Differentiation Of Vascular Smooth Muscle Cells Research Articles

4-Octyl itaconate inhibits vascular calcification partially via modulation of HMOX-1 signaling

Vascular calcification frequently occurs in patients with chronic conditions such as chronic kidney disease (CKD), diabetes, and hypertension and represents a significant cause of cardiovascular events. Thus, identifying effective therapeutic targets to inhibit the progression of vascular calcification is essential. 4-Octyl itaconate (4-OI), a derivative of itaconate, exhibits anti-inflammatory and antioxidant activity, both of which play an essential role in the progression of vascular calcification. However, the role and molecular mechanisms of 4-OI in vascular calcification have not yet been elucidated. In this study, we investigated the effects of exogenous 4-OI on vascular calcification using vascular smooth muscle cells (VSMCs), arterial rings, and mice. Alizarin red staining and western blot revealed that 4-OI inhibited calcification and osteogenic differentiation of human VSMCs. Similarly, 4-OI inhibited calcification of rat arterial rings and VitD3-overloaded mouse aortas. Mechanistically, RNA sequencing analysis revealed that 4-OI treatment is most likely to affect heme oxygenase 1 (HMOX-1) mRNA expression. The study demonstrated that 4-OI treatment increased HMOX-1 mRNA and protein levels, but suppressed inflammation and oxidative stress in VSMCs under osteogenic conditions. Moreover, 4-OI treatment. HMOX-1 knockdown by siRNA or treatment with the HMOX-1 inhibitor ZnPP9 significantly reversed the suppression effect on calcification of VSMCs and aortas of VitD3-overloaded mice by 4-OI. Furthermore, HMOX-1 knockdown by siRNA markedly abrogated the inhibitory effect of 4-OI on inflammation in VSMCs. These findings suggest that 4-OI alleviates vascular calcification and inhibits oxidative stress and inflammation through modulation of HMOX-1, indicating its potential as a therapeutic target for vascular calcification.

MicroRNA-18a-5p promotes vascular smooth muscle cell phenotypic switch by targeting Notch2 as therapeutic targets in vein grafts restenosis

Vascular smooth muscle cells (VSMCs) phenotype switching plays a crucial role in vein graft restenosis following coronary artery bypass grafting (CABG) surgery. To discover novel clinically relevant therapeutic targets for vein graft restenosis after CABG, we therefore investigated whether miRNA-18a-5p mediated phenotype switching plays a critical role in the development of vein graft restenosis. We studied miRNA-18a-5p expression in plasma samples of patients with or without vein graft restenosis at 1, 3 and 5 years after coronary artery bypass graft surgery, and in normal vs. atherosclerotic human femoral artery samples, to prove its role in VSMC phenotype switching. We found that the expression of miRNA-18a-5p significantly increased in vein grafts restenosis rat model after bypass surgery at 7, 14, 28 days and human blood specimens with vein grafts failure after grafting surgery. Through gain- and loss-of-function approaches, we determined that miRNA-18a-5p affects VSMC proliferation, migration, differentiation, and contractility. Notch2 was found to be a direct target of miRNA-18a-5p, which is critical for VSMC phenotype switching. Finally, miRNA-18a-5p knockdown used miRNA sponge via AAV6 locally delivery in vivo, miRNA-18a-5p sponge gene transfer therapy reduced the neointimal area, neointimal thickness, and intimal/media area ratio in vein grafts compared with the controls and improved vein graft hemodynamics. miRNA-18a-5p is a critical modulator of VSMC phenotypic switch during development of vein graft restenosis by downregulating Notch2, therefore targeting miRNA-18a-5p may be a helpful strategy for the treatment of vein grafts restenosis or failure after CABG surgery.

RGS5 balances macrophage vs vascular smooth muscle cell origin of foam cells in apoE-deficient plaques

