Project description:A deeper understanding of the processes that sustain long-term reprogramming of rapidly turned-over cells in humans can offer unprecedented therapeutic potential, especially for immune cells like neutrophils, given their short lifespan in circulation and importance in both acute and chronic diseases. Hypoxia is a hallmark of a plethora of disease states and significantly shapes neutrophil effector functions. However, its potential contribution to long-term neutrophil reprogramming remains largely unexplored. We have observed persistent perturbations in newly formed circulating neutrophils’ phenotype and function in patients 3-6 months following hospitalisation with acute respiratory distress syndrome (ARDS), where poor oxygenation takes place. These lasting changes are associated with widespread loss of H3K4me3 in genomic regions of relevance to neutrophil activities. Notably, the replication of these findings in healthy volunteers months following altitude-induced hypoxaemia attributes a role to the oxygen deprivation as a driver for long-term neutrophil reprogramming. Mechanistically, mouse models of systemic hypoxia reveal deleterious outcomes for infection and show that persistent loss of H3K4me3 originates in proNeu and preNeu populations within the bone marrow and is linked to hypoxia-driven n-terminal histone 3 clipping. Thus, we present novel evidence that acute adaptations to systemic hypoxia trigger central changes in newly formed neutrophil populations, resulting in long-term impairment of effector functions and placing hypoxia as a crucial orchestrator of sustained neutrophil reprogramming.

Project description:A deeper understanding of the processes that sustain long-term reprogramming of rapidly turned-over cells in humans can offer unprecedented therapeutic potential, especially for immune cells like neutrophils, given their short lifespan in circulation and importance in both acute and chronic diseases. Hypoxia is a hallmark of a plethora of disease states and significantly shapes neutrophil effector functions. However, its potential contribution to long-term neutrophil reprogramming remains largely unexplored. We have observed persistent perturbations in newly formed circulating neutrophils’ phenotype and function in patients 3-6 months following hospitalisation with acute respiratory distress syndrome (ARDS), where poor oxygenation takes place. These lasting changes are associated with widespread loss of H3K4me3 in genomic regions of relevance to neutrophil activities. Notably, the replication of these findings in healthy volunteers months following altitude-induced hypoxaemia attributes a role to the oxygen deprivation as a driver for long-term neutrophil reprogramming. Mechanistically, mouse models of systemic hypoxia reveal deleterious outcomes for infection and show that persistent loss of H3K4me3 originates in proNeu and preNeu populations within the bone marrow and is linked to hypoxia-driven n-terminal histone 3 clipping. Thus, we present novel evidence that acute adaptations to systemic hypoxia trigger central changes in newly formed neutrophil populations, resulting in long-term impairment of effector functions and placing hypoxia as a crucial orchestrator of sustained neutrophil reprogramming.

Project description:The long-term impact of systemic hypoxia resulting from Acute Respiratory Distress Syndrome (ARDS) on the function of short-lived innate immune cells is unclear. We show that patients 3-6 months after recovering from ARDS have persistently impaired circulating neutrophil effector functions and an increased susceptibility to secondary infections. These defects are linked to a widespread loss of the activating histone mark H3K4me3 in genes crucial for neutrophil activities. By studying healthy volunteers exposed to altitude-induced hypoxemia, we demonstrate that oxygen deprivation alone causes this long-term neutrophil reprogramming. Mechanistically, mouse models of systemic hypoxia reveal that persistent loss of H3K4me3 originates in proNeu and preNeu progenitors within the bone marrow and is linked to N-terminal histone 3 clipping, which removes the lysine residue for methylation. Thus, we present novel evidence that systemic hypoxia initiates a sustained maladaptive reprogramming of neutrophil immunity by triggering histone 3 clipping and H3K4me3 loss in neutrophil progenitors.

Project description:The long-term impact of systemic hypoxia resulting from Acute Respiratory Distress Syndrome (ARDS) on the function of short-lived innate immune cells is unclear. We show that patients 3-6 months after recovering from ARDS have persistently impaired circulating neutrophil effector functions and an increased susceptibility to secondary infections. These defects are linked to a widespread loss of the activating histone mark H3K4me3 in genes crucial for neutrophil activities. By studying healthy volunteers exposed to altitude-induced hypoxemia, we demonstrate that oxygen deprivation alone causes this long-term neutrophil reprogramming. Mechanistically, mouse models of systemic hypoxia reveal that persistent loss of H3K4me3 originates in proNeu and preNeu progenitors within the bone marrow and is linked to N-terminal histone 3 clipping, which removes the lysine residue for methylation. Thus, we present novel evidence that systemic hypoxia initiates a sustained maladaptive reprogramming of neutrophil immunity by triggering histone 3 clipping and H3K4me3 loss in neutrophil progenitors.

