Although immune checkpoint inhibitors (ICIs) have revolutionized cancer treatment, primary resistance and acquired resistance continue to limit their efficacy for many patients. To address resistance and enhance the anti-tumor activity within the tumor immune microenvironment (TIME), numerous therapeutic strategies targeting both innate and adaptive immune cells have emerged. These include combination therapies with ICIs, chimeric antigen receptor T-cell (CAR-T), chimeric antigen receptor macrophages (CAR-Ms) or chimeric antigen receptor natural killer cell (CAR-NK) therapy, colony stimulating factor 1 receptor (CSF1R) inhibitors, dendritic cell (DC) vaccines, toll-like receptor (TLR) agonists, cytokine therapies, and chemokine inhibition. These approaches underscore the significant potential of the TIME in cancer treatment. This article provides a comprehensive and up-to-date review of the mechanisms of action of various innate and adaptive immune cells within the TIME, as well as the therapeutic strategies targeting each immune cell type, aiming to deepen the understanding of their therapeutic potential.

As pivotal effectors of antiviral immunity, natural killer (NK) cells are crucial for controlling the spread of COVID-19. The nonstructural protein 13 of SARS-CoV-2 can encode a viral peptide (Nsp13232-240) preventing human leukocyte antigen E (HLA-E) from recognizing inhibitory receptor NKG2A, thereby activating NK cells. The underlying molecular mechanisms of Nsp13232-240 remain unclear. Therefore, we compared the interaction discrepancy between the self-peptide and Nsp13232-240, theoretically predicting its source. Results indicate that electrostatic interaction energy provides the main source of binding, and its attenuation greatly promotes binding affinity differences. Nsp13232-240 disrupts the hydrogen bond network between CD94 and HLA-E, impacting the binding of hot-spot residues, including Q112CD94 and E161HLA-E. Moreover, Nsp13232-240 breaks the salt bridges formed by K217NKG2A and K199NKG2A with HLA-E. Conformational changes induced by Nsp13232-240 lead to diminished atomic contacts and an unstable binding pattern. These findings provide novel insights into the immunomodulatory role of Nsp13232-240 and may inform future NK cell-mediated strategies targeting SARS-CoV-2.

Recent evidence highlights the pivotal role of natural killer (NK) cells in allograft rejection.

We explored associations of missing self and gene polymorphisms determining the phenotype and/or functionality of NK cells with microvascular inflammation (MVI) in a single-center cohort of 507 consecutive kidney transplant recipients. Patients were genotyped for killer cell Ig-like receptors and polymorphisms in 4 selected genes ( FCGR3AV/F158 [rs396991], KLRC2wt/del , KLRK1HNK/LNK [rs1049174], and rs9916629-C/T).

MVI was detected in 69 patients (13.6%). In a proportional odds model, the KLRC2del/del variant reduced MVI risk (odds ratio [OR] 0.26; 95% confidence interval [CI], 0.05-0.93; P  = 0.037) independent of donor-specific antibodies, HLA class II eplet mismatch, and number of biopsies. Conversely, missing self (OR 1.40; 95% CI, 1.08-1.80; P  = 0.011) and the rs9916629 T/T gene variant increased the risk (OR 1.70; 95% CI, 1.08-2.68; P  = 0.021). Graft loss tended to be more frequent among patients with missing self ≥2 (hazard ratio 1.97; 95% CI, 0.89-4.37; P  = 0.097), without influence on estimated glomerular filtration trajectories. FCGR3A variants were associated with MVI only in patients with preformed and/or de novo donor-specific antibodies (OR 4.14; 95% CI, 0.99-17.47; P  = 0.052).

Missing self and NK-cell genetics may contribute to MVI, underscoring the important role of NK cells in transplant rejection.

Cytotoxic lymphocytes counter intracellular pathogens and cancer by recognizing and destroying infected or transformed target cells. The basis for their function is the cytolytic immune synapse, a structurally stereotyped cell-cell interface through which lymphocytes deliver toxic proteins to target cells. The immune synapse is a highly dynamic contact capable of exerting nanonewton-scale forces against the target cell. In recent years, it has become clear that the interplay between these forces and the biophysical properties of the target influences the entirety of the cytotoxic response, from the initial activation of cytotoxic lymphocytes to the release of dying target cells. As a result, cellular cytotoxicity has become an exemplar of the ways in which biomechanics can regulate immune cell activation and effector function. This Review covers recent progress in this area, which has prompted a reconsideration of target cell killing from a more mechanobiological perspective.

Natural killer (NK) cells are critical components of the innate immune system. Their primary role is to induce apoptosis in target cells, such as cancerous or virally infected cells. These targets are recognized through interactions between activating or inhibitory receptors on the NK cell surface. Among the activating receptors is the natural cytotoxicity receptor NKp46. Several ligands for this receptor have been identified, including the epithelial adhesin Epa1 from the yeast Candida glabrata. Invasive candidiasis caused by this yeast is a significant complication for patients with hematological diseases. The interaction between NKp46 and Epa1 is thought to depend specifically on an O-glycan at threonine 225 of NKp46. To elucidate the molecular details of this interaction, we optimized the recombinant production of soluble NKp46 and Epa1, generated glycosylation variants of multiple NKp46 mutants, and evaluated the role of NKp46 glycosylation in Epa1 binding using microscale thermophoresis and isothermal titration calorimetry. Additionally, for the first time, we provide a comprehensive glycosylation profile of NKp46, determined through mass spectrometry of intact glycopeptides obtained by O-glycoprotease and trypsin proteolysis. Our findings demonstrate that the NKp46 stalk is glycosylated at multiple sites, involving both an N-glycan and more than one O-glycan. These glycans are critical for the interaction with Epa1, providing NK cells with enhanced sensitivity to Candida glabrata epitopes.

