SUMMARY Lung alveolar type I cells (AT1) and alveolar type II cells (AT2) regulate the structural integrity and function of alveoli. AT1, covering ~95% of the surface area, are responsible for gas exchange, whereas AT2 serve multiple functions, including alveolar repair through proliferation and differentiation into AT1. However, the signaling mechanisms for alveolar repair remain unclear. Here, we demonstrate, in Pseudomonas aeruginosa -induced acute lung injury in mice, that non-canonical Notch ligand Dlk1 (delta-like 1 homolog) is essential for AT2-to-AT1 differentiation. Notch signaling was activated in AT2 at the onset of repair but later suppressed by Dlk1. Deletion of Dlk1 in AT2 induced persistent Notch activation, resulting in stalled transition to AT1 and accumulation of an intermediate cell population that expressed low levels of both AT1 and AT2 markers. Thus, Dlk1 expression leads to precisely timed inhibition of Notch signaling and activates AT2-to-AT1 differentiation, leading to alveolar repair.
Loss-of-function studies have determined that Notch signaling is essential for hematopoietic and endothelial development. By deleting a single allele of the Notch1 transcriptional activation domain we generated viable, post-natal mice exhibiting hypomorphic Notch signaling. These heterozygous mice, which lack only one copy of the transcriptional activation domain, appear normal and have no endothelial or hematopoietic phenotype, apart from an inherent, cell-autonomous defect in T-cell lineage development. Following chemotherapy, these hypomorphs exhibited severe pancytopenia, weight loss and morbidity. This phenotype was confirmed in an endothelial-specific, loss-of-function Notch1 model system. Ang1, secreted by hematopoietic progenitors after damage, activated endothelial Tie2 signaling, which in turn enhanced expression of Notch ligands and potentiated Notch1 receptor activation. In our heterozygous, hypomorphic model system, the mutant protein that lacks the Notch1 transcriptional activation domain accumulated in endothelial cells and interfered with optimal activity of the wildtype Notch1 transcriptional complex. Failure of the hypomorphic mutant to efficiently drive transcription of key gene targets such as Hes1 and Myc prolonged apoptosis and limited regeneration of the bone marrow niche. Thus, basal Notch1 signaling is sufficient for niche development, but robust Notch activity is required for regeneration of the bone marrow endothelial niche and hematopoietic recovery.
Lifelong mammalian hematopoiesis requires continuous generation of mature blood cells that originate from Hematopoietic Stem and Progenitor Cells (HSPCs) situated in the post-natal Bone Marrow (BM). The BM microenvironment is inherently complex and extensive studies have been devoted to identifying the niche that maintains HSPC homeostasis and supports hematopoietic potential. The Notch signaling pathway is required for the emergence of the definitive Hematopoietic Stem Cell (HSC) during embryonic development, but its role in BM HSC homeostasis is convoluted. Recent work has begun to explore novel roles for the Notch signaling pathway in downstream progenitor populations. In this review, we will focus an important role for Notch signaling in the establishment of a T cell primed sub-population of Common Lymphoid Progenitors (CLPs). Given that its activation mechanism relies primarily on cell-to-cell contact, Notch signaling is an ideal means to investigate and define a novel BM lymphopoietic niche. We will discuss how new genetic model systems indicate a pre-thymic, BM-specific role for Notch activation in early T cell development and what this means to the paradigm of lymphoid lineage commitment. Lastly, we will examine how leukemic T-cell acute lymphoblastic leukemia (T-ALL) blasts take advantage of Notch and downstream lymphoid signals in the pathological BM niche.
