Project description:Exploring the mechanisms of valvular heart disease (VHD) at the cellular level may be useful to identify new therapeutic targets; however, the comprehensive cellular landscape of non-diseased human cardiac valve leaflets remains unclear. The cellular landscapes of non-diseased human cardiac valve leaflets (five aortic valves, five pulmonary valves, five tricuspid valves, and three mitral valves) from end-stage heart failure patients undergoing heart transplantation were explored using single-cell RNA sequencing (scRNA-seq)

Project description:To characterize the cell types that compose the mitral valve during the development of autoimmune valvular carditis, we utilized scRNA sequencing. Live cells from inflamed valves of K/B.g7 mice or uninflamed B.g7 controls were collected and analyzed at 3-, 8-, and 25 weeks of age.

Project description:Rational: We previously reported evidence of endothelial to mesenchymal transition (EndMT) and fibrosis in mitral valve (MV) leaflets at two to six months post-myocardial infarction (MI) in sheep. The onset of these changes and the mechanism of their instigation are not known. Early modulation of EndMT and fibrosis in MV leaflets may limit the development of ischemic mitral regurgitation (IMR) and heart failure. H Objective: To test the hypothesis that circulating molecules present in plasma within days after MI incite EndMT and fibrotic processes in MV leaflets. Method and Results: Ovine MVs harvested 8-10 days after inferior MI (IMI) showed an increase in MV thickness by histology and onset of EndMT, shown by increased CD31/α-smooth muscle actin (α-SMA)+ cells in post-MI MV leaflets (10.5±6.9%) versus sham (2.6±4%). In vitro, post-MI plasma induced EndMT and pro-fibrotic markers and enhanced migration of primary mitral valve endothelial cells (VECs). In contrast, sham plasma did not, despite the presence of TGFβ2 at levels known to induce EndMT in VECs (2 ng/ml). Analysis of sham versus post-MI plasma using a cytokine array revealed a significant drop in the Wnt signaling antagonist secreted frizzled-related protein 3 (sFRP3) in post-MI plasma compared to sham plasma, which was confirmed by ELISA. Addition of recombinant sFRP3 to post-MI plasma reversed its EndMT-inducing effect on mitral VECs, measured by restored VE-cadherin, reduced α-SMA, and reduced TGFβ1-3 expression. Extracellular signal related kinase 1/2 and SMAD2/3 phosphorylation were increased in mitral VEC by post-MI plasma, and both were blocked by supplementing the post-MI plasma with sFRP3. RNA-seq analysis of mitral VECs exposed to post-MI versus sham plasma for 24 hours showed upregulated forkhead box M1 (FOXM1), a transcription factor previously shown to drive fibrosis. FOXM1 was co-localized with CD31 in MV leaflets obtained from sheep at 8-10 days post-MI, which suggests FOXM1 may be linked to EndMT initiation. Blocking FOXM1 with Siomycin A (Sio A) reduced EndMT and pro-fibrotic transcripts in post-MI plasma treated mitral VECs. Finally, post-MI plasma-induced and TGFβ-induced FOXM1 was downregulated by sFRP3. Conclusions: Reduced sFRP3 in post-MI plasma appears to facilitate the onset of TGFβ-driven EndMT and fibrosis in mitral VECs by increasing the transcription factor FOXM1. Restoring sFRP3 levels and/or inhibiting FOXM1 may provide new strategies to minimize maladaptive changes that occur in the MV due to MI.

Project description:The mitral valve is a highly complex structure which regulates blood flow from the left atrium to the left ventricle (LV) avoiding a significant forward gradient during diastole or regurgitation during systole. The integrity of the mitral valve is also essential for the maintenance of normal LV size, geometry, and function. Significant advances in the comprehension of the biological, functional, and mechanical behavior of the mitral valve have recently been made. However, current knowledge of protein components in the normal human mitral valve is still limited and complicated by the low cellularity of this tissue and the presence of high abundant proteins from the extracellular matrix. We employed here an integrated proteomic approach to analyse the protein composition of the normal human mitral valve and reported confident identification of 422 proteins, some of which have not been previously described in this tissue. In particular, we described the ability of pre-MS separation technique based on liquid-phase IEF and SDS-PAGE to identify the largest number of proteins. These initial results provide a valuable basis for future studies aimed at analysing in depth the mitral valve protein composition and at investigating potential pathogenetic molecular mechanisms.

Project description:In this study, we carried out a large-scale proteome profiling of human mitral valve tissues resected from patients with mitral valve prolapse.

