Project description:Immunotherapy provides an alternative approach for cancer treatment. However, in-depth analyses of the effects of immunotherapy on the tumor microenvironment (TME) have not been conducted in non-melanoma tumors. Here we describe changes in the pancreatic ductal adenocarcinoma (PDAC) TME following immunotherapy treatment, and show for the first time that vaccine-based immunotherapy directly alters the TME, inducing neogenesis of tertiary lymphoid structures that convert immunologically quiescent tumors into immunologically active tumors. Alterations in five pathways important for immune modulation and lymphoid structure development (TH17/Treg, NFkB, Ubiquitin-proteasome, Chemokines/chemokine receptors, and Integrins/adhesion molecules) in vaccine-induced intratumoral lymphoid aggregates were associated with improved post-vaccination responses. Additional studies in other cancers and patients treated with other forms of immunotherapy are warranted to further develop signatures defined in intratumoral lymphoid structures into biomarkers that predict effective anti-tumor immune responses. These signatures may also expose therapeutic targets for promoting more robust antitumor immune responses in the TME. Between July 2008 and September 2012, 59 patients were enrolled into an ongoing study of an irradiated, allogeneic GM-CSF-secreting pancreatic tumor vaccine (GVAX) administered intradermally either alone or in combination with immune modulatory doses of cyclophophamide (Cy) as neoadjuvant and adjuvant treatment for patients with resectable pancreatic ductal adenocarcinoma (PDAC). Patients were randomized 1:1:1 to 3 treatment arms. In Arm A, patients received GVAX alone; in Arm B, patients received GVAX plus a single intravenous dose of Cy at 200 mg/m2 1 day prior to each vaccination; in Arm C, patients received GVAX plus oral Cy at 100 mg once daily for 1 week on and 1 week off. Up to 6 GVAX treatments were administered and all of the patients remained in their initial treatment arms throughout the duration of the study. All 59 of the patients received the 1st GVAX treatment 2 weeks +/-4 days prior to surgery. Formalin-fixed paraffin-embedded (FFPE) tissue blocks of surgically resected PDAC were obtained from the pathology archive. FFPE tissue blocks from each subject were stained by H&E immediately before the vaccine therapy-induced lymphoid aggregates were microdissected . To better understand the functional status of these vaccine therapy induced lymphoid aggregate structures, gene microarray analysis on RNA isolated from microdissected lymphoid aggregates was performed. Gene expression was compared among samples grouped according to patient overall survival, post-vaccination induction of enhanced mesothelin-specific T cell responses in peripheral blood lymphocytes (PBL), and the intratumoral CD8+ T effector to FoxP3+ Treg ratio. Post-vaccination induction of enhanced mesothelin-specific T cell responses has been reported to correlate with longer survival in patients treated with Panc GVAX.

Project description:Utilizing surgical and chemical skin sensory denervation methods, we show that afferent neurons support the growth of melanoma tumors in vivo. We demonstrate that sensory innervation limits the activation of effective anti-tumor immune response. Specifically, sensory ablation led to improved leukocyte recruitment and infiltration into tumors, decreased intratumoral lymphoid and myeloid immunosuppressive cells, and the activation of T effector cells within the TME. We found that cutaneous sensory nerves hinder the maturation of intratumoral high endothelial venules and the formation of mature tertriary lymphoid-like structures containing organized clusters of CD4+ T cells and B cells. Denervation further increased T cell clonality and expanded the B cell repertoire in the TME. Importantly, CD8a depletion prevented the denervation-dependent anti-tumor effects. Finally, we observed that the gene signatures associated with immune function and sensory innervation were inversely correlated in human primary cutaneous melanomas, and the latter was a negative prognostic marker of the overall survival in the examined cohort. Our results suggest that tumor-associated sensory neurons negatively regulate the development of effective anti-tumor immune responses, thereby defining a novel target for therapeutic intervention in the cancer setting.

