Calcification In Diabetes Research Articles

STING1-accelerated vascular smooth muscle cell senescence-associated vascular calcification in diabetes is ameliorated by oleoylethanolamide via improved mitochondrial DNA oxidative damage

Vascular calcification is a prevalent hallmark of cardiovascular risk in elderly and diabetic individuals. Senescent vascular smooth muscle cells (VSMCs) participate in calcification; however, the associated underlying mechanisms remain unknown. Aberrant activation of the cytosolic DNA sensing adaptor stimulator of interferon gene 1 (STING1) caused by cytosolic DNA, particularly that leaked from damaged mitochondria, is a catalyst for aging-related diseases. Although oleoylethanolamide (OEA) is an endogenous bioactive lipid mediator with lipid overload-associated vasoprotective effects, its benefit in diabetic vascular calcification remains uncharacterized. This study focused on the role of STING1 in mitochondrial dysfunction-mediated calcification and premature VMSC senescence in diabetes and the effects of OEA on these pathological processes. In diabetic in vivo rat/mouse aorta calcification models and an in vitro VSMC calcification model induced by Nε-carboxymethyl-lysine (CML), senescence levels, STING1 signaling activation, and mitochondrial damage markers were significantly augmented; however, these alterations were markedly alleviated by OEA, partially in a nuclear factor erythroid 2-related factor 2 (Nrf2)-dependent manner, and similar anti-calcification and senescence effects were observed in STING1-knockout mice and STING1-knockdown VSMCs. Mechanistically, mitochondrial DNA (mtDNA) damage was aggravated by CML in a reactive oxygen species-dependent manner, followed by mtDNA leakage into the cytosol, contributing to VSMC senescence-associated calcification via STING1 pathway activation. OEA treatment significantly attenuated the aforementioned cytotoxic effects of CML by enhancing cellular antioxidant capacity through the maintenance of Nrf2 translocation to the nucleus. Collectively, targeting STING1, a newly defined VSMC senescence regulator, contributes to anti-vascular calcification effects.

Similarities and Differences of Vascular Calcification in Diabetes and Chronic Kidney Disease.

Presently, the mechanism of occurrence and development of vascular calcification (VC) is not fully understood; a range of evidence suggests a positive association between diabetes mellitus (DM) and VC. Furthermore, the increasing burden of central vascular disease in patients with chronic kidney disease (CKD) may be due, at least in part, to VC. In this review, we will review recent advances in the mechanisms of VC in the context of CKD and diabetes. The study further unveiled that VC is induced through the stimulation of pro-inflammatory factors, which in turn impairs endothelial function and triggers similar mechanisms in both disease contexts. Notably, hyperglycemia was identified as the distinctive mechanism driving calcification in DM. Conversely, in CKD, calcification is facilitated by mechanisms including mineral metabolism imbalance and the presence of uremic toxins. Additionally, we underscore the significance of investigating vascular alterations and newly identified molecular pathways as potential avenues for therapeutic intervention.

Impaired intracellular calcium homeostasis enhances protein O-GlcNAcylation and promotes vascular calcification and stiffness in diabetes

