Project description:The influence of 2D and 3D cell culture platforms on vascular function was investigated by comparing gene expression for human pluripotent stem cell-derived endothelial cells (H1-ECs), primary human brain vascular pericytes (pericytes), and human umbilical vein endothelial cells (HUVECs) cultured on tissue culture polystyrene (TCP, “2D”), on or in poly(ethylene glycol) (PEG) hydrogels formed via “thiol-ene” photopolymerization, and on or in gelled Matrigel. ECs cocultured with pericytes in PEG formed vascular networks with global gene expression that was highly correlated to a standard 3D Matrigel assay (Spearman’s coefficients ≥ 0.98). H1-ECs, HUVECs, and pericytes were characterized gene expression signatures associated with the cell cycle and mitosis when cultured on TCP surfaces compared to cells cultured on top of or encapsulated in PEG hydrogels or Matrigel. The proliferative signature was not necessarily a function of the 2D format, since endothelial cells cultured on PEG hydrogels were not characterized by increased proliferation or a proliferative gene signature compared to cells encapsulated in PEG hydrogels. The proliferative phenotype for H1-ECs on TCP was regulated by FAK-ERK activity, and inhibition or knockdown of ERK pathway signaling decreased proliferation and cell cycle genes while increasing expression of “3D-like” vasculature development genes. Our results suggest that cells in 2D culture adopt a highly proliferative state that interferes with normal vascular function and provides unique insight into the importance of cellular and extracellular context for in vitro tissue modeling.

Project description:The blood-brain barrier (BBB) dynamically controls and maintains a precisely balanced brain microenvironment necessary for reliable functioning. It is made up of highly specialized endothelial cells (ECs) in the lining of the vascular wall. These ECs are surrounded by the basal lamina, astrocytic perivascular endfeet, pericytes, microglia and neuronal processes that have been shown to contribute to barrier function1. In essence, the brain endothelium limits both transcellular and paracellular passage of cells and molecules into the central nervous system (CNS). Transcellular passage of hydrophilic molecules is limited due to a low rate of transcytotic vesicles, an extremely low pinocytotic activity, expression of active efflux transporters, and high metabolic activity. Paracellular diffusion of hydrophilic molecules and trafficking of immune cells is restricted by a network of tight junctions (TJs)2-5. Due to these characteristics, the BBB is able to protect the CNS from sudden changes in blood composition and uncontrolled influx of immune cells. In a large number of neuro-inflammatory diseases, an impaired function and an opening of the BBB are observed. In diseases of the CNS like multiple sclerosis or stroke or after brain trauma, the BBB becomes inflamed (mediated by for example reactive oxygen species (ROS) and hypoxia) and its function severely impaired which gives rise to enhanced cellular infiltration, thus contributing to tissue damage and neurological deficits. Due to the specialized nature of brain ECs, transmigration of leukocytes through cerebrovascular endothelium is likely to differ from that in other vascular beds. Generally, the transmigration process is closely controlled by the interaction of leukocytes with the endothelial surface followed by low velocity rolling, arrest, firm adhesion, and finally transmigration. For the diapedesis of immune cells across the cerebral vasculature a re-arrangement of the cytoskeleton and opening of the TJ complexes is required to allow cells to pass into the sub endothelial space. In the initial step of the adhesive cascade leukocytes adhere to the endothelium with low affinity. This adhesion is mediated by several members of the selectin family and their corresponding ligands. Despite the low affinity of these interactions, resulting contact of leukocytes with the endothelium leads to further activation of both cell types and finally transmigration of the leukocytes through the BBB6,7. The glycosylation of endothelial cells of different vascular bed origins To date it is unknown which specific carbohydrate structures on the BBB endothelium mediate leukocyte capture and rolling, and whether these structures are differentially expressed onto inflamed brain EC compared to normal brain ECs and vascular beds of other organs. Initial studies using qPCR and FACS analysis within our group reveal that brain endothelial cells have a different profile in their glycosylation-related genes compared to microvascular ECs upon inflammation, which may result in a different glycosylation profile of adhesive structures and may underlie rolling, adhesion and diapedesis of leukocytes. In this project we wish to identify specific, glycosylated structures on brain endothelial cells that mediate capture, rolling and diapedesis of leukocytes in the brain. To investigate the expression of glycosyltransferases in dendritic cells and the changes in expression associated with maturation. RNA preparations from stimulated and non-stimulated hcMEC/D3 (human brain endothelial cells line) and FMVEC (human promary microvascular endothelial cells isolated from foreskins) were sent to both Microarray Core (E) and Core(C). The RNA was put on an RNeasy Column, amplified, labeled, and hybridized to the Glycov3 microarrays. Data was sent to Dr. van Kooyk's lab for analysis.