Abstract Background G Protein Coupled Receptors and regulators of G-protein signalling (RGS), play a pivotal role in the signalling processes associated with atherosclerosis [1]. RGS5 is highly expressed in aortic tissue [2]. Development of atherosclerotic plaque is a complex process that involves foam cells originating from macrophages (Mϕ) and/or vascular smooth muscle cells (VSMCs). Differentiation of Mϕ and VSMC into various intermediary cells of varying inflammatory potency affects atherosclerotic plaque composition and vulnerability [3]. We hypothesize that RGS5 is involved in signalling of foam cell transition and thus, plaque biology. Purpose To evaluate the role of RGS5 on atherosclerotic plaque complexity and shifts of foam cell origin. Methods ApoE-/-RGS5+/+ and ApoE-/-RGS5-/- mice were fed a high fat Western Diet for 14 weeks. Cryosections bearing aortic valve cusps were used for staining. Lesion size was quantified on hematoxylin and eosin staining. Plaque composition was assessed by CD68, CD45, Oil red O and collagen staining. Triple staining was performed for CD45, CD68 and aSMA. Double immunofluorescent staining for CD45 and pro- and anti-inflammatory markers was carried out. Co-Localisation was analysed by Zeiss Zen. Data were analysed using Mann-Whitney-U test. Results Lesion size was significantly reduced in RGS5-deficient mice in comparison to control (in mm2: 0.398±0.02 vs 0.191±0.09, p=0.0001, n=15). Relative areas positive for Oil Red O and collagen did not differ between genotypes. Area positive for leukocyte marker CD45 increased significantly by 30.8% (p<0.0001, n=15), whereas area positive for CD68 was reduced by 10.3% (p=0.0292, n=15) in RGS5-deficient mice. Absence of RGS5 decreased co-localization of Mϕ-derived foam cells by 23% (p=0.03734, n=4-5) while leading to an 5.8% increase in aSMA-derived foam cells compared to control. Area positive for pro-inflammatory M1 Mϕ marker CD86 and iNOS increased by 36.3% and 36.8% after RGS5 knock-out (p<0.0001, n=15). No difference in M2 Mϕ positive area was observed when RGS5 was lacking. Conclusion RGS5 promotes plaque formation. The number of Mϕ-derived foam cells is increased by RGS5, while it reduces inflammatory M1 Mϕ. Interestingly, there were no differences in numbers of M2 Mϕ, indicating RGS5 inhibits VSMCs transition to M1 Mϕ resulting in an overall decrease of CD68-positive foam cells. Further study is required to determine molecular signalling of RGS5 that modulates the phenotype of Mϕ- and VSMC-derived cells. RGS5 could be useful as therapeutic target to suppress undesirable plaque phenotypes and to reduce acute cardiovascular events.

Serpina3c deficiency aggravates vascular dysfunction and VSMC dysregulation through regulating adamts4 pathway activity in obese mice

Abstract Background Obesity leads to arterial stiffness (AS), which is an independent risk factor for cardiovascular disease. Vascular smooth muscle cell (VSMC) dysfunction is a critical step in the development of AS. Adamts4 (a disintegrin and metalloproteinase with thrombospondin motifs 4) promoting the ECM remodeling can regulate VSMC differentiation. Serpina3c is a serine protease inhibitor that plays a key role in VSMC proliferation and metabolic diseases. Purpose The present study aimed to investigate the function of Serpina3c in high-fat diet (HFD)-induced AS and regulation of VSMC phenotypic switching and possible mechanisms. Methods 8-week-old male Serpina3c-/- and C57BL/6 mice were fed normal diet (ND) or HFD for 12 weeks. The adipocyte-specific Serpina3c overexpression (AAV8-Serpina3c) were constructed and injected in situ into visceral or perivascular adipose tissue (AT) of Serpina3c-/- mice fed a 12-week HFD to test in vivo effect of AT-derived Serpina3c on arterial stiffness. In vivo vascular stiffness was analyzed by obtaining pulse wave velocity (PWV) measurements. Aortic rings were dissected to assess the ex-vivo effects of Serpina3c deprivation on vascular contractile and diastolic function. Elastin van Gieson (EVG) and Hematoxylin-eosin (H&E) staining were implemented to observe the pathological morphology of aortas. IP-Western analysis was performed for identifying Serpina3c-adamts4 interactions. Results The obese WT mice exhibited significantly increased PWV values, compared with ND-fed mice, which were further increased in HFD+Serpina3c-/- mice (Fig. 1A). Phenylephrine-induced vascular constriction was impaired in HFD fed mice and further deteriorated with Serpina3c deficiency (Fig. 1B). No differences were noted in the endothelial-dependent acetylcholine-mediated relaxation in HFD-fed mice. Notably, Serpina3c-/- mice exhibited poorer endothelium-independent sodium nitroprusside induced relaxation (Fig. 1C and D). The HFD+Serpina3c-/- mice showed an increased breakage of elastin fibres and medial thickness compared with the aortas of HFD+WT mice (Fig. 1E and F). Serpina3c deprivation aggravated collagen deposition and matrix metalloproteinases (MMPs, MMP2 and MMP9) accumulation. VSMC contractile gene α smooth muscle actin were upregulated and synthetic phenotype marker osteopontin were downregulated in HFD+WT mice. The effect was more pronounced in aortas with Serpina3c deficiency (Fig. 1G and H). Overexpression of serpina3c in both visceral and perivascular AT or adamts4 deprivation reversed the above phenotypes. Computer simulations and IP-Western results indicate that Serpina3c and adamts4 bind to and maintain the latter low-expression in response to obesity (Fig. 2). Conclusion Serpina3c interacts with adamts4 to maintain contractile phenotype of VSMC and suppress AS development in the context of nutrient excess. Serpina3c is a novel target for the prevention and treatment of obesity associated artery disease.Serpina3c maintains vascular functionSerpina3c interacts with adamts4

