Project description:Fluid clearance mediated by lymphatic vessels is known to be essential for lung inflation and gas exchange function during the transition from prenatal to postnatal life, yet the molecular mechanisms that regulate lymphatic function remain unclear. Here, we profiled the molecular features of lymphatic endothelial cells (LECs) in embryonic and postnatal day (P) 0 lungs by single-cell RNA-seq analysis. We identified that the expression of c-JUN is transiently upregulated in P0 LECs. Conditional knockout of Jun in LECs impairs the opening of lung lymphatic vessels at birth, leading to fluid retention in the lungs and neonatal death. We further demonstrated that increased mechanical pressure induces the expression of c-JUN in LECs. c-JUN regulates the opening of lymphatic vessels by modulating remodeling of the actin cytoskeleton in LECs. Our study established the essential regulatory function of c-JUN-mediated transcriptional responses in facilitating lung lymphatic fluid clearance at birth.

Project description:Fluid clearance mediated by lymphatic vessels is known to be essential for lung inflation and gas exchange function during the transition from prenatal to postnatal life, yet the molecular mechanisms that regulate lymphatic function remain unclear. Here, we profiled the molecular features of lymphatic endothelial cells (LECs) in embryonic and postnatal day (P) 0 lungs by single-cell RNA-seq analysis. We identified that the expression of c-JUN is transiently upregulated in P0 LECs. Conditional knockout of Jun in LECs impairs the opening of lung lymphatic vessels at birth, leading to fluid retention in the lungs and neonatal death. We further demonstrated that increased mechanical pressure induces the expression of c-JUN in LECs. c-JUN regulates the opening of lymphatic vessels by modulating remodeling of the actin cytoskeleton in LECs. Our study established the essential regulatory function of c-JUN-mediated transcriptional responses in facilitating lung lymphatic fluid clearance at birth.

Project description:The lymphatic vasculature regulates lung homeostasis through drainage of fluid and trafficking of immune cells and plays a key role in the response to lung injury in several disease states. We have previously shown that lymphatic dysfunction occurs early in the pathogenesis of chronic obstructive pulmonary disease (COPD) caused by cigarette smoke (CS) and that this is associated with increased thrombin and fibrin clots in lung lymph. However, the direct effects of CS and thrombin on lymphatic endothelial cells (LECs) in COPD are not entirely clear. Studies of the blood vasculature have shown that COPD is associated with increased thrombin, which causes endothelial dysfunction after CS exposure and is characterized by changes in the expression of coagulation factors and leukocyte adhesion proteins. Here, we determined whether similar changes occur in LECs. We used an in vitro cell culture system and treated human lung microvascular lymphatic endothelial cells with cigarette smoke extract (CSE) and/or thrombin. We found that CSE treatment led to decreased fibrinolytic activity in LECs, which was associated with increased expression of plasminogen activator inhibitor 1 (PAI-1). LECs treated with both CSE and thrombin together had a decreased expression of TFPI and an increased expression of vascular adhesion molecules. RNA sequencing of lung LECs isolated from mice exposed to CS also showed upregulation of prothrombotic and inflammatory pathways at both acute and chronic exposure time points. Analysis of publicly available single-cell RNA sequencing of LECs as well as immunohistochemical staining of lung tissue from COPD patients supported these data and showed an increased expression of inflammatory markers in LECs from COPD patients compared to those from controls. These studies suggest that in parallel with blood vessels, the lymphatic endothelium undergoes inflammatory changes associated with CS exposure and increased thrombin in COPD. Further research is needed to unravel the mechanisms by which these changes affect lymphatic function and drive tissue injury in COPD.

Project description:Lymphatic vessels are involved in fluid drainage and are critical for health. To date, only genetic signaling pathways have been implicated in lymphatic development, and a role for metabolism has not been described. Here, we report that transcription factor Prox1 increases fatty acid ß-oxidation (FAO) through upregulation of CPT1a, a rate-controlling step of FAO. Lymphatic endothelial cells (LECs) oxidize fatty acids to proliferate and migrate. By providing acetyl-CoA, FAO is also critical for the maintenance of differentiated LECs through the regulation of histone acetylation of key lymphangiogenic genes. Loss of CPT1a in LEC precursors causes lymphatic defects in vivo, while restoration of acetyl-CoA by supplementing acetate to replenish cellular acetyl-CoA levels rescues this process.

Project description:Liver lymphatic vessels support liver function by draining interstitial fluid, cholesterol, fat, and immune cells for surveillance in the liver draining lymph node. Chronic liver disease is associated with increased inflammation and immune cell infiltrate. However, it is currently unknown if or how lymphatic vessels respond to increased inflammation and immune cell infiltrate in the liver during chronic disease. Here we demonstrate that lymphatic vessel abundance increases in patients with chronic liver disease and is associated with areas of fibrosis and immune cell infiltration. Using single-cell mRNA sequencing and multi-spectral immunofluorescence analysis we identified liver lymphatic endothelial cells and found that chronic liver disease results in lymphatic endothelial cells (LECs) that are in active cell cycle with increased expression of CCL21. Additionally, we found that LECs from patients with NASH adopt a transcriptional program associated with increased IL13 signaling. Moreover, we found that oxidized low density lipoprotein, associated with NASH pathogenesis, induced the transcription and protein production of IL13 in LECs both in vitro and in a mouse model. Finally, we show that oxidized low density lipoprotein reduced the transcription of PROX1 and decreased lymphatic stability. Together these data indicate that LECs are active participants in the liver, expanding in an attempt to maintain tissue homeostasis. However, when inflammatory signals, such as oxidized low density lipoprotein are increased, as in NASH, lymphatic function declines and liver homeostasis is impeded.

