Valproic Acid Induces Endothelial-to-Mesenchymal Transition-Like Phenotypic Switching

Valproic acid (VPA), a histone deacetylase (HDAC) inhibitor, is a widely used anticonvulsant drug that is currently undergoing clinical evaluation for anticancer therapy due to its anti-angiogenic potential. Endothelial cells (ECs) can transition into mesenchymal cells and this form of EC plasticity is called endothelial-to-mesenchymal transition (EndMT), which is widely implicated in several pathologies including cancer and organ fibrosis. However, the effect of VPA on EC plasticity and EndMT remains completely unknown. We report herein that VPA-treatment significantly inhibits tube formation, migration, nitric oxide production, proliferation and migration in ECs. A microscopic evaluation revealed, and qPCR, immunofluorescence and immunoblotting data confirmed EndMT-like phenotypic switching as well as an increased expression of pro-fibrotic genes in VPA-treated ECs. Furthermore, our data confirmed important and regulatory role played by TGFβ-signaling in VPA-induced EndMT. Our qPCR array data performed for 84 endothelial genes further supported our findings and demonstrated 28 significantly and differentially regulated genes mainly implicated in angiogenesis, endothelial function, EndMT and fibrosis. We, for the first time report that VPA-treatment associated EndMT contributes to the VPA-associated loss of endothelial function. Our data also suggest that VPA based therapeutics may exacerbate endothelial dysfunction and EndMT-related phenotype in patients undergoing anticonvulsant or anticancer therapy, warranting further investigation

Inhibition of Transthyretin Fibrillogenesis Using a Conformation Specific Antibody

Immunoglobulin-mediated inhibition of amyloid fibril formation in vivo is a promising strategy for the treatment of protein misfolding diseases such as the amyloidoses. Here we focus on transthyretin amyloidoses, a group of protein conformation diseases caused by the misfolding of the serum protein transthyretin into fibrillar structures that deposit in specific organs and tissues—often with serious pathological consequences. Using a structure-guided immunological approach, we report a novel antibody that selectively recognizes monomeric, misfolded conformations of transthyretin in vitro. Raised to an epitope normally buried in the native form of transthyretin, this antibody was found to suppress transthyretin fibrillogenesis at substoichiometric concentrations in vitro. Overall, the selectivity and inhibitory nature of the antibody signals the potential use of conformation specific antibodies in the diagnosis and treatment of transthyretin amyloidoses, conditions which remain difficult to treat and are widely under/misdiagnosed at the current time.MAS

High glucose induces Smad activation via the transcriptional coregulator p300 and contributes to cardiac fibrosis and hypertrophy

Abstract Background Despite advances in the treatment of heart failure, mortality remains high, particularly in individuals with diabetes. Activated transforming growth factor beta (TGF-β) contributes to the pathogenesis of the fibrotic interstitium observed in diabetic cardiomyopathy. We hypothesized that high glucose enhances the activity of the transcriptional co-activator p300, leading to the activation of TGF-β via acetylation of Smad2; and that by inhibiting p300, TGF-β activity will be reduced and heart failure prevented in a clinically relevant animal model of diabetic cardiomyopathy. Methods p300 activity was assessed in H9c2 cardiomyoblasts under normal glucose (5.6 mmol/L—NG) and high glucose (25 mmol/L—HG) conditions. 3H-proline incorporation in cardiac fibroblasts was also assessed as a marker of collagen synthesis. The role of p300 activity in modifying TGF-β activity was investigated with a known p300 inhibitor, curcumin or p300 siRNA in vitro, and the functional effects of p300 inhibition were assessed using curcumin in a hemodynamically validated model of diabetic cardiomyopathy – the diabetic TG m(Ren-2)27 rat. Results In vitro, H9c2 cells exposed to HG demonstrated increased p300 activity, Smad2 acetylation and increased TGF-β activity as assessed by Smad7 induction (all p < 0.05 c/w NG). Furthermore, HG induced 3H-proline incorporation as a marker of collagen synthesis (p < 0.05 c/w NG). p300 inhibition, using either siRNA or curcumin reduced p300 activity, Smad acetylation and TGF-β activity (all p < 0.05 c/w vehicle or scrambled siRNA). Furthermore, curcumin therapy reduced 3H-proline incorporation in HG and TGF-β stimulated fibroblasts (p < 0.05 c/w NG). To determine the functional significance of p300 inhibition, diabetic Ren-2 rats were randomized to receive curcumin or vehicle for 6 weeks. Curcumin treatment reduced cardiac hypertrophy, improved diastolic function and reduced extracellular matrix production, without affecting glycemic control, along with a reduction in TGF-β activity as assessed by Smad7 activation (all p < 0.05 c/w vehicle treated diabetic animals). Conclusions These findings suggest that high glucose increases the activity of the transcriptional co-regulator p300, which increases TGF-β activity via Smad2 acetylation. Modulation of p300 may be a novel strategy to treat diabetes induced heart failure

Circulating Extracellular Vesicles From Mouse and Rat Models of Diabetes Reveal Specific Microrna Signatures as Biomarkers of Diabetic Cardiomyopathy