Project description:Cardiovascular disorders, like atherosclerosis and hypertension, are increasingly known to be associated with vascular cognitive impairment (VCI). In particular, intracranial atherosclerosis is one of the main causes of VCI, although plaque development occurs later in time and is structurally different compared to atherosclerosis in extracranial arteries. Recent data suggest that endothelial cells (ECs) that line the intracranial arteries may exert anti-atherosclerotic effects due to yet unidentified pathways. To gain insights into underlying mechanisms, we isolated post-mortem endothelial cells from both the intracranial basilar artery (BA) and the extracranial common carotid artery (CCA) from the same individual (total of 15 individuals) with laser capture microdissection. RNA sequencing revealed a distinct molecular signature of the two endothelial cell populations of which the most prominent ones were validated by means of qPCR. Our data reveal for the first time that intracranial artery ECs exert an immune quiescent phenotype. Secondly, genes known to be involved in the response of ECs to damage (inflammation, differentiation, adhesion, proliferation, permeability and oxidative stress) are differentially expressed in intracranial ECs compared to extracranial ECs. Finally, Desmoplakin (DSP) and Hop Homeobox (HOPX), two genes expressed at a higher level in intracranial ECs, and Sodium Voltage-Gated Channel Beta Subunit 3 (SCN3B), a gene expressed at a lower level in intracranial ECs compared to extracranial ECs, were shown to be responsive to shear stress and/or hypoxia. With our data we present a set of intracranial-specific endothelial genes that may contribute to its protective phenotype, thereby supporting proper perfusion and consequently may preserve cognitive function. Deciphering the molecular regulation of the vascular bed in the brain may lead to the identification of novel potential intervention strategies to halt vascular associated disorders, such as atherosclerosis and vascular cognitive dysfunction.

Project description:N-(1,3-dimethylbutyl)-N′-phenyl-p-phenylenediamine (6PPD), which is widely used as an antiozonant in rubber tires, has recently got much attention for its acute aquatic toxicity. However, the developmental toxicity of 6PPD in cerebrovascular network remains unknown. Here, we investigated the effects of 6PPD exposure in cerebral vascular using the larvae of zebrafish. 6PPD would not affect the body length and shape of zebrafish larvae at the concentrations ranging from 20 μg/L to 1000 μg/L. 6PPD induced developmental defects in the brain in a concentration-dependent manner. The trunk vascular development would not be affected while the cerebrovascular network was disrupted upon 6PPD exposure. 6PPD would trigger excessive Reactive Oxygen Species (ROS) in the brain, indicating abnormal oxidative stress. Mechanistically, brain-specific transcriptome analysis showed that 6PPD could potentially cause the blockage of arachidonic acid (AA) metabolism-related genes and the upregulation of ferroptosis-related genes. Besides, treatment with ferroptosis inhibitor N-Acetyl-L-cysteine (NAC) attenuated oxidative damage and improved the construction of cerebrovascular network upon 6PPD exposure. Moreover, using a human vascular endothelial cell line, we further confirmed that 6PPD could trigger abnormal oxidative stress and defective expansion capacity, implying the conserved toxicity cross species. These findings are useful for the elucidation of toxicity underlying 6PPD in cerebrovascular systems of both zebrafish and humans.

Project description:Vascular aging, which is characterized by brain endothelial cell (EC) senescence and dysfunction, is known to contribute to various age-related cerebrovascular and neurodegenerative diseases. However, the underlying mechanisms remain unclear. EC-derived microvesicles (EMVs) and exosomes (EEXs) retain the characteristics of parent cells and transfer their contents to modulate the functions of recipient cells, showing potential for evaluation or regulation of vascular aging. Here, as indicated by analyses of senescence-associated beta-galactosidase (SA-β-gal) staining, cerebral blood flow, blood–brain barrier function, aging-related markers and cognitive ability, we found that young primary EC (passage 2-4) released EMVs alleviated mouse cerebrovascular and brain aging more effectively than EEXs. Aged EC (passage 15-16) released EMVs were more effective than their released EEXs at exacerbating mouse cerebrovascular and brain aging. We further revealed that these EMVs regulated cerebrovascular and brain aging by transferring miR-17-5p and modulated EC senescence and function via the miR-17-5p/PI3K/Akt pathway. Clinically, the levels of plasma EMVs and their associated miR-17-5p (EMV-miR-17-5p) were significantly increased or decreased in elderly individuals and were closely correlated with reactive oxygen species (ROS) and vascular aging. Receiver operating characteristic (ROC) analysis revealed that the area under the curve (AUC) was 0.724 for EMVs, 0.77 for EMV-miR-17-5p and 0.815 for their combination for distinguishing vascular aging. Our results identified novel roles for EMVs and showed that these vesicles more effectively modulated vascular and brain aging than did EEXs by regulating EC functions through the miR-17-5p/PI3K/Akt pathway; thus, EMVs and EMV-miR-17-5p are promising biomarkers and therapeutic targets for vascular aging.