Vascular calcification is accelerated in patients with diabetes mellitus and increases risk of cardiovascular events and mortality. Vascular smooth muscle cells (VSMC) play a key role in regulating vascular tone and contribute significantly to the development of diabetic vasculopathy. In this study, the function of stromal interaction molecule 1 (STIM1), an important regulator for intracellular calcium homeostasis, in diabetic vascular calcification was investigated, and the underlying molecular mechanisms were uncovered.A SMC-specific STIM1 deletion mouse model (STIM1Δ/Δ) was generated by breeding the STIM1 floxed mice (STIM1f/f) with SM22α-Cre transgenic mice. Using aortic arteries from the STIM1Δ/Δ mice and their STIM1f/f littermates, we found that SMC-specific STIM1 deletion induced calcification of aortic arteries cultured in osteogenic media ex vivo. Furthermore, STIM1 deficiency promoted osteogenic differentiation and calcification of VSMC from the STIM1Δ/Δ mice. In the low-dose streptozotocin (STZ)-induced mouse model of diabetes, SMC-specific STIM1 deletion markedly enhanced STZ-induced vascular calcification and stiffness in the STIM1Δ/Δ mice. The diabetic mice with SMC-specific STIM1 ablation also exhibited increased aortic expression of the key osteogenic transcription factor, Runx2, and protein O-GlcNAcylation, an important post-translational modulation that we have reported to promote vascular calcification and stiffness in diabetes. Consistently, elevation of O-GlcNAcylation was demonstrated in aortic arteries and VSMC from the STIM1Δ/Δ mice. Inhibition of O-GlcNAcylation with a pharmacological inhibitor abolished STIM1 deficiency-induced VSMC calcification, supporting a critical role of O-GlcNAcylation in mediating STIM1 deficiency-induced VSMC calcification. Mechanistically, we identified that STIM1 deficiency resulted in impaired calcium homeostasis, which activated calcium signaling and increased endoplasmic reticulum (ER) stress in VSMC, while inhibition of ER stress attenuated STIM1-induced elevation of protein O-GlcNAcylation.In conclusion, the study has demonstrated a causative role of SMC-expressed STIM1 in regulating vascular calcification and stiffness in diabetes. We have further identified a novel mechanisms underlying STIM1 deficiency-induced impairment of calcium homeostasis and ER stress in upregulation of protein O-GlcNAcylation in VSMC, which promotes VSMC osteogenic differentiation and calcification in diabetes.

Abstract 2093: Protein O-GlcNAcylation is Important for Vascular Calcification in Diabetes

Abstract 2093: Protein O-GlcNAcylation is Important for Vascular Calcification in Diabetes

Abstract 15322: O-glcnac Modification on Runx2 Promotes Vascular Calcification

Vascular calcification is prevalent in patients with diabetes mellitus and well documented in animal models of diabetes. We have previously reported that vascular calcification in diabetes is associated with elevated vascular protein O -linked GlcNAc modification ( O -GlcNAcylation). The present studies sought to determine a causative link of O -GlcNAcylation with diabetic vascular calcification and the underlying molecular mechanisms. Using coronary arteries from diabetic subjects, we identified increased O -GlcNAcylation in the highly calcified lesions compared to those in the surrounding uncalcified areas. By generating a new mouse model with inducible SMC-specific deletion of the O -GlcNAc transferase (OGT), we demonstrated that smooth muscle cell (SMC)-specific OGT deletion significantly inhibited protein O -GlcNAcylation and calcification, and decreased aortic stiffness in the low-dose streptozotocin-induced diabetic mice. Consistent with the observations in human tissues, inhibition of vascular calcification by OGT ablation was associated with down-regulation of Runx2, the essential osteogenic regulator for vascular calcification. OGT deficiency in VSMC further attenuated Runx2-induced VSMC calcification. Immunoprecipitation analysis uncovered a direct O-GlcNAc modification on Runx2, which was abolished in the OGT-deficient VSMC. With a serial of Runx2 truncation mutants and point mutations on putative O -GlcNAcylation sites, we localized the essential Runx2 osteogenic functional domain between amino acids 391 and 432, and identified Runx2 T412 was responsible for Runx2 O -GlcNAcylation and Runx2-induced VSMC calcification. Inhibition of Runx2 O -GlcNAcylation by T412A mutation decreased Runx2 transcription activity and inhibited Runx2 binding with its key co-factors. Taken together, our studies have provided the first genetic proof demonstrating the causative effects of O -GlcNAcylation on vascular calcification in diabetes, and identified a novel mechanism underlying the essential role of O -GlcNAcylation of Runx2 in Runx2 osteogenic activity and Runx2-induced VSMC calcification. These results may shed lights on novel targets that are amenable to drug discovery for diabetic vascular calcification.

Nε-Carboxymethyl-Lysine Mediates Vascular Calcification in Diabetes Caused by Impaired Osteoclastic Resorption Activity Through NFATc1-GNPTAB.