Background: Type-2 diabetes (T2D) is associated with both reduced and preserved ejection fraction heart failure. Obese db/db mice and Goto Kakizaki (GK) rats represents animals models of T2D that develop cardiac dysfunction similar to human diabetic cardiomyopathy, in which dominant early findings are of diastolic (and not systolic) dysfunction. Circulating extracellular vesicles (EV) contain microRNAs (miR) that can be transferred to recipient cells to modulate their function. We explored whether analysis of EV content from animals models of T2D would inform on the pathophysiology, diagnosis and therapeutic targets of cardiac dysfunction. Hypothesis: EV from animal models of T2D will have altered miR content that contributes to the pathophysiology of diabetic cardiomyopathy. Methods & Results: miR qPCR arrays on circulating EV isolated from plasma of db/db mice reveal several miR (-7, -15, -25, -30e, -148a, -150, -195) modulated during disease progression. These changes in miR content occur prior to echocardiographic evidence of diastolic dysfunction, including global longitudinal strain and strain rate. Among circulating EV miR from the GK rat model, miR-30 was also upregulated (1.42 fold, p=0.03) compared to Wistar rat. In GK rat left ventricle, and in H9C2 rat cardiac myoblast cultured in 25 mM high glucose media, mass spectrometry revealed proteins that were overexpressed in the diabetic heart including oxidative phosphorylation, glycolysis, fatty acid degredation and the citrate cycle. Using a bioinformatics approach, we next identified metabolic pathways affected by miR-30. Based on these findings, in vivo therapy with antagomiR and mimics of miR-30 are underway to test causality and reversibility of the observed cardiomyopathy. Conclusion: EV from animal models of T2D have altered miR content, including miR-30. We also identify alterations in the expression of a network of metabolism genes in the heart, which are implicated in diabetic cardiomyopathy. If causality is supported by experiments that enhance or block miR-30 expression in these models of disease, we will have identified a novel biomarker and therapeutic target for diabetic cardiomyopathy

CARDIO VASCULAR DIABETOLOGY ORIGINAL INVESTIGATION Open Access

glucose induces Smad activation via the transcriptional coregulator p300 and contributes to cardiac fibrosis and hypertroph

Substoichiometric inhibition of transthyretin misfolding by immune-targeting sparsely populated misfolding intermediates : a potential diagnostic and therapeutic for TTR amyloidoses

Wild-type and mutant transthyretin (TTR) can misfold and deposit in the heart, peripheral nerves, and other sites causing amyloid disease. Pharmacological chaperones, Tafamidis (R) and diflunisal, inhibit TTR misfolding by stabilizing native tetrameric TTR; however, their minimal effective concentration is in the micromolar range. By immune-targeting sparsely populated TTR misfolding intermediates (i.e. monomers), we achieved fibril inhibition at substoichiometric concentrations. We developed an antibody (misTTR) that targets TTR residues 89-97, an epitope buried in the tetramer but exposed in the monomer. Nanomolar misTTR inhibits fibrillogenesis of misfolded TTR under micromolar concentrations. Pan-specific TTR antibodies do not possess such fibril inhibiting properties. We show that selective targeting of misfolding intermediates is an alternative to native state stabilization and requires substoichiometric concentrations. MisTTR or its derivative may have both diagnostic and therapeutic potential

Data_Sheet_1_Valproic Acid Induces Endothelial-to-Mesenchymal Transition-Like Phenotypic Switching.PDF

<p>Valproic acid (VPA), a histone deacetylase (HDAC) inhibitor, is a widely used anticonvulsant drug that is currently undergoing clinical evaluation for anticancer therapy due to its anti-angiogenic potential. Endothelial cells (ECs) can transition into mesenchymal cells and this form of EC plasticity is called endothelial-to-mesenchymal transition (EndMT), which is widely implicated in several pathologies including cancer and organ fibrosis. However, the effect of VPA on EC plasticity and EndMT remains completely unknown. We report herein that VPA-treatment significantly inhibits tube formation, migration, nitric oxide production, proliferation and migration in ECs. A microscopic evaluation revealed, and qPCR, immunofluorescence and immunoblotting data confirmed EndMT-like phenotypic switching as well as an increased expression of pro-fibrotic genes in VPA-treated ECs. Furthermore, our data confirmed important and regulatory role played by TGFβ-signaling in VPA-induced EndMT. Our qPCR array data performed for 84 endothelial genes further supported our findings and demonstrated 28 significantly and differentially regulated genes mainly implicated in angiogenesis, endothelial function, EndMT and fibrosis. We, for the first time report that VPA-treatment associated EndMT contributes to the VPA-associated loss of endothelial function. Our data also suggest that VPA based therapeutics may exacerbate endothelial dysfunction and EndMT-related phenotype in patients undergoing anticonvulsant or anticancer therapy, warranting further investigation.</p

Table_1_Valproic Acid Induces Endothelial-to-Mesenchymal Transition-Like Phenotypic Switching.PDF

<p>Valproic acid (VPA), a histone deacetylase (HDAC) inhibitor, is a widely used anticonvulsant drug that is currently undergoing clinical evaluation for anticancer therapy due to its anti-angiogenic potential. Endothelial cells (ECs) can transition into mesenchymal cells and this form of EC plasticity is called endothelial-to-mesenchymal transition (EndMT), which is widely implicated in several pathologies including cancer and organ fibrosis. However, the effect of VPA on EC plasticity and EndMT remains completely unknown. We report herein that VPA-treatment significantly inhibits tube formation, migration, nitric oxide production, proliferation and migration in ECs. A microscopic evaluation revealed, and qPCR, immunofluorescence and immunoblotting data confirmed EndMT-like phenotypic switching as well as an increased expression of pro-fibrotic genes in VPA-treated ECs. Furthermore, our data confirmed important and regulatory role played by TGFβ-signaling in VPA-induced EndMT. Our qPCR array data performed for 84 endothelial genes further supported our findings and demonstrated 28 significantly and differentially regulated genes mainly implicated in angiogenesis, endothelial function, EndMT and fibrosis. We, for the first time report that VPA-treatment associated EndMT contributes to the VPA-associated loss of endothelial function. Our data also suggest that VPA based therapeutics may exacerbate endothelial dysfunction and EndMT-related phenotype in patients undergoing anticonvulsant or anticancer therapy, warranting further investigation.</p