Project description:NEXN protects against vascular calcification by promoting SERCA2 SUMOy-lation and stabilization

Project description:Vascular smooth muscle cells (VSMCs) exhibit significant heterogeneity and plasticity, enabling them to switch between contractile and synthetic states, which is crucial for vascular remodeling. NEXN has been identified as a high confidence gene associated with dilated cardiomyopathy (DCM). Existing evidence indicate NEXN is involved in phenotypic switching of VSMCs. However, a comprehensive understanding of the cell - specific roles and precise mechanisms of NEXN in vascular remodeling remains elusive. Using integrative transcriptomics analysis and smooth muscle specific lineage tracing mice, we demonstrate NEXN is highly expressed in VSMCs, and the expression of NEXN is significantly reduced during the phenotypic transformation of VSMCs and intimal hyperplasia induced by vascular injury. VSMC - specific NEXN deficiency promoted the phenotypic transition of VSMCs and exacerbated neointimal hyperplasia in mice following vascular injury. Mechanistically, we found NEXN primarily mediated VSMCs proliferation and phenotypic transition through endoplasmic reticulum (ER) stress and KLF4 signaling. Inhibiting ER stress ameliorated VSMCs phenotypic transition by reducing cell cycle activity and proliferation caused by NEXN deficiency. These findings indicate targeting NEXN could be explored as a promising therapeutic approach for proliferative arterial diseases.

Project description:Background: Vascular calcification is a ubiquitous ageing pathology markedly accelerated in patients with metabolic disorders including diabetes and renal failure. Prelamin A is a biomarker of vascular ageing which accelerates vascular smooth muscle cell (VSMC) senescence and calcification. Using prelamin A as a model we explored the earliest events in VSMC ageing, focussing on the epigenetic landscape as an environmentally modifiable target. Methods: Adenoviral expression of prelamin A was used to induce VSMC ageing and epigenetic modifications were monitored using immunofluorescence and targeted PCR-arrays. Epigenetic findings were verified in vitro using drugs targeting epigenetic modifiers and in vivo using immunohistochemistry in human vessels from young, aged and calcified patients. Transcriptomics, ChIP-seq and antibody arrays were used to identify and verify gene targets impacted by changes in the epigenetic landscape and to monitor effects on inflammation, ageing indices and calcification. A novel mouse model of VSMC-specific inducible prelamin A expression was used to study epigenetic ageing in vivo and calcification was induced with vitamin D. Results: Prelamin A accumulation in VSMCs caused rapid global alterations in the repressive heterochromatin marks, H3K9me3 and H3K27me3 which coincided with downregulation of the epigenetic writers EZH2 and SUV39H1. These same epigenetic changes were recapitulated in primary human VSMCs induced to calcify in response to mineral dysregulation and in the calcified arteries of adults, and young children on dialysis. Global analysis of H3K9me3 and H3K27me3 marks in response to prelamin A expression showed deregulation of cross-talking NF-κB and HIPK2 stress response inflammatory pathways consistent with robust activation of a senescence associated secretory phenotype (SASP). Treatment of VSMCs with EZH2 and SUV39H1 inhibitors amplified the SASP and accelerated senescence and mineral deposition. Induction of prelamin A expression in VSMCs in mice induced rapid loss of heterochromatin which preceded DNA damage and senescence and coincided with early activation of SASP factors creating an environment permissive to calcification. Conclusions: Loss of heterochromatin is accelerated by metabolic disease and acts to promote VSMC inflammaging and a tissue microenvironment prone to calcification. Pre-senescent cells with an active SASP may be an early target for tackling vascular ageing pathologies. tackling vascular ageing pathologies.

