti-cancer immune responses. We developed a new membrane labeling strategy utilizing leucine zipper pairs to fluorescently mark the glycocalyx layer boundary for precise and robust measurement of glycocalyx thickness with SAIM. Using this platform, we evaluated the effects of glycosylation inhibitors and targeted enzymatic degraders of the glycocalyx, with particular focus on strategies for cholangiocarcinoma (CCA), a highly lethal malignancy with limited therapeutic options. We found that CCA had the highest mean expression of the cancer-associated mucin, MUC1, across all cancers represented in the cancer cell line encyclopedia. Pharmacological inhibitors of mucin-type O-glycosylation and mucin-specific proteases, such as StcE, could dramatically reduce the glycocalyx layer in the YSCCC model of intrahepatic CCA. Motivated by these findings, we engineered Natural Killer (NK) cells tethered with StcE to enhance NK cell-mediated cytotoxicity against CCA. In a CCA xenograft model, these engineered NK cells demonstrated superior anti-tumor efficacy compared to wild-type NK cells, with no observable adverse effects. Our findings not only provide a reliable imaging-based screening platform for evaluating glycocalyx-targeting pharmacological interventions but also offer mechanistic insights into how CCA may avoid immune elimination through fortification of the glycocalyx layer with mucins. Additionally, this work presents a novel therapeutic strategy for mucin-overexpressing cancers, potentially improving immunotherapy efficacy across various cancer types.

Expression of Concern: Restoring Anticancer Immune Response by Targeting Tumor-Derived Exosomes With a HSP70 Peptide Aptamer.

Expression of Concern: Restoring Anticancer Immune Response by Targeting Tumor-Derived Exosomes With a HSP70 Peptide Aptamer.

Opposing effects of mycotoxins alternariol and deoxynivalenol on the immunomodulatory effects of oxaliplatin and triapine.

Mycotoxin occurrence in food worldwide is estimated to increase due to climate change. Moreover, studies on how these food contaminants interfere with medications and especially anticancer therapies are rare. With the rise of anticancer immunotherapies, particularly mycotoxins with immunomodulatory activity, such as alternariol (AOH) or deoxynivalenol (DON), are of great concern. Both mycotoxins interfere with the pro-inflammatory nuclear factor kappa B (NF-κB) pathway in myeloid cells. This pathway not only plays an important role in the anticancer immune response but also inflammatory side effects induced by chemotherapeutic drugs. Consequently, the aim of this study was to investigate possible beneficial or detrimental immunomodulatory interactions between these mycotoxins and anticancer drugs. To assess the combined influence of mycotoxins and anticancer therapies on immune cell stimulation, THP-1 NF-κB reporter cells were utilized as monocytes as well as differentiated and polarized macrophages. Parameters for activation (NF-κB activity and protein expression), differentiation (CD14 and CD71 surface marker expression) and polarization (interleukin 10 (IL10), interleukin 8 (CXCL8), tumor necrosis factor α (TNF), prostaglandin-endoperoxide synthase 2 expression and CXCL8 secretion) were assessed upon combinatory treatment. Both mycotoxins affected the immunostimulatory effects of the pre-selected anticancer drugs oxaliplatin and triapine, although in opposing directions. While AOH generally suppressed a drug-induced activation and increased anti-inflammatory IL10 levels, DON potentiated activation and pro-inflammatory markers, such as CXCL8 and TNF in immune cells. In conclusion, AOH and DON have the potential to alter the immunological effects of anticancer therapies, which should be considered during therapy as well as in their future risk assessment.

Setdb1-loss induces type-I interferons and immune clearance of melanoma.

