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: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: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: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: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:Acute respiratory distress syndrome (ARDS) is a severe critical condition with a high mortality that is currently in focus given that it is associated with mortality caused by coronavirus induced disease 2019 (COVID-19). Neutrophils play a key role in the lung injury characteristic of non-COVID-19 ARDS and there is also accumulating evidence of neutrophil mediated lung injury in patients who succumb to infection with SARS-CoV-2. We undertook a functional proteomic and metabolomic survey of circulating neutrophil populations, comparing patients with COVID-19 ARDS and non-COVID-19 ARDS to understand the molecular basis of neutrophil dysregulation. Expansion of the circulating neutrophil compartment and the presence of activated low and normal density mature and immature neutrophil populations occurs in ARDS, irrespective of cause. Release of neutrophil granule proteins, neutrophil activation of the clotting cascade and upregulation of the Mac-1 platelet binding complex with formation of neutrophil platelet aggregates is exaggerated in COVID-19 ARDS. Importantly, activation of components of the neutrophil type I interferon responses is seen in ARDS following infection with SARS-CoV-2, with associated rewiring of neutrophil metabolism to promote glutamine utilisation, and the upregulation of antigen processing and presentation. Whilst dexamethasone treatment constricts the immature low density neutrophil population it does not impact upon prothrombotic hyperinflammatory neutrophil signatures.

Project description:Hypoxemia is a defining feature of acute respiratory distress syndrome (ARDS), an often-fatal complication of pulmonary or systemic inflammation, yet the resulting tissue hypoxia, and its impact on immune responses, is often neglected. Here we showed that ARDS patients were hypoxaemic and monocytopenic within the first 48 hours of ventilation. Monocytopenia was also observed in mouse models of acute lung injury, in which tissue hypoxia drove the suppression of type I interferon signalling in the bone marrow. This impaired monopoiesis, resulted in reduced accumulation of monocyte-derived macrophages and enhanced neutrophil-mediated inflammation in the lung. Administration of CSF1 in mice with hypoxic lung injury rescued the monocytopenia, altered the nature of circulating monocytes, increased monocyte-derived macrophages in the lung and limited injury. Thus, tissue hypoxia altered the dynamics of the immune response to the detriment of the host and interventions to address the aberrant response offer new therapeutic strategies for ARDS.

Project description:Hypoxia in stem cell niches and inner core of solid tumors contributes to cellular senescence and differentiation inhibition. It directly increases histone methylationby inhibiting the activities of O2-and α-ketoglutarate (α-KG)-dependent histone lysine demethylases. This study is the first to demonstrate how the hypoxic increment of methylated histones cross-talks with other epigenetic changes, such as histone clipping and heterochromatin redistribution, named senescence-associated heterochromatin foci (SAHF), which are found during oncogene-induced senescence (OIS). This study showed that Raf activation in primary human fibroblasts IMR90 increases mature cathepsin L (CTSL)-mediated cleavage of H3, H2B, and H4. Hypoxia prevented H3 cleavage not by inhibiting CTSL but by increasing H3K18me3 and H3K23me3 nearby cleaved site of H3. Forced expression of cleaved H3 in IMR90 cells induced senescence even under hypoxia, suggesting that hypoxia breaks this positive feedback senescence driving circle by increasing methylated histones. The decrease in methylated histones is necessary for OIS to trigger histone clipping and SAHFs, but hypoxia maintains methylated histones to prevent both. Forced reduction of methylated histones in hypoxic cells using inhibitors of methyl-transferases makes hypoxic conditions unable to prevent OIS from inducing both histone clipping and SAHFs. Reversely forced enhancement of methylated histones in normoxic cells using inhibitors of histone demethylases protected histones from clipping during OIS but failed to block SAHFs. Altogether, the maintenance of methylated histones, especially H3K23me3 and H3K18me3, is sufficient to protect histones from clipping during OIS, but not for inhibiting SAHFs, suggesting that besides inhibiting KDMs, hypoxia adopts other methods to inhibit SAHFs. These findings provide a novel mechanism by which hypoxia affects cell fate by increasing methylated histones that protect histones and chromatin from dramatic epigenetic changes.