Project description:The role of neutrophils in tumor is still controversial and largely unknown. We previously identified an anticancer tumor microenvironment from mice lacking Smad3, but the underlying mechanism is still largely unclear. Interestingly, depletion of neutrophils largely suppressed the anticancer phenotype of Smad3-KO mice against syngeneic murine Lewis lung carcinoma (LLC). Here, we discovered that Smad3 is essential for promoting N1/N2 polarization of the tumor_x0002_associated neutrophils (TANs) in lung carcinoma. We found that Smad3 deficiency dramatically increased N1 TANs associated with an anticancer phenotype in mice and detected a negative correlation between Smad3 activation and anticancer N1 associated with a higher mortality of NSCLC. By conducting a neutrophil-specific single-cell RNA-sequencing, we uncovered that Smad3 is essential for completing the N1/N2 polarization of TANs, whereas N1 will be the dominated phenotype in the Smad3-KO TME by analyzing the developmental pathways of TANs with pseudo-time at transcriptome level. Mechanistically, direct binding of Smad3 on the developmental genes in neutrophils under cancer condition was evidenced by ChIP-sequencing at genomic level. Importantly, both neutrophil-specific and pharmaceutical inhibition of Smad3 effectively enhanced the anticancer activity of human and murine TANs, thereby suppressing the progression of lung carcinoma in vivo. Thus, Smad3 may represent a precision therapeutic target for enhancing the anticancer activity of TANs via blocking N1/N2 polarization in NSCLC. in C57BL6 (wild-type) and Smad3-deficient (Smad3-/- ) mice and submitted for cell encapsulation and library construction by Chromium controller with 5’ expression kit (10x genomics)

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.

Project description:Tumor-associated neutrophils display a distinct N1 profile following TGFβ modulation: A transcriptomics analysis of pro- vs. antitumor TANs

Project description:Neutrophils are the most abundant circulating leucocytes and constitute an essential component of innate immunity. Although their role in cancer development is still poorly defined, pro- or anti-tumor properties have been attributed to tumor-associated neutrophils (TANs), suggesting major functional diversities. In this study, we focused on the mechanisms involved in neutrophil accumulation within the lung tumor mass. We first identified G-CSF as an inducer of the high-affinity glucose transporter Glut1 in neutrophils, increasing their survival ex vivo. In a genetically engineered mouse model of lung adenocarcinoma, we report that TANs have an increased Glut1 expression and glucose metabolism compared to normal neutrophils. To elucidate the impact of glucose uptake on TANs, we used an in vivo strategy based on two recombinases, Flp to initiate lung tumors, and Cre to delete Glut1 specifically in neutrophils. We demonstrate that the loss of Glut1 decreases the SiglecFhigh TAN subpopulation by accelerating neutrophil turnover in tumors through reduced survival and augmented recruitment. Accelerated TAN turnover led to a decreased tumor growth and synergized with radiotherapy. Altogether, our results demonstrate the importance of Glut1 for neutrophil turnover, which directly affects the pro- versus anti-tumor balance within the tumor. These results also suggest that metabolic vulnerabilities can be exploited to target tumor-supportive neutrophil populations.

Project description:Neutrophils are the most abundant circulating leucocytes and constitute an essential component of innate immunity. Although their role in cancer development is still poorly defined, pro- or anti-tumor properties have been attributed to tumor-associated neutrophils (TANs), suggesting major functional diversities. In this study, we focused on the mechanisms involved in neutrophil accumulation within the lung tumor mass. We first identified G-CSF as an inducer of the high-affinity glucose transporter Glut1 in neutrophils, increasing their survival ex vivo. In a genetically engineered mouse model of lung adenocarcinoma, we report that TANs have an increased Glut1 expression and glucose metabolism compared to normal neutrophils. To elucidate the impact of glucose uptake on TANs, we used an in vivo strategy based on two recombinases, Flp to initiate lung tumors, and Cre to delete Glut1 specifically in neutrophils. We demonstrate that the loss of Glut1 decreases the SiglecFhigh TAN subpopulation by accelerating neutrophil turnover in tumors through reduced survival and augmented recruitment. Accelerated TAN turnover led to a decreased tumor growth and synergized with radiotherapy. Altogether, our results demonstrate the importance of Glut1 for neutrophil turnover, which directly affects the pro- versus anti-tumor balance within the tumor. These results also suggest that metabolic vulnerabilities can be exploited to target tumor-supportive neutrophil populations.