Nε-carboxymethyl-lysine (CML) is closely associated with vascular calcification in diabetes. Osteoclasts are the only cells with bone resorption activity that have the potential to reverse calcification. This study aimed to investigate the mechanism of CML in the bone resorption activity of macrophage-derived osteoclasts in diabetic calcified plaques. Macrophage-derived osteoclasts were found to be present in calcified plaques of the anterior tibial artery in patients with diabetic amputation. Furthermore, in vitro studies showed that CML induced the differentiation of macrophages into osteoclasts, although, the bone resorption activity of these macrophage-derived osteoclasts was impaired. CML significantly increased the levels of NFATc1and GNPTAB. In vivo studies showed that there was more calcium deposition and less TRAP was less in the CML group while this effect was reversed after silencing of NFATc1. In conclusion, CML mediates NFATc1-GNPTAB to regulate bone resorption activity of osteoclasts in diabetic calcified plaques. CML promotes macrophage differentiation into osteoclasts, but their function is impaired in diabetic calcified plaques through NFATc1-GNPTAB, which eventually leads to the further progression of vascular calcification in diabetes.

Abstract 315: Augmentation Of Protein O -glcnacylation By Impaired Intracellular Calcium Homeostasis Promoted Vascular Calcification

Vascular calcification is accelerated in patients with diabetes mellitus and increases risk of cardiovascular events and mortality. Wes have demonstrated elevated protein O -GlcNAcylation promotes vascular calcification in diabetes. Increased O -GlcNAcylation is linked to impaired calcium signaling, which is critical for the development of vascular calcification in both humans and animal models. The present studies determined the role of an important regulator for intracellular calcium homeostasis, the stromal interaction molecule 1 (STIM1), in regulating O -GlcNAcylation and vascular calcification. Deletion of STIM1 induced osteogenic differentiation and calcification of VSMC, which was associated with decreased expression of the SMC marker genes and increased expression of the key osteogenic transcription factor, Runx2. By generating a SMC-specific STIM1 ablation mouse model, we determined that STIM1 ablation induced vascular calcification in aortic rings cultured ex vivo and in diabetic mice injected with low-dose streptozotocin in vivo. The diabetic mide with SMC-specific STIM1 ablation also exhibited increased aortic Runx2 expression and aortic stiffness (pulse wave velocity). Mechanistically, we identified that STIM1 deficiency impaired calcium homeostasis in VSMC, increased activation of the Ca 2+ /calmodulin-dependent protein kinase II and elevation of protein O -GlcNAcylation. Increased O -GlcNAcylation by STIM1 deficiency was further demonstrated in aortic arteries from the SMC-specific STIM1 ablation mice. The essential role of O -GlcNAcylation in mediating STIM1 deficiency-induced VSMC calcification was determined using a specific inhibitor for the O -GlcNAc transferase (OGT), the enzyme adding O -GlcNAc onto proteins. Inhibition of OGT abolished STIM1 deficiency-induced elevation of O -GlcNAcylation and VSMC. In conclusion, our studies have demonstrated a causative effect of SMC-expressed STIM1 on vascular calcification and stiffness in diabetes. We have further identified a novel link connecting STIM1 deficiency-induced impairment of calcium homeostasis and elevation of protein O -GlcNAcylation in VSMC that promotes osteogenic differentiation and calcification of VSMC.

<p>Role of Sortilin and Matrix Vesicles in Nϵ-Carboxymethyl-Lysine-Induced Diabetic Atherosclerotic Calcification</p>

Background and AimsTo investigate the role of Sortilin and matrix vesicles (MVs) in Nε-Carboxymethyl-lysine (CML)-induced diabetic atherosclerotic calcification (AC).MethodsAt human level, the correlation between Sortilin and CD9 (marker proteins of MVs) in serum MVs and CML in serum was explored by enzyme-linked immunosorbent assay (ELISA) detection and Pearson correlation analysis. After a diabetic apoE-/- mouse model was constructed, the calcification of aorta and the expressions of related proteins under CML and MVs injection were observed by calcification staining, immunofluorescence staining, and Western blot. MVs levels released by smooth muscle cells (SMCs) under different treatments was detected by nanometer tracking analysis (NTA). After treating SMCs with MVs and Anti-Sortilin, cell calcification was observed by Alizarin red staining.ResultsSerological analysis of patients showed that the concentrations of Sortilin and CD9 in serum MVs were positively correlated with the concentration of CML in serum. Animal experiments showed that CML could promote the progression of diabetic AC and the high expression of Sortilin in plaques. Diabetic apoE-/- mouse tail vein injection of CML-induced SMCs-derived MVs obviously aggravated AC. Cell experiment results showed that a high concentration of CML significantly promoted the release of MVs from SMCs. MVs from this source could markedly worsen cell calcification, while the administration of GW4869 (a widely used extracellular vesicles biogenesis inhibitor) significantly reduced cell calcification. Finally, treatment of high concentrations of CML could also promote the recruitment of Sortilin to MVs, and administration of Anti-Sortilin could markedly reduce cell calcification caused by MVs.ConclusionWe proved that CML not only affects the release of MVs from SMCs but also affects the recruitment of Sortilin to MVs, thereby promoting diabetic AC. This discovery may provide a new strategy for targeted prevention of vascular calcification in diabetes.