Early growth response 1 exacerbates thoracic aortic aneurysm and dissection of mice by inducing the phenotypic switching of vascular smooth muscle cell through the activation of Krüppel-like factor 5.

Vascular smooth muscle cell (VSMC) phenotypic switching has been reported to regulate vascular function and thoracic aortic aneurysm and dissection (TAAD) progression. Early growth response 1 (Egr1) is associated with the differentiation of VSMCs. However, the mechanisms through which Egr1 participates in the regulation of VSMCs and progression of TAAD remain unknown. This study aimed to investigate the role of Egr1 in the phenotypic switching of VSMCs and the development of TAAD. Wild-type C57BL/6 and SMC-specific Egr1-knockout mice were used as experimental subjects and fed β-aminopropionitrile for 4 weeks to construct the TAAD model. Ultrasound and aortic staining were performed to examine the pathological features in thoracic aortic tissues. Transwell, wound healing, CCK8, and immunofluorescence assays detected the migration and proliferation of synthetic VSMCs. Egr1 was directly bound to the promoter of Krüppel-like factor 5 (KLF5) and promoted the expression of KLF5, which was validated by JASPAR database and dual-luciferase reporter assay. Egr1 expression increased and was partially co-located with VSMCs in aortic tissues of mice with TAAD. SMC-specific Egr1 deficiency alleviated TAAD and inhibited the phenotypic switching of VSMC. Egr1 knockdown prevented the phenotypic switching of VSMCs and subsequently suppressed the migration and proliferation of synthetic VSMCs. The inhibitory effects of Egr1 deficiency on VSMCs were blunted once KLF5 was overexpressed. Egr1 aggravated the development of TAAD by promoting the phenotypic switching of VSMCs via enhancing the transcriptional activation of KLF5. These results suggest that inhibition of SMC-specific Egr1 expression is a promising therapy for TAAD.

BRCC36 regulates β-catenin ubiquitination to alleviate vascular calcification in chronic kidney disease

BackgroundThe prevalence of vascular calcification (VC) in chronic kidney disease (CKD) patients remains substantial, but currently, there are no effective pharmaceutical therapies available. BRCA1/BRCA2-containing complex subunit 36 (BRCC36) has been implicated in osteoblast osteogenic conversion; however, its specific role in VC remains to be fully elucidated. The aim of this study was to investigate the role and underlying mechanisms of BRCC36 in VC.MethodsThe association between BRCC36 expression and VC was examined in radial arteries from patients with CKD, high-adenine-induced CKD mice, and vascular smooth muscle cells (VSMCs). Western blotting, real-time polymerase chain reaction, immunofluorescence, and immunohistochemistry were used to analyse gene expression. Gain- and loss-of-function experiments were performed to comprehensively investigate the effects of BRCC36 on VC. Coimmunoprecipitation and TOPFlash luciferase assays were utilized to further investigate the regulatory effects of BRCC36 on the Wnt/β-catenin pathway.ResultsBRCC36 expression was downregulated in human calcified radial arteries, calcified aortas from CKD mice, and calcified VSMCs. VSMC-specific BRCC36 overexpression alleviated calcium deposition in the vasculature, whereas BRCC36 depletion aggravated VC progression. Furthermore, BRCC36 inhibited the osteogenic differentiation of VSMCs in vitro. Rescue experiments revealed that BRCC36 exerts the protective effects on VC partly by regulating the Wnt/β-catenin signalling pathway. Mechanistically, BRCC36 inhibited the Wnt/β-catenin pathway by decreasing the K63-linked ubiquitination of β-catenin. Additionally, pioglitazone attenuated VC partly through upregulating BRCC36 expression.ConclusionsOur research results emphasize the critical role of the BRCC36-β-catenin axis in VC, suggesting that BRCC36 or β-catenin may be promising therapeutic targets to prevent the progression of VC in CKD patients.Graphical

Vascular Calcification Is Accelerated by Hyponatremia and Low Osmolality.

