Project description:Purpose: Investigate the gene accessibility change of neutrophils from PGE2 stimulation and identify the posibility for PGE2 could induce lung neutrophil like characteristics. Methods: Isolated bone marrow neutrophils with Percoll gradient are treated with 10 μM of PGE2 for 24 hours. Conclusion: Chromatin accessibility for the genes that were upregulated in lung neutrophils and PGE2 treated neutrophils were increased, so PGE2 could induce lung neutrophil like characteristics with change chromatin accessibility.

Project description:ATAC-seq of bone marrow neutrophil treated PGE2 or Vehicle

Project description:Purpose: Investigate the neutrophils could exspress different mRNA de novo from PGE2 stimulation. Methods: Isolated bone marrow neutrophils with Percoll gradient are treated with 10 μM of PGE2 for 24 hours. Results: Qualified sequence reads per sample to the mouse genome (mm10) with Bowtie2 or STAR were processed with StringTie and identified genes. Conclusion : 1,359 genes were significantly different in PGE2 treated bone marrow neutrophils from vehicle treated ones.

Project description:Neutrophils play critical roles in health and disease. Due to their very short half-life in blood and tissue, neutrophils are constantly replenished by bone marrow progenitors. Thus, a comprehensive understanding of bone marrow neutrophil development is of paramount importance to identify how neutrophil production is altered in disease. Recently, two novel human neutrophil progenitor populations were identified; ‘human neutrophil progenitor’ or ‘hNeP’ (Lin-​ ​CD66b+​ ​CD117+​ ​) ​and ‘neutrophil precursor’ or ‘preNeu’ (Lin-​ ​CD66b+​ ​CD15+​ ​CD49d+​ ​). How these subsets fit into the neutrophil lineage is unclear. By using mass and flow cytometry, we show that hNeP are a heterogenous population containing a homogeneous progenitor subset termed ‘early neutrophil progenitor’ or ‘eNeP’ (Lin-​ ​CD66b+​ ​CD117+​ ​CD71+​ ​). ​Surface marker and RNA expression, together with the ability to form colonies ​in vitro and exclusively produce neutrophils ​in vivo in humanized NSG-SGM3 mouse transfer experiments indicate that eNeP are hierarchically the ‘earliest’ cells within preNeu. eNeP constitute ~0.14% of human bone marrow neutrophils, while preNeu constitute ~5% of bone marrow neutrophils. Furthermore, we have identified CD71 as a novel neutrophil surface marker associated with distinct early neutrophil developmental stages. Intriguingly, CD71+​ characterizes proliferating neutrophils, which are expanded in the blood of melanoma and lung cancer patients and detectable in human lung tumors. Collectively, our findings i) identify CD117+​ ​CD71+​ ​eNeP as an early neutrophil progenitor population, ii) introduce a unified model of human neutrophil bone marrow development, iii) identify novel surface markers for distinct neutrophil developmental stages and iv) provide evidence for neutrophil progenitor expansion in cancer.

Project description:To investigate the effects of IL-1β/IL-6/PGE2 on neutrophil modulation, we performed RNA-seq to compare IL-1β/IL-6/PGE2-treated neutrophils to vehicle-treated neutrophils.

Project description:Pneumonia caused by Streptococcus pneumoniae is a leading cause of death worldwide, and bacterial resistance to antimicrobial drugs has become a major issue. A growing body of evidence indicates that the successful treatment of bacterial infections results from synergy between antibiotic-mediated direct antibacterial activity and the host’s immune defenses. However, the mechanisms underlying the protective immune responses induced by amoxicillin (a β-lactam antibiotic used as the first-line treatment of S. pneumoniae infections) have not been characterized. A better understanding of amoxicillin’s effects on host-pathogen interactions might facilitate the development of other treatment options. Given the crucial role of neutrophils in the control of S. pneumoniae infections, we decided to investigate amoxicillin’s impact on neutrophil development in a mouse model of pneumococcal superinfection. Although a single therapeutic dose of amoxicillin prevented local and systemic inflammatory responses, it did not impair the emergency granulopoiesis triggered in the bone marrow by S. pneumoniae. Importantly, treatment of pneumonia with amoxicillin was associated with a greater mature neutrophil count in the bone marrow; these neutrophils had specific transcriptomic and proteomic profiles. Furthermore, amoxicillin-conditioned, mature neutrophils in the bone marrow had a less activated phenotype and might be rapidly mobilized in peripheral tissues in response to systemic inflammation. Thus, by revealing a novel effect of amoxicillin on the development and functions of bone marrow neutrophils during Streptococcus pneumoniae pneumonia, our findings provide new insights into the impact of amoxicillin treatment on host immune responses.

