Project description:In this study, we present NeuMAP, a comprehensive single-cell analysis of neutrophils spanning over 40 anatomical, physiological, and pathological contexts in mice. NeuMAP confirms and expands previous models of neutrophil diversity, revealing the organization of neutrophils into distinct functional hubs under both normal and pathological conditions. Furthermore, we delineate prototypical trajectories as key organizers of granulopoiesis and examine neutrophil dynamics along these trajectories during acute inflammation and cancer. Integrating insights from fate mapping, mutant mouse models, and in vitro experiments, we identified immunological signals guiding neutrophil through these typical trajectories of granulopoiesis, that balance immune protection, tissue homeostasis and repair. Specifically, we identified IFNB, GMCSF, and TGFB as drivers of pro-inflammatory, cancer-associated, and mature neutrophil states, respectively and found that the transcription factor JUNB drives the angiogenic and immunosuppressive function of neutrophils. Additionally, we uncover conserved transcriptional signatures for human neutrophil states, validate their prognostic significance in cancer patients, and introduce a proof-of-concept strategy for exploring the diagnostic potential of neutrophil functional diversity across various diseases using single-cell transcriptomics of blood neutrophils. Our study provides a model that delineates the global architecture of the neutrophil compartment in mammals, and stablishes a robust framework for further exploration of neutrophil biology.

Project description:In this study, we present NeuMAP, a comprehensive single-cell analysis of neutrophils spanning over 40 anatomical, physiological, and pathological contexts in mice. NeuMAP confirms and expands previous models of neutrophil diversity, revealing the organization of neutrophils into distinct functional hubs under both normal and pathological conditions. Furthermore, we delineate prototypical trajectories as key organizers of granulopoiesis and examine neutrophil dynamics along these trajectories during acute inflammation and cancer. Integrating insights from fate mapping, mutant mouse models, and in vitro experiments, we identified immunological signals guiding neutrophil through these typical trajectories of granulopoiesis, that balance immune protection, tissue homeostasis and repair. Specifically, we identified IFNB, GMCSF, and TGFB as drivers of pro-inflammatory, cancer-associated, and mature neutrophil states, respectively and found that the transcription factor JUNB drives the angiogenic and immunosuppressive function of neutrophils. Additionally, we uncover conserved transcriptional signatures for human neutrophil states, validate their prognostic significance in cancer patients, and introduce a proof-of-concept strategy for exploring the diagnostic potential of neutrophil functional diversity across various diseases using single-cell transcriptomics of blood neutrophils. Our study provides a model that delineates the global architecture of the neutrophil compartment in mammals, and stablishes a robust framework for further exploration of neutrophil biology.

Project description:Neutrophils are increasingly recognized as key players in the tumour immune response, and are associated with poor clinical outcomes. Despite recent advances characterizing the diversity of neutrophil states in cancer, common trajectories and mechanisms governing the ontogeny and relationship between these neutrophil states remain undefined. Single-cell RNA sequencing (scRNAseq) of neutrophils from the bone marrow, spleen, and blood in addtion to the pancreatic tumor thus uncovers an unique tumor differentiation trajectory, where immature and mature neutrophils converge into a terminally differentiated tumor neutrophil state.

Project description:Neutrophils are increasingly recognized as key players in the tumour immune response, and are associated with poor clinical outcomes. Despite recent advances characterizing the diversity of neutrophil states in cancer, common trajectories and mechanisms governing the ontogeny and relationship between these neutrophil states remain undefined.Using Assay for Transposase Accessible Chromatin (ATAC) sequencing, we show that immature and mature neutrophils infiltrating the tumor share a similar chromatin accessibility profile that was not observed in non-tumor populations (in both tumor-bearing and wild type mice). Our results thus indicate that tumor-infiltrating neutrophils can be reprogrammed by the tumor microenvironment regardless of their stage of maturity by converging chromatin trajectories towards a distinct T3 state.

Project description:Emergency granulopoiesis refers to the increased production of neutrophils in bone marrow and their release into circulation induced by severe infection. Several studies point to a critical role for granulocyte colony-stimulating factor (G-CSF) as the main mediator of emergency granulopoiesis. However, the consequences of G-CSF stimulation on the transcriptome of neutrophils and their precursors have not yet been investigated in humans. Here, we examine the changes in mRNA expression induced by administration of G-CSF in vivo, as a model of emergency granulopoiesis in humans. Blood samples were collected from healthy individuals after five days of G-CSF administration. Neutrophil precursors were sorted into discrete stages of maturation by flow cytometry, and RNA was subjected to microarray analysis. mRNA levels were compared to previously published expression levels in corresponding populations of neutrophil precursors isolated from bone marrow of untreated, healthy individuals. 1110 mRNAs were differentially expressed more than 2-fold throughout terminal granulopoiesis. Major changes were seen in pathways involved in apoptosis, cytokine signaling, and Toll-like receptor pathways. In addition, G-CSF treatment reduced the levels of four out of five measured granule proteins in mature neutrophils including the proantibacterial protein hCAP-18, which was completely deficient in neutrophils from G-CSF-treated donors. These results indicate that multiple biological processes are altered in order to satisfy the increased demand for neutrophils during G-CSF-induced emergency granulopoiesis in humans.