Hyponatremia, frequently observed in patients with chronic kidney disease, is associated with increased cardiovascular morbidity and mortality. Hyponatremia or low osmolality induces oxidative stress and cell death, both of which accelerate vascular calcification (VC), a critical phenotype in patients with chronic kidney disease. Whether hyponatremia or low osmolality plays a role in the pathogenesis of VC is unknown. Human vascular smooth muscle cells (VSMCs) and mouse aortic rings were cultured in various osmotic conditions and calcifying medium supplemented with high calcium and phosphate. The effects of low osmolality on phenotypic change and oxidative stress in the cultured VSMCs were examined. Microarray analysis was conducted to determine the main signaling pathway of osmolality-related VC. The transcellular sodium and calcium ions flux across the VSMCs were visualized by live imaging. Furthermore, the effect of osmolality on calciprotein particles (CPPs) was investigated. Associations between arterial intimal calcification and hyponatremia or low osmolality were examined by a cross-sectional study using human autopsy specimens obtained in the Hisayama Study. Low osmolality exacerbated calcification of the ECM (extracellular matrix) of cultured VSMCs and mouse aortic rings. Oxidative stress and osteogenic differentiation of VSMCs were identified as the underlying mechanisms responsible for low osmolality-induced VC. Microarray analysis showed that low osmolality activated the Rac1 (Ras-related C3 botulinum toxin substrate 1)-Akt (protein kinase B) pathway and reduced NCX1 (Na-Ca exchanger 1) expression. Live imaging showed synchronic calcium ion efflux and sodium ion influx via NCX1 when extracellular sodium ion concentrations were increased. An NCX1 inhibitor promoted calcifying media-induced VC by reducing calcium ion efflux. Furthermore, low osmolality accelerated the generation and maturation steps of CPPs. The cross-sectional study of human autopsy specimens showed that hyponatremia and low osmolality were associated with a greater area of arterial intimal calcification. Hyponatremia and low osmolality promote VC through multiple cellular processes, including the Rac1-Akt pathway activation.

Loss of Smooth Muscle Tenascin-X Inhibits Vascular Remodeling Through Increased TGF-β Signaling.

Vascular smooth muscle cells (VSMCs) are highly plastic. Vessel injury induces a phenotypic transformation from differentiated to dedifferentiated VSMCs, which involves reduced expression of contractile proteins and increased production of extracellular matrix and inflammatory cytokines. This transition plays an important role in several cardiovascular diseases such as atherosclerosis, hypertension, and aortic aneurysm. TGF-β (transforming growth factor-β) is critical for VSMC differentiation and to counterbalance the effect of dedifferentiating factors. However, the mechanisms controlling TGF-β activity and VSMC phenotypic regulation under in vivo conditions are poorly understood. The extracellular matrix protein TN-X (tenascin-X) has recently been shown to bind TGF-β and to prevent it from activating its receptor. We studied the role of TN-X in VSMCs in various murine disease models using tamoxifen-inducible SMC-specific knockout and adeno-associated virus-mediated knockdown. In hypertensive and high-fat diet-fed mice, after carotid artery ligation as well as in human aneurysmal aortae, expression of Tnxb, the gene encoding TN-X, was increased in VSMCs. Mice with smooth muscle cell-specific loss of TN-X (SMC-Tnxb-KO) showed increased TGF-β signaling in VSMCs, as well as upregulated expression of VSMC differentiation marker genes during vascular remodeling compared with controls. SMC-specific TN-X deficiency decreased neointima formation after carotid artery ligation and reduced vessel wall thickening during Ang II (angiotensin II)-induced hypertension. SMC-Tnxb-KO mice lacking ApoE showed reduced atherosclerosis and Ang II-induced aneurysm formation under high-fat diet. Adeno-associated virus-mediated SMC-specific expression of short hairpin RNA against Tnxb showed similar beneficial effects. Treatment with an anti-TGF-β antibody or additional SMC-specific loss of the TGF-β receptor reverted the effects of SMC-specific TN-X deficiency. In summary, TN-X critically regulates VSMC plasticity during vascular injury by inhibiting TGF-β signaling. Our data indicate that inhibition of vascular smooth muscle TN-X may represent a strategy to prevent and treat pathological vascular remodeling.

