Project description:A key mechanism of tumor resistance to immune cells is mediated by expression of peptide-loaded HLA-E in tumor cells, which suppresses natural killer (NK) cell activity via ligation of the NK inhibitory receptor CD94/NKG2A. To bypass HLA-E inhibition, we developed a way to generate highly functional NK cells lacking NKG2A. Constructs containing a single-chain variable fragment derived from an anti-NKG2A antibody were linked to endoplasmic reticulum-retention domains. After retroviral transduction in human peripheral blood NK cells, these NKG2A Protein Expression Blockers (PEBLs) abrogated NKG2A expression. The resulting NKG2Anull NK cells had higher cytotoxicity against HLA-E-expressing tumor cells.

Project description:Persistent exposure to antigen leads to T cell exhaustion and immunologic dysfunction. We examined the immune exhaustion markers TIGIT and PD-1 in HIV-infected and healthy individuals and the relationship with cytotoxic CD8+ T lymphocyte (CTL) activity. Frequencies of TIGIT but not PD-1 positively correlated with CTL activity in HIV-aviremic and healthy individuals; however, there was no correlation in HIV-viremic individuals. Transcriptome analyses revealed upregulation of genes associated with antiviral immunity in TIGIT+ versus TIGIT-CD8+ T cells. Our data suggest that TIGIT+CD8+ T cells do not necessarily represent a state of immune exhaustion and maintain an intrinsic cytotoxicity in HIV-infected individuals.

Project description:Cancer immunotherapy is gaining increasing attention. However, immune checkpoints are exploited by cancer cells to evade anti-tumor immunotherapy. Here, we knocked out NKG2A, an immune checkpoint expressed on natural killer (NK) cells, in human pluripotent stem cells (hPSCs) and differentiated these hPSCs into NK (PSC-NK) cells. We show that NKG2A knockout (KO) enhances the anti-tumor and anti-viral capabilities of PSC-NK cells. NKG2A KO endows PSC-NK cells with higher cytotoxicity against HLA-E-expressing glioblastoma (GBM) cells, leukemia cells, and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)-infected cells in vitro. The NKG2A KO PSC-NK cells also exerted potent anti-tumor activity in vivo, leading to substantially suppressed tumor progression and prolonged survival of tumor-bearing mice in a xenograft GBM mouse model. These findings underscore the potential of PSC-NK cells with immune checkpoint KO as a promising cell-based immunotherapy. The unlimited supply and ease of genetic engineering of hPSCs makes genetically engineered PSC-NK an attractive option for easily accessible "off-the-shelf" cancer immunotherapy.

Project description:New targets that enhance anti-tumor immunity must be identified to improve the efficacy of cancer immunotherapy. Here we show that loss of endoplasmic reticulum aminopeptidase (ERAP) family proteins improves anti-tumor immunity and synergizes with immune checkpoint blockade. Mechanistically, we show that loss of ERAP inactivates the HLA-E/NKG2A checkpoint, which normally restrains tumor killing by both CD8+ T cells and NK cells. The inhibitory activity of HLA-E is dependent on its presentation of a restricted set of invariant epitopes which form the binding surface for the NKG2A/CD94 receptor complex. Using genetic screening, in vivo models, cell-based assays, and immunopeptidomics, we show that loss of ERAP activity prevents the processing of these invariant peptides and alters the presented peptidome of both HLA-E and classical MHC-I. HLA-E neo-peptides presented after ERAP deletion are unable to bind the NKG2A/CD94 receptor, rendering tumor cells highly susceptible to killing by NKG2A+ cytotoxic T and NK cells. Thus, loss of ERAP phenocopies the loss or inhibition of the HLA-E/NKG2A pathway and represents an attractive therapeutic approach to inhibit this critical checkpoint. More broadly, this work identifies ERAP1/2 as druggable intracellular enzymes that could be targeted using small molecules to inactivate a cell-surface inhibitory pathway and represents a novel approach to therapeutic modulation of immune responses.

