Antigen Recognition Research Articles

Vaccine-induced human monoclonal antibodies to PfRH5 show broadly neutralizing activity against P. falciparum clinical isolates

Vaccines to the Plasmodium falciparum reticulocyte binding-like protein homologue 5 (PfRH5) target the blood-stage of the parasite life cycle. PfRH5 has the potential to trigger the production of strain-transcendent antibodies and has proven its efficacy both in pre-clinical and early clinical studies. Vaccine-induced monoclonal antibodies (mAbs) to PfRH5 showed promising outcomes against cultured P. falciparum laboratory strains from distinct geographic areas. Here, we assessed the functional impact of vaccine-induced anti-PfRH5 mAbs on more genetically diverse P. falciparum clinical isolates. We used mAbs previously isolated from single B cells of UK adult PfRH5 vaccinees and used ex-vivo growth inhibition activity (GIA) assays to assess their efficacy against P. falciparum clinical isolates. Next-generation sequencing (NGS) was used to assess the breadth of genetic diversity in P. falciparum clinical isolates and to infer the genotype/phenotype relationship involved in antibody susceptibility. We showed a dose-dependent inhibition of clinical isolates with three main GIA groups: high, medium and low. Except for one isolate, our data show no significant differences in the mAb GIA profile between P. falciparum clinical isolates and the 3D7 reference strain, which harbors the vaccine allele. We also observed an additive relationship for mAb combinations, whereby the combination of GIA-low and GIA-medium antibodies resulted in increased GIA, having important implications for the contribution of specific clones within polyclonal IgG responses. While our NGS analysis showed the occurrence of novel mutations in the pfrh5 gene, these mutations were predicted to have little or no functional impact on the antigen structure or recognition by known mAbs. Our present findings complement earlier reports on the strain transcendent potential of anti-PfRH5 mAbs and constitute, to our knowledge, the first report on the susceptibility of P. falciparum clinical isolates from natural infections to vaccine-induced human mAbs to PfRH5.

Epitope-anchored contrastive transfer learning for paired CD8+ T cell receptor–antigen recognition

Epitope-anchored contrastive transfer learning for paired CD8+ T cell receptor–antigen recognition

Bibliometric analysis of chimeric antigen receptor T-cell therapy

Objective: Chimeric antigen receptor T-cell (CAR-T) therapy refers to the genetic material with specific antigen recognition domain and T cell activation signal is transferred into T cells through gene modification technology. By engineering T-cells to specifically target and eliminate tumor cells, CAR-T therapy has shown remarkable efficacy in treating certain hematological malignancies. Understanding its advancements helps optimize therapeutic strategies, enhance patient outcomes, and guide future innovations in immunotherapy. Therefore, this study aims to investigate the progress of CAR-T therapy by bibliometrics. Methods: By using the keywords of “CAR-T therapy” and “immune cells”, all relevant literature were comprehensively searched from the Web of Science. Research trends in related field were analyzed by using VOSviewer, Pajek, Microsoft Excel and Endnote software, to explore research hotspots, development trends, and future directions for CAR-T therapy. Results: The United States emerges as the most productive country in related field, and the institutions with the highest number of publications is the University of Pennsylvania. As for journals, Frontiers in Immunology appears to be one of the most productive journals. Notably, Gottschalk Stephen publishes the largest number of articles. Keyword cluster analysis shows that the current research trend is more focused on immune cell, so as to explore the mechanisms and modalities of CAR-T therapy. Conclusion: This study provides a comprehensive summary and analysis of global research trends in CAR-T therapy. In the past 5 years, the number of high-quality papers in this field has increased significantly. CAR-T therapy has emerged as a beacon of hope for tumor treatment, representing a significant advancement in healthcare for a wide range of patients, including those with major diseases and suboptimal health conditions.

SLAMF7 (CD319) on activated CD8+ T cells transduces environmental cues to initiate cytotoxic effector cell responses.

