NK Cells In Mice Research Articles

Abstract 2584: Development of an Fc gamma receptor fully-humanized mouse model to support the accurate preclinical study of therapeutic antibodies

Abstract The Fc gamma receptor (FcγR), a member of the immunoglobulin superfamily, binds the IgG Fc segment of antibodies and is mainly expressed on the surface of immune cell. The FcγR binds to the Fc region of an antibody that is attached to target cells, transmitting an activation or inhibition signal to the FcγR expressing cells, resulting in various biological responses and functions. Many therapeutic antibodies are developed based on the engineering of the Fc region to fine-tune the FcγR mediated effects. There are four subtypes of mouse FcγRs, including Fcgr1, Fcgr2b, Fcgr3, and Fcgr4. In contrast, human FcγRs consist of at least seven members, including FCGR1A, FCGR1B, FCGR2A, FCGR2B, FCGR2C, FCGR3A, and FCGR3B. Additionally, the expression pattern of even the orthologous FcγR genes varies between humans and mice. e.g., the distribution of mouse FCGR3 and FCGR2. Therefore, animals harboring the murine FcγRs are not ideal models for the accurate preclinical evaluation of human therapeutic antibodies. To address this problem, we established an FcγRs fully humanized mouse model by injecting an engineered human bacterial artificial chromosome construct carrying all seven human FcγR genes into mouse zygotes. The transgene carriers were mated with another strain in which all mouse FcγR genes were knocked out to establish the colony. Unlike the endogenous mouse FcγR genes expression profiles, the transgenic human FcγR genes regulated under the control of the human control elements retain the human expression pattern. For example, the transgenic human FCGR3A was observed on mouse NK cells and macrophages, whereas the FCGR3B was detected on mouse neutrophils only, which were consistent with their expression patterns in humans. Antibody-dependent cellular cytotoxicity (ADCC) experiment indicated that a human therapeutic antibody could direct NK cells derived from the FcγRs fully-humanized mice to kill target tumor cells. Moreover, a significant anti-tumor effect could also be achieved by an ADCC based human antibody in tumor-bearing FcγRs humanized mice. Taken together, the FcγR gene fully-humanized model established in this study demonstrates a human FcγR expression pattern and functionality, thus providing a valuable tool for accurate preclinical evaluation of human therapeutic antibodies. Citation Format: Mingkun Zhang, Cunxiang Ju, Ying Li, Yunlong Jiang, Weiwei Yu, Shuai Li, Hongyan Sun, Zhiying Li, Jing Zhao, Xiang Gao. Development of an Fc gamma receptor fully-humanized mouse model to support the accurate preclinical study of therapeutic antibodies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2584.

Abstract 2104: NK cell immunosurveillance of tumors is regulated by NFAT1 and NFAT2

Abstract NK cells are lymphoid components of innate immunity and play an important role in tumor immunosurveillance. One of the major transcriptional regulators in lymphoid cells is NFAT (Nuclear Factor of Activated T cells), controlling lymphocyte development and activity. However, while the role of NFAT signaling is well defined in T cells, the cytotoxic lymphocytes of adaptive immunity, surprisingly little is known regarding the relevance of this transcription factor family in NK cells as effector cells of innate immunity. Available data indicate that NFAT activity is dispensable for development of NK cells. However, several lines of evidence including reports on the effects of the immunosuppressive drugs cyclosporin A and tacrolimus, which mediate their effects through inhibition of calcineurin and consecutively NFAT, implicate an involvement of the NFAT family in NK cell function. We here employed different genetic mouse models to unravel the role of NFAT1 (NFATc2) and NFAT2 (NFATc1) in NK cell reactivity. When NK cells with knockout (KO) of NFAT1 or NFAT2 compared to NK cells of control mice (WT) were employed in in vitro analyses, lack of either NFAT was found to surprisingly result in enhanced NK cell degranulation as well as increased production of granzyme B and perforin upon stimulation of activating receptors like NK1.1 or Nkp46 or upon co-culture with different leukemia and solid tumor tumor cells. In line, cytotoxicity assays revealed increased lysis of YAC-1 and B16F10 tumor cells by both NFAT1- and NFAT2-deficient NK cells as compared to WT controls. The inhibitory effect of NFAT transcription factors on NK cell effector function could also be confirmed in vivo by employing WT and NFAT KO animals in syngeneic B16F10 melanoma and RMA-S flank tumor models, which revealed a significantly reduced tumor burden in NFAT1 and NFAT2 KO mice. Comparative analyses with single NFAT as well as NFAT1+NFAT2 double KO and WT animals further confirmed the inhibitory effect of NFAT1 and NFAT2 and pointed to additive effects of NFAT1 and NFAT2 in NK cell tumor immunosurveillance. Taken together, our results provide the first evidence for the direct functional involvement of NFAT1 and NFAT2 in NK cell antitumor reactivity and, in contrast to T and B cells, identify NFAT as a negative regulator of NK cell function. Citation Format: Melanie Märklin, Samuel Holzmayer, Kübra Kaban, Martin R. Müller, Helmut R. Salih. NK cell immunosurveillance of tumors is regulated by NFAT1 and NFAT2 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2104.