Project description:One third of cardiac congenital diseases affect cardiac valves. Genetically modifiedmice have advancedourunderstandingof valve development and related pathologies. However, little is known with regard tohuman valve development.We aimed to derive a novel human pluripotent stem cellmodel in order to decode the early steps of human valvulogenesis.Human MesP1+mesodermal cells were differentiated toward the fate of second heart field progenitors and then to a selected population of pre-valvular endocardial cells. Gene arrays revealed that these human prevalvular cells (HPVC) express patterns of genes similar to those expressed in theatrioventricular canal (AVC) endocardium of E9.0 mouse embryos. In mice this developmental time precedes endocardial mesenchymal transition (EndoMT),which is required for mature valve formation.HPVC treated with BMP2, cultured onto chick or mouse AVC cushions, or transplanted into the outflow tract or AVC of embryonic chick and mouse hearts, underwent EndoMTin both a Notch-dependent and independent-manner and expressed markers of valve mesenchymal cells and fibroblasts.Similar to the previously described valve interstitial cells (VICs), HPVC also differentiate into tendinous/chondrogenic cells. Our study indicates thathuman pluripotent stem cells canrecapitulate early valvulogenesis and thus provide a powerful model to further decipher the origin and lineage contributionof different valvular cell typesin humans.

Project description:We here report the results of a mitral valve transcriptome study designed to identify genes and molecular pathways involved in development of congestive heart failure (CHF) following myxomatous mitral valve disease (MMVD) in dogs. The study is focused on a cohort of elderly age-matched dogs (n=34, age ~10 years) from a single breed – Cavalier King Charles Spaniels (CKCS) – with a high incidence of MMVD. The cohort comprises 19 dogs (10♀, 9♂) without MMVD-associated CHF, and 15 dogs (6♀, 9♂) with CHF caused by MMVD. I.e. we compare gene expression in breed and age matched groups of dogs, which only differ with respect to CHF status. We identify 56 genes, which are differentially expressed between the two groups. In this list of genes, we confirm an enrichment of genes related to the TNFβ signaling pathway, extracellular matrix organization, vascular development, and endothelium damage, which also have been identified in previous studies. However, the genes with the greatest difference in expression between the two groups are CNTN3 and MYH1. Both genes encode proteins, which are predicted to have an effect on the contractile activity of myocardial cells, which in turn may have an effect on valvular performance and hemodynamics across the mitral valve. This may result in shear forces with impact on MMVD progression.

Project description:One third of cardiac congenital diseases affect cardiac valves. Genetically modified mice have advanced our understanding of valve development and related pathologies. However, little is known with regard to human valve development.We aimed to derive a novel human pluripotent stem cell model in order to decode the early steps of human valvulogenesis. Human MesP1+mesodermal cells were differentiated toward the fate of second heart field progenitors and then to a selected population of pre-valvular endocardial cells. Gene arrays revealed that these human prevalvular cells (HPVC) express patterns of genes similar to those expressed in the atrioventricular canal (AVC) endocardium of E9.0 mouse embryos. In mice this developmental time precedes endocardial mesenchymal transition (EndoMT),which is required for mature valve formation. HPVC treated with BMP2, cultured onto chick or mouse AVC cushions, or transplanted into the outflow tract or AVC of embryonic chick and mouse hearts, underwent EndoMTin both a Notch-dependent and independent-manner and expressed markers of valve mesenchymal cells and fibroblasts. Similar to the previously described valve interstitial cells (VICs), HPVC also differentiate into tendinous/chondrogenic cells. Our study indicates tha thuman pluripotent stem cells canrecapitulate early valvulogenesis and thus provide a powerful model to further decipher the origin and lineage contribution of different valvular cell types in humans.

Project description:The genes Ift88 and Dzip1 are critical for primary cilium biogenesis, the objective this study was to determine the transcriptome changes in Mitral leaflets in these genetic deficiencies.

Project description:Calcific aortic valvular disease (CAVD) is characterized by sclerosis of the aortic valve leaflets and recent clinical studies have linked several other risk factors to this disease, including male sex. In this study we examined potential sex-related differences in gene expression profiles between porcine male and female valvular interstitial cells (VICs) to explore possible differences in CAVD propensity on the cellular level. RNA samples from three male and three female healthy porcine aortic valve leaflets (denuded of endothelial cells) were isolated, processed, and hybridized to AffymetrixM-BM-. GeneChip Porcine Genome microarrays according to manufacturerM-bM-^@M-^Ys instructions. Mean expression values of each probe set in the male samples were compared with those in the female samples.