Project description:The presence of intratumoral tertiary lymphoid structures (TLS) is associated with positive clinical outcomes and responses to immunotherapy in cancer. Here, we used spatial transcriptomics to examine the nature of B cell responses within TLS in renal cell carcinoma (RCC). B cells were enriched in TLS, and therein, we could identify all B cell maturation stages toward plasma cell (PC) formation. B cell repertoire analysis revealed clonal diversification, selection, expansion in TLS, and the presence of fully mature clonotypes at distance. In TLS+ tumors, IgG- and IgA-producing PCs disseminated into the tumor beds along fibroblastic tracks. TLS+ tumors exhibited high frequencies of IgG-producing PCs and IgG-stained and apoptotic malignant cells, suggestive of anti-tumor effector activity. Therapeutic responses and progression-free survival correlated with IgG-stained tumor cells in RCC patients treated with immune checkpoint inhibitors. Thus, intratumoral TLS sustains B cell maturation and antibody production that is associated with response to immunotherapy, potentially via direct anti-tumor effects.

Project description:Here, using the mouse KRT19-deficient (sgKRT19-edited) PDA model, we find that intratumoral accumulation of natural killer T (NKT) cells are required to establish an immunologically active TME. Mechanistically, intratumoral NKT cells facilitate type I interferon (IFN) production to initiate an anti-tumor adaptive immune response, and orchestrate the intratumoral infiltration of T cells, dendritic cells, natural killer cells and myeloid-derived suppressor cells. At the molecular level, NKT cells promote the production of type I IFN through the interaction of their CD40L with CD40 on myeloid cells. To evaluate the theraputical potential of these observations, we find that administration of folinic acid to mice bearing PDA increases NKT cells in the TME and improves their response to anti-PD-1 antibody treatment. In conclusion, NKT cells have an essential role in the immune response to mouse PDA and are potential targets for immunotherapy.

Project description:Tumor immunotherapy has been convincingly demonstrated as a feasible approach for treating cancers. Although promising, however, the immunosuppressive tumor microenvironment (TME) has been recognized as a major obstacle in tumor immunotherapy. It is highly desirable to release an immunosuppressive “brake” for improving cancer immunotherapy. Among tumor-infiltrated immune cells, tumor-associated macrophages (TAMs) play an important role in the growth, invasion and metastasis of tumors. The polarization of TAMs (M2) into the M1 type can alleviate the immunosuppression of the TME and enhance the effect of immunotherapy. Inspired by this, we constructed a therapeutic exosomal vaccine from antigen-stimulated M1-type macrophages (M1OVA-Exos). M1OVA-Exos are capable of polarizing TAMs into M1 type through downregulation of the Wnt signaling pathway. Mediating the TME further activates the immune response and inhibits tumor growth and metastasis via the exosomal vaccine. Our study provides a new strategy for the polarization of TAMs, which augments cancer vaccine therapy efficacy.

Project description:Introduction: Optimal approaches to induce T-cell infiltration of tumors are not known. Chemokines CXCL9, CXCL10, and CXCL11 support effector T-cell recruitment, and may be induced by IFNgamma. This study tests the hypothesis that intratumoral administration of IFNgamma will induce CXCL9-11, and will induce T-cell recruitment and anti-tumor immune signatures in melanoma metastases. Patients and Methods: Nine eligible patients were immunized with a vaccine comprised of 12 class I MHC-restricted melanoma peptides (12MP) and received IFNgamma intratumorally. Effects on the tumor microenvironment (TME) were evaluated in sequential tumor biopsies. Adverse events (AE; CTCAE v4) were recorded. T-cell responses to vaccination were assessed in peripheral blood (PBMC) by IFNgamma ELIspot assay. Tumor biopsies were evaluated for immune cell infiltration, chemokine protein expression and gene expression. Results: Vaccination and intratumoral administration of IFNgamma were well tolerated. Circulating T-cell responses to vaccine were detected in 6 of 9 patients. IFNgamma increased production of chemokines CXCL10, CXCL11, and CCL5 in patient tumors. Neither vaccination alone nor the addition of IFNgamma promoted immune cell infiltration or induced anti-tumor immune gene signatures. Conclusion: The cancer vaccine did not significantly increase T-cell infiltration of tumors. This study provides intriguing findings highlighting some of the limitations of intratumoral IFNgamma treatment. Although IFNgamma is pivotal in anti-tumor immunity, single intratumoral injection may induce secondary immune regulation that paradoxically limits immune infiltration and effector functions. Therefore, alternate dosing strategies or additional combinatorial treatments may be needed to optimally promote trafficking and retention of T-cells in tumor, which merit further study.

