Project description:Resistance of tumor cells to cell-mediated cytotoxicity remains a drawback in the immunotherapy of cancer and its molecular basis is poorly understood. To investigate the acquisition of tumor resistance to cell-mediated cytotoxicity, resistant variants were selected following long term NK cell selection pressure. We found that these variants are resistant to NK cell-mediated lysis but still sensitive to autologous cytotoxic T lymphocytes or cytotoxic drugs. This resistance seems to be dependent, at least partly, of an alteration of the target cell recognition by NK effector cells, but does not appear to involve any alteration of KIR, DNAM1 or NKG2D ligands expression on resistant cells nor the induction of a protective autophagy. To gain further insight into the molecular mechanisms underlying the acquired tumor resistance to NK cells-mediated cytotoxicity, we have conducted a comprehensive analysis of the variants transcriptome. Comparative analysis identified an expression profile of genes that best distinguished resistant variant from parental sensitive cancer cells with candidate genes putatively involved in NK cell-mediated lysis resistance, but also in adhesion, migration and invasiveness including up-regulated genes such as POT1, L1CAM or ECM1 and down-regulated genes like B7-H6 or UCHL1. Consequently, the selected variants did not only display resistance to NK cell-mediated lysis but also exhibited more aggressive properties. The present studies emphasize that NK cells expand far beyond the simple killing of malignant cells and may be important effectors during cancer immunoediting.This study aims to compare transcriptome of T1_ref cells (2 triplicates samples untreated versus 2 triplicate samples of T1 after cocultured with NK cells).

Project description:CAR-T cell therapy against MM currently shows promising results, but usually with serious toxicities. CAR-NK cells may exert less toxicity when redirected against resistant myeloma cells. CARs can be designed through the use of receptors, such as NKG2D, which recognizes a wide range of ligands to provide broad target specificity. Here, we test this approach by analyzing the anti-tumor activity of activated and expanded NK cells (NKAE) and CD45RA- T cells from MM patients that were engineered to express an NKG2D-based CAR. NKAE cells were cultured with irradiated Clone9.mbIL21 cells. Then, cells were transduced with an NKG2D-4-1BB-CD3z-CAR. CAR-NKAE cells exhibited no evidence of genetic abnormalities. Although memory T cells were more stably transduced, CAR-NKAE cells exhibited greater in vitro cytotoxicity against MM cells, while showing minimal activity against healthy cells. In vivo, CAR-NKAE cells mediated highly efficient abrogation of MM growth, and two of the treated mice remained disease-free. Overall, these results demonstrate that it is feasible to modify autologous NKAE cells from MM patients to safely express a NKG2D-CAR. Additionally, autologous CAR-NKAE cells display enhanced anti-myeloma activity demonstrating that they could be an effective strategy against MM supporting the development of NKG2D-CAR NK cell therapy for MM.

Project description:This model describes the effects of Il-21 on tumor eradication via natural killer cell-mediated and CD8+ T-cell-mediated lysis of tumor cells. The model demonstrates changes in growth dynamics in nonimmunogenic B16 melanoma and the immunogenic MethA and MCA205 fibrosarcomas, showing a strong dependence of the NK-cell/CD8+ T-cell balance on tumor immunogenicity.

Project description:Natural Killer cells (NK), a major constituent of innate immune system, have the ability to kill the transformed and infected cells without prior sensitization; can be put to immunotherapeutic use against various malignancies. NK cells discriminate between normal cells and transformed cells via a balance of inhibitory and activating signals induced by interactions between NK cell receptors and target cell ligands. Present study investigates whether expansion of NK cells could augment their anti-myeloma (MM) activity. For NK cell expansion, peripheral blood mononuclear cells from healthy donors and myeloma patients were co-cultured with irradiated K562 cells transfected with 4-1BBL and membrane-bound IL15 (K562-mb15-41BBL). A genome-wide profiling approach was performed to identify gene expression signature in expanded NK (ENK) cells and non-expanded NK cells isolated from healthy donors and myeloma patients. A specific set of genes involved in proliferation, migration, adhesion, cytotoxicity, and activation were up regulated post expansion, also confirmed by flow cytometry. Exp-NK cells killed both allogeneic and autologous primary MM cells more avidly than non-exp-NK cells in vitro. Multiple receptors, particularly NKG2D, natural cytotoxicity receptors, and DNAM-1 contributed to target lysis, via a perforin mediated mechanism. In summary, vigorous expansion and high anti-MM activity both in vitro and in vivo provide the rationale for testing exp-NK cells in a clinical trial for high risk MM. Differential gene expression profile in expanded natural killer (ENK) cells and non-expanded natural killer (NK) cells from healthy donors and myeloma patients Eight healthy donor and eight myeloma patients were used in the study. Non-expanded natural killer (NK) cells were isolated from PBMCs of healthy donors and myeloma patients. Expanded natural killer (ENK) cells were generated from same set of samples as mentioned in expansion protocol. All ENK and NK cells were used for gene expression profiling.