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:The characteristics of the tumor immunosuppressive microenvironment represent a major challenge limiting the efficacy of immunotherapy. Our previous results suggested that cryo-thermal therapy (CTT), a tumor ablation system developed in our laboratory, could promote macrophage M1-type polarization and full maturation of DCs to remodel the immunosuppressive environment. However, it is not clear which cells respond promptly to CTT. CTT can cause extensive cell death and the release of danger-associated molecular patterns (DAMPs) and antigens. Neutrophils are the first white blood cells recruited to sites of damage and acute inflammation. We therefore hypothesized that neutrophils were the initial cells to respond to CTT and were involved in the subsequent establishment of antitumor immunity. We found that CTT led to a rapid and strong proinflammatory neutrophil response, which was essential for the long-term survival of mice. In vivo neutrophil depletion and in vitro coculture experiments demonstrated that CTT-induced neutrophils promoted the differentiation of monocytes toward to mature antigen presenting cells and further upregulated the expression of IFN-γ and cytotoxic molecules in T and NK cells in a CD86-dependent manner. These results reveal the important role of neutrophil-monocyte interactions for the development of anti-tumor immunity and highlight that CTT could be used as an immunotherapy for targeting neutrophils and monocytes to enhance antitumor immunity.

Project description:An acidic tumor microenvironment plays a critical role in tumor progression. However, understanding of metabolic reprogramming of tumors in response to acidic extracellular pH has remained elusive. Using comprehensive metabolomic analyses, we demonstrated that acidic extracellular pH (pH 6.8) leads to the accumulation of N1-acetylspermidine, a pro-tumor metabolite, through upregulation of the expression of spermidine/spermine acetyl transferase 1 (SAT1). Inhibition of SAT1 expression suppressed the accumulation of intra- and extracellular N1-acetylspermidine at acidic pH. Conversely, overexpression 3 of SAT1 increased intra- and extracellular N1-acetylspermidine levels, supporting the proposal that SAT1 is responsible for accumulation of N1-acetylspermidine. While inhibition of SAT1 expression only had a minor effect on cancer cell growth in vitro, SAT1 knockdown significantly decreased tumor growth in vivo, supporting a contribution of the SAT1-N1-acetylspermidine axis to pro-tumor immunity. Immune cell profiling revealed that inhibition of SAT1 expression decreased neutrophil recruitment to the tumor, resulting in impaired angiogenesis and tumor growth. We showed that anti-neutrophil neutralizing antibodies suppressed growth in control tumors to a similar extent to that seen in SAT1 knockdown tumors in vivo. Further, a SAT1 signature was found to be correlated with poor patient prognosis. Our findings demonstrate that extracellular acidity stimulates recruitment of pro-tumor neutrophils via the SAT1-N1-acetylspermidine axis, which may represent a novel target for anti-tumor immune therapy.

Project description:Neutrophils accumulate in solid tumors and their abundance correlates with poor prognosis. Neutrophils are not homogenous, however, and could play different roles in cancer therapy. Here, we investigated the role of neutrophils in immunotherapy leading to tumor control. We show that successful therapies acutely expanded tumor neutrophil numbers. This expansion could be attributed to a Sell-hi state, rather than to other neutrophils that accelerate tumor progression. Therapy-elicited neutrophils acquired an interferon gene signature, also seen in human patients, and appeared essential for successful therapy, as loss of the interferon-responsive transcription factor IRF1 in neutrophils led to failure of immunotherapy. The neutrophil response depended on key components of antitumor immunity, including BATF3-dependent DCs, IL12 and IFNγ. In addition, we found that a therapy-elicited systemic neutrophil response positively correlated with disease outcome in lung cancer patients. Thus, we establish a crucial role of a neutrophil state in mediating effective cancer therapy.

Project description:Neutrophils accumulate in solid tumors and their abundance correlates with poor prognosis. Neutrophils are not homogenous, however, and could play different roles in cancer therapy. Here, we investigated the role of neutrophils in immunotherapy leading to tumor control. We show that successful therapies acutely expanded tumor neutrophil numbers. This expansion could be attributed to a Sell-hi state, rather than to other neutrophils that accelerate tumor progression. Therapy-elicited neutrophils acquired an interferon gene signature, also seen in human patients, and appeared essential for successful therapy, as loss of the interferon-responsive transcription factor IRF1 in neutrophils led to failure of immunotherapy. The neutrophil response depended on key components of antitumor immunity, including BATF3-dependent DCs, IL12 and IFNγ. In addition, we found that a therapy-elicited systemic neutrophil response positively correlated with disease outcome in lung cancer patients. Thus, we establish a crucial role of a neutrophil state in mediating effective cancer therapy.