Project description:The tumor microenvironment (TME) is a complex mixture of tumor cells, immune cells, endothelial cells and fibroblastic stroma cells (FSC). While cancer-associated fibroblasts are generally seen as a tumor-promoting entity, it is conceivable that distinct FSC populations within the TME contribute to immune-mediated tumor control. Here, we show that intra-tumoral injection of a recombinant LCMV-based vaccine vector (r3LCMV) expressing the melanocyte differentiation antigen TRP2 results in T cell-dependent eradication of melanomas. Analysis of the TME revealed that viral vector transduction precipitates activation of particular FSC subsets. Using single-cell RNA-seq analysis, we identified a Cxcl13-expressing FSC population with a pronounced immune-stimulatory signature and increased expression of the inflammatory cytokine IL-33. Genetic ablation of Il33 in Cxcl13-Cre+ FSC impeded functionality of intratumoral T cells and consequently tumor control. Thus, reprogramming of distinct FSC subsets in the TME through LCMV-based vectors efficiently promotes tumor eradication by locally sustaining the activity of tumor-specific T cells.

Project description:Immune responses against tumor cells depend on T lymphocyte attraction and activity within the tumor microenvironment. Specialized immune-interacting fibroblasts, commonly referred to as fibroblastic reticular cells (FRC), form specialized niches in secondary lymphoid organs, originate from embryonic progenitors and foster T cell activation. FRCs have also been detected in tertiary lymphoid structures (TLS) in tumors, differentiating from cancer associated fibroblasts. However, the identity and differentiation of niche-forming cells that foster intra-tumoral T cell activity have remained elusive. Here, we employed single cell RNA-sequencing of EYFP+ fibroblasts and GP33/34-Tetramer+CD8+ T cells from experimental murine lung cancer and cell fate-mapping analysis, which revealed the ability of FRC subsets in lung tumors to differentiate from progenitors situated in mural and adventitial sites. Ablation of FRC progenitors in Tumor T cell environments (TTEs) of murine lungs led to reduced anti-tumor T cell activity and loss of tumor control during experimental coronavirus vector-based immunotherapy. Collectively, our study defines lung cancer-associated FRC niches and key processes involved in stromal-T cell interaction that could pave the way for improved cancer immunotherapy.

Project description:T lymphocytes can efficiently counteract the growth of tumors within the tumor microenvironment. Specialized immune-interacting fibroblasts, termed fibroblastic reticular cells (FRC) are responsible for the formation of specialized niches promoting immune cell activation in secondary lymphoid organs and originate from embryonic progenitors. FRCs have also been identified in tertiary lymphoid structures (TLS) in tumor tissues. However, the identity and differentiation of TLS-associated FRC subsets that promote intra-tumoral T cell activity have remained unexplored. Here, we employed single cell RNA-sequencing of fibroblasts and immune cells, sampled from subpleural margin, central margin and unaffected lung tissue in non small cell lung cancer (NSCLC), demonstrating the formation of specific tumor T cell environments (TTEs) underpinned by CCL19-expressing FRCs. We detected tumor-specific FRC subsets namely CCL19-expressing TRCs and perivascular reticular cells (PRCs) interacting with intratumoral T cells, and thus regulating FRC differentiation and T cell activation. Our results highlight a remarkable functionality of FRCs to efficiently determine protective antitumoral T cell responses in NSCLC.

Project description:Chemotherapy is often combined with immune checkpoint inhibitor (ICI) to enhance immunotherapy responses. Despite the approval of chemo-immunotherapy in multiple human cancers including triple-negative breast cancer (TNBC), immunologically cold tumors remain largely unresponsive due to weak chemotherapy-stimulated immune responses. The mechanisms determining the immunogenicity of chemotherapy in immunologically cold tumors remain largely unknown. Here, we identify the endoplasmic reticulum (ER) stress sensor IRE1α as a critical checkpoint that restricts the immunogenicity of taxane chemotherapy and prevents the innate immune recognition of immunologically cold TNBC. IRE1α RNase silences chemotherapy-induced double-stranded RNA (dsRNA) through RIDD (Regulated IRE1-Dependent Decay) to prevent NLRP3 inflammasome–dependent pyroptosis. Inhibition of IRE1α RNase activity with a selective RNase inhibitor ORIN1001, currently in Phase I clinical trial, allows taxane chemotherapy to induce extensive dsRNA accumulation and activate NLRP3 inflammasome–dependent gasdermin D (GSDMD) cleavage. This triggers pyroptosis and a highly effective immune response in immunologically cold TNBC.