EVs-miR-17-5p attenuates the osteogenic differentiation of vascular smooth muscle cells potentially via inhibition of TGF-β signaling under high glucose conditions

Vascular calcification, which is a major complication of diabetes mellitus, is an independent risk factor for cardiovascular disease. Osteogenic differentiation of vascular smooth muscle cells (VSMCs) is one of the key mechanisms underlying vascular calcification. Emerging evidence suggests that macrophage-derived extracellular vesicles (EVs) may be involved in calcification within atherosclerotic plaques in patients with diabetes mellitus. However, the role of macrophage-derived EVs in the progression of vascular calcification is largely unknown. In this study, we investigated whether macrophage-derived EVs contribute to the osteogenic differentiation of VSMCs under high glucose conditions. We isolated EVs that were secreted by murine peritoneal macrophages under normal glucose (EVs-NG) or high glucose (EVs-HG) conditions. miRNA array analysis in EVs from murine macrophages showed that miR-17-5p was significantly increased in EVs-HG compared with EVs-NG. Prediction analysis with miRbase identified transforming growth factor β receptor type II (TGF-β RII) as a potential target of miR-17-5p. EVs-HG as well as miR-17-5p overexpression with lipid nanoparticles inhibited the gene expression of Runx2, and TGF-β RII. Furthermore, we demonstrated that VSMCs transfected with miR-17-5p mimic inhibited calcium deposition. Our findings reveal a novel role of macrophage-derived EVs in the negative regulation of osteogenic differentiation in VSMCs under high glucose conditions.

Hemodynamics regulate spatiotemporal artery muscularization in the developing circle of Willis.

Vascular smooth muscle cells (VSMCs) envelop vertebrate brain arteries and play a crucial role in regulating cerebral blood flow and neurovascular coupling. The dedifferentiation of VSMCs is implicated in cerebrovascular disease and neurodegeneration. Despite its importance, the process of VSMC differentiation on brain arteries during development remains inadequately characterized. Understanding this process could aid in reprogramming and regenerating dedifferentiated VSMCs in cerebrovascular diseases. In this study, we investigated VSMC differentiation on zebrafish circle of Willis (CoW), comprising major arteries that supply blood to the vertebrate brain. We observed that arterial specification of CoW endothelial cells (ECs) occurs after their migration from cranial venous plexus to form CoW arteries. Subsequently, acta2+ VSMCs differentiate from pdgfrb+ mural cell progenitors after they were recruited to CoW arteries. The progression of VSMC differentiation exhibits a spatiotemporal pattern, advancing from anterior to posterior CoW arteries. Analysis of blood flow suggests that earlier VSMC differentiation in anterior CoW arteries correlates with higher red blood cell velocity and wall shear stress. Furthermore, pulsatile flow induces differentiation of human brain PDGFRB+ mural cells into VSMCs, and blood flow is required for VSMC differentiation on zebrafish CoW arteries. Consistently, flow-responsive transcription factor klf2a is activated in ECs of CoW arteries prior to VSMC differentiation, and klf2a knockdown delays VSMC differentiation on anterior CoW arteries. In summary, our findings highlight blood flow activation of endothelial klf2a as a mechanism regulating initial VSMC differentiation on vertebrate brain arteries.