Over the past few years, cellular immunotherapy has emerged as a promising treatment for certain hematologic cancers, with various CAR-T therapies now widely used in clinical settings. However, challenges related to the production of autologous cell products and the management of CAR-T cell toxicity highlight the need for new cell therapy options that are universal, safe, and effective. Natural killer (NK) cells, which are part of the innate immune system, offer unique advantages, including the potential for off-the-shelf therapy. A recent first-in-human trial of CD19-CAR-NK infusion in patients with relapsed/refractory lymphoid malignancies demonstrated safety and promising clinical activity. Building on these positive clinical outcomes, current research focuses on enhancing CAR-NK cell potency by increasing their in vivo persistence and addressing functional exhaustion. There is also growing interest in applying the successes seen in hematologic malignancies to solid tumors. This review discusses current trends and emerging concepts in the engineering of next-generation CAR- NK therapies. It will cover the process of constructing CAR-NK cells, potential targets for their manufacturing, and their role in various solid tumors. Additionally, it will examine the mechanisms of action and the research status of CAR-NK therapies in the treatment of solid tumors, along with their advantages, limitations, and future challenges. The insights provided may guide future investigations aimed at optimizing CAR-NK therapy for a broader range of malignancies.

Endoplasmic reticulum (ER) aminopeptidase 1 (ERAP1) metabolizes peptides inside the ER and shapes the peptide repertoire available for binding to major histocompatibility complex class I molecules (MHC-I). However, it may have additional effects on cellular homeostasis, which have not been explored. To address these questions, we used both genetic silencing of ERAP1 expression as well as treatment with a selective allosteric ERAP1 inhibitor to probe changes in the immunopeptidome and proteome of the A375 melanoma cancer cell line. We observed significant immunopeptidome shifts with both methods of functional ERAP1 disruption, which were distinct for each method. Both methods of inhibition led to an enhancement, albeit slight, in tumor cell killing by stimulated human peripheral blood mononuclear cells and in significant proteomic alterations in pathways related to metabolism and cellular stress. Similar proteomic changes were also observed in the leukemia cell line THP-1. Biochemical analyses suggested that ERAP1 inhibition affected sensitivity to ER stress, reactive oxygen species production, and mitochondrial metabolism. Although the proteomics shifts were significant, their potential in shaping immunopeptidome shifts was limited since only 9.6% of differentially presented peptides belonged to proteins with altered expression and only 4.0% of proteins with altered expression were represented in the immunopeptidome shifts. Taken together, our findings suggest that modulation of ERAP1 activity can generate unique immunopeptidomes, mainly due to altered peptide processing in the ER, but also induce changes in the cellular proteome and metabolic state which may have further effects on tumor cells.

The new era of cell therapeutics has started with autologous products to avoid immune rejection. However, therapeutics derived from allogeneic cells could be scaled and made available for a much larger patient population if immune rejection could reliably be overcome. In this review, we outline gene engineering concepts aimed at generating immune-evasive cells. First, we summarize the current state of allogeneic immune cell therapies, and second, we compile the still limited data for allogeneic cell replacement therapies. We emphasize the advances in this fast-developing field and provide an optimistic outlook for future allogeneic cell therapies.

The purpose of this review is to describe the immune function of the liver, guiding the reader from the homeostatic tolerogenic status to the aberrant activation demonstrated in chronic liver disease. An extensive description of the pathways behind the inflammatory modulation of the healthy liver will be provided focusing on the complex immune cell network residing within the liver. The limit of tolerance will be presented in the context of organ transplantation, seizing the limits of homeostatic mechanisms that fail in accepting the graft, progressing eventually toward rejection. The triggers and mechanisms behind chronic activation in metabolic liver conditions and viral hepatitis will be discussed. The last part of the review will be dedicated to one of the greatest paradoxes for a tolerogenic organ, developing autoimmunity. Through the description of the three most common autoimmune liver diseases, the autoimmune reaction against hepatocytes and biliary epithelial cells will be dissected.

Immunity declines with age. This results in a higher risk of age-related diseases, diminished ability to respond to new infections and reduced response to vaccines. The causes of this immune dysfunction are cellular senescence, which occurs in both lymphoid and non-lymphoid tissue, and chronic, low-grade inflammation known as 'inflammageing'. In this Review article, we highlight how the processes of inflammation and senescence drive each other, leading to loss of immune function. To break this cycle, therapies are needed that target the interactions between the altered tissue environment and the immune system instead of targeting each component alone. We discuss the relative merits and drawbacks of therapies that are directed at eliminating senescent cells (senolytics) and those that inhibit inflammation (senomorphics) in the context of tissue niches. Furthermore, we discuss therapeutic strategies designed to directly boost immune cell function and improve immune surveillance in tissues.

Natural Killer (NK) cells are lymphocytes of the innate immunity and sense healthy or diseased target cells with activating and inhibitory NK cell receptor (NKR) molecules expressed on the cell surface. The protection provided by NK cells against viral infections and tumors critically depends on their ability to distinguish healthy cells from diseased target cells that express 100-fold more activating ligands. NK cell signaling and activation depend on integrating opposing signals initiated by activating and inhibitory NKRs interacting with the cognate ligands expressed on target cells. A wide range of imaging experiments have demonstrated aggregation of both activating and inhibitory NKRs in the plasma membrane on submicron scales in resting NK cells. How do these submicron size NKR clusters formed in the resting state affect signal discrimination? Using in silico mechanistic signaling modeling with information theory and published superresolution imaging data for two well-studied human NKRs, activating NKG2D and inhibitory KIR2DL1, we show that early time signal discrimination by NK cells depends on the spatial statistics of these clusters. When NKG2D and KIR2DL1 clusters are disjoint in the resting state, these clusters help NK cells to discriminate between target cells expressing low and high doses of the activating cognate ligand, whereas, when the NKR clusters fully overlap the NK cells are unable to distinguish between healthy and diseased target cells. Therefore, the spatial statistics of submicron scale clusters of activating and inhibitory NKRs at the resting state provides an additional layer of control for signal discrimination in NK cells.