A role for a DEAD box RNA helicase in natural killer cells

Abstract The X chromosome linked RNA helicase DDX3X plays numerous roles in regulation of cellular RNA metabolism and immune responses. Loss of function mutations in this helicase are linked to neurological disease and malignancies, including NK/T-cell lymphoma. To investigate how DDX3X contributes to development of NK cells, we generated mice with a conditional deletion Ddx3x in Ncr1-expressing cells. Female mice with homozygous deletion of NK cells exhibit a complete loss of NK cells. By comparison, the frequency of NK cells was significantly reduced in hemizygous male mice. The reduction in NK cells is associated with increased apoptosis in this lineage early during differentiation in the bone marrow. Our ongoing work is focused on elucidation of the mechanisms by which DDX3X regulates NK cell survival, differentiation, and malignant transformation, as well as on the capacity of DDX3Y to compensate for loss of DDX3X in hemizygous male mice. Our data identify a novel role for DDX3 RNA helicases in the development and survival of NK cells in mice.

Sensory Neurotransmitter CGRP Modulates Oral Cancer Growth and Cancer-associated Immune Response

Head and neck squamous cell carcinoma (HNSCC) induces severe pain due in part to activation of primary afferent neurons by cancer-secreted mediators. Local neurotransmitter release (e.g., calcitonin gene-related peptide (CGRP)) from trigeminal neurons innervating the cancer has been linked to tumorigenesis. We hypothesize that CGRP exerts a dual effect on both cancer-associated pain and tumor progression, suggesting that CGRP may be a promising therapeutic target in HNSCC treatment. We used human tumor tissue and patient-reported outcomes to explore the relationship between CGRP+ sensory nerve innervation and cancer pain in patients. To determine CGRP receptor expression on tumor cells, immunohistochemistry and PCR were performed on human and mouse oral cancer cell lines. We used a syngeneic tongue tumor transplant mouse model of oral cancer and a global Calca knockout mouse (i.e. CGRP-KO) to investigate the impact of CGRP signaling on tumor growth and the associate immune response in vivo. We found prominent CGRP-immunoreactive sensory nerve presence innervating human HNSCC tumor tissue, which positively correlated to patient-reported pain (r2=0.357). Furthermore, human HNSCC cell lines expressed 3-fold more CGRP receptor, RAMP1, compared to a non-tumorigenic keratinocyte cell line. In tumor-bearing CGRP-KO mice, we found a significant reduction in tumor size at post-inoculation days 7 and 14 compared to wildtype. We also found a 4-fold increase in tumor infiltrating RAMP1-expressing CD4+ T cells, as well as a 5-fold increase cytotoxic CD8+ T cells and NK1.1+ NK cells in tumor tissue CGRP-KO mice compared to wildtype. This preliminary data suggests that CGRP signaling from sensory neurons may increase cancer associated pain and tumor progression. Further knowledge regarding the relationship between sensory neurons and cancer could allow for the repurposing clinically available nervous system drugs (e.g., anti-CGRP antibodies) for the treatment of cancer and cancer pain. Grant support from the Rita Allen Foundation.