CD8+ T-cell responses are meticulously orchestrated processes regulated by intercellular receptor:ligand interactions. These interactions critically control the dynamics of CD8+ T-cell populations that is crucial to overcome threats such as viral infections or cancer. Yet, the mechanisms governing these dynamics remain incompletely elucidated. Here, we identified a hitherto unknown T-cell referred function of the self-ligating surface receptor SLAMF7 (CD319) on CD8+ T cells during initiation of cytotoxic T-cell responses. According to its cytotoxicity related expression on T effector cells, we found that CD8+ T cells could utilize SLAMF7 to transduce environmental cues into cellular interactions and information exchange. Indeed, SLAMF7 facilitated a dose-dependent formation of stable homotypic contacts that ultimately resulted in stable cell-contacts, quorum populations and commitment to expansion and differentiation. Using pull-down assays and network analyses, we identified novel SLAMF7-binding intracellular signaling molecules including the CRK, CRKL, and Nck adaptors, which are involved in T-cell contact formation and may mediate SLAMF7 functions in sensing and adhesion. Hence, providing SLAMF7 signals during antigen recognition of CD8+ T cells enhanced their overall magnitude, particularly in responses towards low-affinity antigens, resulting in a significant boost in their proliferation and cytotoxic capacity. Overall, we have identified and characterized a potent initiator of the cytotoxic T lymphocyte response program and revealed advanced mechanisms to improve CD8+ T-cell response decisions against weak viral or tumor-associated antigens, thereby strengthening our defense against such adversaries.

Direct Mapping of Polyclonal Epitopes in Serum by HDX-MS.

Elucidating the interactions that drive antigen recognition is central to understanding antibody-mediated protection and is vital for the rational design of immunogens. Often, structural knowledge of epitopes targeted by antibodies is derived from isolated studies of monoclonal antibodies, for which numerous structural techniques exist. In contrast, there are very few approaches capable of mapping the full scope of antigen surfaces targeted by polyclonal sera through the course of a natural antibody response. Here, we develop an approach using immobilized antigen coupled to hydrogen/deuterium exchange with mass spectrometry (HDX-MS) to probe epitope targeting in the context of the fully native serum environment. Using the well-characterized Staphylococcal enterotoxin B (SEB) as a model system, we show that complex combinations of epitopes can be detected and subtle differences across different antisera can be discerned. This work reveals new insight into how neutralizing antibodies and antisera target SEB and, more importantly, establishes a novel method for directly mapping the epitope landscape of polyclonal sera.

Mannose and Lactobionic Acid in Nasal Vaccination: Enhancing Antigen Delivery via C-Type Lectin Receptors.

Nasal vaccines are a promising strategy for enhancing mucosal immune responses and preventing diseases at mucosal sites by stimulating the secretion of secretory IgA, which is crucial for early pathogen neutralization. However, designing effective nasal vaccines is challenging due to the complex immunological mechanisms in the nasal mucosa, which must balance protection and tolerance against constant exposure to inhaled pathogens. The nasal route also presents unique formulation and delivery hurdles, such as the mucous layer hindering antigen penetration and immune cell access. This review focuses on cutting-edge approaches to enhance nasal vaccine delivery, particularly those targeting C-type lectin receptors (CLRs) like the mannose receptor and macrophage galactose-type lectin (MGL) receptor. It elucidates the roles of these receptors in antigen recognition and uptake by antigen-presenting cells (APCs), providing insights into optimizing vaccine delivery. While a comprehensive examination of targeted glycoconjugate vaccine development is outside the scope of this study, we provide key examples of glycan-based ligands, such as lactobionic acid and mannose, which can selectively target CLRs in the nasal mucosa. With the rise of new viral infections, this review aims to facilitate the design of innovative vaccines and equip researchers, clinicians, and vaccine developers with the knowledge to enhance immune defenses against respiratory pathogens, ultimately protecting public health.

Evaluation of immune sensor responses to a viral small noncoding RNA.

Gammaherpesviruses are widespread pathogens causing persistent infections linked to the development of numerous types of lymphomas in humans. During latency, most of the viral protein-coding genes are suppressed, facilitating evasion of adaptive immune recognition of protein antigens. In contrast, many noncoding RNA (ncRNA) molecules are expressed in infected cells and can regulate key cellular pathways while simultaneously evading adaptive immune recognition. To counteract this, many cells express internal pattern recognition receptors that can intrinsically sense ongoing infections and initiate cellular defenses. Murine gammaherpesvirus 68 (MHV68) is a valuable model to study in vivo aspects of gammaherpesvirus pathogenesis. The MHV68 ncRNA TMER4 (tRNA-miRNA-encoding RNA 4) promotes lymph node egress of infected B cells: in the absence of TMER4, MHV68-infected B cells accumulate in the lymph node in a manner similar to B cells activated through specific antigen encounter. We hypothesized that TMER4 may alter intrinsic immune activation. In research described here, we aimed to explore the immunomodulatory functions of TMER4 by evaluating its impact on signaling through the critical immune sensors Toll-like receptor 4 (TLR4), TLR3, TLR7, and retinoic acid-inducible gene I (RIG-I). To accomplish this, we developed a system to test noncoding RNAs using commercially available reporter cell lines. We optimized the experimental procedure to ensure ncRNA expression and to quantify immune sensory molecule induction or inhibition by the expressed ncRNA. Expression of TMER4 RNAs from plasmid constructs did not alter TLR or RIG-I signaling. This study provides a clear experimental framework that can be applied to test other small ncRNAs for their impact on various innate immune sensor proteins.