Despite recent advances in the treatment of melanoma, many patients with metastatic disease still succumb to their disease. To identify tumor-intrinsic modulators of immunity to melanoma, we performed a whole-genome CRISPR screen in melanoma and identified Setdb1 as well as all components of the HUSH complex. We found that loss of Setdb1 leads to increased immunogenicity and complete tumor clearance in a CD8+ T-cell dependent manner. Mechanistically, loss of Setdb1 causes de-repression of endogenous retroviruses (ERVs) in melanoma cells and triggers tumor-cell intrinsic type-I interferon signaling, upregulation of MHC-I expression, and increased CD8+ T-cell infiltration. Importantly, spontaneous immune clearance observed in Setdb1-/- tumors results in subsequent protection from other ERV-expressing tumor lines, supporting the functional anti-tumor role of ERV-specific CD8+ T-cells found in the Setdb1-/- microenvironment. Blocking the type-I interferon receptor in mice grafted with Setdb1-/- tumors decreases immunogenicity by decreasing MHC-I expression, leading to decreased T-cell infiltration and increased melanoma growth, comparable to Setdb1wt tumors. Together, these results provide key in vivo evidence of a critical role for Setdb1 and type-I interferons in generating an inflamed tumor microenvironment, and potentiating tumor-cell intrinsic immunogenicity in melanoma. This study further emphasizes regulators of ERV expression and type-I interferon expression as potential therapeutic targets for augmenting anti-cancer immune responses.

Peptide Antigen‐Surfaced TLR9‐Adjuvanting Nanovaccines as a Versatile Therapeutic Modality to Eradicate Acute Myeloid Leukemia

AbstractPeptide antigen vaccines constitute a promising clinical strategy for treating cancer patients. However, their anticancer immune response remains modest because of the suboptimal presentation of peptide antigens and/or insufficient activation of antigen‐presenting cells (APCs). The development of therapeutic vaccines for acute myeloid leukemia (AML) poses an even greater challenge because AML cells disseminate throughout the body. In this study, the peptide antigen‐surfaced TLR9‐adjuvanting nanovaccines (PASTA‐NV), which display multiple Wilm's tumor 1 (WT1) peptides on their surface and encapsulate CpG ODN adjuvants within their watery interior to simultaneously increase antigen presentation and APC activation/proliferation, are reported. Interestingly, systemic administration of PASTA‐NV induces strong cellular and humoral anticancer immune responses in orthotopic murine AML MLL‐AF9 models. When combined with an anti‐CTLA4 antibody, PASTA‐NV achieves complete regression of AML in mouse models and establishes durable anti‐AML immunity, effectively resisting rechallenge with leukemic cells. PASTA‐NV provides a new and general avenue to induce robust and specific anticancer immunity, which has the potential to revive peptide antigen‐based nanovaccines for tumor therapy.

Multifaceted Aspects of Dysfunctional Myelopoiesis in Cancer and Therapeutic Perspectives with Focus on HCC.

Myelopoiesis provides for the formation and continued renewal of cells belonging primarily to the innate immune system. It is a highly plastic process that secures the response to external and internal stimuli to face acute and changing needs. Infections and chronic diseases including cancer can modulate it by producing several factors, impacting proliferation and differentiation programs. While the lymphocytic compartment has attracted major attention due to the role of adaptive immunity in anticancer immune response, in recent years, research has found convincing evidence that confirms the importance of innate immunity and the key function played by emergency myelopoiesis. Due to cancer's ability to manipulate myelopoiesis to its own advantage, the purpose of this review is to outline myelopoiesis processes within the tumor microenvironment and suggest possible therapeutic lines of research to restore the physiological functioning of the host's immune system, with a special outlook on hepatocellular carcinoma (HCC).

Structural characterization and AlphaFold modeling of human T cell receptor recognition of NRAS cancer neoantigens.

T cell receptors (TCRs) that recognize cancer neoantigens are important for anticancer immune responses and immunotherapy. Understanding the structural basis of TCR recognition of neoantigens provides insights into their exquisite specificity and can enable design of optimized TCRs. We determined crystal structures of a human TCR in complex with NRAS Q61K and Q61R neoantigen peptides and HLA-A1 major histocompatibility complex (MHC), revealing the molecular underpinnings for dual recognition and specificity versus wild-type NRAS peptide. We then used multiple versions of AlphaFold to model the corresponding complex structures, given the challenge of immune recognition for such methods. One implementation of AlphaFold2 (TCRmodel2) with additional sampling was able to generate accurate models of the complexes, while AlphaFold3 also showed strong performance, although success was lower for other complexes. This study provides insights into TCR recognition of a shared cancer neoantigen as well as the utility and practical considerations for using AlphaFold to model TCR-peptide-MHC complexes.