CD3ζ adaptor structure determines functional differences between human and mouse CD16 Fc-gamma receptor signaling in natural killer cells

Abstract Natural killer (NK) cells are innate lymphocytes capable of distinguishing between healthy and pathogenic cells using a myriad of receptors expressed on their cell surface. The CD16 receptor detects the Fc portion of IgG on antibody-coated cells resulting in NK cell activation. The importance of this receptor on human NK cell biology has long been appreciated; however, how CD16 functions in mouse NK cells remains poorly understood. Here, we report drastic differences between human and mouse CD16 functions in NK cells. We demonstrate that one of the adaptor molecules that CD16 associates with and signals through, CD3ζ, plays a critical role in these functional differences. Using a systematic approach, we demonstrate that key residues in the transmembrane domain of the mouse CD3ζ molecule prevent efficient complex formation with mouse CD16, thereby dampening receptor function. Mutating these residues in mouse CD3ζ to those encoded by human CD3ζ resulted in rescue of CD16 receptor function. Supported by grants from the Cancer Research Institute (CRI), Burroughs Wellcome Fund (BWF), the Parker Institute for Cancer Immunotherapy (PICI) and NIH grants AI068129 and AI146581.

The role of Cdk5/p35 kinase activity in natural killer cell cytotoxicity

Abstract Natural killer (NK) cells and T cells are immune cells with cytotoxic function, but while the distinct role of Cyclin-dependent kinase 5 (Cdk5) in the activation and effector function of T cells has been explored, its role in NK cells is unknown. Here, we show that both Cdk5 and its obligatory co-activator p35 protein are expressed in NK cells. We also detect Cdk5 kinase activity in NK cells, and kinase inhibition via p35 shRNA results in increased NK cell cytotoxicity. Overexpression of p35, which increases Cdk5 kinase activity, results in decreased NK cell cytotoxicity. Exogenous expression of a kinase-dead Cdk5 mutant that is still capable of binding p35 also increases NK cell cytotoxicity. Meanwhile, p35 knockout mouse NK cells exhibit significantly higher cytotoxicity against murine melanoma cells compared to wild-type NK cells. Based on our preliminary data, we conclude that Cdk5/p35 kinase activity negatively regulates NK cell cytotoxicity, with implications for the potential improvement of NK cell-based cancer immunotherapies. Supported by grants from the NIH (R21 CA246194, T32 GM007250) and the St. Baldrick's Scholar Award.

Influence of Self-MHC Class I Recognition on the Dynamics of NK Cell Responses to Cytomegalovirus Infection.

Although interactions between inhibitory Ly49 receptors and their self-MHC class I ligands in C57BL/6 mice are known to limit NK cell proliferation during mouse CMV (MCMV) infection, we created a 36-marker mass cytometry (CyTOF) panel to investigate how these inhibitory receptors impact the NK cell response to MCMV in other phenotypically measurable ways. More than two thirds of licensed NK cells (i.e., those expressing Ly49C, Ly49I, or both) in uninfected mice had already differentiated into NK cells with phenotypes indicative of Ag encounter (KLRG1+Ly6C-) or memory-like status (KLRG1+Ly6C+). These pre-existing KLRG1+Ly6C+ NK cells resembled known Ag-specific memory NK cell populations in being less responsive to IL-18 and IFN-α stimulation in vitro and by selecting for NK cell clones with elevated expression of a Ly49 receptor. During MCMV infection, the significant differences between licensed and unlicensed (Ly49C-Ly49I-) NK cells disappeared within both CMV-specific (Ly49H+) and nonspecific (Ly49H-) responses. This lack of heterogeneity carried into the memory phase, with only a difference in CD16 expression manifesting between licensed and unlicensed MCMV-specific memory NK cell populations. Our results suggest that restricting proliferation is the predominant effect licensing has on the NK cell population during MCMV infection, but the inhibitory Ly49-MHC interactions that take place ahead of infection contribute to their limited expansion by shrinking the pool of licensed NK cells capable of robustly responding to new challenges.

Combinatorial Expression of NK Cell Receptors Governs Cell Subset Reactivity and Effector Functions but Not Tumor Specificity.

NK cell receptors allow NK cells to recognize targets such as tumor cells. Many of them are expressed on a subset of NK cells, independently of each other, which creates a vast diversity of receptor combinations. Whether these combinations influence NK cell antitumor responses is not well understood. We addressed this question in the C57BL/6 mouse model and analyzed the individual effector response of 444 mouse NK cell subsets, defined by combinations of 12 receptors, against tumor cell lines originating from different tissues and mouse strains. We found a wide range of reactivity among NK subsets, but the same hierarchy of responses was observed for the different tumor types, showing that the repertoire of NK cell receptors does not encode for different tumor specificities but for different intrinsic reactivities. The coexpression of CD27, NKG2A, and DNAM-1 identified subsets with relative cytotoxic specialization, whereas reciprocally, CD11b and KLRG1 defined the best IFN-γ producers. The expression of educating receptors Ly49C, Ly49I, and NKG2A was also strongly correlated with IFN-γ production, but this effect was suppressed by unengaged receptors Ly49A, Ly49F, and Ly49G2. Finally, IL-15 coordinated NK cell effector functions, but education and unbound inhibitory receptors retained some influence on their response. Collectively, these data refine our understanding of the mechanisms governing NK cell reactivity, which could help design new NK cell therapy protocols.