Role of the Scavenger Receptor CD36 in Accelerated Diabetic Atherosclerosis.

Diabetes mellitus entails increased atherosclerotic burden and medial arterial calcification, but the precise mechanisms are not fully elucidated. We aimed to investigate the implication of CD36 in inflammation and calcification processes orchestrated by vascular smooth muscle cells (VSMCs) under hyperglycemic and atherogenic conditions. We examined the expression of CD36, pro-inflammatory cytokines, endoplasmic reticulum (ER) stress markers, and mineralization-regulating enzymes by RT-PCR in human VSMCs, cultured in a medium containing normal (5 mM) or high glucose (22 mM) for 72 h with or without oxidized low-density lipoprotein (oxLDL) (24 h). The uptake of 1,1′-dioctadecyl-3,3,3′,3-tetramethylindocarbocyanine perchlorate-fluorescently (DiI) labeled oxLDL was quantified by flow cytometry and fluorimetry and calcification assays were performed in VSMC cultured in osteogenic medium and stained by alizarin red. We observed induction in the expression of CD36, cytokines, calcification markers, and ER stress markers under high glucose that was exacerbated by oxLDL. These results were confirmed in carotid plaques from subjects with diabetes versus non-diabetic subjects. Accordingly, the uptake of DiI-labeled oxLDL was increased after exposure to high glucose. The silencing of CD36 reduced the induction of CD36 and the expression of calcification enzymes and mineralization of VSMC. Our results indicate that CD36 signaling is partially involved in hyperglycemia and oxLDL-induced vascular calcification in diabetes.

Loss of PARP-1 attenuates diabetic arteriosclerotic calcification via Stat1/Runx2 axis

Accelerated atherosclerotic calcification is responsible for plaque burden, especially in diabetes. The regulatory mechanism for atherosclerotic calcification in diabetes is poorly characterized. Here we show that deletion of PARP-1, a main enzyme in diverse metabolic complications, attenuates diabetic atherosclerotic calcification and decreases vessel stiffening in mice through Runx2 suppression. Specifically, PARP-1 deficiency reduces diabetic arteriosclerotic calcification by regulating Stat1-mediated synthetic phenotype switching of vascular smooth muscle cells and macrophage polarization. Meanwhile, both vascular smooth muscle cells and macrophages manifested osteogenic differentiation in osteogenic media, which was attenuated by PARP-1/Stat1 inhibition. Notably, Stat1 acts as a positive transcription factor by directly binding to the promoter of Runx2 and promoting atherosclerotic calcification in diabetes. Our results identify a new function of PARP-1, in which metabolism disturbance-related stimuli activate the Runx2 expression mediated by Stat1 transcription to facilitate diabetic arteriosclerotic calcification. PARP-1 inhibition may therefore represent a useful therapy for this challenging complication.

Reticulocalbin 2 enhances osteogenic differentiation of human vascular smooth muscle cells in diabetic conditions