Natural killer (NK) cells are prototypic cytotoxic innate lymphocytes that can kill target cells, such as tumor cells, in the absence of antigen-restriction. Peripheral NK cells exhibit a high degree of heterogeneity. Here, we set out to broadly assess intrinsic modulators of NK cell degranulation in an unbiased manner. We stimulated human primary blood-borne NK cells pre-treated with different cytokine regimens with the HCT116 human colon cancer cell line and used detection of lysosome-associated membrane glycoprotein 1 (LAMP1) as an identifier of rapid NK cell degranulation. RNA sequencing of FACS-sorted LAMP1hi NK cells showed CXCR4 and S1PR5 were top down-regulated genes. Using compounds that modulate activity of CXCR4 and S1P receptor family members S1P1 and S1P5, we confirmed they play an important immunosuppressive role in NK cell cytotoxicity. Mechanistically, engagement of CXCR4 and S1P1/5 receptors triggered phosphorylation of p42 and Ca2+ influx. CXCR4 activation promoted S1P5 upregulation and vice versa, and joint activation of both receptors amplified the defect NK cell degranulation. Intriguingly, in tumor samples the expression of both receptors and the synthesis of their ligands themselves appear to be coordinately regulated. Together, these data suggest that specifically and simultaneously targeting CXCR4 and S1P5 activity in the tumor microenvironment (TME) could be a beneficial strategy to unleash full cytotoxic potential of cytotoxic NK effector cells in the tumor.

Loss of anticancer natural killer (NK) cell function in patients with acute myeloid leukemia (AML) is associated with fatal disease progression and remains poorly understood. Here, we demonstrate that AML blasts isolated from patients rapidly inhibit NK cell function and escape NK cell-mediated killing. Transcriptome analysis of NK cells exposed to AML blasts revealed increased CREM expression and transcriptional activity, indicating enhanced cyclic adenosine monophosphate (cAMP) signaling, confirmed by uniform production of the cAMP-inducing prostanoid prostaglandin E2 (PGE2) by all AML-blast isolates from patients. Phosphoproteome analysis disclosed that PGE2 induced a blockade of lymphocyte-specific protein tyrosine kinase (LCK)-extracellular signal-regulated kinase signaling that is crucial for NK cell activation, indicating a 2-layered escape of AML blasts with low expression of NK cell-activating ligands and inhibition of NK cell signaling. To evaluate the therapeutic potential to target PGE2 inhibition, we combined Fcγ-receptor-mediated activation with the prevention of inhibitory PGE2 signaling. This rescued NK cell function and restored the killing of AML blasts. Thus, we identify the PGE2-LCK signaling axis as the key barrier for NK cell activation in 2-layered immune escape of AML blasts that can be targeted for immune therapy to reconstitute anticancer NK cell immunity in patients with AML.

The purpose of this study was to examine whether supplementation of ultra- and nanofiltered colostrum-based products, combined with egg yolk extract, nicotinamide mononucleotide (NMN), quercetin, alpha-ketoglutarate, white button mushroom, and celery seed extracts (the formula was patented by 4Life Research Company, USA and named as AgePro), modulate the functional activity of natural killer (NK) cells in vivo. We found that this supplement, taken orally in two capsules twice a day for 30 days, significantly enhanced the cytotoxic activity of NK cells. This was evidenced by the increased NK cell-mediated killing of carboxyfluorescein diacetate succinimidyl ester (CFSE)-labeled K562 human myeloid leukemia cells. As expected, this effect was dependent on the ratio between the effector (E) (e.g., peripheral blood mononuclear cells (PBMCs)) and target (T) (e.g., K562) cells, illustrating maximal killing of K562 cells at a 50:1 E/T ratio. Of note, increased NK-mediated killing of K562 cells after taking AgePro correlated with increased perforin release, evidenced by the CD107a degranulation assay. In concordance with these findings, taking of AgePro for 1 month increased production of several cytokines and chemokines, including IL-1β, IL-1Rα, IL-6, IL-8, IL-10, IFN-γ, TNF-α, G-CSF, PDGF-AA, PDGF-AB/BB, GRO, MCP-1, MCP-3, and MIP-1α, in PBMCs co-cultured with K562 cells. Of note, increased production of the cytokines correlated with the activation state of PBMCs, as evidenced by increased expression of the surface activation markers (e.g., the interleukin-2 receptor alpha chain-CD25). A strong correlation was found between NK-based cytotoxic activity and the production of IL-1β, IL-6, TNF-α, and MIP-1α. Importantly, no increase in the aforementioned soluble factors and activation markers was detected in PBMCs cultured alone, thereby illustrating the potent immunoregulatory activity of AgePro only in the presence of the harmful target cells. Hematological parameters also remained unchanged over the entire study period. Collectively, we show herein the significant enhancement of the cytotoxic activity of NK cells against target tumor cells after taking AgePro for 1 month. Notably, this effect was observed for all age groups, including young, adult, and elderly participants. Moreover, a significant improvement in NK cytotoxic activity was also detected for participants with low basal (e.g., before taking AgePro) numbers of NK-mediated killing. The enhancement of NK-based cytotoxicity was associated with an increased release of several cytokines and chemokines involved in regulating a broad spectrum of mechanisms outside the cell-mediated cytotoxicity and killing of target cells. Of note, spontaneous activation of PBMCs, particularly NK cells, was not detected after taking AgePro. Given that spontaneous activation of autoreactive lymphocytes is a feature associated with autoimmunity and taking into account our data illustrating the AgePro-induced activation of NK cells detected only in the presence of the potentially harmful cells, we conclude that our innovative product exhibits potent immunoregulatory activity and high safety profile.

