natural killer (NK) cells

natural killer (NK) cells

Overview

Natural killer (NK) cells are innate lymphoid cells that constitute a critical component of the innate immune system, defined by their capacity to recognize and eliminate infected, stressed, or malignantly transformed cells without requiring prior antigen sensitization. Unlike adaptive immune cells such as cytotoxic T cells, NK cells patrol tissues and circulation armed with germline-encoded activating and inhibitory receptors that enable a rapid, contact-dependent cytotoxic response. Their effector functions include direct target cell lysis through release of cytotoxic granules containing granzymes (GZMA/GZMB) and perforin, engagement of death receptor pathways, and secretion of proinflammatory cytokines such as interferon-gamma (IFNG) and interleukin-6. NK cells also mediate antibody-dependent cellular cytotoxicity (ADCC) through the Fc receptor FCGR3A (CD16), enabling cooperation with therapeutic antibodies to eliminate tumor cells. Their surface microstructures — including microvilli — are essential for target cell recognition and the subsequent formation of immunological synapses, underscoring the importance of membrane architecture in their functional execution.

NK cells occupy a pivotal niche in cancer immunosurveillance through expression of a repertoire of activating receptors, most notably NKG2D, which detects stress-induced ligands upregulated on transformed cells. Their cytotoxic potential can, however, be markedly suppressed within the immunosuppressive tumor microenvironment by factors including transforming growth factor-beta (TGF-β), immunosuppressive steroids such as cortisol, lipid metabolic reprogramming, and inhibitory glycoimmune checkpoints such as Siglec-7 and Siglec-9. The dynamic interplay between activating and inhibitory signals — including those mediated by checkpoint receptors like NKG2A, TIGIT, and CLEC12B — determines the net cytotoxic output of NK cells in both physiological and pathological settings. Ongoing research is rapidly expanding both the mechanistic understanding and therapeutic exploitation of NK cell biology across a wide range of malignancies.


Focus of Latest Publications

Recent publications have positioned NK cells at the center of a broad and rapidly evolving cancer immunotherapy landscape, with investigations spanning their fundamental biology, suppression mechanisms, engineering strategies, and combinatorial therapeutic potential.

Checkpoint and glycoimmune regulation. Several studies have examined how inhibitory receptor signaling constrains NK cell anti-tumor activity. Work published in Oncoimmunology (PMID 41928453) investigated the role of sialic acid cis-ligand dynamics in modulating Siglec-7 and Siglec-9 function on NK cells. These glycoimmune checkpoints, expressed on primary NK cells isolated from peripheral blood, interact with sialylated ligands presented in trans on tumor cells but also in cis on the NK cell surface itself. The study demonstrated that Siglec-7 and/or -9 blockade increased NK cell-mediated killing of melanoma and acute myeloid leukemia (AML) cell lines, as well as patient-derived AML cells, establishing co-blockade of both receptors as a strategy to potentiate anti-tumor activity. Complementary findings in Cancer Immunology, immunotherapy (PMID 41961075) showed that targeting ST3GAL1 to downregulate sialylated ligands for Siglec-7 in hepatocellular carcinoma could reverse immune escape. Additionally, a study in Nature Communications (PMID 41998001) on ovarian carcinoma found that NKG2A inhibition not only enhanced NK cell cytotoxicity but also promoted productive NK cell–CD8+ T cell interactions, underscoring the crosstalk between innate and adaptive effectors in anti-cancer immunity. In Nature Immunology (PMID 41844941), CLEC12B was identified as an inhibitory receptor on NK cells that, when targeted, enhanced cancer immunotherapy efficacy within the immunosuppressive tumor microenvironment.