AimDiabetes accelerates pro-atherogenic and pro-osteogenic phenotypes of vascular smooth muscle cells (VSMCs), an important process for vascular calcification. Reticulocalbin 2 (RCN2) is a candidate gene for atherosclerosis and involved in vascular remodeling in hypertension. However, the role of RCN2 in VSMCs calcification under diabetic conditions is unclear. Materials and methodsExpression of RCN2 and Runt-related transcription factor 2 (Runx2) in femoropopliteal arterial plaques was compared between type 2 diabetes mellitus (DM) and non-DM patients using immunohistochemical staining (IHCS). Human aortic VSMCs (HAVSMCs) were analyzed under RCN2 gene knockdown and overexpression conditions. Alizarin red staining and intracellular calcium deposition quantification were used to observe calcification induced in vitro under normal glucose or high glucose combined with β-glycerol phosphoric acid conditions. The cells were investigated for gene modulation of osteogenic differentiation markers using Western blotting. Key findingsThe expression of RCN2 and Runx2 in femoropopliteal artery plaques was significantly higher in DM than in non-DM patients. In addition, a significant positive correlation was observed between RCN2 and Runx2 levels. RCN2 was highly expressed when HAVSMCs were treated with high glucose and the expression levels correlated with the calcification characteristics. RCN2 upregulated osteogenic transformation markers Runx2 and Osterix in HAVSMCs and downregulated contractile phenotype markers α-SMA and SM22α. SignificanceThe results from this study indicate RCN2 is a major factor in mediating the calcification process of HAVSMCs in diabetic conditions. Thus, RCN2 may serve as a future therapeutic target for vascular calcification in diabetes.

Serum concentration and vascular expression of adiponectin are differentially associated with the diabetic calcifying peripheral arteriopathy

BackgroundMedial calcification in diabetes contributes to the arterial occlusive process occurring below the knee level. Adiponectin is an adipokine with atheroprotective properties and possible protective role against arterial calcification. The aim of the study was to investigate, in type 2 diabetes, the link between vascular expression and serum concentration of adiponectin and (1) peripheral arterial calcification and (2) lower limb occlusive arterial disease.MethodsScoring of peripheral vascular calcification and peripheral arterial occlusive disease, using CT-scan and color-duplex ultrasonography respectively, were conducted and explored in relation to serum adiponectin level in a cross sectional study of 197 patients with type 2 diabetes. Vascular adiponectin expression in the arterial wall of diabetic patients with and without medial calcification was evaluated by immunohistochemistry.ResultsPeripheral arterial calcification score was higher in patients with the highest adiponectin concentration. In a multivariate logistic regression analysis, an increase of 1 µg/mL of adiponectin was associated with a 22% increase of arterial calcification (adjusted OR = 1.22; 95% CI 1.03–1.44; p = 0.02). Arterial occlusive score was also higher in patients with adiponectin concentration > median (2.8 ± 4.8 vs 4.2 ± 5.7, p = 0.034). Immunohistochemical analyses showed a strong and specific staining of adiponectin in smooth muscle cells in calcified arteries, with a more pronounced expression of adiponectin in early stages of medial calcification.ConclusionsPeripheral arterial calcification is positively associated with circulating adiponectin levels in patients with type 2 diabetes, but vascular adiponectin expression is already observed at early stages of calcification. Adiponectin secretion could be a compensatory mechanism against the calcification process.Trial registration DIACART NCT number: NCT02431234. Registered 30 April 2015

Suppression of SIRT1 in Diabetic Conditions Induces Osteogenic Differentiation of Human Vascular Smooth Muscle Cells via RUNX2 Signalling

Vascular calcification is associated with significant morbidity and mortality within diabetes, involving activation of osteogenic regulators and transcription factors. Recent evidence demonstrates the beneficial role of Sirtuin 1 (SIRT1), an NAD+ dependant deacetylase, in improved insulin sensitivity and glucose homeostasis, linking hyperglycaemia and SIRT1 downregulation. This study aimed to determine the role of SIRT1 in vascular smooth muscle cell (vSMC) calcification within the diabetic environment. An 80% reduction in SIRT1 levels was observed in patients with diabetes, both in serum and the arterial smooth muscle layer, whilst both RUNX2 and Osteocalcin levels were elevated. Human vSMCs exposed to hyperglycaemic conditions in vitro demonstrated enhanced calcification, which was positively associated with the induction of cellular senescence, verified by senescence-associated β-galactosidase activity and cell cycle markers p16 and p21. Activation of SIRT1 by SRT1720 reduced Alizarin red staining by a third, via inhibition of the RUNX2 pathway and prevention of senescence. Conversely, inhibition of SIRT1 via Sirtinol and siRNA increased RUNX2 by over 50%. These findings demonstrate the key role that SIRT1 plays in preventing calcification in a diabetic environment, through the inhibition of RUNX2 and senescence pathways, suggesting a downregulation of SIRT1 may be responsible for perpetuating vascular calcification in diabetes.