Whole-genome profiling of DNA methylation and hydroxymethylation identifies distinct regulatory programs among innate lymphocytes.

Innate lymphocytes encompass a diverse array of phenotypic identities with specialized functions. DNA methylation and hydroxymethylation are essential for epigenetic fidelity and fate commitment. The landscapes of these modifications are unknown in innate lymphocytes. Here, we characterized the whole-genome distribution of methyl-CpG and 5-hydroxymethylcytosine in mouse ILC3, ILC2, and NK cells. We identified differentially methylated and hydroxymethylated DNA regions between ILC-NK subsets and correlated them with transcriptional signatures. We associated lineage-determining transcription factors with demethylation and demonstrated unique patterns of DNA methylation/hydroxymethylation in relationship to open chromatin regions, histone modifications, and transcription factor binding sites. We further discovered a novel association between hydroxymethylation and NK cell super-enhancers. Using mice lacking DNA hydroxymethylase TET2, we showed its requirement for optimal production of hallmark cytokines by ILC3 and IL-17A by inflammatory ILC2. These findings provide a powerful resource for studying innate lymphocyte epigenetic regulation and decode the regulatory logic governing their identity.

Phenotypic and Functional Plasticity of CXCR6+ Peripheral Blood NK Cells.

Human NK cells are comprised of phenotypic subsets, whose potentially unique functions remain largely unexplored. C-X-C-motif-chemokine-receptor-6 (CXCR6) + NK cells have been identified as phenotypically immature tissue-resident NK cells in mice and humans. A small fraction of peripheral blood (PB)-NK cells also expresses CXCR6. However, prior reports about their phenotypic and functional plasticity are conflicting. In this study, we isolated, expanded, and phenotypically and functionally evaluated CXCR6+ and CXCR6– PB-NK cells, and contrasted results to bulk liver and spleen NK cells. We found that CXCR6+ and CXCR6– PB-NK cells preserved their distinct phenotypic profiles throughout 14 days of in vitro expansion (“day 14”), after which phenotypically immature CXCR6+ PB-NK cells became functionally equivalent to CXCR6– PB-NK cells. Despite a consistent reduction in CD16 expression and enhanced expression of the transcription factor Eomesodermin (Eomes), day 14 CXCR6+ PB-NK cells had superior antibody-dependent cellular cytotoxicity (ADCC) compared to CXCR6– PB-NK cells. Further, bulk liver NK cells responded to IL-15, but not IL-2 stimulation, with STAT-5 phosphorylation. In contrast, bulk splenic and PB-NK cells robustly responded to both cytokines. Our findings may allow for the selection of superior NK cell subsets for infusion products increasingly used to treat human diseases.

Targeting Fc Receptor-Mediated Effects and the "Don't Eat Me" Signal with an Oncolytic Virus Expressing an Anti-CD47 Antibody to Treat Metastatic Ovarian Cancer.

mAbs blocking immune checkpoints have emerged as important cancer therapeutics, as exemplified by systemic administration of the IgG1 anti-CD47 mAb that blocks the "don't eat me" pathway. However, this strategy is associated with severe toxicity. To improve therapeutic efficacy while reducing toxicities for ovarian cancer, we engineered an oncolytic herpesvirus (oHSV) to express a full-length, soluble anti-CD47 mAb with a human IgG1 scaffold (OV-αCD47-G1) or IgG4 scaffold (OV-αCD47-G4). Both IgG1 and IgG4 anti-CD47 mAbs secreted by oHSV-infected tumor cells blocked the CD47-SIRPα signal pathway, enhancing macrophage phagocytosis against ovarian tumor cells. OV-αCD47-G1, but not OV-αCD47-G4, activated human NK-cell cytotoxicity and macrophage phagocytosis by binding to the Fc receptors of these cells. In vivo, these multifaceted functions of OV-αCD47-G1 improved mouse survival in xenograft and immunocompetent mouse models of ovarian cancer when compared with OV-αCD47-G4 and a parental oHSV. The murine counterpart of OV-αCD47-G1, OV-αmCD47-G2b, also enhanced mouse NK-cell cytotoxicity and macrophage phagocytosis and prolonged survival of mice bearing ovarian tumors compared with OV-αmCD47-G3. OV-αmCD47-G2b was also superior to αmCD47-G2b and showed a significantly better effect when combined with an antibody against PD-L1 that was upregulated by oHSV infection. Our data demonstrate that an oHSV encoding a full-length human IgG1 anti-CD47 mAb, when used as a single agent or combined with another agent, is a promising approach for improving ovarian cancer treatment via enhancing innate immunity, as well as performing its known oncolytic function and modulation of immune cells.