Project description:Hyperglycemia accelerates calcification of atherosclerotic plaques in diabetic patients, and the prolonged accumulation of advanced glycation end products (AGEs) induced by hyperglycemia may be closely related to the pathogenesis of aortic calcification. However, the mechanisms underlying this association remain unclear. In the current study, we investigated the role of vascular smooth muscle cell nuclear factor 90/110 (NF90/110) in mediating AGEs accumulation and accelerating diabetic atherosclerotic calcification. Using vascular smooth muscle cells (VSMCs), human samples, and mouse models, we found that hyperglycemia-mediated AGEs markedly increased VSMC NF90/110 activation both in human and mouse atherosclerotic calcified tissues with diabetes. Silencing of NF90/110 in vitro and genetic deletion of VSMC NF90/110 in mice decreased obviously AGEs-induced arteriosclerotic calcification. Mechanistically, AGEs increased the activity of NF90, which then enhanced ubiquitination and degradation of AGE receptor 1 (AGER1) by stabilizing the mRNA of E3 ubiquitin ligase, F-box, and WD repeat domain 7 (FBXW7), thus causing the accumulation of more AGEs. Furthermore, AGEs accumulation accelerated diabetic atherosclerotic calcification by inducing VSMC phenotypic changes to osteoblast-like cells, apoptosis, and matrix vesicle release. Collectively, our study demonstrated the effects of VSMC NF90 in mediating the metabolic imbalance of AGEs to accelerate diabetic arteriosclerotic calcification. These novel findings elucidate a pivotal mechanism underlying AGE-induced diabetic atherosclerotic calcification and provide a framework for potential interventions against diabetic vascular complications.

Project description:Vascular calcification is a common and life-threatening complication in patients with chronic kidney disease, in which osteogenic differentiation of vascular smooth muscle cells (VSMCs) plays an essential role. Paraspeckle protein NONO is a multifunctional protein involved in many nuclear biological processes but its role in vascular calcification and osteogenic differentiation of VSMCs remains unclear.By RNA sequencing analysis in primary mouse VSMCs with or without NONO knockout, we observed significant changes of genes important in regulating vascular function and osteogenic differentiation of VSMCs.

Project description:Background: Ectopic vascular calcifications represent a major clinical problem associated with cardiovascular disease and mortality. However, the mechanisms underlying pathological vascular calcifications are largely unknown hampering the development of therapies to tackle this life threatening medical condition. Results: In order to gain insight into the genes and mechanisms driving this pathological calcification process we analyzed the transcriptional profile of calcifying vascular smooth muscle cells (C-VSMCs). These profiles were compared to differentiating osteoblasts, cells that constitute their physiological calcification counterparts in the body. Overall the transcriptional program of C-VSMC and osteoblasts did not overlap. Several genes, some of them relevant for bone formation, were distinctly modulated by C-VSMCs which did not necessarily lose their smooth muscle cell markers while calcifying. Bioinformatics gene clustering and correlation analysis disclosed limited bone-related mechanisms being shared by two cell types. Extracellular matrix (ECM) and biomineralization genes represented common denominators between pathological vascular and physiological bone calcifications. These genes constitute the strongest link between these cells and represent potential drivers for their shared end-point phenotype. Conclusions: the analyses support the hypothesis that VSMC trans-differentiate into C-VSMCs keeping their own identity while using mechanisms that osteoblasts use to mineralize. The data provide novel insights into groups of genes and biological processes shared in MSC and VSMC osteogenic differentiation. The distinct gene regulation between C-VSMC and osteoblasts might hold clues to find cell-specific pathway modulations, opening the possibility to tackle undesired vascular calcifications without disturbing physiologic bone formation and vice versa. Total RNA obtained from hMSC and hVSMC cultured in osteogenic differentiation medium supplemented with 1.8 mM Ca2+ for 0, 2, 8, 12 or 25 days respectively. For each timepoint 3 replicates were used, with exception for day 0 where 4 replicates were collected.

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:SGLT-2 inhibitors, such as empagliflozin, have been shown to reduce the occurrence of cardiovascular events and delay the progression of atherosclerosis. However, its role in atherosclerotic calcification remains unclear. In this research, ApoE-/- mice were fed with western diet and empagliflozin was added to the drinking water for 24 weeks. Empagliflozin treatment significantly alleviated arterial calcification assessed by alizarin red and von kossa staining in aortic roots and reduced the lipid levels, while had little effect on body weight and blood glucose levels in ApoE-/- mice. In vitro studies, empagliflozin significantly inhibits calcification of primary vascular smooth muscle cells (VSMCs) and aortic rings induced by osteogenic media (OM) or inorganic phosphorus (Pi). RNA sequencing of VSMCs cultured in OM with or without empagliflozin showed that empagliflozin negatively regulated the osteogenic differentiation of VSMCs. And further studies confirmed that empagliflozin significantly inhibited osteogenic differentiation of VSMCs via qRT-PCR. Our study demonstrates that empagliflozin alleviates atherosclerotic calcification by inhibiting osteogenic differentiation of VSMCs, which addressed a critical need for the discovery of a drug-based therapeutic approach in the treatment of atherosclerotic calcification.