Hemodynamics regulate spatiotemporal artery muscularization in the developing circle of Willis

Vascular smooth muscle cells (VSMCs) envelop vertebrate brain arteries and play a crucial role in regulating cerebral blood flow and neurovascular coupling. The dedifferentiation of VSMCs is implicated in cerebrovascular disease and neurodegeneration. Despite its importance, the process of VSMC differentiation on brain arteries during development remains inadequately characterized. Understanding this process could aid in reprogramming and regenerating dedifferentiated VSMCs in cerebrovascular diseases. In this study, we investigated VSMC differentiation on zebrafish circle of Willis (CoW), comprising major arteries that supply blood to the vertebrate brain. We observed that arterial specification of CoW endothelial cells (ECs) occurs after their migration from cranial venous plexus to form CoW arteries. Subsequently, acta2+ VSMCs differentiate from pdgfrb+ mural cell progenitors after they were recruited to CoW arteries. The progression of VSMC differentiation exhibits a spatiotemporal pattern, advancing from anterior to posterior CoW arteries. Analysis of blood flow suggests that earlier VSMC differentiation in anterior CoW arteries correlates with higher red blood cell velocity and wall shear stress. Furthermore, pulsatile flow induces differentiation of human brain PDGFRB+ mural cells into VSMCs, and blood flow is required for VSMC differentiation on zebrafish CoW arteries. Consistently, flow-responsive transcription factor klf2a is activated in ECs of CoW arteries prior to VSMC differentiation, and klf2a knockdown delays VSMC differentiation on anterior CoW arteries. In summary, our findings highlight blood flow activation of endothelial klf2a as a mechanism regulating initial VSMC differentiation on vertebrate brain arteries.

A Dynamic Cellular Model as an Emerging Platform to Reproduce the Complexity of Human Vascular Calcification In Vitro.

Vascular calcification (VC) is a cardiovascular disease characterized by calcium salt deposition in vascular smooth muscle cells (VSMCs). Standard in vitro models used in VC investigations are based on VSMC monocultures under static conditions. Although these platforms are easy to use, the absence of interactions between different cell types and dynamic conditions makes these models insufficient to study key aspects of vascular pathophysiology. The present study aimed to develop a dynamic endothelial cell-VSMC co-culture that better mimics the in vivo vascular microenvironment. A double-flow bioreactor supported cellular interactions and reproduced the blood flow dynamic. VSMC calcification was stimulated with a DMEM high glucose calcification medium supplemented with 1.9 mM NaH2PO4/Na2HPO4 (1:1) for 7 days. Calcification, cell viability, inflammatory mediators, and molecular markers (SIRT-1, TGFβ1) related to VSMC differentiation were evaluated. Our dynamic model was able to reproduce VSMC calcification and inflammation and evidenced differences in the modulation of effectors involved in the VSMC calcified phenotype compared with standard monocultures, highlighting the importance of the microenvironment in controlling cell behavior. Hence, our platform represents an advanced system to investigate the pathophysiologic mechanisms underlying VC, providing information not available with the standard cell monoculture.

Myogenic Anti-Nucleolin Aptamer iSN04 Inhibits Proliferation and Promotes Differentiation of Vascular Smooth Muscle Cells.

De-differentiation and subsequent increased proliferation and inflammation of vascular smooth muscle cells (VSMCs) is one of the mechanisms of atherogenesis. Maintaining VSMCs in a contractile differentiated state is therefore a promising therapeutic strategy for atherosclerosis. We have reported the 18-base myogenetic oligodeoxynucleotide, iSN04, which serves as an anti-nucleolin aptamer and promotes skeletal and myocardial differentiation. The present study investigated the effect of iSN04 on VSMCs because nucleolin has been reported to contribute to VSMC de-differentiation under pathophysiological conditions. Nucleolin is localized in the nucleoplasm and nucleoli of both rat and human VSMCs. iSN04 without a carrier was spontaneously incorporated into VSMCs, indicating that iSN04 would serve as an anti-nucleolin aptamer. iSN04 treatment decreased the ratio of 5-ethynyl-2'-deoxyuridine (EdU)-positive proliferating VSMCs and increased the expression of α-smooth muscle actin, a contractile marker of VSMCs. iSN04 also suppressed angiogenesis of mouse aortic rings ex vivo, which is a model of pathological angiogenesis involved in plaque formation, growth, and rupture. These results demonstrate that antagonizing nucleolin with iSN04 preserves VSMC differentiation, providing a nucleic acid drug candidate for the treatment of vascular disease.

Endothelial cell Piezo1 promotes vascular smooth muscle cell differentiation on large arteries.