NKTR-255 is a polymer-conjugated IL-15 with unique mechanisms of action on T and natural killer cells.

NKTR-255 is a PEG conjugate of recombinant human IL-15 (rhIL-15) being examined as a potential cancer immunotherapeutic. Since IL-15 responses can be mediated by trans or cis presentation via IL-15Rα or soluble IL-15/IL-15Rα complexes, we investigated the role of IL-15Rα in driving NKTR-255 responses using defined naive and memory OVA-specific CD8+ T cells (OT-I) and NK cells in mice. NKTR-255 induced a 2.5- and 2.0-fold expansion of CD8+ T and NK cells, respectively, in WT mice. In adoptive transfer studies, proliferation of naive and memory WT OT-I T cells in response to NKTR-255 was not impaired in IL-15Rα-/- mice, suggesting trans presentation was not utilized by NKTR-255. Interestingly, naive IL-15Rα-/- OT-I cells had deficient responses to NKTR-255, while memory IL-15Rα-/- OT-I cell responses were partially impaired, suggesting that naive CD8+ T cells are more dependent on cis presentation of NKTR-255 than memory CD8+ T cells. In bone marrow chimera studies, IL-15Rα-/- and WT NK cells present in WT recipients had similar responses to NKTR-255, suggesting that cis presentation is not utilized by NK cells. NKTR-255 could form soluble complexes with IL-15Rα; binding to murine IL-15Rα generated superagonists that preferentially stimulated NK cells, showing that conversion to IL-15Rβ agonist biases the response toward NK cells. These findings highlight the ability of NKTR-255 to utilize IL-15Rα for cis presentation and act as an IL-15Rαβ agonist on CD8+ T cells.

TIPE2 is a checkpoint of natural killer cell maturation and antitumor immunity.

The maturation process of NK cells determines their functionality during which IL-15 plays a critical role. However, very few checkpoints specifically targeting this process have been discovered. Here, we report that TIPE2 expression gradually increased during NK cell ontogenesis correlating to their maturation stages in both mice and humans. NK-specific TIPE2 deficiency increased mature NK cells in mice, and these TIPE2-deficient NK cells exhibited enhanced activation, cytotoxicity, and IFN-γ production upon stimulation and enhanced response to IL-15 for maturation. Moreover, TIPE2 suppressed IL-15–triggered mTOR activity in both human and murine NK cells. Consequently, blocking mTOR constrained the effect of TIPE2 deficiency on NK cell maturation in response to IL-15. Last, NK-specific TIPE2-deficient mice were resistant to tumor growth in vivo. Our results uncover a potent checkpoint in NK cell maturation and antitumor immunity in both mice and humans, suggesting a promising approach of targeting TIPE2 for NK cell–based immunotherapies.

HSP70iQ435A to subdue autoimmunity and support anti-tumor responses.