Project description:Vascular calcification and increased extracellular matrix (ECM) stiffness are hallmarks of vascular ageing. Sox9 (SRY-Box Transcription Factor 9) is a master regulator of chondrogenesis, also expressed in the vasculature, that has been implicated in vascular smooth muscle cell (VSMC) osteo-chondrogenic conversion. Here, we investigated the relationship between vascular ageing, calcification and Sox9-driven ECM regulation in VSMCs. Immunohistochemistry in human aortic samples showed that Sox9 was not spatially associated with vascular calcification but correlated with the senescence marker p16. Analysis of Sox9 expression in vitro showed it was mechanosensitive with increased expression and nuclear translocation in senescent cells and on stiff matrices. Manipulation of Sox9 via overexpression and depletion, combined with atomic force microscopy (AFM) and proteomics, revealed that Sox9 regulates ECM stiffness and organisation by orchestrating changes in collagen expression and reducing VSMC contractility, leading to the formation of an ECM that mirrored that of senescent cells. These ECM changes promoted phenotypic modulation of VSMCs whereby senescent cells plated onto ECM synthesized from cells depleted of Sox9 returned to a proliferative state, while proliferating cells on a matrix produced by Sox9 expressing cells showed reduced proliferation and increased DNA damage, reiterating features of senescent cells. Procollagen-lysine, 2-oxoglutarate 5-dioxygenase 3 (LH3) was identified as a Sox9 target, and key regulator of ECM stiffness. LH3 is packaged into extracellular vesicles (EVs) and Sox9 promoted EV secretion, leading to increased LH3 deposition within the ECM. These findings identify cellular senescence and Sox9 as a key regulators of ECM stiffness during VSMC ageing and highlight a crucial role for ECM structure and composition in regulating VSMC phenotype. We identify a positive feedback cycle whereby cellular senescence and increased ECM stiffening promote Sox9 expression which drives further ECM modifications that act to accelerate vascular stiffening and cellular senescence.

Project description:Vascular calcification is a hallmark of atherosclerosis and end-stage renal disease (ESRD). However, the molecular mechanism of vascular calcification is poorly understood. Diabetes mellitus is increasingly recognized as the most important cause for atherosclerosis and ESRD. Emerging evidence supports the concept that vascular calcification resembles the process of osteogenesis, in which the vascular smooth muscle cells (VSMC) undergo osteochondrogenic differentiation. Recently, we have established an in vitro calcification system with primary mouse VSMC. With the use of osteogenic stimuli, we induced trans-differentiation of primary mouse VSMC into bone-like cells. Interestingly stroptozotocin (STZ), O-GlcNAcase inhibitor and a drug that has been used to induce diabetes in mice, was able to induce calcification of VSMC and the expression of the osteogenic transcription factor Runx2, suggesting glycosylation may be involved in regulation of Runx2. We have reported an essential role of Runx2 in oxidative stress-induce VSMC calcification and have recently generated a tissue specific mouse with Runx2 ablation in smooth muscle cells. Therefore, we will use STZ and other relevant reagents in the glucose synthesis/metabolism pathways as stimuli for VSMC calcification to characterize the glycogene profiles during VSMC calcification. Results from VSMC of Runx2 knockout mice will be compared with those from control mice to determine the regulation of calcification-associated glycogenes by Runx2 in response to STZ. These studies will provide foundation for further mechanistic studies and may lead to identification of novel strategies and targets for diabetes-induced vascular calcification. To examine vascular smooth muscle cells (VSMC) under two conditions: 1) wild-type VSMC differentiated into bone-like cells with osteogenic media, 2) wild-type VSMC treated with STZ and osteogenic media