Project description:Suppressive myeloid cells can contribute to immunotherapy resistance, but their role in response to checkpoint inhibition (CPI) in anti-PD-1 refractory cancers, such as biliary tract cancer (BTC), is largely unknown. We use multiplexed single-cell transcriptomic and epitope sequencing to profile greater than 200,000 peripheral blood mononuclear cells from advanced BTC patients (n=9) and matched healthy donors (n=8). Following anti-PD-1 treatment, CD14+ monocytes expressing high levels of immunosuppressive cytokines and chemotactic molecules (CD14CTX) increase in the circulation of patients with BTC tumors that are CPI-resistant. CD14CTX can directly suppress CD4+ T cells and induce SOCS3 expression in CD4+ T cells rendering them functionally unresponsive. The CD14CTX gene signature associates with worse survival in patients with BTC as well as in other anti-PD-1 refractory cancers. These results demonstrate that monocytes arising after anti-PD-1 treatment can induce T cell paralysis as a distinct mode of tumor-mediated immunosuppression leading to CPI resistance. 

Project description:Suppressive myeloid cells can contribute to immunotherapy resistance, but their role in response to checkpoint inhibition (CPI) in anti-PD-1 refractory cancers, such as biliary tract cancer (BTC), is largely unknown. We use multiplexed single-cell transcriptomic and epitope sequencing to profile greater than 200,000 peripheral blood mononuclear cells from advanced BTC patients (n=9) and matched healthy donors (n=8). Following anti-PD-1 treatment, CD14+ monocytes expressing high levels of immunosuppressive cytokines and chemotactic molecules (CD14CTX) increase in the circulation of patients with BTC tumors that are CPI-resistant. CD14CTX can directly suppress CD4+ T cells and induce SOCS3 expression in CD4+ T cells rendering them functionally unresponsive. The CD14CTX gene signature associates with worse survival in patients with BTC as well as in other anti-PD-1 refractory cancers. These results demonstrate that monocytes arising after anti-PD-1 treatment can induce T cell paralysis as a distinct mode of tumor-mediated immunosuppression leading to CPI resistance. 

Project description:Checkpoint inhibitors (CPIs) targeting PD-1/PD-L1 and CTLA-4 have revolutionized cancer treatment but can trigger autoimmune complications including CPI-induced diabetes (CPI-DM), which occurs preferentially with PD-1 blockade. We found evidence of pancreatic inflammation in patients with CPI-DM with shrinkage of pancreases, increased pancreatic enzymes, and in a case from a patient who died with CPI-DM, peri-islet lymphocytic infiltration. In the NOD mouse model, anti-PD-L1 but not anti-CTLA-4 induces DM rapidly. RNA sequencing revealed that cytolytic IFNγ+ CD8+ T cells infiltrated islets with anti-PD-L1. Changes in β cells were predominantly driven by IFNγ and TNFα and included induction of a novel β cell population with transcriptional changes suggesting dedifferentiation. IFNγ increased checkpoint ligand expression and activated apoptosis pathways in human β cells in vitro. Treatment with anti-IFNγ and anti-TNFα prevented CPI-DM in anti-PD-L1 treated NOD mice. CPIs targeting the PD-1/PD-L1 pathway result in transcriptional changes in β cells and immune infiltrates that may lead to the development of diabetes. Inhibition of inflammatory cytokines can prevent CPI-DM, suggesting a strategy for clinical application to prevent this complication.

Project description:Checkpoint inhibitors (CPIs) targeting PD-1/PD-L1 and CTLA-4 have revolutionized cancer treatment but can trigger autoimmune complications including CPI-induced diabetes (CPI-DM), which occurs preferentially with PD-1 blockade. We found evidence of pancreatic inflammation in patients with CPI-DM with shrinkage of pancreases, increased pancreatic enzymes, and in a case from a patient who died with CPI-DM, peri-islet lymphocytic infiltration. In the NOD mouse model, anti-PD-L1 but not anti-CTLA-4 induces DM rapidly. RNA sequencing revealed that cytolytic IFNγ+ CD8+ T cells infiltrated islets with anti-PD-L1. Changes in β cells were predominantly driven by IFNγ and TNFα and included induction of a novel β cell population with transcriptional changes suggesting dedifferentiation. IFNγ increased checkpoint ligand expression and activated apoptosis pathways in human β cells in vitro. Treatment with anti-IFNγ and anti-TNFα prevented CPI-DM in anti-PD-L1 treated NOD mice. CPIs targeting the PD-1/PD-L1 pathway result in transcriptional changes in β cells and immune infiltrates that may lead to the development of diabetes. Inhibition of inflammatory cytokines can prevent CPI-DM, suggesting a strategy for clinical application to prevent this complication.