Project description:Human lymphoid tissues harbor, in addition to CD56bright and CD56dim natural killer (NK) cells, a third NK cell population: CD69+CXCR6+ lymphoid tissue (lt)NK cells. The function and development of ltNK cells remain poorly understood. In this study we performed RNA sequencing on the CD56bright and CD56dim NK cells (from bone marrow and blood), and the ltNK cells (from bone marrow). In addition, the blood derived CD56dim, and bone marrow derived ltNK cells were further subdivided into a NKG2A+ and NKG2A- fraction. Paired blood and bone marrow samples of 4 healthy donors were included. When comparing the NKG2A fractions, only 3 genes (of 9382 genes included) had a significantly differential expression. Therefore, we pooled the expression data proportionally from the NKG2A+ and NKG2A- fractions in subsequent analyses. In ltNK cells, 1353 genes were differentially expressed compared to circulating NK cells. Several molecules involved in migration were downregulated in ltNK cells: S1PR1, SELPLG and CD62L. By flow cytometry we confirmed that the expression profile of adhesion molecules (CD49e-, CD29low, CD81high, CD62L-, CD11c-) and transcription factors (Eomeshigh, Tbetlow) of ltNK cells differed from their circulating counterparts. LtNK cells were characterized by enhanced expression of inhibitory receptors TIGIT and CD96 and low expression of DNAM1 and cytolytic molecules (GZMB, GZMH, GNLY). Their proliferative capacity was reduced compared to the circulating NK cells. By performing gene set enrichment analysis we identified DUSP6 and EGR2 as potential regulators of the ltNK cell transcriptome. Remarkably, comparison of the ltNK cell transcriptome to the published human spleen-resident memory CD8+ T (Trm) cell transcriptome revealed an overlapping gene signature. Moreover, the phenotypic profile of ltNK cells resembled that of CD8+ Trm cells in bone marrow. Together, we provide a comprehensive molecular framework of the conventional CD56bright and CD56dim NK cells as well as the tissue-resident ltNK cells and provide a core gene signature which might be involved in promoting tissue-residency.

Project description:Checkpoint blockage has revolutionized cancer treatment. NKG2A is an inhibitory receptor expressed by cytotoxic lymphocytes, including NK cells. In contrast to other checkpoint inhibitory antibodies, anti-NKG2A antibodies have shown only limited success. Here, we designed a Cas9-based strategy to delete KLRC1 from human NK cells. Electroporation of KLRC1-targeting Cas9-RNP efficiently eliminated NKG2A expression from primary human NK cells. NKG2A-deficient NK cells showed normal proliferation, only minor transcriptional changes related to enhanced NK cell activation and maintained their phenotype and licensing status. Genetic deletion of NKG2A fully bypassed HLA-E inhibition and further enhanced NK cell activity against various tumor cell lines, thereby outperforming anti-NKG2A antibodies. In combination with antibody-coating of tumor cells to induce antibody-dependent cellular cytotoxicity, genetic deletion of NKG2A independently promoted cytotoxicity. Thus, Cas9-mediated targeting of NKG2A is an effective way to target this important inhibitory checkpoint. This technique is easily amenable to adoptive cell therapy in the clinical setting, where NKG2A deletion will promote anti-tumor responses and may help NK cells to better infiltrate and persist in an inhibitory tumor microenvironment.

Project description:We investigated the effects of HIV infection on immune cell exhaustion at the transcriptomic level by analyzing single-cell RNA sequencing of peripheral blood mononuclear cells from four healthy subjects (37,847 cells) and six HIV-infected donors (28,610 cells). We identified nine immune cell clusters and eight T cell subclusters according to their unique gene expression programs; three of these (exhausted CD4+ and CD8+ T cells and interferon-responsive CD8+ T cells) were detected only in samples from HIV-infected donors. An inhibitory receptor KLRG1 was identified in the exhausted T cell populations and further characterized in HIV infected individuals. We identified a HIV-1 specific exhausted CD8+ T cell population expressing KLRG1, TIGIT, and T-betdimEomeshi markers. Ex-vivo antibody blockade of KLRG1 restored the function of HIV-specific exhausted CD8+ T cells demonstrating the contribution of KLRG1+ population to T cell exhaustion and providing an immunotherapy target to treat HIV chronic infection. Analysis of gene signatures also revealed impairment of B cell and NK cell function in HIV-infected donors. These data provide a comprehensive analysis of gene signatures associated with immune cell exhaustion during HIV infection, which could be useful in understanding exhaustion mechanisms and developing new cure therapies.