Natural killer (NK) cells are critical innate immune cells involved in the clearance of virally infected and malignant cells. Human NK cells are distinguished by their surface expression of CD56 and a lack of CD3. While CD56 expression and cell surface density has long been used as the prototypic marker to characterize primary human NK cell functional subsets, the exact functional role of CD56 in primary human NK cells is still not fully understood. Here, we eliminated the expression of CD56 in human ex vivo expanded NK cells (CD56bright) using CRISPR/Cas9 in order to assess the function of CD56 in this highly activated and cytotoxic NK cell population. We show that the expression of CD56 has no effect on NK cell proliferative capacity or expression of various activation and inhibitory markers. Further, CD56 does not contribute to NK cell-mediated cytotoxicity, inflammatory cytokine production, or the ability of NK cells to control tumor engraftment in vivo. We also found that while deletion of CD56 did not impact NK cell glycolytic metabolism, it did increase NK cell reliance on oxidative phosphorylation. Last, CD56 does not alter expanded NK cell in vivo tissue trafficking. Our results indicate that while CD56 expression could be used to indicate a hyperfunctional state of NK cells, it does not directly influence the antitumor functions of expanded NK cells.

Sympathetic nerves innervate bone marrow and various immune organs, where norepinephrine-the primary sympathetic neurotransmitter-directly interacts with immune cells that express adrenergic receptors. This article reviewed the key molecular pathways triggered by sympathetic activation and explored how sympathetic activity influences immune cell migration. Norepinephrine serves as a chemoattractant for monocytes, macrophages, and stem cells, promoting the migration of myeloid cells while inhibiting the migration of lymphocytes at physiological concentrations. We also examined the role of immune cell infiltration in cardiovascular diseases and cancer. Evidence suggests that sympathetic activation increases myeloid cell infiltration into target tissues across various cardiovascular diseases, including atherosclerosis, hypertension, cardiac fibrosis, cardiac hypertrophy, arrhythmia, myocardial infarction, heart failure, and stroke. Conversely, inhibiting sympathetic activity may serve as a potential therapeutic strategy to treat these conditions by reducing macrophage infiltration. Furthermore, sympathetic activation promotes macrophage accumulation in cancer tissues, mirroring its effects in cardiovascular diseases, while suppressing T lymphocyte infiltration into cancerous sites. These changes contribute to increased cancer growth and metastasis. Thus, inhibiting sympathetic activation could help to protect against cancer by enhancing T cell infiltration and reducing macrophage presence in tumors.

Pluripotent stem cells provide opportunities for treating injuries and previously incurable diseases. A major concern is the immunogenicity of stem cells and their progeny. Here, we have dissected the molecular mechanisms that allow natural killer (NK) cells to respond to human pluripotent stem cells, investigating a wide selection of activating and inhibitory NK-cell receptors and their ligands. Reporter cells expressing the activating receptor NKG2D responded strongly to embryonic stem (ES) cell lines and induced pluripotent stem (iPS) cell lines, whereas reporter cells expressing the activating receptors NKp30, NKp46, KIR2DS1, KIR2DS2, and KIR2DS4 did not respond. Human ES and iPS cells invariably expressed several ligands for NKG2D. Expression of HLA-C and HLA-E was lacking or low, insufficient to trigger reporter cells expressing the inhibitory receptors KIR2DL1, -2DL2, or -2DL3. Similar results were obtained for the pluripotent embryonic carcinoma cell lines NTERA-2 and 2102Ep, and also iPS-cell-derived neural progenitor cells. Importantly, neural progenitor cells and iPS-cell-derived motoneurons also expressed B7H6, the ligand for the activating receptor NKp30. In line with these observations, IL-2-stimulated NK cells showed robust cytotoxic responses to ES and iPS cells as well as to iPS-cell-derived motoneurons. No significant differences in cytotoxicity levels were observed between KIR/HLA matched and mismatched combinations of NK cells and pluripotent targets. Together, these data indicate that pluripotent stem cells and their neural progeny are targets for NK-cell killing both by failing to sufficiently express ligands for inhibitory receptors and by expression of ligands for activating receptors.

Background/Objectives: Abnormal glycan formation on the cancer cell surface plays a crucial role in regulating tumor functions in bladder cancer. In this study, we investigated the roles of glucosaminyl (N-acetyl) transferase 2 (GCNT2) in bladder cancer progression and immune evasion. GCNT2 synthesizes I-branched polylactosamine chains on cell surface glycoproteins. Understanding its functions will provide insights into tumor-immune interactions, facilitating the development of effective immunotherapeutic strategies. Methods: GCNT2 expression levels in bladder cancer cell lines and patient tumor samples were analyzed via quantitative polymerase chain reaction and immunohistochemistry. GCNT2 functions were assessed via overexpression and knockdown experiments. Its effect on natural killer (NK) cell-mediated cytotoxicity was evaluated via in vitro assay. Cytotoxic granule release from NK cells was measured via enzyme-linked immunosorbent assay. Results: GCNT2 expression was inversely correlated with bladder cancer aggressiveness in both cell lines and patient samples. Low GCNT2 levels were associated with advanced tumor stage and grade, suggesting the tumor-suppressive roles of GCNT2. Notably, GCNT2 overexpression enhanced the susceptibility of bladder cancer cells to NK cell-mediated killing, whereas its knockdown promoted immune evasion. GCNT2-overexpressing cells strongly induced the release of cytotoxic granules from NK cells, indicating enhanced immune recognition. Conclusions: Our findings suggest that aggressive bladder tumors evade NK cell immunity by decreasing the GCNT2 levels and that I-antigen glycans synthesized by GCNT2 are crucial for NK cell recognition by tumor cells. Our findings provide insights into the tumor-immune interactions in bladder cancer and GCNT2 and its associated pathways as potential targets for novel immunotherapeutic strategies.

