Project description:The highly heterogeneous and plastic nature of tumor-associated neutrophils (TANs) has been recognized, but how different cell states of TANs emerge, evolve, distribute, and impact cancer immunotherapy efficacy remains elusive. Using single-cell RNA sequencing, spatial transcriptomic analysis, and genetic manipulations, we show that, while anti-PDL1/CD40 agonist immunotherapy can reprogram TANs to gain strong anti-tumor activities in squamous cell carcinomas (SCCs), a subset of neutrophils residing at the tumor-stroma interface can preserve their immune-suppressive state. Importantly, we identified a group of Sox2Hi tumor-initiating stem cells (tSCs) at the tumor-stroma interface that can activate Fatty Acid Desaturase 1 (Fads1) and produce arachidonic acid (AA) to induce autocrine prostaglandin E2 signaling which can disrupt the interferon responses in neutrophils. Thus, through this interaction, tSCs fine-tunes the cell states of neutrophils, shapes neutrophil heterogeneity, and sculpts a protective micro-niche to drive cancer relapse following immunotherapy.

Project description:The highly heterogeneous and plastic nature of tumor-associated neutrophils (TANs) has been recognized, but how different cell states of TANs emerge, evolve, distribute, and impact cancer immunotherapy efficacy remains elusive. Using single-cell RNA sequencing, spatial transcriptomic analysis, and genetic manipulations, we show that, while anti-PDL1/CD40 agonist immunotherapy can reprogram TANs to gain strong anti-tumor activities in squamous cell carcinomas (SCCs), a subset of neutrophils residing at the tumor-stroma interface can preserve their immune-suppressive state. Importantly, we identified a group of Sox2Hi tumor-initiating stem cells (tSCs) at the tumor-stroma interface that can activate Fatty Acid Desaturase 1 (Fads1) and produce arachidonic acid (AA) to induce autocrine prostaglandin E2 signaling which can disrupt the interferon responses in neutrophils. Thus, through this interaction, tSCs fine-tunes the cell states of neutrophils, shapes neutrophil heterogeneity, and sculpts a protective micro-niche to drive cancer relapse following immunotherapy.

Project description:The highly heterogeneous and plastic nature of tumor-associated neutrophils (TANs) has been recognized, but how different cell states of TANs emerge, evolve, distribute, and impact cancer immunotherapy efficacy remains elusive. Using single-cell RNA sequencing, spatial transcriptomic analysis, and genetic manipulations, we show that, while anti-PDL1/CD40 agonist immunotherapy can reprogram TANs to gain strong anti-tumor activities in squamous cell carcinomas (SCCs), a subset of neutrophils residing at the tumor-stroma interface can preserve their immune-suppressive state. Importantly, we identified a group of Sox2Hi tumor-initiating stem cells (tSCs) at the tumor-stroma interface that can activate Fatty Acid Desaturase 1 (Fads1) and produce arachidonic acid (AA) to induce autocrine prostaglandin E2 signaling which can disrupt the interferon responses in neutrophils. Thus, through this interaction, tSCs fine-tunes the cell states of neutrophils, shapes neutrophil heterogeneity, and sculpts a protective micro-niche to drive cancer relapse following immunotherapy.

Project description:The highly heterogeneous and plastic nature of tumor-associated neutrophils (TANs) has been recognized, but how different cell states of TANs emerge, evolve, distribute, and impact cancer immunotherapy efficacy remains elusive. Using single-cell RNA sequencing, spatial transcriptomic analysis, and genetic manipulations, we show that, while anti-PDL1/CD40 agonist immunotherapy can reprogram TANs to gain strong anti-tumor activities in squamous cell carcinomas (SCCs), a subset of neutrophils residing at the tumor-stroma interface can preserve their immune-suppressive state. Importantly, we identified a group of Sox2Hi tumor-initiating stem cells (tSCs) at the tumor-stroma interface that can activate Fatty Acid Desaturase 1 (Fads1) and produce arachidonic acid (AA) to induce autocrine prostaglandin E2 signaling which can disrupt the interferon responses in neutrophils. Thus, through this interaction, tSCs fine-tunes the cell states of neutrophils, shapes neutrophil heterogeneity, and sculpts a protective micro-niche to drive cancer relapse following immunotherapy.

Project description:The highly heterogeneous and plastic nature of tumor-associated neutrophils (TANs) has been recognized, but how different cell states of TANs emerge, evolve, distribute, and impact cancer immunotherapy efficacy remains elusive. Using single-cell RNA sequencing, spatial transcriptomic analysis, and genetic manipulations, we show that, while anti-PDL1/CD40 agonist immunotherapy can reprogram TANs to gain strong anti-tumor activities in squamous cell carcinomas (SCCs), a subset of neutrophils residing at the tumor-stroma interface can preserve their immune-suppressive state. Importantly, we identified a group of Sox2Hi tumor-initiating stem cells (tSCs) at the tumor-stroma interface that can activate Fatty Acid Desaturase 1 (Fads1) and produce arachidonic acid (AA) to induce autocrine prostaglandin E2 signaling which can disrupt the interferon responses in neutrophils. Thus, through this interaction, tSCs fine-tunes the cell states of neutrophils, shapes neutrophil heterogeneity, and sculpts a protective micro-niche to drive cancer relapse following immunotherapy.