Checkpoint editing and genetic reprogramming. Building on checkpoint biology, a study in Cancer Research (PMID 41982126) employed base-editing technology to disrupt TIGIT in NK cells, reprogramming CD155 signaling to enhance anti-tumor efficacy. Separately, work in The Journal of Experimental Medicine (PMID 42126429) demonstrated that nonviral precision genome editing of NK cells using homology-directed repair (HDR) could reprogram endogenous NK circuits, addressing longstanding challenges of poor HDR efficiency and DNA toxicity that limited prior off-the-shelf immunotherapy manufacturing. The SMAD7-mediated resistance to TGF-β suppression was described in Journal for immunotherapy of Cancer (PMID 41956539), where SMAD7 overexpression in NK cells was shown to enhance antitumor activity through canonical TGF-β blockade and non-canonical transcriptional activation of STAT5A, the latter representing a newly characterized mechanism for preserving NK cell function in the tumor microenvironment.

CAR-NK engineering and off-the-shelf therapy. The field of chimeric antigen receptor (CAR)-NK cell therapy was reviewed comprehensively in Immunology and Cell Biology (PMID 42003566), highlighting translational and regulatory breakthroughs in CAR-NK platforms as alternatives to CAR T cell therapies. CAR-NK cells were specifically studied in the context of cortisol-mediated immunosuppression in Signal Transduction and Targeted Therapy (PMID 41956993), where cortisol-resistant CAR-NK cells were engineered to overcome steroid-induced suppression in lung cancer, a mechanism that had been underexplored relative to other immunosuppressive factors. The NKG2D receptor, described as a central component of immune surveillance expressed on NK cells and several T lymphocyte subsets, was also targeted in the context of engineered T-cell strategies to treat human disease (Human Vaccines & Immunotherapeutics, PMID 41656162).

Adoptive transfer, ADCC, and allogeneic transplantation contexts. A study in Oncoimmunology (PMID 42216567) demonstrated that umbilical cord blood-derived NK cells improve the efficacy of anti-GD2 antibody in neuroblastoma by amplifying ADCC, translating findings from mouse models to human cells and highlighting the role of FCGR3A-mediated mechanisms. In the context of allogeneic haematopoietic stem cell transplantation (allo-HSCT) for AML, a review in Annals of Medicine (PMID 41622937) synthesized emerging evidence on the synergistic roles of T cells and NK cells in transplant immunity, noting the importance of NK cell reconstitution. A complementary clinical study in Cancer Letters (PMID 41720450) assessed the prognostic significance of HLA-B leader matching status and its relationship with NK cell reconstitution in patients with hematological malignancies following haploidentical hematopoietic stem cell transplantation.

Memory-like and trained NK cells. Two studies highlighted NK cell plasticity beyond their classical innate role. In Blood Advances (PMID 41538301), exercise-mobilized lymphocytes were shown to enhance the function of cytokine-induced memory-like (CIML) NK cells — generated by short-term activation with IL-12, IL-15, and IL-18 — against myeloid leukemia following adoptive transfer. In Molecular Therapy (PMID 42237539), a single dose of therapeutic Salmonella was found to confer long-lasting protection against cancer metastasis in mice by inducing "trained" NK cells, a form of innate immune memory that persisted to provide durable anti-metastatic surveillance.

tumor microenvironment modulation and combination strategies. Numerous studies examined how manipulating the tumor microenvironment (TME) influences NK cell infiltration and function. A study in Biomaterials (PMID 41587524) showed that spatiotemporal control of neutrophil extracellular traps increased infiltration of NK cells and T cells, while promoting anti-tumor polarization of neutrophils and macrophages to reverse the immunosuppressive TME. In ACS Nano (PMID 41949057), engineered BCG was shown to recruit M1-type macrophages, NK cells, and induce dendritic cell maturation at the tumor site in triple-negative breast cancer. A neoantigen and shared MICB α3 antigen dual-targeted vaccine (EMBO Molecular Medicine, PMID 41998137) improved NK cell and neoantigen-specific T cell infiltration across multiple preclinical models. Lipid metabolism reprogramming within the TME was identified in Cellular & Molecular Immunology (PMID 41946907) as a driver of NK cell and CD8+ T cell dysfunction, linking metabolic perturbations to immune suppression. Engineered NK and T cells equipped with metabolite-sensing receptors were reported in Nature Immunology (PMID 41872506) to improve tumor infiltration and eradication in solid tumors. In Journal of Controlled Release (PMID 41905408), targeted lipid nanoparticle co-delivery of decitabine and siTNF-α to the bone marrow niche enhanced CD8+ T, NK, and NKT cell infiltration in leukemia therapy.