Project description:The heterogeneity of endothelial cells (ECs), lining blood vessels, across tissues remains incompletely inventoried. We constructed an atlas of >32,000 single-EC transcriptomic data from 11 tissues of the model organism Mus musculus. We propose a new classification of EC phenotypes based on transcriptome signatures and inferred putative biological features. We identified top-ranking markers for ECs from each tissue. ECs from different vascular beds (arteries, capillaries, veins, lymphatics) resembled each other across tissues, but only arterial, venous and lymphatic (not capillary) ECs shared markers, illustrating a greater heterogeneity of capillary ECs. We identified high-endothelial-venule and lacteal-like ECs in the intestines, and angiogenic ECs in healthy tissues. Metabolic transcriptomes of ECs differed amongst spleen, lung, liver, brain and testis, while being similar for kidney, heart, muscle and intestines. Within tissues, metabolic gene expression was heterogeneous amongst ECs from different vascular beds, altogether highlighting large EC heterogeneity.

Project description:PD1-mediated microglia assisted cerebrovascular pruning during vascular development.

Project description:The extracellular matrix (ECM), a key interface between the cerebrovasculature and other cells within the neuro-glial-vascular unit , provides structural stability and modulates cell behaviour and signalling. These functions are dependent on ECM protein composition. Since ECM defects may contribute to a broad range of disorders including cerebrovascular disease, it is crucially important to characterize ECM composition to better understand the mechanisms by which the ECM modulates brain health and disease. To date, molecular studies of the cerebrovascular ECM have been limited. We therefore generated ECM extracts from vascular enriched tissues of both mouse and human post-mortem brain. We used mass spectrometry with off-line high-pH reversed-phase fractionation to increase proteome depth and characterized the identified proteins. This identified a large number of proteins (>1000 mouse, >2000 human) in the ECM-enriched fractions, with > 66% of the identified proteins covered in both human and mouse samples. We now report 147 ECM proteins, including collagens (as major ECM components), laminins, fibronectin and nidogens, that can be considered as the core constituents of the human brain vascular matrisome. We also identified 12 novel proteins in the ECM-enriched fraction, that may have regulate or interact with the matrisome, including several key regulators of neurovascular interactions, such as BCAM, CDH5 and PARVB. Many of the identified brain vascular matrisome proteins are encoded by genes identified in stroke and cerebral small vessel disease genome-wide association studies, underscoring the importance of the vascular ECM in health and disease. This brain vascular matrisome represents a powerful resource for investigating the impact of aging and disease on the cerebrovasculature.

Project description:<p>The vasculature represents a highly plastic compartment, capable of switching from a quiescent to an active proliferative state during angiogenesis. Metabolic reprogramming in endothelial cells (ECs) thereby is crucial to cover the increasing cellular energy demand under growth conditions. Here we assess the impact of mitochondrial bioenergetics on neovascularisation, by deleting cox10 gene encoding an assembly factor of cytochrome c oxidase (COX) specifically in mouse ECs, providing a model for vasculature-restricted respiratory deficiency. We show that EC-specific cox10 ablation results in deficient vascular development causing embryonic lethality. In adult mice induction of EC-specific cox10 gene deletion produces no overt phenotype. However, the angiogenic capacity of COX-deficient ECs is severely compromised under energetically demanding conditions, as revealed by significantly delayed wound-healing and impaired tumour growth. We provide genetic evidence for a requirement of mitochondrial respiration in vascular endothelial cells for neoangiogenesis during development, tissue repair and cancer. </p>

Project description:Successful implantation and long-term survival of engineered tissue grafts hinges on adequate vascularization of the implant. Endothelial cells are essential for patterning vascular structures, but they require supportive mural cells such as pericytes/mesenchymal stem cells (MSCs) to generate stable, functional blood vessels.1-5 While there is evidence that the angiogenic effect of MSCs is mediated via the secretion of paracrine signals,6,7 the identity of these signals is unknown. Here, by utilizing two functionally distinct human MSC clones, we found that so-called “pericytic” MSCs secrete the pro-angiogenic neurovascular guidance molecule SLIT3,8 which guides vascular development by directing ROBO4-positive endothelial cells to form networks in engineered tissue. In contrast, “non-pericytic” MSCs exhibit reduced activation of the SLIT3/ROBO4 pathway and do not support vascular networks. Using live cell imaging of organizing 3D vascular networks, we show that knockdown of SLIT3 in MSCs leads to disorganized clustering of ECs, and knockdown of its receptor ROBO4 in ECs abolishes the generation of functional human blood vessels in an in vivo xenogenic implant. These data suggest that the SLIT3/ROBO4 pathway regulates MSC-guided vascularization in engineered tissues. Heterogeneity of SLIT3 expression may underlie the variable clinical success of MSCs for tissue repair applications. 4 samples with 2 replicates each