Project description:Background: Calcific aortic valve disease (CAVD) is the pathological remodeling of valve leaflets. The initial steps in the osteogenic reprogramming of the leaflet are not fully understood. Studies have shown that TERT overexpression primes mesenchymal stem cells to differentiate into osteoblasts, and we investigated whether TERT contributes to the osteogenic reprogramming of valve interstitial cells (VICs). Methods: Human control and CAVD aortic valve leaflets and patient-specific hVICs were used in in vivo and in vitro calcification assays. Loss of function experiments in hVICs and cells isolated from Tert-/- and Terc-/- mice were used for mechanistic studies. In silico modeling, proximity ligation and co-immunoprecipitation assays defined novel TERT interacting partners. Chromatin immunoprecipitation and CUT&TAG sequencing defined protein-DNA interactions. Results: TERT protein was highly expressed in calcified valve leaflets without changes in telomere length, DNA damage, or senescence markers, and these features were retained in isolated primary hVICs. TERT expression increased with osteogenic stimuli, while knock-down or genetic deletion of TERT prevented calcification. Mechanistically, TERT was required to initiate osteogenic reprogramming independent of its canonical telomere-extending activity and the lncRNA TERC. TERT’s osteogenic functions via binding with Signal Transducer and Activator of Transcription 5 (STAT5). Depletion and inhibition of STAT5 prevented calcification. STAT5 was found to bind the promoter region of Runt-Related Transcription Factor 2 (RUNX2), the master regulator of osteogenic reprogramming. Finally, we demonstrate that TERT and STAT5 are upregulated and colocalized in CAVD tissue. Conclusions: TERT's non-canonical activity is required to initiate VIC calcification. TERT partners with STAT5 to bind the RUNX2 gene promoter. These data identify a novel mechanism and potential therapeutic target to decrease vascular calcification.

Project description:The role of long noncoding RNAs (lncRNAs) in calcific aortic valve disease (CAVD) remains largely elusive. This study aims to report a novel therapeutic lncRNA, SNHG3, and elucidate its role in CAVD. Based on high-throughput transcriptomic sequencing of human aortic valves, SNHG3 is among the most highly expressed lncRNAs in CAVD. Furthermore, SNHG3 upregulation is verified in human calcified aortic valves, osteoblastic human aortic valve interstitial cells (hVICs), and aortic valve tissues in CAVD mice. Moreover, knockdown of SNHG3 with antisense oligonucleotide markedly ameliorates aortic valve calcification in high cholesterol diet-treated ApoE-/- mice, as evidenced by reduced calcium deposition in the aortic valve leaflets, improved echocardiographic parameters, and decreased osteogenic differentiation markers (RUNX2, osteopontin, and osteocalcin) in aortic valves. Consistent with these in vivo findings, SNHG3 overexpression aggravates the calcification of hVICs, while knockdown of SNHG3 alleviates the process of differential calcification. Transcriptomics sequencing, gene set enrichment analyses, RNA-pull down, RNA immunoprecipitation and chromatin immunoprecipitation-qPCR show that SNHG3 physically interacts with polycomb repressive complex 2 to suppress the H3K27 tri-methylation BMP2 locus, which in turn activates BMP2 expression and signaling pathways. Taken together, SNHG3 promotes aortic valve calcification by upregulating BMP2, which might be a novel therapeutic target in human CAVD.

Project description:Calcific aortic valve disease (CAVD) primarily involves osteogenic differentiation in human aortic valve interstitial cells (hVICs). Schisandrol B (SolB), a natural bioactive constituent, has known therapeutic effects on inflammatory and fibrotic disorders. However, its impact on valve calcification has not been reported. Transcriptome sequencing was used to analyze potential molecular pathways affected by SolB treatment. To explore the therapeutic mechanism of SolB, human valve interstitial cells were induced to undergo osteogenic differentiation by OM, with or without SolB treatment meanwhile. Among the signaling pathways enriched, the P53 signaling pathway was identified as the upstream regulator of other enriched pathways such as Cell cycle, Oocyte meiosis, Cytokine-cytokine receptor interactions. These pathways were regulated by the P53 signaling pathway and were reported to be stimulated by DNA damage, an early stage of pathological change in CAVD. The cytokine-cytokine receptor interaction signaling pathway was reported to correlate with calcified aortic valve disease. taken together, our data revealed potential therapitic mechanism p53 signaling of Schisandrol B treatment in hVICs calcification.

Project description:Calcific aortic valve disease (CAVD) is an slowly progressive calcification of heart valve which leads to aortic stenosis. The only existing treatment of CAVD is surgical replacment of calcified valve - development of anti-CAVD treatment is urgent task. For better understanding of molecular mechanisms of CAVD progression we performed proteomics analysis of osteogenic differentiation of human valve interstitial cells isolated from healthy humans or patients with CAVD.

Project description:Purpose:To explore the the function and underlying mechanisms of basic fibroblast growth factor (BFGF) on calcific aortic valve disease (CAVD) a. Methods: The valvular interstitial cells were isolated from porcine aortic valve leaflets. To investigate the effect of BFGF on osteogenic differentiation of VICs, the osteogenic induced medium (OIM) and BFGF were added. RNA sequencing is used to identify changes in gene proffles. Results:This analysis completed the full transcriptome sequencing of 9 samples, with a total of 2 differentially expressed gene groups. The number of differentially expressed genes detected was 2526, 159. 6596 lncRNAs were identified, and the number of differentially expressed lncRNAs detected was 349,100. 6179 new circRNAs were predicted, and the number of differentially expressed circRNAs detected was 4,243. Conclusions:This study completed for the first time to the sequencing of the full transcriptome expression of valve interstitial cells under the action of BFGF, and has proved that BFGF can inhibit the calcification process of valve interstitial cells, our study suggests that bFGF has important value in the prevention and treatment of CAVD.