Project description:Checkpoint inhibition (CPI), particularly that targeting the inhibitory co-receptor, programmed cell death protein (PD-1), has transformed cancer care. Although CPI can de repress cancer antigen-specific αβ T cells that ordinarily show PD-1-dependent exhaustion, it can also be efficacious against cancers evading αβ T cell recognition. In such settings γδ T cells have been implicated, but the immunological significance of PD-1 expression by tissue associated human Vδ1+ cells remains uncharacterised. Here we demonstrate that a transcriptional signature of intratumoral Vδ1+ cells predicts response to anti-PD-1 in patients with melanomas of relatively low neoantigen load. Moreover, by employing a protocol yielding substantial numbers of human skin γδ cells, we show that PD-1+ Vδ1+ cells display a transcriptomic programme of tissue-residence, survival/self-renewal, and functional competence distinct from the canonical exhaustion programme of co-located PD- 1+ CD8+ αβ T cells. Indeed, skin PD-1+ Vδ1+ cells retained effector responses to T cell receptor signalling that were inhibitable by PD-1 engagement and partially derepressed by CPI. The biological and therapeutic implications are both discussed.

Project description:Checkpoint inhibitor colitis (CPI colitis) is a frequent immune-related adverse event resulting from cancer immunotherapy that is currently treated with empiric immunosuppression such as corticosteroids. A greater understanding of the pathogenesis of CPI colitis in the steroid-refractory setting is required to develop better colitis interventions targeted to each patient. Using paired colon biopsies and blood from steroid-experienced patients with endoscopically confirmed CPI colitis, combined with control patients, we performed multiplexed single-cell transcriptomics (scRNA/TCRseq) and proteomics (CITEseq, CyTOF) to identify contributing immune and non-immune populations. In CPI colitis patient biopsies compared to healthy controls, we found enrichment of resident memory (RM) T cells in both the CD8+ and unexpectedly the CD4+ compartments, as well as cytotoxic CD8+ T cells. These 3 populations expressed exact matching TCR, suggesting that CD4+ RM and CD8+ RM T cells are clonal progenitors that give rise to tissue-destructive cytotoxic effectors. Unbiased CyTOF and confirmatory scRNAseq and CITEseq analysis identifies specific mobilized subpopulations of both cytotoxic CD8+ and CD4+ RM cells that express both activation markers CD38 and HLA-DR, underscoring their pathogenic potential. CPI colitis induces global upregulation of interferon signaling and antigen presentation, as well as epithelial-specific dysregulation of homeostatic pathways (aquaporin/solute transporters) which is shared with ulcerative colitis. However, distinct from ulcerative colitis, CPI colitis involves specific alterations in stromal cell metabolic (NAD+, tryptophan) or extracellular signaling (BMP) pathways that directly impact epithelial cell survival, arguing for distinct therapeutic targeting. Finally, endothelial cells in CPI colitis demonstrate enrichment of the integrin 47 ligand MADCAM-1 (which is targeted by anti-47 antibody vedolizumab to treat colitis). This ligand is enriched in CPI colitis patients who received TNF blockade and anti-CTLA-4, identifying subsets of patients who may be more responsive to vedolizumab treatment. This work identifies putative pathogenic resident memory and cytotoxic T cells, and non-immune stromal and endothelial populations, whose properties may nominate subsets of CPI colitis patients amenable to distinct targeting strategies.

Project description:Checkpoint inhibitor colitis (CPI colitis) is a frequent immune-related adverse event resulting from cancer immunotherapy that is currently treated with empiric immunosuppression such as corticosteroids. A greater understanding of the pathogenesis of CPI colitis in the steroid-refractory setting is required to develop better colitis interventions targeted to each patient. Using paired colon biopsies and blood from steroid-experienced patients with endoscopically confirmed CPI colitis, combined with control patients, we performed multiplexed single-cell transcriptomics (scRNA/TCRseq) and proteomics (CITEseq, CyTOF) to identify contributing immune and non-immune populations. In CPI colitis patient biopsies compared to healthy controls, we found enrichment of resident memory (RM) T cells in both the CD8+ and unexpectedly the CD4+ compartments, as well as cytotoxic CD8+ T cells. These 3 populations expressed exact matching TCR, suggesting that CD4+ RM and CD8+ RM T cells are clonal progenitors that give rise to tissue-destructive cytotoxic effectors. Unbiased CyTOF and confirmatory scRNAseq and CITEseq analysis identifies specific mobilized subpopulations of both cytotoxic CD8+ and CD4+ RM cells that express both activation markers CD38 and HLA-DR, underscoring their pathogenic potential. CPI colitis induces global upregulation of interferon signaling and antigen presentation, as well as epithelial-specific dysregulation of homeostatic pathways (aquaporin/solute transporters) which is shared with ulcerative colitis. However, distinct from ulcerative colitis, CPI colitis involves specific alterations in stromal cell metabolic (NAD+, tryptophan) or extracellular signaling (BMP) pathways that directly impact epithelial cell survival, arguing for distinct therapeutic targeting. Finally, endothelial cells in CPI colitis demonstrate enrichment of the integrin 47 ligand MADCAM-1 (which is targeted by anti-47 antibody vedolizumab to treat colitis). This ligand is enriched in CPI colitis patients who received TNF blockade and anti-CTLA-4, identifying subsets of patients who may be more responsive to vedolizumab treatment. This work identifies putative pathogenic resident memory and cytotoxic T cells, and non-immune stromal and endothelial populations, whose properties may nominate subsets of CPI colitis patients amenable to distinct targeting strategies.