The interaction between immune cells brings a consequence either on their role and functioning or the functioning of the other immune cells, modulating the whole mechanistic pathway. The interaction between natural killer (NK) cells and macrophages is one such interaction which is relatively less explored amongst diseased conditions. Their significance comes from their innate nature and secretion of large proportions of cytokines and chemokines which results in influencing adaptive immune responses. Their interplay can lead to several functional outcomes such as NK cell activation/inhibition, increased cytotoxicity and IFNγ release by NK cells, inhibition of macrophage function, etc. This paper delves into the interaction amongst NK cells and macrophages via different receptor-ligands and cytokines, particularly emphasising microbial infections and tumours. The review has the potential to uncover new insights and approaches that could lead to the development of innovative therapeutic tools and targets.

As important innate immune cells, natural killer (NK) cells play an essential role in resisting pathogen invasion and eliminating transformed cells. However, the hypoxic microenvironment caused by disease conditions is an important physicochemical factor that impairs NK cell function. With the increasing prominence of NK cells in immunotherapy, there has been a surge of interest in developing biological means through which NK cells may overcome the inhibition caused by hypoxia in disease conditions. Although the effects of hypoxic conditions in shaping the functions of NK cells have been increasingly recognized and investigated, reviews have been scantly. A comprehensive understanding of how NK cells adapt to hypoxia can provide valuable insights into how the functional capacity of NK cells may be restored. This review focuses on the functional alterations of NK cells in response to hypoxia. It delineates the mechanisms by which NK cells adapt to hypoxia at the transcriptional, metabolic, translational levels. Furthermore, given the complexity of the hypoxic microenvironment, we also elucidated the effects of key hypoxic metabolites on NK cells. Finally, this review discusses the current clinical therapies derived from targeting hypoxic NK cells. The study of NK cell adaptation to hypoxia has yielded new insights into immunotherapy. These insights may lead to development of novel strategies to improve the treatment of infectious diseases and cancer.

Leishmaniasis is a group of parasitic diseases whose etiological agent is the protozoa Leishmania. These diseases afflict impoverished populations in tropical and subtropical regions and affect wild and domestic animals. Canine leishmaniasis is a global disease mostly caused by L. infantum. Dogs are recognized as a good reservoir since harbor the infection long before developing the disease, facilitating parasite transmission. Furthermore, there is growing evidence that dogs may also be the reservoir of the American Leishmania spp. as L. amazonensis. The innate immune response is the first defense line against pathogens, which includes natural killer (NK) and dendritic cells (DCs). By recognizing and ultimately destroying infected cells, and by secreting immune mediators that favor inflammatory microenvironments, NK cells take the lead in the infectious process. When interacting with Leishmania parasites, DCs become activated and play a key role in driving the host immune response. While activated DCs can modulate NK cell activity, Leishmania parasites can directly activate NK cells by interacting with innate immune receptors. Once activated, NK cells can engage in a bidirectional interplay with DCs. However, the complexity of these interactions during Leishmania infection makes it challenging to fully understand the underlying processes. To further explore this, the present study investigated the dynamic interplay established between monocyte-derived DCs (moDCs) and putative NK (pNK) cells of dogs during Leishmania infection. Findings indicate that the crosstalk between moDCs exposed to L. infantum or L. amazonensis and pNK cells enhances chemokine upregulation, potentially attracting other leukocytes to the site of infection. pNK cells activated by L. infantum infected DCs upregulate IL-10, which can lead to a regulatory immune response while moDCs exposed to L. amazonensis induced pNK cells to overexpress IFN-γ and IL-13, favoring a mix of pro- and anti-inflammatory response. In addition, parasite-derived extracellular vesicles (EVs) can modulate the host immune response by stimulating the upregulation of anti-inflammatory cytokines and perforin release, which may impact infection outcomes. Thus, Leishmania and parasitic EVs can influence the bidirectional interplay between canine NK cells and DCs.

Head and neck squamous cell carcinoma (HNSCC) has a poor prognosis, and current treatments are limited by high toxicity and low survival rates, highlighting the need for new therapeutic approaches. Natural killer (NK) cells can identify and eliminate cancer cells without prior antigen exposure. Radiotherapy directly targets tumors and increases activating ligands on tumor cells, promoting NK cell interactions. Cetuximab, an EGFR-targeting antibody, enhances NK cell cytotoxicity. Additionally, anti-PD-1 antibodies may further boost NK cell function by blocking inhibitory signals. The study aimed to enhance HNSCC treatment efficacy by combining radiotherapy and targeted therapy with expanded NK cells.

NK cells were isolated, activated, and expanded from healthy donors. The FaDu and SCC-47 cell lines were inoculated into NOD/SCID mice. The mice were treated with PD-1 inhibitors, cetuximab, and radiation, followed by intravenous injection of NK cells.

Radiation increased ligands that regulate NK cell sensitivity. The combination of cetuximab, radiotherapy, and expanded NK cells significantly suppressed cancer progression and improved survival rates. However, adding anti-PD-1 antibodies did not further enhance outcomes.

This study suggests that a multimodal approach combining cetuximab, radiotherapy, and NK cells can significantly improve HNSCC therapy efficacy, offering a novel and promising treatment strategy.

Killer immunoglobulin-like receptors (KIRs) are key molecules used by natural killer (NK) cells to interact with target cells. These receptors exhibit extensive genotypic polymorphism which has been associated with varying outcomes in immune responses against diseases. This study aimed to investigate the relationships between KIR genotypes and haplotypes with acute lymphoblastic leukemia (ALL) in Saudi patients.

A total of 259 Saudi subjects including 145 cases of acute lymphoblastic leukemia (ALL) and 114 healthy controls living in Riyadh were genotyped for 16 KIR genes and the two HLA-C1 and -C2 allotypes using PCR-SSP genotyping method.

