Project description:Vascular calcification (VC) is often associated with cardiovascular and metabolic diseases. However, the molecular mechanisms linking VC to these diseases have yet to be elucidated. Here we report that MDM2-induced polyubiquitination of histone deacetylase 1 (HDAC1) mediates VC. Loss of HDAC1 activity via either chemical inhibitor or genetic ablation enhanced VC. HDAC1 protein, but not mRNA, was reduced in cell and animal calcification models and in human calcified coronary artery. In the calcification-provoking condition, proteasomal degradation of HDAC1 preceded VC. The calcification-provoking condition induced MDM2 E3 ligase, which then resulted in HDAC1 K74 polyubiquitination. Overexpression of MDM2 enhanced VC, whereas loss of MDM2 blunted it. Decoy peptides spanning HDAC1 K74 and RG 7112, an MDM2 inhibitor, prevented VC in vivo and in vitro. These results demonstrate a previously unknown ubiquitination pathway and suggest MDM2-mediated HDAC1 polyubiquitination as a new therapeutic target in VC. Calcification was induced in rat aorta vascular smooth muscle cells with inorganic phosphate (Pi). Total RNA were extracted from the cells 3 and 6 days later. mRNA profile of the sample was compared with normal control.

Project description:Hyponatremia, one of the most frequently observed electrolyte disorders in patients with chronic kidney disease (CKD), is associated with increased mortality. Lower sodium concentrations or low osmolar conditions are shown to induce cell damages via apoptosis and oxidative stress, both of accelerate vascular calcification (VC), a critical phenotype of CKD patients. It is unknown whether hyponatremia or low osmolar condition plays roles in the pathogenesis of VC.Human vascular smooth muscle cells (VSMCs) were cultured with calcifying medium, which was supplemented high calcium and phosphate. Concentrations of sodium in the culture media were further modified to determine the impacts of osmotic pressure on VC. Microarray analysis of VSMCs revealed low osmolality activated Rac1-Akt pathway and reduced expression of NCX1, which is calcium-sodium exchanger.Lower osmolality including hyponatremic condition promotes high-phosphate-induced VC through multiple cellular processes including Rac1-Akt pathway activation.

Project description:Vascular calcification, the ectopic deposition of calcium in blood vessels, develops in association with various metabolic diseases and atherosclerosis. Because it often causes stiffness and remodeling of the blood vessels, vascular calcification increases morbidity and mortality. Both miRNA and mRNA microarrays (Series GSE74755) were performed with rat VSMCs and reciprocally regulated pairs of miRNA and mRNA were selected after bioinformatic analysis.

Project description:Vascular Calcification (VC) is a life threatening cardiovascular complication that accounts for high death rates particularly in association with diabetes, atherosclerosis and Chronic Kidney Disease (CKD. during VC, Vascular Smooth Muscle Cells (VSMCs) undergo reprogramming into osteoblast-like cells in response to calcium and phosphate mineral imbalance in CKD patients. This osteogenic switch is driven by the expression of several bone markers such as Runt- related transcription factor 2 (Runx2), Alkaline Phosphatase (ALP), Osteopontin (OPN), Matrix-Gla Protein (MGP), Osteocalcin (OCN), Type I Collagen (COL1), and Bone Sialo Proteins (BSPs). Recent studies showed that VSMCs secrete heterogeneous populations of Extracellular Vesicles (EVs)11 that are enriched under physiological conditions by calcification inhibitors such as Fetuin-A and MGP12,13,14. Interestingly, under pathological conditions, secreted EVs have a pro-calcifying profile and thereby act as nucleating foci for hydroxyapatite crystallization and propagation11,15. Electron Microscopy based studies revealed that EVs were embedded between collagen and elastin fibrils of arterial walls suggesting that calcification can be initiated through the EVs’ direct physical interaction with them13,16. We previously showed that a specific oligogalacturonic acid with a degree of polymerization of 8 (DP8) was able to inhibit vascular calcification. This inhibition was partly due to a decrease of osteogenic markers’s expression but also to the masking of a consensus sequence found in COL1 i.e. GFOGER sequence, thus preventing EVs from binding to COL1. Although the use of DP8 in-vivo seems to be compromised due to probable enzymatic digestion, these results suggested that the inhibition of VSMCs’ osteogenic switch and the prevention of EVs-COL1 interaction could represent new potential therapeutic targets for inhibiting VC17. Since we have already showed that the triple-helical GFOGER consensus sequence forms a preferential binding site for EVs17, we thereby chemically synthesized a GFOGER peptide in order to determine its ability to inhibit VC on VSMCs and on an aortic ring ex-vivo model. We also aim to decipher the mechanisms of inhibition by investigating the osteogenic markers’ expression as well as the protein content of secreted EVs in the presence of the GFOGER peptide.