NK cell subsets and clinical biomarkers. A phase II clinical trial combining pembrolizumab with paclitaxel and carboplatin in melanoma (Oncoimmunology, PMID 41732954) found that objective response was associated with a larger proportion of mature NK cells at baseline, alongside lower frequencies of naive CD8 T cells and low plasma CCL3, situating NK cell maturation status as a predictive biomarker. In nasopharyngeal carcinoma, British Journal of Cancer (PMID 41992060) characterized alterations in NK cell subsets in patient blood and examined the regulatory role of JAB1 in tumor immunity. Evasion of NK cell-mediated killing was systematically reviewed in Pharmaceutical Science Advances (PMID 41799416), cataloging mechanisms by which tumor cells evade the innate cytotoxic response and surveying advances in NK cell-based cancer immunotherapy.


Key Publications

  • Jun Fungal metabolite-based immunotherapy overcomes tumor-associated macrophage immunosuppression. (Cell reports. Medicine, 2026, PMID 42173096): "Mechanistically, IM502 primarily inhibits PI3Kγ and redirects STAT signaling from STAT3/6 to STAT1/2 dominance, thereby reversing TAM-mediated immunosuppression, substantially enhancing the abundance and functional quality of natural killer (NK) and T cells."
  • Jun Droplet microfluidic profiling of NK cell cytotoxicity with machine learning-enabled target-cell death analysis. (Lab on a chip, 2026, PMID 42132875): "Predicting the clinical efficacy of Natural Killer (NK) cell immunotherapies remains challenging due to functional heterogeneity within effector populations and tumor microenvironment (TME)-mediated suppression."
  • Jun Baiting-enhanced extravasation of lipid nanoparticles for targeted co-delivery of decitabine and siTNF-α to the bone marrow niche in leukemia therapy. (Journal of controlled release : official journal of the Controlled Release Society, 2026, PMID 41905408): "...leading to enhanced CD8+ T, natural killer (NK), and natural killer T (NKT) cell infiltration in the bone marrow site."
  • Jun Therapeutic bacteria-trained NK cells confer long-term protection against cancer metastasis. (Molecular therapy : the journal of the American Society of Gene Therapy, 2026, PMID 42237539): "Here, we report that a single dose of therapeutic Salmonella, a prominent anti-tumor bacterial therapy, provides long-lasting protection against metastasis in mice by inducing "trained" Natural Killer (NK) cells."
  • May Umbilical cord blood natural killer cells improve anti-GD2 antibody efficacy in neuroblastoma: from mouse to human. (Oncoimmunology, 2026, PMID 42216567): "Natural killer (NK) cell-mediated antibody-dependent cellular cytotoxicity is a potent mechanism of action of anti-GD2 antibody."
  • May Reprogramming endogenous NK circuits by highly efficient nonviral genome editing. (The Journal of experimental medicine, 2026, PMID 42126429): "Natural killer (NK) cells are promising platforms for off-the-shelf immunotherapy, yet nonviral precision engineering remains limited by poor HDR efficiency, DNA toxicity, and manufacturing challenges."
  • May Targeting NK cell CLEC12B enhances cancer immunotherapy. (Nature immunology, 2026, PMID 41844941): "Natural killer (NK) cells are innate immune effectors, but their cytotoxic potential can be compromised within the immunosuppressive tumor microenvironment."
  • May Engineering NK and T cells with metabolite-sensing receptors to target solid tumors. (Nature immunology, 2026, PMID 41872506): "Natural killer (NK) cells and T cells need to infiltrate solid tumors to eradicate them."
  • May An APS-hydrogel composite provides dual molecular-physical protection to NK-92 cells by preserving membrane stability and surface microstructures. (International journal of biological macromolecules, 2026, PMID 41962724): "The surface microstructures of Natural Killer (NK) cells, such as microvilli, are essential for target cell recognition and the subsequent formation of immunological synapses."
