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: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:To delineate gene expression levels in whole non-metastatic and metastatic transplantable primary mouse mammary tumour allografts Abstract to be provided from publication Primary mouse mammary tumours were grown till 400-600mm3 in size. Five different tumour models were analysed in triplicate. Thus, 3 different tumours/mice were used per model for a total of 15 mice. Each sample was applied to a separate microarray. Total RNA was prepared from whole primary tumours using Trizol reagent. Each sample was applied to Affymetrix gene expression arrays Mouse Gene 1.0ST.

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:MiR-21 was identified as a gene whose expression correlated with the extent of metastasis of murine mammary tumours. Since miR-21 is recognized as being associated with poor prognosis in cancer, we investigated its contribution to mammary tumour growth and metastasis in tumours with capacity for spontaneous metastasis. Unexpectedly, we found that suppression of miR-21 activity in highly metastatic tumours resulted in regression of primary tumour growth in immunocompetent mice but did not impede growth in immunocompromised mice. Analysis of the immune infiltrate of the primary tumours at the time when the tumours started to regress revealed an influx of both CD4+ and CD8+ activated T cells and a reduction in PD-L1+ infiltrating monocytes, providing an explanation for the observed tumour regression. Loss of anti-tumour immune suppression caused by decreased miR-21 activity was confirmed by transcriptomic analysis of primary tumours. This analysis also revealed reduced expression of genes associated with cell cycle progression upon loss of miR-21 activity. A second activity of miR-21 was the promotion of metastasis as shown by the loss of metastatic capacity of miR-21 knockdown tumours established in immunocompromised mice, despite no impact on primary tumour growth. A proteomic analysis of tumour cells with altered miR-21 activity revealed deregulation of proteins known to be associated with tumour progression. The development of therapies targeting miR-21, possibly via targeted delivery to tumour cells, could be an effective therapy to combat primary tumour growth and suppress the development of metastatic disease.

Project description:The experiment was design to address the intrinsic differences between metastatic cancer stem cells in the primary tumour and during metastatic colonization in the mouse mammary gland tumour model MMTV-pyMT. Total RNA was prepared from the indicated cancer cells freshly isolated, stained and FACS sorted either from primary tumours or from lungs upon intravenous injection of cancer cells.

Project description:Sepsis, the dysregulated host response to infection leading to organ dysfunction, arises from diverse mechanisms that are poorly resolved by sepsis as a syndromic classification, confounding immunotherapy trials. Here we delineate neutrophil and granulopoietic disturbances underlying sepsis pathophysiology. We present a whole blood single-cell multiomic sepsis response atlas (272,993 cells, n=39 individuals), revealing multiple immature neutrophil populations that were collectively immunosuppressive, inhibiting CD4+ T cell proliferation and activation in co-culture. We traced this to altered granulopoiesis using single-cell multiomic mapping of circulating hematopoietic stem cells (HSCs) (29,366 cells, n=27). We show how these features are enriched in a subset of patients, resolving a specific poor outcome endotype (sepsis response signature SRS1). SRS1 patients have increased IL1R2+ immature neutrophils, epigenetic signatures of emergency granulopoiesis transcription factors in HSCs, and STAT3 features across infectious disease settings. Our findings delineate an immunohematopoietic axis, therapeutic targets and stratified medicine approach to sepsis.

Project description:Sepsis, the dysregulated host response to infection leading to organ dysfunction, arises from diverse mechanisms that are poorly resolved by sepsis as a syndromic classification, confounding immunotherapy trials. Here we delineate neutrophil and granulopoietic disturbances underlying sepsis pathophysiology. We present a whole blood single-cell multiomic sepsis response atlas (272,993 cells, n=39 individuals), revealing multiple immature neutrophil populations that were collectively immunosuppressive, inhibiting CD4+ T cell proliferation and activation in co-culture. We traced this to altered granulopoiesis using single-cell multiomic mapping of circulating hematopoietic stem cells (HSCs) (29,366 cells, n=27). We show how these features are enriched in a subset of patients, resolving a specific poor outcome endotype (sepsis response signature SRS1). SRS1 patients have increased IL1R2+ immature neutrophils, epigenetic signatures of emergency granulopoiesis transcription factors in HSCs, and STAT3 features across infectious disease settings. Our findings delineate an immunohematopoietic axis, therapeutic targets and stratified medicine approach to sepsis.

Project description:Hypoxia episodes and areas in tumours have been associated with metastatic dissemination and poor prognosis. Given the link between tumour tissue oxygen levels and cellular metabolic activity, we hypothesised that the metabolic profile between metastatic and non-metastatic tumours would reveal potential new biomarkers and signalling cues. We have used a previously established chick embryo model for neuroblastoma growth and metastasis, where the metastatic phenotype can be controlled by neuroblastoma cell hypoxic preconditioning (3 days at 1% O2). We measured, with fibre-optic oxygen sensors, the effects of the hypoxic preconditioning on the tumour oxygenation, within tumours formed by SK-N-AS cells on the chorioallantoic membrane (CAM) of chick embryos. We found that the difference between the metastatic and non-metastatic intratumoural oxygen levels was small (0.35% O2), with a mean below 1.5% O2 for most tumours. The metabolomic profiling, using NMR spectroscopy, of neuroblastoma cells cultured in normoxia or hypoxia for 3 days, and of the tumours formed by these cells showed that the effects of hypoxia in vitro did not compare with in vivo tumours. One notable difference was the high levels of the glycolytic end-products triggered by hypoxia in vitro, but not by hypoxia preconditioning in tumours, likely due to the very high basal levels of these metabolites in tumours compared with cells. In conclusion, we have identified high levels of ketones (3-hydroxybutyrate), lactate and phosphocholine in hypoxic preconditioned tumours, all known to fuel tumour growth, and we herein point to the poor relevance of in vitro metabolomic experiments for cancer research.