A significant high frequency of the two inhibitory KIR genes; 2DL1 (OR = 2.4; p < 0.0001) and 3DL1(OR = 10.87; p = 0.0068) in ALL compared to healthy group was observed. In contrast, the activating 2DS4 gene was significantly higher in healthy controls (OR = 0.15, p < 0.0001) compared to ALL patients. Haplotype analysis shows that BX haplogroup was strongly associated with the occurrence of ALL (OR = 4.39; p < 0.0001). Further combinatory analysis of KIR genes with their HLA-C1 and -C2 ligands demonstrated strong statistically protective effect of the 2DS1-C2 combination from ALL (OR = 0.06; p = 0.0003).

This study presents strong evidence supporting the connection between certain KIR genotypes, haplotypes, and KIR-HLA combinations with acute ALL in the Saudi population. The heightened occurrence of inhibitory KIR genes (2DL1 and 3DL1) and the BX haplotype in ALL patients indicates a possible involvement of these genetic variability with the dysfunctional of NK cells in the context of ALL disease.

Natural killer (NK) cells are essential elements of the innate immune response against tumors and viral infections. NK cell activation is governed by NK cell receptors that recognize both cellular (self) and viral (non-self) ligands, including MHC, MHC-related, and non-MHC molecules. These diverse receptors belong to two distinct structural families, the C-type lectin superfamily and the immunoglobulin superfamily. NK receptors include Ly49s, KIRs, LILRs, and NKG2A/CD94, which bind MHC class I (MHC-I) molecules, and NKG2D, which binds MHC-I paralogs such MICA and ULBP. Other NK receptors recognize tumor-associated antigens (NKp30, NKp44, NKp46), cell-cell adhesion proteins (KLRG1, CD96), or genetically coupled C-type lectin-like ligands (NKp65, NKR-P1). Additionally, cytomegaloviruses have evolved various immunoevasins, such as m157, m12, and UL18, which bind NK receptors and act as decoys to enable virus-infected cells to escape NK cell-mediated lysis. We review the remarkable progress made in the past 25 years in determining structures of representatives of most known NK receptors bound to MHC, MHC-like, and non-MHC ligands. Together, these structures reveal the multiplicity of solutions NK receptors have developed to recognize these molecules, and thereby mediate crucial interactions for regulating NK cytolytic activity by self and viral ligands.

Natural killer (NK) cells are a promising approach for cellular cancer immunotherapy and are being investigated to treat patients with multiple myeloma (MM). We found that MM patient blood NK cell frequencies were normal with increased activating receptors and cytotoxic granules, without evidence of functional exhaustion. Despite this activated state, MM target cells were resistant to conventional NK cells by unclear mechanisms. Memory-like (ML) NK cells are generated after brief activation via the interleukin (IL)-12, IL-15, and IL-18 receptors and exhibit multiple enhanced antitumor properties. ML NK cell differentiation improved healthy donor and MM patient NK cell responses against MM target cells, in vitro and in vivo in immunodeficient murine xenograft models. Moreover, incorporating NKG2A checkpoint blockade to overcome HLA-E-induced inhibition further enhanced ML NK cell responses against MM in vitro and in vivo. Because activating receptor recognition of MM by ML NK cells was inadequate, strategies to improve this were investigated. Utilizing anti-SLAMF7 monoclonal antibody (elotuzumab) or anti-BCMA chimeric antigen receptors resulted in robust increases in ML NK cell functional responses against MM. In summary, ML differentiation enhances NK cell attack against myeloma, and combination with approaches to block inhibitory checkpoints and promote MM-specific activation are promising translational NK cell strategies for MM immunotherapy.

Antibody-dependent cell-mediated cytotoxicity (ADCC) by NK cells is a key mechanism in anti-cancer therapies with monoclonal antibodies, including cetuximab (EGFR-targeting) and avelumab (PDL1-targeting). Fc gamma receptor IIIa (FcγRIIIa) polymorphisms impact ADCC, yet their clinical relevance in NK cell functionality remains debated. We developed two complementary flow cytometry assays: one to predict the FcγRIIIa-V158F polymorphism using a machine learning model, and a 15-color flow cytometry panel to assess antibody-induced NK cell functionality and cancer-immune cell interactions. Samples were collected from healthy donors and metastatic colorectal cancer (mCRC) patients from the FIRE-6-Avelumab phase II study. The machine learning model accurately predicted the FcγRIIIa-V158F polymorphism in 94% of samples. FF homozygous patients showed diminished cetuximab-mediated ADCC compared to VF or VV carriers. In mCRC patients, NK cell dysfunctions were evident as impaired ADCC, decreased CD16 downregulation, and reduced CD137/CD107a induction. Elevated PD1+ NK cell levels, reduced lysis of PDL1-expressing CRC cells and improved NK cell activation in combination with the PDL1-targeting avelumab indicate that the PD1-PDL1 axis contributes to impaired cetuximab-induced NK cell function. Together, these optimized assays effectively identify NK cell dysfunctions in mCRC patients and offer potential for broader application in evaluating NK cell functionality across cancers and therapeutic settings.

Panax ginseng (P. ginseng) C.A. Meyer. Has been studied for decades for its various biological activities, especially in terms of immune-regulatory properties. Traditionally, it has been known that root, leaves, and fruits of P. ginseng were eaten for improving body's Qi and homeostasis. Also, these were used to protect body from various types of infectious diseases. However, molecular mechanisms of immunomodulatory activities of ginseng berries have not been systemically studied as often as other parts of the plant.

The aim of this research is to discover the regulatory effects of P. ginseng berries, more importantly, their ginsenosides, on innate immune responses and to elucidate the molecular mechanism.