B cell mechanosensing regulates ER remodeling at the immune synapse.

Engagement of the B-cell receptor with immobilized antigens triggers the formation of an immune synapse (IS), a complex cellular platform where B-cells recruit signaling molecules and reposition lysosomes to promote antigen uptake and processing. Calcium efflux from the endoplasmic reticulum (ER) released upon BCR stimulation is necessary to promote B-cell survival and differentiation. Whether the spatial organization of the ER within the B-cell synapse can tune IS function and B-cell activation remains unaddressed. Here, we characterized ER structure and interaction with the microtubule network during BCR activation and evaluated how mechanical cues arising from antigen presenting surfaces affect this process. B-cells were cultured on surfaces of varying stiffness coated with BCR ligands, fixed, and stained for the ER and microtubule network. Imaging analysis was used to assess the distribution of the ER and microtubules at the IS. Upon BCR activation, the ER is redistributed towards the IS independently of peripheral microtubules and accumulates around the microtubule-organization center. Furthermore, this remodeling is also dependent on substrate stiffness, where greater stiffness triggers enhanced redistribution of the ER. Our results highlight how spatial reorganization of the ER is coupled to the context of antigen recognition and could tune B-cell responses. Additionally, we provide novel evidence that the structural maturation of the ER in plasma cells is initiated during early activation of B-cells.

Effect of O-acetylation on the antigenicity and glycoconjugate immunogenicity of the Streptococcus pneumoniae serotype 7F capsular polysaccharide.

Streptococcus pneumoniae is a bacterial pathogen causing diseases as severe as pneumonia, sepsis and meningitis. Commercial pneumococcal conjugate vaccines contain the 7F serotype, which is epidemiologically relevant and highly invasive. This serotype contains an O-acetyl group at the internal L-rhamnose of its polysaccharide repeating unit. Herein we report on the role of the O-acetyl moiety of 7F polysaccharide in both antigen recognition and the induction of a protective antibody response against 7F. Fully and partially de-O-acetylated 7F polysaccharides were chemically prepared and compared with the O-acetylated counterpart in their antigenicity and immunogenicity of their tetanus toxoid glycoconjugates. These comparative studies showed a slight but consistent decrease in the antigenicity for the fully de-O-acetylated polysaccharide, but not for the partly de-O-acetylated variant. The glycoconjugates derived from the O-acetylated and the fully de-O-acetylated polysaccharides had similar sizes and polysaccharide-to-protein ratio, and all proved both to be immunogenic and induce opsonophagocytic responses in mice. Nevertheless, the immune response elicited by the O-acetylated glycoconjugate was better in both quantity and quality, proving that the O-acetyl group is not strictly necessary but also not irrelevant for the antigenicity and immunogenicity of the 7F serotype polysaccharide and its glycoconjugates.

Transcriptomic and Proteomic Insights into Host Immune Responses in Pediatric Severe Malarial Anemia: Dysregulation in HSP60-70-TLR2/4 Signaling and Altered Glutamine Metabolism.