  • Apr Prognostic significance of HLA-B leader matching status and its relationship with NK cell reconstitution in patients with hematological malignancies following haploidentical transplantation. (Cancer letters, 2026, PMID 41720450): "Cohort 2 comprised 130 patients who underwent natural killer (NK) cell reconstitution tests post-transplantation."
Show 22 more publications
  • Apr Inhalable Cryo-Shocked Tumor Cells for Synergistic Chemoimmunotherapy. (ACS applied materials & interfaces, 2026, PMID 41947504): "...robust DC activation, M1 macrophage polarization, and significant recruitment of NK cells and CD8+ T cells into the tumor microenvironment."
  • Apr CAR-NK cell-based therapies: translational and regulatory breakthroughs. (Immunology and cell biology, 2026, PMID 42003566): "We discuss advances in chimeric antigen receptor (CAR)-engineered natural killer (NK) cell therapies."
  • Apr NKG2A inhibition promotes NK cell-CD8+ T cell interactions to improve anticancer immunity in ovarian carcinoma. (Nature communications, 2026, PMID 41998001): "Natural killer (NK) cells contribute to tumor immunosurveillance, yet their heterogeneity across cancer types remains incompletely understood."
  • Apr Neoantigens and shared MICB α3 antigen dual-targeted vaccine generates potent antitumor immunity. (EMBO molecular medicine, 2026, PMID 41998137): "This strategy significantly improves the infiltration of neoantigen-specific T cells and NK cells, and reverses immunosuppression across various preclinical models."
  • Apr Alterations in NK cell subsets and the regulatory role of JAB1 in nasopharyngeal carcinoma with implications for tumor immunity and biomarker development. (British journal of cancer, 2026, PMID 41992060): "This study investigates changes in NK cell subsets in the blood of NPC patients"
  • Apr Potential immunomodulatory and antitumor properties of hydatid cysts components. (International immunopharmacology, 2026, PMID 41785598): "activate immune effector cells, including macrophages, natural killer (NK) cells, and T lymphocytes."
  • Apr Base Editing of TIGIT Reprograms CD155 Signaling in Natural Killer Cells to Enhance Cancer Immunotherapy Efficacy. (Cancer research, 2026, PMID 41982126): "NK cells hold great promise for cancer immunotherapy owing to their intrinsic capacity to recognize and eliminate malignant cells."
  • Apr Exercise-mobilized lymphocytes enhance the function of cytokine-induced memory-like NK cells against myeloid leukemia. (Blood advances, 2026, PMID 41538301): "Short-term activation of natural killer (NK) cells with interleukin-12 (IL-12), IL-15, and IL-18 (IL-12/15/18) gives rise to cytokine-induced memory-like (CIML) NK cells after adoptive transfer, which exhibit enhanced antitumor activity, proliferation, and persistence."
  • Apr Bioengineered iPSC-derived human macrophages with increased angiotensin-converting enzyme (ACE) expression suppress solid tumor growth. (Signal transduction and targeted therapy, 2026, PMID 41968179): "Here, ACE-iMac treatment significantly reduced the growth of human melanoma xenografts by enhancing the activation of human T cells and NK cells."
  • Apr SMAD7 drives natural killer cell antitumor activity through canonical TGF-β blockade and non-canonical transcriptional activation of STAT5A. (Journal for immunotherapy of cancer, 2026, PMID 41956539): "Natural killer (NK) cells are key effectors in antitumor immunity, yet their function is markedly suppressed by transforming growth factor-β (TGF-β) in the tumor microenvironment."
  • Apr Cortisol-resistant CAR-NK cells overcome steroid-induced immunosuppression in lung cancer. (Signal transduction and targeted therapy, 2026, PMID 41956993): "However, the influence of intratumoral immunosuppressive steroids on tumor-infiltrating natural killer (NK) cells and their implications for effective immunotherapy has remained largely unexplored."