Project description:RNA sequencing of different neutrophil subpopulations from bone marrow

Project description:Neutrophils are short-lived immune cells that play important roles in a variety of diseases. The oligopotent Granulocyte Monocyte Progenitors (GMP) in the bone marrow give rise to monocytes and all granulocytes. Although several monocyte progenitors have been identified in mouse bone marrow, the unipotent neutrophil progenitors are still not well-defined. Here, we use Cytometry by Time-of-Flight (CyTOF) and Single-cell RNA-Sequencing (scRNA-Seq) methodologies to identify a committed unipotent early-stage neutrophil progenitor in adult mouse bone marrow. Importantly, we also discovered a similar unipotent, committed neutrophil progenitor (hNeP) that is present in healthy human bone marrow. Both mouse and human progenitors demonstrate unipotent neutrophil potency in vivo. Study of the identified mouse (NeP) and human (hNeP) neutrophil progenitors in cancer revealed that both NeP and hNeP significantly increased tumor growth when transferred into murine cancer models, including a humanized model. Further, we discovered that the hNeP was present in the blood of human patients recently diagnosed with melanoma, and could be readily identified by flow cytometry, suggesting that this human neutrophil progenitor could be used as a biomarker for early cancer discovery. The discovery of this early committed unipotent neutrophil progenitor in humans will allow for development of important new therapeutic targets for regulation of neutrophil levels and function in disease, particularly in cancers, where neutrophils play a significant role.

Project description:Neutrophils are short-lived immune cells that play important roles in a variety of diseases. The oligopotent Granulocyte Monocyte Progenitors (GMP) in the bone marrow give rise to monocytes and all granulocytes. Although several monocyte progenitors have been identified in mouse bone marrow, the unipotent neutrophil progenitors are still not well-defined. Here, we use Cytometry by Time-of-Flight (CyTOF) and Single-cell RNA-Sequencing (scRNA-Seq) methodologies to identify a committed unipotent early-stage neutrophil progenitor in adult mouse bone marrow. Importantly, we also discovered a similar unipotent, committed neutrophil progenitor (hNeP) that is present in healthy human bone marrow. Both mouse and human progenitors demonstrate unipotent neutrophil potency in vivo. Study of the identified mouse (NeP) and human (hNeP) neutrophil progenitors in cancer revealed that both NeP and hNeP significantly increased tumor growth when transferred into murine cancer models, including a humanized model. Further, we discovered that the hNeP was present in the blood of human patients recently diagnosed with melanoma, and could be readily identified by flow cytometry, suggesting that this human neutrophil progenitor could be used as a biomarker for early cancer discovery. The discovery of this early committed unipotent neutrophil progenitor in humans will allow for development of important new therapeutic targets for regulation of neutrophil levels and function in disease, particularly in cancers, where neutrophils play a significant role.Neutrophils are short-lived immune cells that play important roles in a variety of diseases. The oligopotent Granulocyte Monocyte Progenitors (GMP) in the bone marrow give rise to monocytes and all granulocytes. Although several monocyte progenitors have been identified in mouse bone marrow, the unipotent neutrophil progenitors are still not well-defined. Here, we use Cytometry by Time-of-Flight (CyTOF) and Single-cell RNA-Sequencing (scRNA-Seq) methodologies to identify a committed unipotent early-stage neutrophil progenitor in adult mouse bone marrow. Importantly, we also discovered a similar unipotent, committed neutrophil progenitor (hNeP) that is present in healthy human bone marrow. Both mouse and human progenitors demonstrate unipotent neutrophil potency in vivo. Study of the identified mouse (NeP) and human (hNeP) neutrophil progenitors in cancer revealed that both NeP and hNeP significantly increased tumor growth when transferred into murine cancer models, including a humanized model. Further, we discovered that the hNeP was present in the blood of human patients recently diagnosed with melanoma, and could be readily identified by flow cytometry, suggesting that this human neutrophil progenitor could be used as a biomarker for early cancer discovery. The discovery of this early committed unipotent neutrophil progenitor in humans will allow for development of important new therapeutic targets for regulation of neutrophil levels and function in disease, particularly in cancers, where neutrophils play a significant role.

Project description:Neutrophils are one of the first responders to infection and are a key component of the innate immune system through their ability to phagocytose and kill invading pathogens, secrete antimicrobial molecules and produce extracellular traps. Neutrophils are produced in the bone marrow, circulate within the blood and upon immune challenge migrate to the site of infection. We wanted to understand whether this transition shapes the mouse neutrophil protein landscape, how the mouse neutrophil proteome is impacted by systemic infection and perform a comparative analysis of human and mouse neutrophils. Using quantitative mass spectrometry we reveal tissue-specific, infection-induced and species-specific neutrophil protein signatures. We show a high degree of proteomic conservation between mouse bone marrow, blood and peritoneal neutrophils, but also identify key differences in the molecules that these cells express for sensing and responding to their environment. Systemic infection triggers a change in the bone marrow neutrophil population with considerable impact on the core machinery for protein synthesis and DNA replication along with environmental sensors. We also reveal profound differences in mouse and human blood neutrophils, particularly their granule contents and their receptor repertoires. Our proteomics data provides a valuable resource for understanding neutrophil function and phenotypes across species and model systems.