Developing immunosuppressive therapies for autoimmune diseases comes with a caveat that immunosuppression may promote the risk of developing other conditions or diseases. We have previously shown that biolistic delivery of an expression construct encoding inducible HSP70 (HSP70i) with one amino acid modification in the dendritic cell (DC) activating moiety 435-445 (HSP70iQ435A) to mouse skin resulted in significant immunosuppressive activity of autoimmune vitiligo, associated with fewer tissue infiltrating T cells. To prepare HSP70iQ435A as a potential therapeutic for autoimmune vitiligo, in this study we evaluated whether and how biolistic delivery of HSP70iQ435A in mice affects anti-tumor responses. We found that HSP70iQ435A in fact supports anti-tumor responses in melanoma-challenged C57BL/6 mice. Biolistic delivery of the HSP70iQ435A-encoding construct to mice elicited significant anti-HSP70 titers, and anti-HSP70 IgG and IgM antibodies recognize surface-expressed and cytoplasmic HSP70i in human and mouse melanoma cells. A peptide scan revealed that the anti-HSP70 antibodies recognize a specific C-terminal motif within the HSP70i protein. The antibodies elicited surface CD107A expression among mouse NK cells, representative of antibody-mediated cellular cytotoxicity (ADCC), supporting the concept, that HSP70iQ435A-encoding DNA elicits a humoral response to the stress protein expressed selectively on the surface of melanoma cells. Thus, besides limiting autoimmunity and inflammation, HSP70iQ435A elicits humoral responses that limit tumor growth and may be used in conjunction with immune checkpoint inhibitors to not only control tumor but to also limit adverse events following tumor immunotherapy.

Anti-F4/80 treatment attenuates Th2 cell responses: Implications for the role of lung interstitial macrophages in the asthmatic mice

Lung interstitial macrophages (IMs) can be polarized towards an alternative activation phenotype in ovalbumin (OVA)-induced asthmatic mice. However, the role of alternative activation of lung IMs in Th2 cell responses in the asthmatic murine is still unclear. Here, we leverage an anti-F4/80 treatment which has been shown to selectively deplete IMs in mice and investigate how this treatment modulates Th2 cell responses in lung and whether the modulation is dependent on lung IMs in murine models of asthma. We show that anti-F4/80 treatment alleviates Th2 cell responses in mice immunized and challenged with OVA or house dust mite (HDM). The anti-F4/80 treatment does not target lung alveolar macrophages (AMs) in OVA-induced asthmatic mice or impact the abundance of other immune cell types, including B cells, T cells, and NK cells in wild-type mice. However, this treatment does inhibit the expression of polarized markers of alternatively activated macrophages, including arginase-1, Ym-1, and Fizz-1 in the lung tissues from OVA-induced asthmatic mice. Furthermore, we find that the inhibitory effects of anti-F4/80 treatment on Th2 cell responses can be reversed upon adoptive transfer of lung IMs. Taken together, our data show that anti-F4/80 treatment attenuates Th2 cell responses, which is at least partially related to depletion of lung IMs in murine models of asthma. This suggests that targeted lung IMs may provide a potential therapeutic protocol for the treatment of asthmatics.

Abstract 1563: DRP-104, a broad acting glutamine antagonist, synergizes with immune checkpoint blockade in vivo

Abstract We previously reported that DRP-104, a novel broad acting glutamine antagonist, has significant therapeutic potential in cancer by directly targeting tumor metabolism and simultaneously inducing a potent antitumor immune response. We also reported the immunomodulatory effect of DRP-104 on tumor growth inhibition (TGI) as a single agent and in combination with PD-1/PD-L1 checkpoint inhibitors in the MC38 and CT26 colon cancer syngeneic models(1). DRP-104 mediated TGI is associated with increased tumor-infiltrating leukocytes (TIL) including T, NKT, and NK cells; M1-polarized tumor associated macrophages; and decreased immune-suppressive cells such as MDSCs.Here we further elucidate the immunomodulatory effect of DRP-104 on tumor growth inhibition. In the MC38 mouse model, CD8+, CD4+, or NK cells were depleted by anti-CD8+Ab, anti-CD4+Ab, or anti-asialoGM1 Ab respectively to assess the contribution of these immune cells towards DRP-104 efficacy. CD8+T cell depletion significantly reduced anti-tumor efficacy for DRP-104 (73.9% TGI in CD8+T depletion setting vs 120% TGI with 57.8% regression in undepleted animals). NK cell depletion delayed early anti-tumor response to DRP-104 treatment, while in undepleted mice DRP-104 treatment showed TGI as early as 2 days after dose initiation. Interestingly, CD4+depleted mice showed enhanced efficacy to DRP-104 with TGI of 213% (regressions) and 6/8 tumor free mice 29 days after the end of treatment vs 1/8 mice tumor free in the CD4+ undepleted group with DRP-104 treatment. As such, we tested the combination of DRP-104 with anti-TIGIT antibody which has been reported to deplete Treg cells in the TME(2). In MC38 (anti-TIGIT insensitive) and CT26 (anti-TIGIT sensitive), DRP-104 showed significant single agent TGI. Furthermore, combination of DRP-104 with anti-TIGIT Ab demonstrated enhanced tumor growth inhibition and resulted in improvement in survival. In summary, immune cell depletion experiments confirmed DRP-104's immuno-oncology mechanism of action. CD8+ or NK cell depletion reduced DRP-104 efficacy while CD4+ cell depletion enhanced efficacy. Furthermore, combination therapy of DRP-104 with anti-PD-1 or anti-TIGIT Ab achieved significantly enhanced anti-tumor efficacy even in checkpoint inhibitor resistant models. This unique and non-overlapping mechanism of action supports clinical development of DRP-104 alone and in combination with immune checkpoint inhibitors. The first in human clinical study of DRP-104 is ongoing.