Project description:Chronic kidney disease (CKD) is associated with increased cardiovascular risk, morphologically characterized by vascular calcification (VC). In CKD, high serum phosphate levels result in enhanced calcification propensity and the formation of circulating crystalline nanoaggregates (calciprotein particles, CPP2) containing calcium, phosphate and serum proteins. CPP2 can induce VC directly and this is recapitulated in vascular smooth muscle cells (VSMCs) in vitro. Under physiological conditions, vascular endothelial cells (ECs), rather than VSMCs are primarily exposed to circulating CPP2. Knowledge on the modulating effects of ECs on VC development is still in its infancy. The aim of this study was to investigate the paracrine signaling between ECs and VSMCs in CPP2-induced VC. To identify secreted soluble factors for CPP2-activated ECsthis factor, CPP2-activated ECs secretome was analyzed using mass spectrometry (LC/MS).

Project description:The goal of this study was to identify new mutations in the ENPP1 gene that produce infantile arterial calcification and fetal demise. A stillborn (proband) was diagnosed with infantile arterial calcification. Mutations in the ENPP1 gene account for ~80% of the cases of infantile arterial calcification through loss of function in both alleles (recessive inheritance).

Project description:Vasclar calcification (VC) is concomitant with atherosclerosis. CD163+ M(Hb) macrophages at the site of intraplaque hemorrhage of advanced atherosclerosis provoke angiogenesis and microvascular permeability contributing plaque destabilazation. We investigated the role of CD163+ macrophage on the process of VC, and found CD163+ macrohpages inhibit VC through NFκB-induced hyaluronan synthase augmentation and subsequently promote the high-risk plaque development.

Project description:microRNA expression profile in vascular smooth muscle cells (VSMCs) after inducing calcification

Project description:Vascular calcification is the ectopic deposition of calcium hydroxyapatite minerals in arterial wall. However, the underlying molecular mechanisms regulating vascular calcification remain incompletely understood. In this study, we applied RNA sequencing to explore the mechanism of vascular calcificaiton in both medial and atherosclerotic vascular calcification models.

Project description:Calcific aortic valve disease (CAVD) is an increasingly prevalent condition and endothelial dysfunction is implicated in its etiology. We previously identified nitric oxide (NO) as a calcification inhibitor by its activation of NOTCH1, which is genetically linked to human CAVD. Here, we show that NO rescues calcification by a S-nitrosylation-mediated mechanism in porcine aortic valve interstitial cells (pAVICs) and single cell RNA-seq demonstrated regulation of NOTCH pathway by NO. A unbiased proteomic approach to identify S-nitrosylated proteins in valve cells found enrichment of the ubiquitin proteasome pathway and implicated S-nitrosylation of USP9X in NOTCH regulation during calcification. Furthermore, S-nitrosylated USP9X was shown to deubiquitinate and stabilize MIB1 for NOTCH1 activation. Consistent with this, genetic deletion of Usp9x in mice demonstrated aortic valve disease and human calcified aortic valves displayed reduced S-nitrosylation of USP9X. These results demonstrate a novel mechanism by which S-nitrosylation dependent regulation of ubiquitin-associated pathway prevents CAVD.