Embryonic hematopoietic stem cells (HSC) expand rapidly during development in the fetal liver. Notch1 is required for emergence of the definitive hematopoietic stem cells (HSCs) from the hemogenic endothelium, and is essential for survival and function of HSCs in the fetal liver. The identity of the ligand and the ligand-presenting cell during hematopoietic development would provide valuable information of the Notch signaling mechanism in HSCs as well as the identity of key niche cells that drive the expansion and cell fate decisions of embryonic HSCs. In the present study, we have taken a comprehensive approach to determine the ligands and cells that initiate Notch signaling in the mouse fetal liver. To this end, we have performed single-cell analysis for all Notch signaling proteins and many known targets in E14.5 fetal HSCs and adult bone marrow HSCs as well as fetal liver endothelial cells. We determined that Jagged1 (Jag1) is highly expressed in both endothelial cells as well as in fetal HSCs but not in adult HSCs. We have performed conditional loss-of-function analysis of Jag1 in fetal endothelial cells as well as in fetal hematopoietic lineages, where both myeloid and megakaryocytic progenitors are shown to express high levels of Jag1. Our results indicate that while loss of endothelial Jag1 has severe effects in embryonic vascular development, loss of hematopoietic Jag1 allows for normal fetal morphology, yet severely impedes the functional ability of fetal liver HSCs to expand and differentiate. RNA-Sequencing analysis of long-term fetal HSCs in Jag1-mutant embryos (VavCreJag f/f) revealed reduced expression of Gata2, Mllt3, Hoxa7, Angpt1 and IL-12a genes in fetal HSCs, which are well-known regulators of self-renewal and expansion. Our findings indicate that Jag1 is an essential niche factor for development of HSCs in the fetal liver and for functional potential of fetal HSCs once in the bone marrow microenvironment. Figure 1 Figure 1. Disclosures No relevant conflicts of interest to declare.
Notch signaling is essential for the emergence of definitive hematopoietic stem cells (HSCs) in the embryo and their development in the fetal liver niche. However, how Notch signaling is activated and which fetal liver cell type provides the ligand for receptor activation in HSCs is unknown. Here we provide evidence that endothelial Jagged1 (Jag1) has a critical early role in fetal liver vascular development but is not required for hematopoietic function during fetal HSC expansion. We demonstrate that Jag1 is expressed in many hematopoietic cells in the fetal liver, including HSCs, and that its expression is lost in adult bone marrow HSCs. Deletion of hematopoietic Jag1 does not affect fetal liver development; however, Jag1-deficient fetal liver HSCs exhibit a significant transplantation defect. Bulk and single-cell transcriptomic analysis of HSCs during peak expansion in the fetal liver indicates that loss of hematopoietic Jag1 leads to the downregulation of critical hematopoietic factors such as GATA2, Mllt3, and HoxA7, but does not perturb Notch receptor expression. Ex vivo activation of Notch signaling in Jag1-deficient fetal HSCs partially rescues the functional defect in a transplant setting. These findings indicate a new fetal-specific niche that is based on juxtracrine hematopoietic Notch signaling and reveal Jag1 as a fetal-specific niche factor essential for HSC function.
A major clinical obstacle after treatment of blood disorders with hematopoietic stem cell transplantation (HSCT) is the resultant long‐term impairment in T cell mediated adaptive immunity. Though T cell development in the thymus has been extensively characterized, there are significant gaps in our understanding of pre‐thymic T cell commitment. The Notch pathway is vital for the development of T cell progenitors in the thymus. We have confirmed a role for Notch signaling in the bone marrow Common Lymphoid Progenitor (CLP) population which suggests that Notch signals may instruct lymphoid progenitors towards the T cell fate even before exiting the bone marrow. Using a genetic Notch1 hypomorhic mouse model, we find defective T cell lineage development as early as the CLP, with no defect in B cell or NK cell development downstream of the CLP. We further generated a list of genes dependent on Notch signaling within the CLP population using RNA sequencing. One downstream target of Notch in CLPs is IL21r, which we have confirmed plays a role in the proliferation of Notch activated CLP cells in the bone marrow. Our work uncovers a T cell lineage developmental pathway initiated by Notch signaling in the bone marrow CLP population.
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