Severe malarial anemia (SMA, Hb < 6.0 g/dL) is a leading cause of childhood morbidity and mortality in holoendemic Plasmodium falciparum transmission zones. This study explored the entire expressed human transcriptome in whole blood from 66 Kenyan children with non-SMA (Hb ≥ 6.0 g/dL, n = 41) and SMA (n = 25), focusing on host immune response networks. RNA-seq analysis revealed 6862 differentially expressed genes, with equally distributed up-and down-regulated genes, indicating a complex host immune response. Deconvolution analyses uncovered leukocytic immune profiles indicative of a diminished antigenic response, reduced immune priming, and polarization toward cellular repair in SMA. Weighted gene co-expression network analysis revealed that immune-regulated processes are central molecular distinctions between non-SMA and SMA. A top dysregulated immune response signaling network in SMA was the HSP60-HSP70-TLR2/4 signaling pathway, indicating altered pathogen recognition, innate immune activation, stress responses, and antigen recognition. Validation with high-throughput gene expression from a separate cohort of Kenyan children (n = 50) with varying severities of malarial anemia (n = 38 non-SMA and n = 12 SMA) confirmed the RNA-seq findings. Proteomic analyses in 35 children with matched transcript and protein abundance (n = 19 non-SMA and n = 16 SMA) confirmed dysregulation in the HSP60-HSP70-TLR2/4 signaling pathway. Additionally, glutamine transporter and glutamine synthetase genes were differentially expressed, indicating altered glutamine metabolism in SMA. This comprehensive analysis underscores complex immune dysregulation and novel pathogenic features in SMA.

Computational Analysis of T-Cell Receptor Repertoire Workflow: From T-Cell Isolation to Bioinformatics Analysis.

The T-cell receptor (TCR) is the key molecule involved in the adaptive immune response. It is generated by the V(D)J recombination, responsible of the enormous diversity of the TCR repertoire, a crucial feature determining the individual capability to response to antigens and to build immunological memory. A pivotal role in the recognition of antigen is played by the hypervariable complementarity-determining region 3 (CDR3) of the V-beta chain of TCR. Investigating the CDR3 supports the understanding of the adaptive immune system dynamics in physiological processes, such as immune aging, and in disease, especially autoimmune disorders in which T cells are main actors. High-throughput sequencing (HTS) paved the way for a great progress in the investigation of TCR repertoire, enhancing the read depth in the process of library generation of sequencing and the number of samples that can be analyzed simultaneously. Therefore, the leverage of big datasets stressed the need to develop computational approach, by bioinformatics, to unravel the characteristics of the TCR repertoire.

TLR-2 and TLR-4 mRNA expression in different grades of histopathological lesions of equine endometrium from follicular phase.

Increased synthesis and deposition of collagen(COL) in the extracellular matrix (ECM) of equine endometrium contributes to endometrosis. Toll-like receptors (TLRs) are transmembrane receptors involved in the innate immune response, recognized for their role in antigen recognition and previously associated with equine endometritis. The TLRs not only recognize pathogen-associated molecular patterns but also regulate inflammations, fibrosis and cancer. The aim of this study was to explore the relationship between TLR expression at different stages of Kenney and Doig's (K-D) grading and COL1 expression during the follicular phase of the oestrous cycle. Forty samples of endometrial tissues were collected post-mortem from mares on the follicular phase of the oestrous cycle (10 samples of each K-D category). Relative mRNA transcription of TLR-2, TLR-4 and COL1A2 genes was assessed using qPCR, and COL1 protein expression by Western blot analysis. The COL1A2 transcription increased in category IIB when compared to categories I, IIA and III endometria (p < .01). The relative protein abundance of COL1 showed no significant differences between endometrial categories (p > .05). As for the TLRs mRNA transcription, TLR-2/-4 transcripts increased in IIA when compared to the other K-D endometria categories (p < .05). Our findings suggest that TLRs may be involved in the initiation of the endometrial inflammatory response. Additional studies are needed to explore TLRs' potential role as diagnostic markers for monitoring inflammation progression and fibrosis development, as well as their involvement in the mechanisms underlying fibrotic pathways.

Fabrication of a Heptapeptide-Modified Poly(glycidyl Methac-Rylate) Nanosphere for Oriented Antibody Immobilization and Immunoassay