Project description:Proper functioning of the lymphatic system is required for normal immune response, fluid balance and lipid reabsorption. Multiple regulatory mechanisms are employed to ensure correct formation of lymphatic vessels; however, whether epigenetic regulation is involved in this process remains largely unknown. We report that epigenetic priming by the Disruptor of telomeric silencing 1-like (DOT1L) in endothelial cell (EC) is indispensable for generation and function of lymphatic endothelial cells (LECs). Mechanistically, loss function of DOT1L leads to reduction of H3K79 di-methylation and expression of the genes important for LEC development and function. Thus, our study establishes DOT1L-mediated transcriptional regulation in ECs plays an important role in differentiation and function of LECs.

Project description:Proper functioning of the lymphatic system is required for normal immune response, fluid balance and lipid reabsorption. Multiple regulatory mechanisms are employed to ensure correct formation of lymphatic vessels; however, whether epigenetic regulation is involved in this process remains largely unknown. We report that epigenetic priming by the Disruptor of telomeric silencing 1-like (DOT1L) in endothelial cell (EC) is indispensable for generation and function of lymphatic endothelial cells (LECs). Loss function of DOT1L leads to reduction of H3K79 di-methylation and expression of the genes important for LEC development and function. Thus, our study establishes DOT1L-mediated transcriptional regulation in ECs plays an important role in differentiation and function of LECs.

Project description:Complex lymphatic anomalies (CLAs) are sporadically occurring diseases caused by the maldevelopment of lymphatic vessels. We and others recently reported that somatic activating mutations in KRAS can cause CLAs. However, the mechanisms by which activating KRAS mutations cause CLAs are poorly understood. Here we show that KRASG12D expression in lymphatic endothelial cells (LECs) during embryonic development impairs the formation of lymphovenous valves and causes the enlargement of lymphatic vessels. We demonstrate that KRASG12D expression in primary human LECs induces cell spindling, proliferation, and migration. It also increases AKT and ERK1/2 phosphorylation and decreases the expression of genes that regulate lymphatic vessel maturation. We show that MEK1/2 inhibition with the FDA-approved drug trametinib suppresses KRASG12D-induced morphological changes, proliferation, and migration. Trametinib also decreases ERK1/2 phosphorylation and increases the expression of genes that regulate the maturation of lymphatic vessels. We also show that trametinib and Cre-mediated expression of a dominant-negative form of MEK1 (Map2k1K97M) suppresses KRASG12D-induced lymphatic vessel hyperplasia in embryos. Last, we demonstrate that conditional knockout of wild-type Kras in LECs does not affect the formation or function of lymphatic vessels. Together, our data indicate that KRAS/MAPK signaling must be tightly regulated during embryonic development for the proper development of lymphatic vessels and further support the testing of MEK1/2 inhibitors for treating CLAs.

Project description:Maturation of lung cell types occurs during late gestation to ensure lung function and optimal gas exchange at birth. The pulmonary lymphatic endothelium is an understudied cell type and is essential for immune regulation and interstitial fluid removal. Here we provide the first characterization of the pulmonary lymphatic endothelium during late gestation prior to birth. We used microarrays to detail the global transcriptional programme underlying maturation of pulmonary lymphatic endothelium and identified 1,281 genes with significant changes in gene expression over time. Gene expression was validated by qPCR and in situ hybridization, which indicated a potential role for IFN-I signaling in pulmonary lymphatic endothelial cell (PLEC) maturation prior to birth.

Project description:Afferent lymphatic vessels (LVs) connect peripheral tissues with draining lymph nodes (dLNs) and are important for immune-surveillance and tissue drainage. They begin in the tissue as initial lymphatic capillaries, which are highly permeable and branched vessels specialized in the uptake of macromolecules, fluids and immune cells. Conversely, the downstream collecting LVs are impermeable and contractile structures that transport the taken up lymph and immune cells to the dLN. We and others have recently observed that intralymphatic leukocytes actively migrate within lymphatic capillaries but de-adhere and are passively transported by flow once they have reached in the collecting vessels. Besides potential differences in lymph flow we hypothesize that gene expression differences between capillaries and collectors could account for this transition from a crawling to a flowing mode of migration. In this project we aimed to perform a sequencing-based gene expression analysis of lymphatic endothelial cells (LECs) isolated from lymphatic capillaries and collectors, in order to identify new genes involved in leukocyte migration, as well as genes involved in shaping the morphologic phenotype of capillaries and collectors. For this, murine skin was enzymatically digested and LECs from capillaries or collectors were FACS-sorted and their RNA extracted and subjected to sequencing.