Project description:Somatic mutations can lead to the transformation of healthy cells into malignant cells and allow their evasion from immune surveillance. To uncover genes that play a role in the detection and lysis of tumor cells by natural killer (NK) cells, a B lymphoblastoid cell line was subjected to a genome-wide CRISPR screen. Deletion of genes for death receptor and ligands for NK activation receptors was found in cells that survived incubation with primary NK cells. Among the top hits that facilitated NK evasion was SPPL3, a gene for an endoprotease that cleaves transmembrane glycosyl transferases. SPPL3-deficient cells accumulated glycosyl transferases, such as MGAT5, and displayed increased N-glycosylation. Binding of NK receptors NKG2D and CD2 to their corresponding ligands MICB and CD58, and binding of rituximab to CD20, was disrupted. Inhibition of N-glycan maturation restored receptor binding and sensitivity to NK cells. To investigate the cause of this resistant phenotype, a secondary CRISPR screen using a glycosylation-focused library was performed in SPPL3-deficient cells. This screen identified transferases that promote the formation of highly branched N-glycans and N-acetyl-lactosamine (LacNAc) extensions as key regulators that prevent killing. A significant enrichment of poly-LacNAc-containing tetra-antennary species was confirmed by glycoproteomic analysis. These findings provide a basis for understanding why SPPL3 deletions have been linked to cancer.

Project description:Cancer associated fibroblasts (CAFs) are one of the most abundant components of the breast tumor microenvironment (TME) and major contributors to immune modulation in the TME. CAFs are well known to regulate the activity of diverse types of immune cells including T cells, macrophages and dendritic cells, however little is known about their interaction with Natural killer (NK) cells. NK cells constitute an important arm of anti-tumor immunity, yet the regulation of NK cell activity by CAFs in solid tumors is poorly understood. Here we find, using mouse models of cancer and ex-vivo cocultures, that immunosuppressive CAF subsets severely inhibit NK cell cytotoxicity towards cancer cells. We unravel the mechanism by which this suppression occurs, through CAF-mediated downregulation of the NK-surface receptors, Natural Killer Group 2D (NKG2D) and DNAX Accessory Molecule-1 (DNAM-1). Ligands for these receptors are known to be expressed by cancer cells and minimally expressed in healthy tissue. Here we find that CAFs also upregulate ligands for NKG2D and DNAM-1. Ligand-receptor engagement between NK cells and CAFs leads to CAF cytolysis, which in turn diminishes the expression of NKG2D and DNAM-1 on NK cells via a negative feedback loop, and promotes cancer escape from NK cell surveillance. These results reveal a CAF-mediated immunosuppressive mechanism with implications for treatment of solid tumors.