Project description:Tumor resistance to immune cells remains a major obstacle for successful treatment. NK cells are emerging tools for cancer therapy. However, due to differential and subset-specific expression of inhibitory NK cell receptors, often only subsets of NK cells exert reactivity against particular cancer types. Using a genome-wide CRISPR/Cas9 knockout (KO) screen in melanoma, we revealed resistance factors against NK cell attack and evaluated their differential impact on NK cell subpopulations. We show that melanoma cells deficient in antigen-presenting machinery or the IFNγ signaling pathway displayed enhanced sensitivity to NK cell killing. Treatment with IFNγ induced melanoma cell resistance that depended on B2M required for both classical and non-classical MHC-I expression. HLA-E mediated melanoma cell resistance to NKG2A+ KIR-, and partially to NKG2A+ KIR+ NK cells. Treatment of NK cells with the NKG2A blocking monalizumab resulted in enhanced NK cell reactivity to similar extent as deletion of HLA-E in melanoma cells. The combination of monalizumab with lirilumab, blocking KIR2 receptors, together with DX9, an anti-KIR3DL1 mAb, was required to restore the response of all NK cells against IFNγ-pretreated tumor cells of different origins. Our data reveal insights into NK cell subset reactivity and strategies how to leverage their full anti-tumor potential.

Project description:Primary chimeric antigen receptor (CAR) natural killer (NK) cells show strong cytotoxic efficacy against acute myeloid leukemia (AML) in vivo. However, NK cell-mediated tumor killing is often impaired by tumor-mediated immune cell inactivation. Here, we report a novel strategy to overcome NK cell inhibition caused by the immune checkpoint NKG2A, which interacts with HLA-E expressed on AML blasts. We generated AML-specific CD33-directed CAR (CAR33)-KLRC1ko-NK cells with CRISPR/Cas9-based gene editing of the NKG2A-encoding KLRC1 gene. Single-cell multi-omic analyses revealed a higher proportion of activated cells in CAR33-NK- and CAR33-KLRC1ko-NK pools, which were preserved following AML-cell contact. This activated state of the CAR33-KLRC1ko-NK cells has been translated into improved antileukemic activity in vitro and in vivo against AML cell lines and primary blasts. This dual modification of primary NK cells has the potential to bypass the suppressive effect not only of AML but also in a broad range of other cancer identities.

Project description:Accumulating evidences suggest that colorectal cancer (CRC) progression is not solely determined by the genetic abnormalities of the tumor cells but also by the host response. Indeed, recent studies in CRC have associated improved survival with a high number of tumor-infiltrating (TIL) memory and cytotoxic T lymphocytes, suggesting a link between tumor progression and in situ T cell response. Gene expression profiling studies have clearly isolated a well-known subgroup of CRC characterized by microsatellite instability (MSI) CRC, associated with a strong immune response signature involving both Th1/cytotoxic and immune evasion pathways. Moreover, the investigators have previously shown that HLA-E/β2m is overexpressed by tumor cells in roughly 20% of CRC and is associated with a worse prognosis, most likely due to NK and T effector cell functions upon engagement with the inhibitory NK receptor CD94/NKG2A. However, our recent results on an enlarger cohort of patients suggest that if this observation holds true for MSS CRC, HLA-E over-expression is inversely associated with a good prognosis in MSI CRC. Thus, the phenotype and function of TIL, depending on the MSI/MSS status of CRC have to be precised. The investigators hypothesized that in MSI CRC, known to express a high number of MSI-H related frameshift peptides which represent a pool of tumor specific antigens, HLA-E could present peptides to TCR of non conventional CD8+ HLA-E-restricted alpha-betaT cells (also expressing CD94), then inducing a strong antitumor cytolytic activity. Therefore, the aim of this project is to determine the exact phenotype, function and specificity of the CD94+ TIL in CRC, depending on both the HLA-E and the MSI/MSS status of tumor cells. These results could impact the clinical practice as anti-NKG2A monoclonal antibodies or frameshift peptide based immunotherapy that could be promising new therapeutic options in CRC patients.