Project description:Constrictive vascular remodeling limiting blood flow, as well as compensatory outward remodeling, have been observed in many cardiovascular diseases; however, the underlying mechanisms regulating the remodeling response of the vessels remain unclear. Plasminogen activators (PA) are involved in many of the processes of vascular remodeling. We have shown previously that increased tissue-type PA (tPA) contributes to outward vascular remodeling. To elucidate the mechanisms involved in the induction of outward remodeling we characterized changes in the expression profiles of 8799 genes in injured rat carotid arteries one and four days after recombinant tPA treatment compared to vehicle. Periadventitial tPA significantly increased lumen size and vessel area, encompassed by the external elastic lamina, at both one and four days after treatment. Among 41 differentially expressed known genes one day after tPA application, 5 genes were involved in gene transcription, 5 genes were related to the regulation of vascular tone (for example, thromboxane A2 receptor (D32080) or nonselective-type endothelin receptor (S65355)), and 8 genes were identified as participating in vascular innervation (for example, calpain (D14478) or neural cell adhesion molecule L1 (X59149)). Four days after injury in tPA-treated arteries, 4 genes, regulating vascular tone, were differentially expressed. Thus, tPA promotes outward arterial remodeling after injury, at least in part, by regulating expression of genes in the vessel wall related to function of the nervous system and vascular tone.

Project description:Fluid shear stress (FSS) from blood flow sensed by vascular endothelial cells (ECs) determines vessel behavior but regulatory mechanisms are only partially understood. We used cell State Transition Assessment and Regulation (cSTAR), a powerful new computational method, to elucidate EC transcriptomic states under low shear stress (LSS), physiological shear stress (PSS), high shear stress (HSS), and oscillatory shear stress (OSS) that induce vessel inward remodeling, stabilization, outward remodeling or disease susceptibility, respectively. Combined with publicly available EC transcriptomic responses to drug treatments from the LINCS database, this approach inferred a regulatory network controlling EC states and made several novel predictions. Particularly, inhibiting cell cycle dependent kinase (CDK) 2 was predicted to initiate inward vessel remodeling and promote atherogenesis. In vitro, PSS activated CDK2 and induced late G1 cell cycle arrest. In mice, EC deletion of CDK2 triggered inward artery remodeling, pulmonary and systemic hypertension and accelerated atherosclerosis. These results validate use of cSTAR and identify key determinants of normal and pathological artery remodeling.

Project description:Von Hippel-Lindau (VHL) gene mutations induce neural tissue hemangioblastomas as well as highly vascularized clear cell renal cell carcinomas (ccRCCs). Pathological vessel remodeling arises from mis-regulation of hypoxia inducible factors and vascular endothelial growth factor, among other genes. Variation in disease penetrance has long been recognized in relation to genotype. We show Vhl mutations also disrupt Notch signaling, causing mutation-specific vascular abnormalities e.g. type 1 (null) vs. type 2B (murine G518A representing human R167Q). In conditional mutation retina vasculature, Vhl null mutation (i.e. UBCCreER/+; Vhlfl/fl) had little effect on initial vessel branching, but severely reduced arterial and venous branching at later stages. Interestingly, this mutation accelerated arterial maturation, as observed in retina vessel morphology and aberrant a-smooth muscle actin localization, particularly in vascular pericytes. RNA sequencing analysis identified gene expression changes within several key pathways including Notch and smooth muscle cell contractility. Notch inhibition failed to reverse later-stage branching defects but rescued the accelerated arterialization. Retinal vessels harboring the type 2B Vhl mutation (i.e. UBCCreER/+; Vhlfl/2B) displayed stage-specific changes in vessel branching and an advanced progression toward an arterial phenotype. Disrupting Notch signaling in 2B mutants increased both artery and vein branching, and restored arterial maturation toward non-mutant levels. By revealing differential effects of the null and type 2B Vhl mutations on vessel branching and maturation, these data may provide insight into the variability of VHL-associated vascular changes, particularly the heterogeneity and aggressiveness in ccRCC vessel growth, as well as suggest Notch pathway targets for treating VHL syndrome.

Project description:The nuclear membrane protein SUN1 promotes blood vessel formation and barrier function by stabilizing endothelial cell-cell junctions. Communication between SUN1 and endothelial cell junctions relies upon proper microtubule dynamics and Rho signaling, revealing long-range cellular communication from the nucleus to the cell periphery that is important for vascular development and function.