Oriented antibody immobilization has been widely employed in immunoassays and immunodiagnoses due to its efficacy in identifying target antigens. Herein, a heptapeptide ligand, HWRGWVC (HC7), was coupled to poly(glycidyl methacrylate) (PGMA) nanospheres (PGMA-HC7). The antibody immobilization behavior and antigen recognition performance were investigated and compared with those on PGMA nanospheres by nonspecific adsorption and covalent coupling via carbodiimide chemistry. The antibodies tested included bovine, rabbit, and human immunoglobulin G (IgG), while the antigens included horseradish peroxidase (HRP) and β-2-Microglobulin (β2-MG). The nanospheres were characterized using zeta potential and particle size analyzers, scanning electron microscopy, transmission electron microscopy, Fourier transform infrared spectroscopy, and reversed-phase chromatography, proving each synthesis step was succeeded. Isothermal titration calorimetry assay demonstrated the strong affinity interaction between IgG and PGMA-HC7. Notably, PGMA-HC7 achieved rapid and extremely high IgG adsorption capacity (~3 mg/mg) within 5 min via a specific recognition via HC7 without nonspecific interactions. Moreover, the activities of immobilized anti-HRP and anti-β2-MG antibodies obtained via affinity binding were 1.5-fold and 2-fold higher than those of their covalent coupling counterparts. Further, the oriented-immobilized anti-β2-MG antibody on PGMA-HC7 exhibited excellent performance in antigen recognition with a linear detection range of 0–5.3 μg/mL, proving its great potential in immunoassay applications.

TCR3d 2.0: expanding the T cell receptor structure database with new structures, toolsand interactions.

Recognition of antigens by T cell receptors (TCRs) is a key component of adaptive immunity. Understanding the structures of these TCR interactions provides major insights into immune protection and diseases, and enables design of therapeutics, vaccinesand predictive modeling algorithms. Previously, we released TCR3d, a database and resource for structures of TCRs and their recognition. Due to the growth of available structures and categories of complexes, the content of TCR3d has expanded substantially in the past 5 years. This expansion includes new tables dedicated to TCR mimic antibody complex structures, TCR-CD3 complexesand annotated Class I and II peptide-MHC complexes. Additionally, tools are available for users to calculate docking geometries for input TCR and TCR mimic complex structures. The core tables of TCR-peptide-MHC complexes have grown by 50%, and include binding affinity data for experimentally determined structures. These major content and feature updates enhance TCR3d as a resource for immunology, therapeuticsand structural biology research, and enable advanced approaches for predictive TCR modeling and design. TCR3d is available at: https://tcr3d.ibbr.umd.edu.

Abstract C147: Impact of genetic ancestry in triple-negative breast cancer subtypes

Abstract Background: Triple-negative breast cancer (TNBC) is an aggressive BC subtype characterized by significant molecular and clinical heterogeneity, influenced by genetic, phenotypic, and environmental factors, as well as interactions of the tumor with its surrounding milieu. A significant racial disparity has been observed between African American (AA) and European American (EA) women regarding the incidence and clinical progression of TNBC. TNBC frequently occurs in young parous women who self-identify as AA and in women who harbor a germline BRCA1 mutation. Notably, AA women are diagnosed with TNBC at a younger age and exhibit a higher risk of developing stage IV disease. Studies examining gene expression signatures that distinguish AA and EA TNBC have reported distinct tumor-associated immunologic profiles in AA patients. We have developed a novel cell type-driven subtyping system based on a racially diverse TNBC sample set that identified three TNBC subtypes, each with distinct biology and prognosis: CC1- immune signaling/T-cell response; CC2- pro- migratory/inflammatory; CC3- fatty acid and hormone and nuclear receptor signaling. In this study, we propose to examine ancestry-inferred differences within each TNBC subtype between patients with African and European ancestry. Methods: RNA-Sequencing data for the Louisiana Tumor Registry, a TNBC cohort of 250 diverse women [EA: 123 and AA: 127], was obtained from our collaborators at Louisiana State University Health Sciences Center. Genetic admixture was performed on 227/250 patients using the method described by Pakstis, A. J. et al. Differentially expressed genes (DEGs) were identified in pairwise comparisons at p-adj ≤ 0.05. Survival was assessed using log-rank tests. Results: We investigated DEGs within each subtype between patients with &amp;gt;60% African (Aa, n=102) or &amp;gt;60% European ancestry (Ea, n=99) (identified via admixture analysis). In all three subtypes, upregulated genes, and their associated enrichment in Aa were related to immune pathways, while DEGs in Ea patients were related to epithelial cell regulation. In CC1, Aa was associated with the upregulation of immunoglobulin genes involved in immunoglobulin production and antigen recognition, while Ea was associated with the upregulation of embryonic development genes. In CC2, Aa showed enriched complement activation and immunoglobulin genes, while Ea exhibited upregulation of basal cytokeratin and growth factor EGFR. In CC3, Aa was associated with the upregulation of inflammatory genes, whereas Ea showed upregulation of cellular senescence genes. Survival analysis demonstrated favorable outcomes for Aa in CC1 and less favorable outcomes for Aa in CC2. Conclusion: Our study highlights significant ancestry-inferred differences in gene expression within TNBC subtypes, with Aa patients showing immune pathways enrichment and Ea patients exhibiting differential epithelial cell regulation. These findings underscore the importance of considering genetic ancestry in TNBC prognosis and treatment strategies. Citation Format: Zahra Mesrizadeh, Kavitha Mukund, Fokrul Hossain, Jovanny Zabaleta, Denise Danos, Luis De Valle, Xiao-Cheng Wu, Chindo Hicks, Augusto Ochoa, Lucio Miele, Victoria L. Seewaldt, Shankar Subramaniam. Impact of genetic ancestry in triple-negative breast cancer subtypes [abstract]. In: Proceedings of the 17th AACR Conference on the Science of Cancer Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; 2024 Sep 21-24; Los Angeles, CA. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2024;33(9 Suppl):Abstract nr C147.