Project description:The aim of this study was to characterize in vivo miRNA expression in normal myeloid development of the neutrophil granulocyte (granulopoiesis) to gain insight into miRNA control of these processes. Cell populations highly enriched in precursors from successive stages of granulopoiesis and mature neutrophils were isolated from bone marrow (BM) and peripheral blood (PB) samples, respectively, from 4 healthy human donors. Total RNA was extracted from each cell population and subjected to miRNA gene expression profiling using miRCURYTM LNA microRNA Arrays Total RNA from cell populations highly enriched in precursors from three succesive stages of neutrophil granulopoiesis and mature neutrophils isolated from bone marrow and peripheral blood, respectively, from four healthy donors (SKP, AJ, AO, JO). The three cell populations from bone marrow where extracted and named B3, B2, and B1, corresponding to immature (myeloblasts [MBs] and promyelocytes [PMs]); intermediate mature (myelocytes [MCs] and metamyelocytes [MMs]); and mature neutrophil cells (band cells [BCs] and segmented neutrophil cells [SCs]), respectively, as described in Bjerregaard MD, Jurlander J, Klausen P, Borregaard N, Cowland JB: The in vivo profile of transcription factors during neutrophil differentiation in human bone marrow. Blood 2003, 101: 4322-4332. In total, 16 samples were compared (4 cell maturation stages from 4 donors)

Project description:To identify transcriptional diversity of neutrophils in steady state we performed single cell sequencing analysis on 13033 individual neutrophils across 6 different body compartments (bone marrow, blood, spleen, lung, liver and intestine). Dimensional reduction analysis identified unprecedented heterogeneity of the mature neutrophil compartment in healthy mice. Maturation state and tissue origin were both highly associated with neutrophil diversity. Moreover, we found that transcriptional profiles of discrete neutrophil clusters were enriched in genes associated with specific functions or disease states, These results identified preexisting heterogeneity in neutrophils under steady state and suggest that a wide array of ready-to-use functional programs regulate neutrophil function both in health and disease.

Project description:Tumour-induced systemic accumulation and polarisation of neutrophils to an immunosuppressive phenotype is a potent driver of metastasis formation. Yet how mammary tumours reprogram granulopoiesis at the molecular level and when tumour imprinting occurs during neutrophil development remains underexplored. Here we combined single cell, chromatin and functional analyses to unravel the tumour-driven reprogramming of granulopoiesis, along with intervention studies aimed at reversing this process. We observe that mammary tumours accelerate commitment to the neutrophil lineage at the expense of lymphopoiesis and erythropoiesis without stimulating the development of a novel myeloid lineage. Moreover, tumour-directed immunosuppressive imprinting of neutrophils starts early in haematopoiesis. Treatment with anti-IL-1β normalised tumour-induced granulopoiesis, reduced neutrophil production of T cell suppressive superoxides and mitigated metastatic spread. Together, these data provide molecular insights into the aberrant tumour-driven neutrophil differentiation pathway leading to metastasis-promoting chronic inflammation and how it can be reversed to reduce metastatic spread.

Project description:Tumour-induced systemic accumulation and polarisation of neutrophils to an immunosuppressive phenotype is a potent driver of metastasis formation. Yet how mammary tumours reprogram granulopoiesis at the molecular level and when tumour imprinting occurs during neutrophil development remains underexplored. Here we combined single cell, chromatin and functional analyses to unravel the tumour-driven reprogramming of granulopoiesis, along with intervention studies aimed at reversing this process. We observe that mammary tumours accelerate commitment to the neutrophil lineage at the expense of lymphopoiesis and erythropoiesis without stimulating the development of a novel myeloid lineage. Moreover, tumour-directed immunosuppressive imprinting of neutrophils starts early in haematopoiesis. Treatment with anti-IL-1β normalised tumour-induced granulopoiesis, reduced neutrophil production of T cell suppressive superoxides and mitigated metastatic spread. Together, these data provide molecular insights into the aberrant tumour-driven neutrophil differentiation pathway leading to metastasis-promoting chronic inflammation and how it can be reversed to reduce metastatic spread.

Project description:Tumour-induced systemic accumulation and polarisation of neutrophils to an immunosuppressive phenotype is a potent driver of metastasis formation. Yet how mammary tumours reprogram granulopoiesis at the molecular level and when tumour imprinting occurs during neutrophil development remains underexplored. Here we combined single cell, chromatin and functional analyses to unravel the tumour-driven reprogramming of granulopoiesis, along with intervention studies aimed at reversing this process. We observe that mammary tumours accelerate commitment to the neutrophil lineage at the expense of lymphopoiesis and erythropoiesis without stimulating the development of a novel myeloid lineage. Moreover, tumour-directed immunosuppressive imprinting of neutrophils starts early in haematopoiesis. Treatment with anti-IL-1β normalised tumour-induced granulopoiesis, reduced neutrophil production of T cell suppressive superoxides and mitigated metastatic spread. Together, these data provide molecular insights into the aberrant tumour-driven neutrophil differentiation pathway leading to metastasis-promoting chronic inflammation and how it can be reversed to reduce metastatic spread.