Project description:Purpose:Pulmonary arterial hypertension secondary to congenital heart disease (CHD-PAH) with systemic-to-pulmonary shunt is characterized by proliferative vascular remodeling. Capillary morphogenesis gene-2 (CMG2) exhibits roles in cell proliferation and apoptosis. The purpose of this study was to determine the possible roles of CMG2 in the pathogenesis of systemic-to-pulmonary shunt induced PAH. Methods Lung tissue sections from CHD-PAH patients, systemic-to-pulmonary shunt induced PAH rat model, CMG2-/- rats, and PASMCs were used. Immunohistochemistry, real time polymerase chain reaction, Western blot, proliferation, apoptosis, and next generation sequencing (NGS) were performed in this study. Results CMG2 expression was reduced in lung tissues and pulmonary arterioles from Eisenmenger’s syndrome patient and rats with systemic-to-pulmonary shunt induced PAH. CMG2-/- rats exhibited heavier PAH and pulmonary vascular remodeling following exposure to systemic-to-pulmonary shunt for 8 weeks. Over-expression of CMG2 in cultured human PASMCs inhibited cell proliferation and promoted apoptosis, while knockdown of CMG2 promoted cell proliferation and inhibited apoptosis. A total of 1319 genes were found to be dysregulated in CMG2-/- rat lungs as detected by NGS. Biological processes influenced by these differentially expressed genes include regulation of blood vessel diameter, vasoconstriction, regulation of blood vessel size, vascular process in circulatory system, etc., and the most prominent pathway regulated is PI3K-Akt signaling pathway. Conclusion Our work identifies a novel role for CMG2 in systemic-to-pulmonary shunt induced PAH based on the findings that CMG2 deficiency could exacerbate systemic-to- pulmonary shunt induced vascular remodeling in the development of PAH. CMG2 may be a potential target for CHD-PAH treatment.

Project description:Our single-cell transcriptomic profiling study depicted the heterogeneity of human dermal blood vascular endothelial cells and molecularly refined individual blood vessel compartments.

Project description:Biomechanical forces influence vascular function, but the molecular mechanisms regulating many of these mechano-activated cellular events remain largely uncharacterized. In particular, the vascular endothelium can sense alterations in hemodynamic shear stress which, in the context of adaptive remodeling or arteriogenesis, has been shown to lead to the generation of endothelial-derived signals critical for controlling blood vessel structure and function. Here, we sought to define the arteriogenic responses evoked in endothelial cells exposed to flow using transciptional profiling. Analysis of these transcriptional programs identified several genes previously shown to be important for endothelial-smooth muscle interactions and vascular remodeling, including the transcription factor kruppel-like factor 2 (KLF2).

Project description:Notch signaling is an evolutionarily conserved pathway that functions via direct cell-cell contact. The Notch ligand Jagged1 (Jag1) has been extensively studied in vascular development, particularly for its role in smooth muscle cell maturation. Endothelial cell-expressed Jag1 is essential for blood vessel formation by signaling to nascent vascular smooth muscle cells and promoting their differentiation. Given the established importance of Jag1 in endothelial cell/smooth muscle crosstalk during development, we sought to determine the extent of this communication in the adult vasculature for blood vessel function and homeostasis.

Project description:Diabetes is prevalent worldwide and associated with severe health complications, including blood vessel damage that leads to cardiovascular disease and death. We report the development of 3D blood vessel organoids from human embryonic and induced pluripotent stem cells. These human blood vessel organoids contain endothelium, perivascular pericytes, and basal membranes, and self-assemble into lumenized interconnected capillary networks. We treat these vascular organoids with hyperglycemia and inflammatory cytokines in vitro, which leads to basement membrane thickening, a structural hallmark of diabetic patient. To compare differential gene expression we performed RNAseq on endothelial cells, derived from control (NG) or diabetic (DI) vascular organoids.

Project description:Acute vascular injury is an unwelcome consequence of invasive treatments designed to alleviate symptoms of vascular stenosis. Resulting fibrotic scarring and neointima formation may result in loss of lumen diameter and diminished vascular function. Understanding of the key phases of acute inflammation, resolution and remodeling has the potential to minimise unwanted effects on the vasculature and therefore improve patient outcomes. The cellular landscape of blood vessels is highly hetergeneous in nature, and therefore data at single-cell resolution is of high relevance to this problem. Herein, the cellularity of murine carotid artery tissue is described in a cell- and time-resolved manner. Single-cell RNA-sequencing of carotid tissue isolated at time-points ranging from uninjured vessel to 14 days post-injury enabled the recapitulation of all stages of vascular injury. In these data, a sub-population of smooth muscle cells which also arises in atherosclerosis and myocardial infarction was identified. So-called stem cells/endothelial cells/monocytes (SEM) cells are candidates for repopulating injured vessels, and were amongst the most proliferative cell clusters following wire-injury of the carotid artery. Transcriptional signatures reflecting SEM gene expression patterns could also be detected in bulk RNA-sequencing of neointimal tissue isolated by laser capture microdissection. These data indicate that phenotypic plasticity of smooth muscle cells is highly important to the progression of lumen loss following acute vascular insult.