  • Apr Targeting ST3GAL1 to downregulate ligands for the glycoimmune checkpoint Siglec-7 and reverse immune escape in hepatocellular carcinoma. (Cancer immunology, immunotherapy : CII, 2026, PMID 41961075): "Primary natural killer (NK) cells, freshly isolated from peripheral blood or following culture and expansion, expressed the glycoimmune checkpoints Siglec-7 and Siglec-9."
  • Apr Lipid metabolism reprogramming shapes the immune landscape in the tumor microenvironment. (Cellular & molecular immunology, 2026, PMID 41946907): "detailing how this reprogramming drives dysfunction in antitumor subsets such as CD8+ T cells and natural killer cells"
  • Apr Engineered Bacillus Calmette-Guérin Mediated Immunotherapy of Triple-Negative Breast Cancer. (ACS nano, 2026, PMID 41949057): "BCG acts as a potent immune initiator, significantly enhancing the recruitment of M1-type macrophages and natural killer cells to the tumor site, and also induced the maturation of dendritic cells."
  • Apr Single-cell and spatial transcriptome-based metabolism-immunity interaction network and therapeutic target discovery of matrine in cervical cancer. (Naunyn-Schmiedeberg's archives of pharmacology, 2026, PMID 41283998): "While CD8+ T cell function may be inhibited, immuno-microenvironmental examination showed a considerable increase in the infiltration of neutrophils, NK cells, and macrophages in tumor tissues."
  • Apr Spatiotemporal controls of neutrophil extracellular traps boosts neutrophils immunotherapy efficiency against solid tumors. (Biomaterials, 2026, PMID 41587524): "Data show that NE@LTT@DNase1 treatment was associated with increased infiltration of NK cells and T cells, as well as a shift of neutrophils and macrophages toward an anti-tumor polarization, collectively contributing to the reversal of the immunosuppressive tumor microenvironment (TME)."
  • Apr Synergistic immune interactions between T cells and natural killer cells in allogeneic haematopoietic stem cell transplantation for acute myeloid leukaemia: current status and future directions. (Annals of medicine, 2026, PMID 41622937): "emerging evidence highlighting the synergistic roles of T cells and natural killer (NK) cells in allo-HSCT immunity."
  • Apr Harnessing the NKG2D immune surveillance pathway using engineered T-cells for the treatment of human disease. (Human vaccines & immunotherapeutics, 2026, PMID 41656162): "The NKG2D receptor is a central component of immune surveillance and is expressed on natural killer (NK) cells and several T lymphocyte subsets."
  • Apr Mechanisms of tumor cell evasion from NK cell-mediated killing and advances in NK cell-based cancer immunotherapy. (Pharmaceutical science advances, 2026, PMID 41799416): "Natural killer (NK) cells represent a critical component of the innate immune system, capable of exerting potent cytotoxic activity against infected and transformed cells."
  • Apr A mixed inflammatory peripheral signature defines clinical outcomes in a phase II trial combining pembrolizumab with paclitaxel and carboplatin in melanoma. (Oncoimmunology, 2026, PMID 41732954): "Objective response was associated with a lower frequency of naive CD8 T cells and low plasma CCL3 at baseline, along with a larger proportion of mature NK cells and of CD4 T cells expressing BTLA or LAIR-1."
  • Apr Sialic acid cis-ligand dynamics modulate Siglec-7 and -9 function and affect Siglec-7/9 co-blockade to potentiate natural killer cell anti-tumor activity. (Oncoimmunology, 2026, PMID 41928453): "Extrapolating our findings to human primary cells, NK cell-mediated killing of melanoma and acute myeloid leukemia (AML) cell lines and patient-derived AML cells was increased upon Siglec-7 and/or -9 blockade."
  • Apr Therapeutic potential of BH3-mimetics and NK cell-mediated immunotherapy in T-ALL. (Cell death & disease, 2026, PMID 41935056): "Therefore, we investigated the potential of NK cell-mediated killing in T-ALL and found heterogeneous sensitivity, with some cell lines showing responses even at low effector-to-target (E:T) ratios."