Project description:Checkpoint inhibitor colitis (CPI colitis) is a frequent immune-related adverse event resulting from cancer immunotherapy that is currently treated with empiric immunosuppression such as corticosteroids. A greater understanding of the pathogenesis of CPI colitis in the steroid-refractory setting is required to develop better colitis interventions targeted to each patient. Using paired colon biopsies and blood from steroid-experienced patients with endoscopically confirmed CPI colitis, combined with control patients, we performed multiplexed single-cell transcriptomics (scRNA/TCRseq) and proteomics (CITEseq, CyTOF) to identify contributing immune and non-immune populations. In CPI colitis patient biopsies compared to healthy controls, we found enrichment of resident memory (RM) T cells in both the CD8+ and unexpectedly the CD4+ compartments, as well as cytotoxic CD8+ T cells. These 3 populations expressed exact matching TCR, suggesting that CD4+ RM and CD8+ RM T cells are clonal progenitors that give rise to tissue-destructive cytotoxic effectors. Unbiased CyTOF and confirmatory scRNAseq and CITEseq analysis identifies specific mobilized subpopulations of both cytotoxic CD8+ and CD4+ RM cells that express both activation markers CD38 and HLA-DR, underscoring their pathogenic potential. CPI colitis induces global upregulation of interferon signaling and antigen presentation, as well as epithelial-specific dysregulation of homeostatic pathways (aquaporin/solute transporters) which is shared with ulcerative colitis. However, distinct from ulcerative colitis, CPI colitis involves specific alterations in stromal cell metabolic (NAD+, tryptophan) or extracellular signaling (BMP) pathways that directly impact epithelial cell survival, arguing for distinct therapeutic targeting. Finally, endothelial cells in CPI colitis demonstrate enrichment of the integrin 47 ligand MADCAM-1 (which is targeted by anti-47 antibody vedolizumab to treat colitis). This ligand is enriched in CPI colitis patients who received TNF blockade and anti-CTLA-4, identifying subsets of patients who may be more responsive to vedolizumab treatment. This work identifies putative pathogenic resident memory and cytotoxic T cells, and non-immune stromal and endothelial populations, whose properties may nominate subsets of CPI colitis patients amenable to distinct targeting strategies.

Project description:Prostate cancers are considered immunologically ‘cold’ tumors given the very few patients who respond to checkpoint inhibitor therapy (CPI). Recently, enrichment of interferon stimulated genes (ISGs) predicts a favorable response to CPI across various disease sites. The enhancer of zeste homolog-2 (EZH2) is over-expressed in prostate cancer and is known to negatively regulate ISGs. Here, we demonstrate that a majority of ISGs are not directly silenced by EZH2 mediated H3K27me3 deposition, but instead in a poised chromatin state associated with accessible chromatin (ATAC+) and H3K27ac deposition. Inhibition of EZH2 catalytic activity in prostate cancer models activates a dsRNA-STING-ISG cellular stress response upregulating genes involved in antigen presentation, Th-1 chemokine signaling, and interferon (IFN) response, including PD-L1 that is dependent on STING activation. EZH2 inhibition combined with PD-1 CPI significantly enhances anti-tumor response dependent on up-regulation of tumor PD-L1 expression. Further, combination therapy significantly increases intratumoral trafficking of activated CD8+ T-cells and M1 tumor associated macrophages (TAMs) with concurrent loss of M2 TAMs. Our study identifies EZH2 as a potent inhibitor of antitumor immunity and responsiveness to CPI. This data suggests EZH2 inhibition is a novel therapeutic direction to enhance prostate cancer response to PD-1 CPI.

Project description:Immune checkpoint blockade has revolutionized cancer therapy. In particular, inhibition of programmed cell death protein 1 (PD-1) is effective for the treatment of metastatic melanoma and other cancers. Despite a dramatic increase in progression-free survival, a large proportion of patients do not show durable response. Therefore, predictive biomarkers of clinical response are urgently needed. Here, we employed high-dimensional single cell mass cytometry and a bioinformatics pipeline for the in-depth characterization of the immune cell subsets in the peripheral blood of metastatic melanoma patients before and after anti-PD-1 immunotherapy. During therapy, we observed a clear treatment response to immunotherapy in the T cell compartment. However, prior to commending therapy a strong predictor of progression free and overall survival in response to anti-PD-1 immunotherapy was the frequency of CD14+CD16-HLA-DRhi monocytes. We could confirm this by conventional flow cytometry in an independent validation cohort and propose this as a novel predictive biomarker for therapy decisions in the clinic. In order to determine whether there are cell intrinsic changes in the monocyte signature, we performed RNA sequencing on sorted CD14+CD16-HLA-DRhi cells from HD, NR and R at baseline. Representative samples (n=4, each) of responders/non responders/ and healthy donors were selected from archival samples stored in the dermatology biobank according to the same clinical criteria used in the discovery and validation cohorts for CyTOF and FACS analysis. CD14+CD16-HLA-DRhiLin- (CD3, CD4, CD19, CD45RO) monocytes were sorted from frozen PBMC form blood samples from HD, R and NR at baseline.