Project description:Cancer associated fibroblasts (CAFs) are one of the most abundant components of the breast tumor microenvironment (TME) and major contributors to immune modulation in the TME. CAFs are well known to regulate the activity of diverse types of immune cells including T cells, macrophages and dendritic cells, however little is known about their interaction with Natural killer (NK) cells. NK cells constitute an important arm of anti-tumor immunity, yet the regulation of NK cell activity by CAFs in solid tumors is poorly understood. Here we find, using mouse models of cancer and ex-vivo cocultures, that immunosuppressive CAF subsets severely inhibit NK cell cytotoxicity towards cancer cells. We unravel the mechanism by which this suppression occurs, through CAF-mediated downregulation of the NK-surface receptors, Natural Killer Group 2D (NKG2D) and DNAX Accessory Molecule-1 (DNAM-1). Ligands for these receptors are known to be expressed by cancer cells and minimally expressed in healthy tissue. Here we find that CAFs also upregulate ligands for NKG2D and DNAM-1. Ligand-receptor engagement between NK cells and CAFs leads to CAF cytolysis, which in turn diminishes the expression of NKG2D and DNAM-1 on NK cells via a negative feedback loop, and promotes cancer escape from NK cell surveillance. These results reveal a CAF-mediated immunosuppressive mechanism with implications for treatment of solid tumors.

Project description:Background: Poly (ADP-ribose) polymerase inhibitors (PARPi) prevent single-stranded DNA repair. Olaparib is a PARPi approved for the treatment of BRCA mutant ovarian and breast carcinoma. Emerging clinical data suggest a benefit of combining olaparib with immunotherapy in prostate cancer patients both with and without somatic BRCA mutations. Methods: We examined if olaparib, when combined with IgG1 antibody-dependent cellular cytotoxicity (ADCC)-mediating monoclonal antibodies (mAbs) cetuximab (anti-EGFR), or avelumab (anti-PD-L1), would increase tumor cell sensitivity to killing by natural killer (NK) cells independently of BRCA status or mAb target upregulation. BRCA mutant and BRCA wildtype (WT) prostate carcinoma cell lines were pretreated with olaparib and then exposed to NK cells in the presence or absence of cetuximab or avelumab. Results: NK-mediated killing was significantly increased in both cell lines and was further increased using the ADCC-mediating mAbs. Pre-exposure of NK cells to recombinant IL-15/IL-15RA further increased the lysis of olaparib treated tumor cells. In addition, olaparib treated tumor cells were killed to a significantly greater degree by engineered high-affinity NK cells (haNK). We show here for the first time that (a) olaparib significantly increased tumor cell sensitivity to NK killing and ADCC in both BRCA WT and BRCA mutant prostate carcinoma cells, independent of PD-L1 or EGFR modulation; (b) mechanistically, treatment with olaparib upregulated death receptor TRAIL-R2, and (c) olaparib significantly enhanced NK killing of additional tumor types, including breast, non-small cell lung carcinoma, and chordoma. Conclusions: These studies support the combined use of NK- and ADCC-mediating agents with correctly timed PARP inhibition.

Project description:Epigenetic modulation elicits an NK-mediated Immune Response in Urothelial Carcinoma

Project description:Natural Killer cells (NK), a major constituent of innate immune system, have the ability to kill the transformed and infected cells without prior sensitization; can be put to immunotherapeutic use against various malignancies. NK cells discriminate between normal cells and transformed cells via a balance of inhibitory and activating signals induced by interactions between NK cell receptors and target cell ligands. Present study investigates whether expansion of NK cells could augment their anti-myeloma (MM) activity. For NK cell expansion, peripheral blood mononuclear cells from healthy donors and myeloma patients were co-cultured with irradiated K562 cells transfected with 4-1BBL and membrane-bound IL15 (K562-mb15-41BBL). A genome-wide profiling approach was performed to identify gene expression signature in expanded NK (ENK) cells and non-expanded NK cells isolated from healthy donors and myeloma patients. A specific set of genes involved in proliferation, migration, adhesion, cytotoxicity, and activation were up regulated post expansion, also confirmed by flow cytometry. Exp-NK cells killed both allogeneic and autologous primary MM cells more avidly than non-exp-NK cells in vitro. Multiple receptors, particularly NKG2D, natural cytotoxicity receptors, and DNAM-1 contributed to target lysis, via a perforin mediated mechanism. In summary, vigorous expansion and high anti-MM activity both in vitro and in vivo provide the rationale for testing exp-NK cells in a clinical trial for high risk MM. Differential gene expression profile in expanded natural killer (ENK) cells and non-expanded natural killer (NK) cells from healthy donors and myeloma patients