Research update on the AGE/RAGE signaling mediated vascular calcification in diabetes

Research update on the AGE/RAGE signaling mediated vascular calcification in diabetes

Advanced Glycation End-Products Induce Apoptosis of Vascular Smooth Muscle Cells: A Mechanism for Vascular Calcification.

Vascular calcification, especially medial artery calcification, is associated with cardiovascular death in patients with diabetes mellitus and chronic kidney disease (CKD). To determine the underlying mechanism of vascular calcification, we have demonstrated in our previous report that advanced glycation end-products (AGEs) stimulated calcium deposition in vascular smooth muscle cells (VSMCs) through excessive oxidative stress and phenotypic transition into osteoblastic cells. Since AGEs can induce apoptosis, in this study we investigated its role on VSMC apoptosis, focusing mainly on the underlying mechanisms. A rat VSMC line (A7r5) was cultured, and treated with glycolaldehyde-derived AGE-bovine serum albumin (AGE3-BSA). Apoptotic cells were identified by Terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) staining. To quantify apoptosis, an enzyme-linked immunosorbent assay (ELISA) for histone-complexed DNA fragments was employed. Real-time PCR was performed to determine the mRNA levels. Treatment of A7r5 cells with AGE3-BSA from 100 µg/mL concentration markedly increased apoptosis, which was suppressed by Nox inhibitors. AGE3-BSA significantly increased the mRNA expression of NAD(P)H oxidase components including Nox4 and p22phox, and these findings were confirmed by protein levels using immunofluorescence. Dihydroethidisum assay showed that compared with cBSA, AGE3-BSA increased reactive oxygen species level in A7r5 cells. Furthermore, AGE3-induced apoptosis was significantly inhibited by siRNA-mediated knockdown of Nox4 or p22phox. Double knockdown of Nox4 and p22phox showed a similar inhibitory effect on apoptosis as single gene silencing. Thus, our results demonstrated that NAD(P)H oxidase-derived oxidative stress are involved in AGEs-induced apoptosis of VSMCs. These findings might be important to understand the pathogenesis of vascular calcification in diabetes and CKD.

Carotid plaque calcification predicts future cardiovascular events in type 2 diabetes.

The presence of carotid plaques is associated with future cardiovascular events, with local plaque composition being an independent outcome predictor. We examined the association between ultrasonographically determined carotid plaque calcification and incident major adverse cardiovascular events (MACE) and death in type 2 diabetes (T2D). We enrolled 581 patients with T2D who underwent routine carotid ultrasonography. Plaques were classified as echolucent (lipid rich), heterogenous, and echogenic (calcific). We collected demographic, anthropometric, and clinical data at baseline and followed the patients for up to 9 years. Plaques were detected in 81.8% of the patients (echolucent in 16.4%, heterogenous in 43.2%, and echogenic in 22.2%). During follow-up (4.3 ± 0.1 years), 58 deaths (27 cardiovascular) and 236 fatal and nonfatal MACE occurred. In univariate analyses, presence versus absence of any carotid plaque was associated with incident MACE, and the hazard ratio (95% CI) progressively increased from echolucent (1.97 [0.93-3.44]), to heterogeneous (3.10 [2.09-4.23]), to echogenic (3.71 [2.09-5.59]) plaques. Compared with echolucent plaques, echogenic plaques were associated with incident MACE independently from confounders. This association was attenuated after adjusting for the degree of stenosis, but in patients with stenosis ≤30%, echogenic plaque type still predicted total and atherosclerotic MACE, even after further adjusting for mean intima-media thickness. In T2D, carotid plaque calcification predicts MACE, especially in patients with a low degree of stenosis. The biology of atherosclerotic calcification in diabetes needs to be further elucidated to understand the basis of this association.