Project description:Hypoxia induces histone clipping and H3K4me3 loss in neutrophil progenitors resulting in long-term impairment of neutrophil immunity [CUT&Run]

Project description:Hypoxia induces histone clipping and H3K4me3 loss in neutrophil progenitors resulting in long-term impairment of neutrophil immunity [ChIP-seq]

Project description:Orchestrated recruitment of neutrophils to inflamed tissue is essential during initiation of inflammation. Inflamed areas are usually hypoxic, and adaptation to reduced oxygen pressure is typically mediated by hypoxia pathway proteins. However, it is still unclear how these factors influence the migration of neutrophils to and at the site of inflammation either during their transmigration through the blood-endothelial cell barrier, or their motility in the interstitial space. Here, we reveal that activation of the Hypoxia Inducible Factor-2 (HIF2α) due to deficiency of HIF-prolyl hydroxylase domain protein-2 (PHD2) boosts neutrophil migration specifically through highly confined microenvironments. In vivo, the increased migratory capacity of PHD2-deficient neutrophils resulted in massive tissue accumulation in acute local inflammation. Using systematic RNAseq analyses and mechanistic approaches, we identified RhoA, a cytoskeleton organizer, as the central downstream factor that mediates HIF2α-dependent neutrophil motility. Thus, we propose that the here identified novel PHD2-HIF2α-RhoA axis is vital to the initial stages of inflammation as it promotes neutrophil movement through highly confined tissue landscapes.

Project description:This dataset combines transcriptional and chromatin analysis of neutrophils from the air pouch mouse model, an in vivo model of acute inflammation, with transcriptional analysis of Hoxb8 neutrophils, an in vitro model of neutrophil development.

Project description:In this study, we used chromatin immunoprecipitation sequencing (ChIP-Seq) analysis of histone H3K4me3-marked, to identify various TSSs associated with LPS-, TNF-alfa- and IL-10-stimulated neutrophils from healthy individuals, as well as neutrophils derived from the patients with sepsis (systemic septic inflammation with LPS-stimulated neutrophils), NMOSD (aseptic inflammation with neutrophils pre-activated by TNF-alfa and periodontitis (localized self-limiting septic inflammation with IL-10-positive neutrophils). We provided comprehensive epigenomic analysis within H3K4me3- marked histone that allowed us to identify human neutrophil regulators affecting their plasticity during inflammation as well as suppression.

Project description:During systemic inflammation, different neutrophil subsets are mobilized to the blood circulation. These neutrophil subsets can be distinguished from normal circulating neutrophils (CD16bright/CD62Lbright) based on either an immature CD16dim/CD62Lbright or a CD16bright/CD62Ldim phenotype. Interestingly, the latter neutrophil subset is known to suppress lymphocyte proliferation ex vivo, but the underlying mechanism is largely unknown. We performed transcriptome analysis on the different neutrophil subsets to identify changes that are relevant for their functions. Neutrophil subsets were isolated by FACS sorting from the blood of healthy volunteers who were administered a single dose of lipopolysaccharide (LPS). The transcriptome was determined by microarray. The mobilized neutrophil subsets were characterized by specific transcriptome profiles reflecting their phase in neutrophil lifespan. Interestingly, the CD16bright/CD62Ldim suppressive neutrophils showed an interferon-induced transcriptome profile. This was confirmed by stimulation of peripheral neutrophils with IFNgamma. These cells acquired the capacity to suppress lymphocyte proliferation through the expression of programmed death ligand 1 (PD-L1). These data demonstrate that the suppressive phenotype of the neutrophil subset is induced by IFNgamma. Specific stimulation of neutrophils might have a pivotal role in regulating lymphocyte-mediated inflammation and autoimmune disease. After LPS infusion, blood was taken at t=0 and t=4 hours. Neutrophils were FACS sorted based on CD16 and CD62L expression. Gene expression of neutrophil subsets was assessed relative to t=0 as control.