ADCC-Inducing Antibody Trastuzumab and Selection of KIR-HLA Ligand Mismatched Donors Enhance the NK Cell Anti-Breast Cancer Response.

Simple SummaryNatural killer (NK) cells are potent killers of tumor cells. Many tumors, including breast cancers, develop mechanisms to suppress anti-tumor immune responses, requiring the development of strategies to overcome suppression. Here, we tested a combination therapy that aims to (1) enhance NK cell activation and (2) reduce NK cell inhibition mediated by suppressive factors in tumors or in the tumor microenvironment. We cultured cell lines under hypoxia to mimic the tumor microenvironment or used patient-derived breast cancer cells that were primed by the patient’s tumor environment. Our results demonstrated that cytokine-activated NK cells remained active under hypoxia and that tumor-targeting antibodies enhanced the NK cell anti-breast cancer response. Moreover, we observed that NK cell suppression by inhibitory ligands on the tumor cells can be reduced by the selection of NK cell donors with NK receptors that are incompatible with these ligands. Collectively, we present two powerful strategies to enhance the NK cell responses against breast cancer.Natural killer (NK)-cell-based immunotherapies are an attractive treatment option for cancer. We previously showed that alloreactive mouse NK cells cured mice of 4T1 breast cancer. However, the tumor microenvironment can inhibit immune responses, and these suppressive factors must be overcome to unfold the NK cells’ full anti-tumor potential. Here, we investigated the combination of antibody-dependent cellular cytotoxicity (ADDC) and the selection of KIR-HLA-ligand mismatched NK cells to enhance NK cell anti-breast cancer responses in clinically relevant settings. Donor-derived and IL-2-activated NK cells were co-cultured with patient-derived breast cancer cells or cell lines MCF7 or SKBR3 together with the anti-HER2 antibody trastuzumab. NK cells mediated anti-breast cancer cytotoxicity under normoxic and hypoxic conditions. Under both conditions, trastuzumab vigorously enhanced NK cell degranulation (CD107a) against HER2-overexpressing SKBR3 cells, but we observed a discrepancy between highly degranulating NK cells and a rather modest increase in cytotoxicity of SKBR3. Against patient-derived breast cancer cells, the anti-tumor efficacy was rather limited, and HLA class I expression seemed to contribute to inhibited NK cell functionality. KIR-ligand-mismatched NK cells degranulated stronger compared to the matched NK cells, further highlighting the role of HLA. In summary, trastuzumab and KIR-ligand-mismatched NK cells could be two strategies to potently enhance NK cell responses to breast cancer.

Blockade of checkpoint receptor PVRIG unleashes anti-tumor immunity of NK cells in murine and human solid tumors

BackgroundAlthough checkpoint-based immunotherapy has shown exciting results in the treatment of tumors, around 70% of patients have experienced unresponsiveness. PVRIG is a recently identified immune checkpoint receptor and blockade of which could reverse T cell exhaustion to treat murine tumor; however, its therapeutic potential via NK cells in mice and human remains seldom reported.MethodsIn this study, we used patient paraffin-embedded colon adenocarcinoma sections, various murine tumor models (MC38 colon cancer, MCA205 fibrosarcoma and LLC lung cancer), and human NK cell- or PBMC-reconstituted xenograft models (SW620 colon cancer) to investigate the effect of PVRIG on tumor progression.ResultsWe found that PVRIG was highly expressed on tumor-infiltrating NK cells with exhausted phenotype. Furthermore, either PVRIG deficiency, early blockade or late blockade of PVRIG slowed tumor growth and prolonged survival of tumor-bearing mice by inhibiting exhaustion of NK cells as well as CD8+ T cells. Combined blockade of PVRIG and PD-L1 showed better effect in controlling tumor growth than using either one alone. Depletion of NK or/and CD8+ T cells in vivo showed that both cell types contributed to the anti-tumor efficacy of PVRIG blockade. By using Rag1−/− mice, we demonstrated that PVRIG blockade could provide therapeutic effect in the absence of adaptive immunity. Further, blockade of human PVRIG with monoclonal antibody enhanced human NK cell function and inhibited human tumor growth in NK cell- or PBMC-reconstituted xenograft mice.ConclusionsOur results reveal the importance of NK cells and provide novel knowledge for clinical application of PVRIG-targeted drugs in future.