RANKL–OPG and RAGE modulation in vascular calcification and diabetes: novel targets for therapy

Type 2 diabetes is associated with increased cardiovascular morbidity and mortality and early vascular ageing. This takes the form of atherosclerosis, with progressive vascular calcification being a major complication in the pathogenesis of this disease. Current research and drug targets in diabetes have hitherto focused on atherosclerosis, but vascular calcification is now recognised as an independent predictor of cardiovascular morbidity and mortality. An emerging regulatory pathway for vascular calcification in diabetes involves the receptor activator for nuclear factor κB (RANK), RANK ligand (RANKL) and osteoprotegerin (OPG). Important novel biomarkers of calcification are related to levels of glycation and inflammation in diabetes. Several therapeutic strategies could have advantageous effects on the vasculature in patients with diabetes, including targeting the RANKL and receptor for AGE (RAGE) signalling pathways, since there has been little success-at least in macrovascular outcomes-with conventional glucose-lowering therapy. There is substantial and relevant clinical and basic science evidence to suggest that modulating RANKL-RANK-OPG signalling, RAGE signalling and the associated proinflammatory milieu alters the natural course of cardiovascular complications and outcomes in people with diabetes. However, further research is critically needed to understand the precise mechanisms underpinning these pathways, in order to translate the anti-calcification strategies into patient benefit.

In This Issue

HomeCirculation ResearchVol. 114, No. 7In This Issue Free AccessResearch ArticlePDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessResearch ArticlePDF/EPUBIn This Issue Ruth Williams Ruth WilliamsRuth Williams Search for more papers by this author Originally published28 Mar 2014https://doi.org/10.1161/RES.0000000000000020Circulation Research. 2014;114:1069Activated Platelet Targeted Fibrinolysis (p 1083)Download figureDownload PowerPointWang et al develop a low dose, low risk thrombolytic fusion protein for busting blood clots.Thrombolytic drugs such as tissue plasminogen activator are used to breakdown blood clots in the event of a heart attack or stroke, but because these drugs act systemically, they carry a high risk of causing excessive bleeding. If such drugs could be targeted specifically to blood clots, it would both increase their potency and decrease their associated bleeding risk. Wang and colleagues therefore created a new fusion protein between a plasminogen activator and an antibody that specifically targets clot-initiating activated platelets. They found that the fusion protein inhibited platelet aggregation in culture, and maintained blood flow velocity more effectively than an equivalent dose of commercial untargeted plasminogen activator when given to mice that were induced to develop thrombi. A high dose of the commercial drug gave results similar to the fusion protein, but it dramatically increased bleeding times following tail transections. Based on the ability to the fusion protein to breakdown clots at a lower dose, without drastically increasing bleeding risk, Wang and colleagues suggest that such antibody targeted clot-busting strategies might be used not only as thrombolytic agents but also as a preventative treatment in patients at high risk of thrombosis.O-GlcNAcylation and Vascular Calcification (p 1094)Download figureDownload PowerPointHeath et al find a causative link between O-GlcNAcylation and vascular calcification in diabetes.Vascular calcification is a common complication of diabetes and is associated with an increased risk of life-threatening cardiovascular events. Determining how calcification occurs and how to prevent it are therefore major goals of current diabetes research. Previous work has shown that proteins in the calcified blood vessels of patients with diabetes exhibit high levels of a post-translational modification called O-GlcNAcylation, in which N-acetylglucosamine moieties are linked to serine or threonine residues. But whether and how O-GlcNAcylation might cause calcification was unknown. Heath and colleagues, therefore, experimentally induced O-GlcNAcylation in mouse vascular smooth muscle cells (VSMCs) and in the blood vessels of diabetic mice and found that both were subject to increased calcification. Furthermore, they found that O-GlcNAcylation directly modified AKT, a protein kinase known to promote VSMC calcification. Mutational analysis revealed that the O-GlcNAcylation occurred on threonine 430 and 479 of AKT, which in turn promoted phosphorylation of serine 473; thereby enhancing AKT activity and activating the downstream calcification pathway. Blocking O-GlcNAcylation of AKT may therefore be a novel strategy for preventing vessel calcification in diabetes, say the authors.CPVT CaM Mutants and RyR2 Channels (p 1114)Download figureDownload PowerPointHwang et al investigate how different calmodulin mutants affect ryanodine receptor 2 calcium channels.Calmodulin (CaM) is a calcium-binding protein that regulates several cell functions, including calcium sensing and calcium release from intracellular stores. Mutations in the CaM gene have been linked to cardiac arrhythmia, although different mutations cause different types of irregularity. For example, two specific CaM mutants, associated with stress-induced polymorphic ventricular tachycardia, are referred to as CPVT-CaMs, while another three associated with long QT syndrome are referred to as LQTS-CaMs. In the heart, wild type CaM binds to and inhibits the sarcoplasmic reticulum calcium channel ryanodine receptor 2 (RyR2), reducing the frequency of calcium release. Hwang and colleagues have now discovered that CPVT-CaMs bind with higher efficiency to RyR2 and that they increase rather than reduce the frequency of calcium release. LQTS-CaMs on the other hand tend not to affect RyR2 function, suggesting an alternative mechanism of arrhythmogenesis. CPVT-CaMs dysregulated RyR2 even in the presence of an 8-fold excess of wild type protein. This potency of the mutant proteins explains their dominant phenotypic effects. Altogether the results explain the distinct types of arrhythmia caused by the different CaM mutations, which in turn may help in the development of appropriate treatment strategies for carriers of the mutations. Previous Back to top Next FiguresReferencesRelatedDetails March 28, 2014Vol 114, Issue 7 Advertisement Article InformationMetrics © 2014 American Heart Association, Inc.https://doi.org/10.1161/RES.0000000000000020 Originally publishedMarch 28, 2014 PDF download Advertisement