Project description:Background: Calcific aortic valve disease (CAVD), the most common valve disease is comprised of a chronic interplay of inflammation, fibrosis, and calcification. In this study, sortilin (SORT1) was identified as a novel key player in the pathophysiology of CAVD, and its role in the transformation of valvular interstitial cells (VICs) into pathological phenotypes is explored. Methods: An aortic valve (AV) wire injury (AVWI) mouse model with sortilin deficiency was used to determine the effects of sortilin on AV stenosis, fibrosis and calcification. In vitro experiments employed human primary VICs cultured in osteogenic conditions for 7, 14 and 21 days; and processed for imaging, proteomics, transcriptomics and single-cell RNA sequencing (scRNA-seq). Results: The AVWI mouse model showed reduced AV fibrosis, calcification, and stenosis in sortilin-deficient mice versus littermate controls. We identified the transition of human VICs into a myofibroblast-like phenotype mediated by sortilin and p-38 MAPK signaling. Sortilin loss-of-function decreased in vitro VIC calcification. ScRNA-seq identified 12 differentially expressed cell clusters in human VIC samples, where a novel combined inflammatory myofibroblastic-osteogenic VIC (IMO-VIC) phenotype was detected with increased expression of SORT1, COL1A1, WNT5A, IL-6 and SAA1. VICs sequenced with sortilin deficiency showed decreased IMO-VIC phenotype. Conclusions: Sortilin promotes experimental CAVD by mediating valvular fibrosis and calcification, and newly identified phenotype (IMO-VIC). This is the first study to examine the role of sortilin in aortic valve calcification and it may render it a therapeutic target to inhibit IMO-VIC emergence by simultaneously reducing inflammation, fibrosis, and calcification, the three key pathological processes underlying CAVD.

Project description:Calcification of the aortic valve leads to increased leaflet stiffness resulting in development of calcific aortic valve disease (CAVD); however, the underlying molecular and cellular mechanisms of calcification are poorly understood. Here, we investigated gene expressions in relation to valvular calcification and promotion of CAVD progression.

Project description:Vascular calcification is common pathology various forms of which presented in the half of humans. Calcific aortic valve disease (CAVD) is one of the most dangerous forms of vascular calcification. Despite high mortality there is no target therapy against CAVD. Thus, we tested crenigacestat (LY3039478), inhibitor of Notch-signaling, and shRNA against RBPJk for inhibition of osteogenic differentiation of velve intersticial cells (VICs) in vitro. Both of them effectivelly enhibited osteogenic differentiation and we performed proteomics analysis do describe molecular mechanisms of their effect. Presented dataset contain results of shotgun proteomics analysis with ion mobility in TimsToF Pro instrument (in DDA PASEF mode) of VICs in classic osteogenic medium (OM) and OM supplemented with crenigacestat, DMSO or shCSL.

Project description:The pathogenesis of calcific aortic valve disease (CAVD) is unknown. XCT790 is a specific inhibitor of estrogen-associated receptor alpha (ERR-alpha) that inhibits valve calcification in mouse models. Here, we designed a nanocarrier targeting osteoblast-differentiated valve interstitial cells (VICs) for targeted delivery of XCT790 to the calcified area. We stimulated osteogenic differentiated VICs with this targeting nanoparticle, and performed RNA-seq to assess transcriptional alterations of VICs and explore specific mechanisms.

Project description:Aims Calcific aortic valve disease (CAVD) is a significant cause of illness and death worldwide. The disease mechanism involves age-associated immuno-osteogenic processes but developmental origins and early disease mechanisms are not fully characterized. Identification of early predictive markers could help optimize therapy decisions and patient follow-up. Methods and Results RNA-sequencing was carried out on human fetal aortic valves at weeks 9, 13, and 22, and adult control, calcified bicuspid (BAV) and tricuspid aortic valves (TAV). K-means clustering was implemented to identify co-expressed gene patterns simultaneously up- and down-regulated over the different conditions. Canonical pathway analysis revealed a predominant immune-metabolic gene signature indicative of ongoing innate and adaptive immune responses, including lymphocyte T-cell metabolic adaptation. Specifically, cytokine and chemokine signalling, cellular migration and proliferation, were all increased in CAVD, while oxidative phosphorylation and protein translation were decreased. Discrete immune-metabolic gene signatures were present at foetal stages and adult controls, indicating that inflammation initiates as soon as the valves are formed and is maintained and amplified during post-natal life. Multiple pathways involved in cellular stress response and neurodegenerative disease were also aberrantly expressed, suggesting that chronic inflammation drives metabolic stress- and age-associated valve pathology in CAVD. Comparing the valve RNA-sequencing dataset with whole blood transcriptomes from asymptomatic individuals with early aortic valve calcification identified a gene signature including the CD28 pathway, highly predictive of patients with CAVD and healthy individuals with moderate levels of aortic valve calcification. Conclusion These data deepen and broaden our understanding of the molecular basis of CAVD, and identify a gene signature for the early detection of aortic valve calcification. Keywords Human foetal valve, CAVD, BAV, inflammation, biomarker, gene signature,PESA