TIGIT modulates sepsis-induced immune dysregulation in mice with preexisting malignancy.

TIGIT is a recently identified coinhibitory receptor that is upregulated in the setting of cancer and functionally contributes to the impairment of antitumor immunity. However, its role during sepsis is unknown. Because patients with cancer are 10 times more likely to die of sepsis than previously healthy (PH) patients with sepsis, we interrogated the role of TIGIT during sepsis in the context of preexistent malignancy. PH mice or cancer (CA) mice inoculated with lung carcinoma cells were made septic by cecal ligation and puncture (CLP). We found that sepsis induced TIGIT upregulation predominantly on Tregs and NK cells in both PH and CA mice. Anti-TIGIT Ab improved the 7-d survival of CA septic mice but not PH mice after CLP. Treatment of CA septic animals but not PH septic animals with anti-TIGIT mAb significantly reversed sepsis-induced loss of CD4+ T cells, CD8+ T cells, Foxp3+ Treg, and CD19+ B cells in the spleen, which was the result of decreased caspase-3+ apoptotic cells. In sum, we found that anti-TIGIT Ab reversed sepsis-induced T cell apoptosis in CA septic mice and led to a significant survival benefit, suggesting its use as a potential immunotherapy to improve outcomes in septic patients with cancer.

Downregulation of NK cell activities in Apolipoprotein C-III-induced hyperlipidemia resulting from lipid-induced metabolic reprogramming and crosstalk with lipid-laden dendritic cells

ObjectiveApolipoprotein C-III (Apoc3) is a key component of triglyceride-rich lipoproteins (TRL). The Apoc3-transgenic mice are characterized by high levels of plasma triglyceride and free fatty acids (FFAs). Apoc3 stimulates human monocytes via activation of the NLRP3 inflammasome. Considering the NK cell downregulation in obese individuals and the possible stimulatory-effects of macrophages, variations of NK cell functions and underlying mechanisms were investigated in mice with Apoc3-induced hyperlipidemia. MethodsVariations of activities and glycolipid metabolism in NK cells of the Apoc3-transgenic mice with hyperlipidemia were detected. Molecular mechanisms of lipid-induced metabolic-reprogramming in NK cells were analyzed based on the transcriptome sequencing. Finally, effects of DCs in mice with hyperlipidemia on NK cell functions were determined. ResultsImpaired number and function of NK cells in Apoc3TG mice was involved with the increased fatty acid oxidation and decreased glycolysis. Increased uptake of FFAs in Apoc3TG-NK cells contributed to the peroxisome proliferator-activated receptor (PPAR) activation and the downstream PTEN–AKT–mTOR/FOXO1 signaling pathway. Inhibition of PPAR or CPT1α only partly reversed the IFN-γ production of Apoc3TG-NK cells, but completely restored IFN-γ secretion by palmitic acid-treated NK cells ex vivo, indicating that other factors contributed to the Apoc3TG-NK cell downregulation. Meanwhile, Apoc3TG-DCs, which contained more lipids in the cytoplasm, depended on reactive oxygen species (ROS) to increase the expressions PD-L1, TGF-β1, and NKG2D ligands and suppress NK cell activities. DCs of the Apoc3TG-CD36−/+ hybrid mice with less intracellular lipids and ROS production could not inhibit NK cells, indicating that intracellular FFAs promoted the immune-modulatory function of DCs. ConclusionsThe downregulation of NK cell activities in individuals with Apoc3-induced hyperlipidemia was due to the increased fatty acid oxidation in NK cells and the bystander suppression caused by lipid-laden DCs. The dual recovery function of NK cells and DCs would improve the prognosis of patients with metabolic syndrome.