Mechanisms of Medial Arterial Calcification in Diabetes

Medial artery calcification (MAC) is a characteristic feature of diabetes. MAC represents a concentric calcification that proceeds via matrix vesicle-nucleated mineralization accompanied with apatitic calcium phosphate deposits in the arterial tunica media in the absence of atheroma and neointima. Multiple factors contribute to the induction and progression of diabetic MAC including inflammation, oxidative stress, adiposity, insulin resistance, advanced glycation end-products, and hyperphosphatemia. Osteoblast-like cells form in the vessel wall from vascular smooth muscle cells and multipotent vascular mesenchymal progenitors. These mineralizing cells as well as the recruitment of undifferentiated progenitors to the osteochondrocyte lineage play a critical role in the calcification process. Important transcription factors such as Msx 2, Osterix, and RUNX2 are crucial in the programming of osteogenesis. Currently, no therapy is available to reverse vascular calcification. Available therapies can only reduce and slow the progression of vascular calcification. Targeting regulatory proteins and enzymes directly involved in osteochondrogenesis and hydroxyapatite accumulation in the vascular wall may be beneficial for generating new efficient anti-calcific drugs.

Reduction of Advanced-Glycation End Products Levels and Inhibition of RAGE Signaling Decreases Rat Vascular Calcification Induced by Diabetes

Advanced-glycation end products (AGEs) were recently implicated in vascular calcification, through a process mediated by RAGE (receptor for AGEs). Although a correlation between AGEs levels and vascular calcification was established, there is no evidence that reducing in vivo AGEs deposition or inhibiting AGEs-RAGE signaling pathways can decrease medial calcification. We evaluated the impact of inhibiting AGEs formation by pyridoxamine or elimination of AGEs by alagebrium on diabetic medial calcification. We also evaluated if the inhibition of AGEs-RAGE signaling pathways can prevent calcification. Rats were fed a high fat diet during 2 months before receiving a low dose of streptozotocin. Then, calcification was induced with warfarin. Pyridoxamine was administered at the beginning of warfarin treatment while alagebrium was administered 3 weeks after the beginning of warfarin treatment. Results demonstrate that AGEs inhibitors prevent the time-dependent accumulation of AGEs in femoral arteries of diabetic rats. This effect was accompanied by a reduced diabetes-accelerated calcification. Ex vivo experiments showed that N-methylpyridinium, an agonist of RAGE, induced calcification of diabetic femoral arteries, a process inhibited by antioxidants and different inhibitors of signaling pathways associated to RAGE activation. The physiological importance of oxidative stress was demonstrated by the reduction of femoral artery calcification in diabetic rats treated with apocynin, an inhibitor of reactive oxygen species production. We demonstrated that AGE inhibitors prevent or limit medial calcification. We also showed that diabetes-accelerated calcification is prevented by antioxidants. Thus, inhibiting the association of AGE-RAGE or the downstream signaling reduced medial calcification in diabetes.