SummaryTrained innate immunity fosters a sustained favorable response of myeloid cells to a secondary challenge, despite their short lifespan in circulation. We thus hypothesized that trained immunity acts via modulation of hematopoietic stem and progenitor cells (HSPCs). Administration of β-glucan (prototypical trained-immunity-inducing agonist) to mice induced expansion of progenitors of the myeloid lineage, which was associated with elevated signaling by innate immune mediators, such as IL-1β and granulocyte-macrophage colony-stimulating factor (GM-CSF), and with adaptations in glucose metabolism and cholesterol biosynthesis. The trained-immunity-related increase in myelopoiesis resulted in a beneficial response to secondary LPS challenge and protection from chemotherapy-induced myelosuppression in mice. Therefore, modulation of myeloid progenitors in the bone marrow is an integral component of trained immunity, which to date, was considered to involve functional changes of mature myeloid cells in the periphery.
Resolution of inflammation is essential for tissue homeostasis and a promising approach to inflammatory disorders. Here we found that DEL-1, a secreted protein inhibiting leukocyte-endothelial adhesion and inflammation initiation, also functions as a non-redundant downstream effector in inflammation clearance. In human and murine periodontitis, waning of inflammation correlated with DEL-1 upregulation, whereas resolution of experimental periodontitis failed in DEL-1 deficiency. This concept was mechanistically substantiated in acute monosodium urate crystal-induced inflammation, where the pro-resolution function of DEL-1 was attributed to effective apoptotic neutrophil clearance (efferocytosis). DEL-1-mediated efferocytosis induced liver-X-receptor-dependent macrophage reprogramming to pro-resolving phenotype and was required for optimal production of at least certain specific pro-resolving mediators. Experiments in transgenic mice with cell-specific overexpression of DEL-1 linked its anti-leukocyte recruitment action to endothelial-derived DEL-1 and its efferocytic/pro-resolving action to macrophage-derived DEL-1. Thus, the compartmentalized expression of DEL-1 facilitates distinct homeostatic functions in an appropriate context that can be harnessed therapeutically.
es. We show that Del-1, via its interaction with the αvβ3 integrin, promotes several critical functions in the niche, including HSC retention, hematopoietic progenitor cell cycle progression, and myeloid lineage commitment of HSCs. Del-1 thereby regulates myelopoiesis under steady-state conditions and in G-CSF-or inflammation-induced stress myelopoiesis, as well as myelopoiesis reconstitution under regenerative/transplantation conditions. Del-1 is hence a niche component that serves a juxtacrine homeostatic adaptation of the hematopoietic system in inflammation-related and regeneration myelopoiesis. ResultsDel-1 expression in the BM. First, we sought to investigate whether Del-1 is present in the BM. We initially studied the expression of the Del-1-encoding gene Edil3 in the BM niche and hematopoietic cell populations. We found that Edil3 mRNA expression was significantly higher in the endosteal region as compared with the central BM (cBM) ( Figure 1A), suggesting that Del-1 is enriched at the endosteal area of the BM. Analysis of sorted cells from CXCL12-GFP mice (33, 34) demonstrated that Edil3 was highly expressed integrin receptors (29-31). It consists of three N-terminal EGF-like repeats and two C-terminal discoidin I-like domains, and hence also is designated EGF-like repeats and discoidin-I-like domains-3 (EDIL3) (32). We have previously identified Del-1 as an endogenous modulator of leukocyte adhesion through interaction with integrin αLβ2 (LFA-1; CD11a/CD18) (29, 31). Moreover, Del-1 interacts with β3 integrin (CD61) via an Arg-Gly-Asp (RGD) motif on the second EGF-like repeat (30).In the present work, we observed that Del-1 is expressed by several major cellular components of the HSC niche, though not by hematopoietic progenitors. In particular, Del-1 is expressed by those niche cells that have a major role in the maintenance of HSCs, i.e., arteriolar endothelial cells and perivascular CAR cells (3,6,7,9,15). In addition, Del-1 is expressed by cells of the osteoblastic lineage that crucially mediate the engraftment of HSCs in the post-transplantation niche (3,17,18). This spatial distribution of Del-1 raised the possibility that it might be involved in the regulation of hematopoiesis. We addressed this hypothesis using in vivo models of steady-state, regenerative, and stress hematopoiesis and in vitro mechanistic approach-
Bardet-Biedl Syndrome (BBS) is a pleiotropic ciliopathy caused by dysfunction of primary cilia. More than half of BBS patients carry mutations in one of eight genes encoding for subunits of a protein complex, the BBSome, which mediates trafficking of ciliary cargoes. In this study we elucidated the mechanisms of the BBSome assembly in living cells and how this process is spatially regulated. We generated a large library of human cell lines deficient in particular BBSome subunit and expressing another subunit tagged with a fluorescent protein. We analyzed these cell lines utilizing biochemical assays, conventional and expansion microscopy and quantitative fluorescence microscopy techniques: fluorescence recovery after photobleaching (FRAP) and fluorescence correlation spectroscopy (FCS). Our data revealed that the BBSome formation is a sequential process. We show that the pre-BBSome is nucleated by BBS4 and assembled at pericentriolar satellites, followed by the translocation of the BBSome into the ciliary base mediated by BBS1. Our results provide a framework for elucidating how BBS causative mutations interfere with the biogenesis of the BBSome.
IL‐17 mediates immune protection from fungi and bacteria, as well as it promotes autoimmune pathologies. However, the regulation of the signal transduction from the IL‐17 receptor (IL‐17R) remained elusive. We developed a novel mass spectrometry‐based approach to identify components of the IL‐17R complex followed by analysis of their roles using reverse genetics. Besides the identification of linear ubiquitin chain assembly complex (LUBAC) as an important signal transducing component of IL‐17R, we established that IL‐17 signaling is regulated by a robust negative feedback loop mediated by TBK1 and IKKε. These kinases terminate IL‐17 signaling by phosphorylating the adaptor ACT1 leading to the release of the essential ubiquitin ligase TRAF6 from the complex. NEMO recruits both kinases to the IL‐17R complex, documenting that NEMO has an unprecedented negative function in IL‐17 signaling, distinct from its role in NF‐κB activation. Our study provides a comprehensive view of the molecular events of the IL‐17 signal transduction and its regulation.
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