Physical extraction of antigen and information

To respond and adapt, cells use surface receptors to sense environmental cues. While biochemical signal processing inside the cell is studied in depth, less is known about how physical processes during cell-cell contact impact signal acquisition. New experiments found that fast-evolving immune B cells in germinal centers (GCs) apply force to acquire antigen clusters prior to internalization, suggesting adaptive benefits of physical information extraction. We present a theory of stochastic antigen transfer and show that maximizing information gain via physical extraction can explain the dramatic phenotypic transition from naive to GC B cells-attenuated receptor signaling, enhanced force usage, and decentralized contact architecture. Our model suggests that binding-lifetime measurement and physical extraction serve as complementary modes of antigen recognition, greatly extending the dynamic range of affinity discrimination when combined. This physical-information framework further predicts that the optimal size of receptor clusters decreases as affinity improves, rationalizing the use of a multifocal synaptic pattern seen in GC B cells. By linking extraction dynamics to selection fidelity via discriminatory performance, we propose that cells may physically enhance information acquisition to sustain adaptive evolution.

Craters on the melanoma surface facilitate tumor-immune interactions and demonstrate pathologic response to checkpoint blockade in humans.

Immunotherapy leads to cancer eradication despite the tumor's immunosuppressive environment. Here, we used extended long-term in-vivo imaging and high-resolution spatial transcriptomics of endogenous melanoma in zebrafish, and multiplex imaging of human melanoma, to identify domains that facilitate immune response during immunotherapy. We identified crater-shaped pockets at the margins of zebrafish and human melanoma, rich with beta-2 microglobulin (B2M) and antigen recognition molecules. The craters harbor the highest density of CD8+ T cells in the tumor. In zebrafish, CD8+ T cells formed prolonged interactions with melanoma cells within craters, characteristic of antigen recognition. Following immunostimulatory treatment, the craters enlarged and became the major site of activated CD8+ T cell accumulation and tumor killing that was B2M dependent. In humans, craters predicted immune response to ICB therapy, showing response better than high T cell infiltration. This marks craters as potential new diagnostic tool for immunotherapy success and targets to enhance ICB response.

Dual-functional probe-based multi-signal immunosensor platform for tropane alkaloids: Verification and evaluation

This study aims to realise rapid detecting of tropane alkaloids (TAs) in food. For this purpose, a broad-spectrum single-chain fragment variable was fused with horseradish peroxidase to create an antibody–enzyme complex (AEC) with antigen recognition and catalytic activity. A multi-signal immunosensor platform based on AEC in the direct competitive reaction mode was constructed using 3,3′,5,5′-tetramethylbenzidine and 10-acetyl-3,7-dihydroxyphenoxazine as substrates. The sensitivity of TAs in the immunosensor platform ranged from 0.25 μg/kg to 7912.46 μg/kg. Honey was selected as a representative food sample, and the limit of detection of TAs in honey ranged from 0.02 μg/kg to 409.11 μg/kg, with a recovery rate of 65.7 %–117.1 % and a coefficient of variation less than 21.4 %. Results showed that the immunosensor platform possesses satisfactory accuracy and precision, which highlights its potential for practical applications and its suitability as an ideal tool for rapid screening of TAs in food.

Research Progress on Dendritic Cells in Hepatocellular Carcinoma Immune Microenvironments.