Ginseng berry concentrate (GBC) was orally injected into BALB/c mice for 30 days, and spleens were extracted for evaluation of immune-regulatory effects. Murine macrophage RAW264.7 cells were used for detailed molecular mechanism studies. Splenic natural killer (NK) cells were isolated using the magnetic-activated cell sorting (MACS) system, and the cytotoxic activity of isolated NK cells was measured using a lactate dehydrogenase (LDH) release assay. The splenic immune cell population was determined by flow-cytometry. NF-κB promoter activity was assessed by in vitro luciferase assay. Expression of inflammatory proteins and cytokines of the spleen and RAW264.7 cells were evaluated using western blotting and real-time PCR, respectively.

The GBC enhanced cytotoxic activity of NK cells and the immune-regulation-related splenic cell population. Moreover, GBC promoted NF-κB promoter activity and stimulated the NF-κB signaling cascade. In spleen and RAW264.7 cells, expression of pro-inflammatory cytokines was increased upon GBC application, while expression of anti-inflammatory cytokines decreased.

These results suggest that P. ginseng berry can stimulate innate immune responses and help maintain a balanced immune condition, mostly due to the action of its key ginsenoside Re, along with other protopanaxadiol- and protopanaxatriol-type ginsenosides. Such finding will provide a new insight into the field of well-being diet research as well as non-chemical immune modulator, by providing nature-derived and plant-based bioactive materials.

Natural killer (NK) cells have multifaceted roles within the complex tumor milieu. They are pivotal components of innate immunity and shape the dynamic landscape of tumor-immune cell interactions, and thus can be leveraged for use in therapeutic interventions. NK-based immunotherapies have had remarkable success in hematological malignancies, but these therapies are met with many challenges in solid tumors, including neuroblastoma (NB), a childhood tumor arising from the sympathetic nervous system. With a focus on NB, this review outlines the mechanisms employed by NK cells to recognize and eliminate malignant cells, delving into the dynamic relationship between ligand-receptor interactions, cytokines, and other molecules that facilitate the cross talk between NK and NB cells. We discuss the immunomodulatory functions of NK cells and the mechanisms that contribute to loss of this immunosurveillance in NB, with a focus on how this dynamic has been utilized in recent immunotherapy advancements for NB.

HLA-E expression plays a central role for modulation of NK cell function by interaction with inhibitory NKG2A and stimulatory NKG2C receptors on canonical and adaptive NK cells, respectively. Here, we demonstrate that infection of human primary lung tissue with SARS-CoV-2 leads to increased HLA-E expression and show that processing of the peptide YLQPRTFLL from the spike protein is primarily responsible for the strong, dose-dependent increase of HLA-E. Targeting the peptide site within the spike protein revealed that a single point mutation was sufficient to abrogate the increase in HLA-E expression. Spike-mediated induction of HLA-E differentially affected NK cell function: whereas degranulation, IFN-γ production, and target cell cytotoxicity were enhanced in NKG2C+ adaptive NK cells, effector functions were inhibited in NKG2A+ canonical NK cells. Analysis of a cohort of COVID-19 patients in the acute phase of infection revealed that adaptive NK cells were induced irrespective of the HCMV status, challenging the paradigm that adaptive NK cells are only generated during HCMV infection. During the first week of hospitalization, patients exhibited a selective increase of early NKG2C+CD57- adaptive NK cells whereas mature NKG2C+CD57+ cells remained unchanged. Further analysis of recovered patients suggested that the adaptive NK cell response is primarily driven by a wave of early adaptive NK cells during acute infection that wanes once the infection is cleared. Together, this study suggests that NK cell responses to SARS-CoV-2 infection are majorly influenced by the balance between canonical and adaptive NK cells via the HLA-E/NKG2A/C axis.

Adrenergic receptors (ARs) are preferentially expressed by innate lymphocytes such as natural killer (NK) cells. Here, we study the effect of epinephrine-mediated stimulation of the β2-adrenergic receptor (β2AR) on the function of human NK cells. Epinephrine stimulation inhibited early NK cell signaling events and blocked the function of the integrin LFA-1. This reduced the adhesion of NK cells to ICAM-1, explaining how NK cells are mobilized into the peripheral blood upon epinephrine release during acute stress or exercise. Additionally, epinephrine stimulation transiently reduced NK cell degranulation, serial killing, and cytokine production and affected metabolic changes upon NK cell activation via the cAMP-protein kinase A (PKA) pathway. Repeated exposure to β2AR agonists resulted in the desensitization of the β2AR via a PKA feedback loop-initiated G-protein switch. Therefore, acute epinephrine stimulation of chronically β2AR stimulated NK cells no longer resulted in inhibited signaling and reduced LFA-1 activity. Sustained stimulation by long-acting β2-agonists (LABA) not only inhibited NK cell functions but also resulted in desensitization of the β2AR. However, peripheral NK cells from LABA-treated asthma patients still reacted unchanged to epinephrine stimulation, demonstrating that local LABA administration does not result in detectable systemic effects on NK cells.

Natural killer (NK) cells are a subset of innate lymphoid cells that are inherently capable of recognizing and killing infected or tumour cells. This has positioned NK cells as a promising live drug for tumour immunotherapy, but limited success suggests incomplete knowledge of their killing mechanism. NK cell-mediated killing involves a complex decision-making process based on integrating activating and inhibitory signals from various ligand-receptor repertoires. However, the relative importance of the different activating ligand-receptor interactions in triggering NK killing remains unclear.