Project description:Tumor-associated neutrophils (TANs) are heterogeneous; thus, their roles in tumor development could vary depending on the cancer type. Here, we showed that TANs were more detrimental to metabolic dysfunction-associated steatohepatitis hepatocellular carcinoma (MASH-related HCC) than to viral-associated HCC. We attributed this difference to the predominance of SiglecFhi TANs in MASH-related HCC tumors. Linoleic acid and GM-CSF, which are commonly elevated in the MASH-related HCC microenvironment, fostered the development of this c-Myc-driven TAN subset. Through TGFβ secretion, SiglecFhi TANs promoted HCC stemness, proliferation, and migration. Importantly, SiglecFhi TANs supported immune evasion by directly suppressing the antigen presentation machinery of tumor cells. SiglecFhi TAN removal increased the immunogenicity of a MASH-related HCC model and sensitized it to immunotherapy. Likewise, a high SiglecFhi TAN signature was associated with poor prognosis and immunotherapy resistance in HCC patients. Overall, our study highlights the importance of understanding TAN heterogeneity in cancer to improve therapeutic development

Project description:Tumor-associated neutrophils (TANs) are heterogeneous; thus, their roles in tumor development could vary depending on the cancer type. Here, we showed that TANs were more detrimental to metabolic dysfunction-associated steatohepatitis hepatocellular carcinoma (MASH-related HCC) than to viral-associated HCC. We attributed this difference to the predominance of SiglecFhi TANs in MASH-related HCC tumors. Linoleic acid and GM-CSF, which are commonly elevated in the MASH-related HCC microenvironment, fostered the development of this c-Myc-driven TAN subset. Through TGFβ secretion, SiglecFhi TANs promoted HCC stemness, proliferation, and migration. Importantly, SiglecFhi TANs supported immune evasion by directly suppressing the antigen presentation machinery of tumor cells. SiglecFhi TAN removal increased the immunogenicity of a MASH-related HCC model and sensitized it to immunotherapy. Likewise, a high SiglecFhi TAN signature was associated with poor prognosis and immunotherapy resistance in HCC patients. Overall, our study highlights the importance of understanding TAN heterogeneity in cancer to improve therapeutic development

Project description:We performed RNA-seq analysis of tumor infiltrating neutrophils from C57BL/6 mice and iNKT deficient Traj18-/- mice to understand the role of iNKT cells in affecting phenotype and functions of neutrophils in CRC. We observed that TANs from B6 animals were enriched for transcripts of chemokines and inflammation as well as of immune suppression. These data suggest that iNKT cells condition the phenotype of TANs.

Project description:It is becoming increasingly clear that tumor-associated neutrophils (TANs) play an important role in cancer biology, through direct impact on tumor growth and by recruitment of other cells types into the tumor. The function of neutrophils in cancer has been the subject of seemingly contradicting reports, pointing toward a dual role played by TANs in tumor progression. The existence of multiple neutrophil subsets, as well as phenotypic modulation of the neutrophils by various factors in the tumor microenvironment, has been shown. TGFβ plays a significant role in the determination of neutrophils' phenotype, by shifting the balance from an antitumor (N1) toward a more permissive (N2) phenotype. The full range of mechanisms responsible for the pro- vs. antitumor effects of TANs has not yet been elucidated. Therefore, the ability to identify the different neutrophil subpopulations in the tumor is critical in order to understand TANs evolution and contribution throughout tumor progression. Using a transcriptomic approach, we identified alternations in gene expression profile following TGFβ inhibition. We show that N1 and N2 TANs represent distinct subpopulations with different transcriptional signatures and both differ from naive bone marrow neutrophils. The analysis highlights a clear difference in pathways involved in neutrophil function such as cytoskeletal organization and antigen presentation, as well as alterations in chemokine profile, eventually affecting their effect on tumor cells and tumor growth. These data highlights several potential new pathways and mechanisms by which neutrophils can influence both the tumor cells and the adaptive immune system.

Project description:Tumor-associated neutrophils (TANs) can be conditioned to become “N2” pro-tumorigenic neutrophils in the tumor microenvironment. TANs have been shown to acquire N2 features and promote multiple aspects of tumor growth in mouse models of many cancers, including non-small cell lung cancer. We developed a novel mouse model for lung squamous cell carcinoma (LSCC): Rosa26LSL-Sox2-IRES-GFP;Nkx2-1fl/fl;Lkb1fl/fl (SNL). SNL mice develop tumors with short latency of ~3 months and SNL tumors have high neutrophil infiltration similar to other LSCC mouse models. We employed this novel model and single-cell RNA-sequencing to profile TANs in SNL lung tumors in comparison to peripheral blood neutrophils (PBNs) from tumor-bearing SNL mice.