Dendritic cells (DCs) are antigen-presenting cells that play a crucial role in initiating immune responses by cross-presenting relevant antigens to initial T cells. The activation of DCs is a crucial step in inducing anti-tumor immunity. Upon recognition and uptake of tumor antigens, activated DCs present these antigens to naive T cells, thereby stimulating T cell-mediated immune responses and enhancing their ability to attack tumors. It is particularly noted that DCs are able to cross-present foreign antigens to major histocompatibility complex class I (MHC-I) molecules, prompting CD8+ T cells to proliferate and differentiate into cytotoxic T cells. In the malignant progression of hepatocellular carcinoma (HCC), the inactivation of DCs plays an important role, and the activation of DCs is particularly important in anti-HCC immunotherapy. In this review, we summarize the mechanisms of DCs activation in HCC, the involved regulatory factors and strategies to activate DCs in HCC immunotherapy. It provides a basis for the study of HCC immunotherapy through DCs activation.

Abstract PR-08: Reprogramming and selective recruitment of distinct neutrophil subpopulations restrain cancer metastasis

Abstract Neutrophils are integral to the metastatic tumor microenvironment (TME), and discrete subsets of neutrophils have been associated with pro- and anti-tumor responses. However, the composition of neutrophils in the metastatic TME and strategies to harness neutrophils for the treatment of metastatic disease remain poorly understood. Here, we studied the role of neutrophils in metastatic disease using mouse models of metastatic pancreatic ductal adenocarcinoma (PDAC). By utilizing mouse PDAC cells driven by mutant KRAS and p53 with controllable expression of ovalbumin, an immunogenic antigen (“TumorAg ON” or “TumorAg OFF”), we found that TumorAg ON PDAC engendered more than 10-fold higher recruitment of neutrophils into liver metastatic lesions compared to TumorAg OFF PDAC. RNA sequencing analysis of micro-dissected metastatic lesions showed that TumorAg ON PDAC elicited transcription of genes associated with neutrophil chemotaxis, including Cxcr2 and its ligands. Multimodal immune phenotyping and imaging mass cytometry (IMC) analysis further revealed that neutrophils within metastatic lesions consisted of CXCR2high and CXCR2low subpopulations and were spatially associated with distinct subsets of tumor cells, T cells, and myeloid cells. In both mouse models of liver and lung metastasis, small molecule inhibition of CXCR2 using SX-682 led to enrichment of CXCR2low neutrophils and reduced metastatic burden in TumorAg ON PDAC. In contrast, CXCR2 inhibition had no impact on metastatic burden in TumorAg OFF PDAC. To define the subpopulations of neutrophils in further depth, we also performed single-cell spatial transcriptomics using Xenium. Notably, CXCR2 inhibition in TumorAg ON PDAC, but not in TumorAg OFF, led to enrichment of neutrophil subsets that expressed higher levels of Mpo, Nos2, and Ly6g and lower levels of Cxcr2 and Siglecf into metastatic lesions. In this setting, depletion of neutrophils using anti-Ly6G antibodies worsened metastatic burden, highlighting anti-tumor properties of these neutrophil subsets in the presence of antigenic recognition. Indeed, in a highly immune-resistant model of PDAC, 6419c5, the use of tumor-targeting listeria vaccine CRS-207 along with CXCR2 inhibition significantly reduced metastatic burden, whereas CXCR2 inhibitor or CRS-207 alone had no impact. To extend the clinical relevance of these observations, we analyzed serial tissue biopsies collected from patients with metastatic PDAC in the liver treated with immunotherapy regimen incorporating CRS-207 (NCT03190265). Consistent with our mouse model results, IMC analysis revealed increased proportion of MPOhigh NOS2high neutrophils upon treatment, suggesting that induction of tumor antigen response results in an effective remodeling of the neutrophil compartment . Taken together, our results show that neutrophils may acquire anti-tumor properties under appropriate inflammatory conditions and that distinct subpopulations of neutrophils may be leveraged for the treatment of metastatic disease. Citation Format: Jae W Lee, Diana Caroline Vargas Carvajal, Yeonju Cho, Sarah M Shin, Erin M Coyne, Alexei Hernandez, Courtney D Cannon, Xuan Yuan, Zhehao Zhang, Nicole E Gross, Soren Charmsaz, Daniel H Shu, Katherine M Bever, Dung T Le, Luciane T Kagohara, Elizabeth M Jaffee, Won Jin Ho. Reprogramming and selective recruitment of distinct neutrophil subpopulations restrain cancer metastasis [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 PR-08.