We employed a systematic approach combining clinical, in silico, in vitro, and in vivo data analysis to quantify the impact of various activating ligands. Clinical data analysis was conducted using massive pan-cancer data (n = 10,595), where patients with high NK cell levels were stratified using CIBERSORT. Subsequently, multivariate Cox regression and Kaplan-Meier (KM) survival analysis were performed based on activating ligand expression. To examine the impact of ligand expression on NK killing at the cellular level, we assessed surface expression of five major activating ligands (B7H6, MICA/B, ULBP1, ULBP2/5/6, and ULBP3) of human tumour cell lines of diverse origins (n = 33) via flow cytometry (FACs) and their NK cell-mediated cytotoxicity on by calcein-AM assay using human primary NK cells and NK-92 cell lines. Based on this data, we quantified the contribution of each activating ligand to the NK killing activity using mathematical models and Bayesian statistics. To further validate the results, we performed calcein-AM assays upon ligand knockdown and overexpression, conjugation assays, and co-culture assays in activating ligand-downregulated/overexpressed in liquid tumour (LT) cell lines. Moreover, we established LT-xenograft mouse models to assess the efficacy of NK cell targeting toward tumours with dominant ligands.

Through the clinical analysis, we discovered that among nearly all 18 activating ligands, only patients with LT who were NK cell-rich and specifically had higher B7H6 level exhibited a favorable survival outcome (p = 0.0069). This unexpected dominant role of B7H6 was further confirmed by the analysis of datasets encompassing multiple ligands and a variety of tumours, which showed that B7H6 exhibited the highest contribution to NK killing among five representative ligands. Furthermore, LT cell lines (acute myeloid leukemia (AML), B cell lymphoma, and T-acute lymphocytic leukemia (ALL)) with lowered B7H6 demonstrated decreased susceptibility to NK cell-mediated cytotoxicity compared to those with higher levels. Even within the same cell line, NK cells selectively targeted cells with higher B7H6 levels. Finally, LT-xenograft mouse models (n = 24) confirmed that higher B7H6 results in less tumour burden and longer survival in NK cell-treated LT mice (p = 0.0022).

While NK cells have gained attention for their potent anti-tumour effects without causing graft-versus-host disease (GvHD), thus making them a promising off-the-shelf therapy, our limited understanding of NK killing mechanisms has hindered their clinical application. This study illuminates the crucial role of the activating ligand B7H6 in driving NK cell killing, particularly in the context of LT. Therefore, the expression level of B7H6 could serve as a prognostic marker for patients with LT. Moreover, for the development of NK cell-based immunotherapy, focusing on increasing the level of B7H6 on its cognate receptor, NKp30, could be the most effective strategy.

This work was supported by the National Research Council of Science & Technology (NST) grant (CAP-18-02-KRIBB, GTL24021-000), a National Research Foundation grant (2710012258, 2710004815), and an Institute for Basic Science grant (IBS-R029-C3).

Chimeric antigen receptor (CAR)-engineered T (CAR-T) cell therapy has revolutionized the treatment of various diseases, including cancers and autoimmune disorders. However, all US Food and Drug Administration (FDA)-approved CAR-T cell therapies are autologous, and their widespread clinical application is limited by several challenges, such as complex individualized manufacturing, high costs, and the need for patient-specific selection. Allogeneic off-the-shelf CAR-engineered cell therapy offers promising potential due to its immediate availability, consistent quality, potency, and scalability in manufacturing. Nonetheless, significant challenges, including the risks of graft-versus-host disease (GvHD) and host-cell-mediated allorejection, must be addressed. Strategies such as knocking out endogenous T cell receptors (TCRs) or using alternative therapeutic cells with low GvHD risk have shown promise in clinical trials aimed at reducing GvHD. However, mitigating allorejection remains critical for ensuring the long-term sustainability and efficacy of off-the-shelf cell products. In this review, we discuss the immunological basis of allorejection in CAR-engineered therapies and explore various strategies to overcome this challenge. We also highlight key insights from recent clinical trials, particularly related to the sustainability and immunogenicity of allogeneic CAR-engineered cell products, and address manufacturing considerations aimed at minimizing allorejection and optimizing the efficacy of this emerging therapeutic approach.

NK cells offer a promising alternative to T cell therapies in cancer. We evaluated IPH6501, a clinical-stage, tetraspecific NK cell engager (NKCE) armed with a non-alpha IL-2 variant (IL-2v), which targets CD20 and was developed for treating B cell non-Hodgkin lymphoma (B-NHL). CD20-NKCE-IL2v boosts NK cell proliferation and cytotoxicity, showing activity against a range of B-NHL cell lines, including those with low CD20 density. Whereas it presented reduced toxicities compared with those commonly associated with T cell therapies, CD20-NKCE-IL2v showed greater killing efficacy over a T cell engager targeting CD20 in in vitro preclinical models. CD20-NKCE-IL2v also increased the cell surface expression of NK cell-activating receptors, leading to activity against CD20-negative tumor cells. In vivo studies in nonhuman primates and tumor mouse models further validated its efficacy and revealed that CD20-NKCE-IL2v induces peripheral NK cell homing at the tumor site. CD20-NKCE-IL2v emerges as a potential alternative in the treatment landscape of B-NHL.

The NK-92MI cell line has displayed significant promise in clinical trials for cancer treatment. However, challenges persist in obtaining sufficient cell quantities and achieving optimal cytotoxicity. The proliferation of natural killer (NK) cells involves the formation of cell aggregates, but excessively large aggregates can impede nutrient and waste transport, leading to reduced cell survival rates. In this study, a custom bioreactor was designed to mimic pseudostatic culture conditions by integrating brief mechanical rotation during a 6-h static culture period. This method aimed to achieve an optimal aggregate size while improving cell viability. The findings revealed a 144-fold expansion of 3D NK-92MI cell aggregates, reaching an ideal size of 80-150 µm, significantly increasing both cell proliferation and survival rates. After 14 days of culture, the NK-92MI cells maintained their phenotype during the subsequent phase of cell activation. Moreover, these cells presented elevated levels of IFN-γ expression after IL-18 activation, resulting in enhanced NK cell-mediated cytotoxicity against K562 cells. This innovative strategy, which uses a closed suspension-based culture system, presents a promising approach for improving cell expansion and activation techniques in immunocellular therapy.