Vascular stabilization is a mechanosensitive process, in part driven by blood flow. Here, we demonstrate the involvement of the mechanosensitive ion channel, Piezo1, in promoting arterial accumulation of vascular smooth muscle cells (vSMCs) during zebrafish development. Using a series of small molecule antagonists or agonists to temporally regulate Piezo1 activity, we identified a role for the Piezo1 channel in regulating klf2a levels and altered targeting of vSMCs between arteries and veins. Increasing Piezo1 activity suppressed klf2a and increased vSMC association with the cardinal vein, while inhibition of Piezo1 activity increased klf2a levels and decreased vSMC association with arteries. We supported the small molecule data with in vivo genetic suppression of piezo1 and 2 in zebrafish, resulting in loss of transgelin+ vSMCs on the dorsal aorta. Further, endothelial cell (EC)-specific Piezo1 knockout in mice was sufficient to decrease vSMC accumulation along the descending dorsal aorta during development, thus phenocopying our zebrafish data, and supporting functional conservation of Piezo1 in mammals. To determine mechanism, we used in vitro modeling assays to demonstrate that differential sensing of pulsatile versus laminar flow forces across endothelial cells changes the expression of mural cell differentiation genes. Together, our findings suggest a crucial role for EC Piezo1 in sensing force within large arteries to mediate mural cell differentiation and stabilization of the arterial vasculature.

RANKL, but Not R-Spondins, Is Involved in Vascular Smooth Muscle Cell Calcification through LGR4 Interaction.

Vascular calcification has a global health impact that is closely linked to bone loss. The Receptor Activator of Nuclear Factor Kappa B (RANK)/RANK ligand (RANKL)/osteoprotegerin (OPG) system, fundamental for bone metabolism, also plays an important role in vascular calcification. The Leucine-rich repeat-containing G-protein-coupled receptor 4 (LGR4), a novel receptor for RANKL, regulates bone remodeling, and it appears to be involved in vascular calcification. Besides RANKL, LGR4 interacts with R-spondins (RSPOs), which are known for their roles in bone but are less understood in vascular calcification. Studies were conducted in rats with chronic renal failure fed normal or high phosphorus diets for 18 weeks, with and without control of circulating parathormone (PTH) levels, resulting in different degrees of aortic calcification. Additionally, vascular smooth muscle cells (VSMCs) were cultured under non-calcifying (1 mM phosphate) and calcifying (3 mM phosphate) media with different concentrations of PTH. To explore the role of RANKL in VSMC calcification, increasing concentrations of soluble RANKL were added to non-calcifying and calcifying media. The effects mediated by RANKL binding to its receptor LGR4 were investigated by silencing the LGR4 receptor in VSMCs. Furthermore, the gene expression of the RANK/RANKL/OPG system and the ligands of LGR4 was assessed in human epigastric arteries obtained from kidney transplant recipients with calcification scores (Kauppila Index). Increased aortic calcium in rats coincided with elevated systolic blood pressure, upregulated Lgr4 and Rankl gene expression, downregulated Opg gene expression, and higher serum RANKL/OPG ratio without changes in Rspos gene expression. Elevated phosphate in vitro increased calcium content and expression of Rankl and Lgr4 while reducing Opg. Elevated PTH in the presence of high phosphate exacerbated the increase in calcium content. No changes in Rspos were observed under the conditions employed. The addition of soluble RANKL to VSMCs induced genotypic differentiation and calcification, partly prevented by LGR4 silencing. In the epigastric arteries of individuals presenting vascular calcification, the gene expression of RANKL was higher. While RSPOs show minimal impact on VSMC calcification, RANKL, interacting with LGR4, drives osteogenic differentiation in VSMCs, unveiling a novel mechanism beyond RANKL-RANK binding.

The mitochondrial protease ClpP is a druggable target that controls VSMC phenotype by a SIRT1-dependent mechanism

Vascular smooth muscle cells (VSMCs), known for their remarkable lifelong phenotypic plasticity, play a pivotal role in vascular pathologies through their ability to transition between different phenotypes. Our group discovered that the deficiency of the mitochondrial protein Poldip2 induces VSMC differentiation both in vivo and in vitro. Further comprehensive biochemical investigations revealed Poldip2's specific interaction with the mitochondrial ATPase caseinolytic protease chaperone subunit X (CLPX), which is the regulatory subunit for the caseinolytic protease proteolytic subunit (ClpP) that forms part of the ClpXP complex – a proteasome-like protease evolutionarily conserved from bacteria to humans. This interaction limits the protease's activity, and reduced Poldip2 levels lead to ClpXP complex activation. This finding prompted the hypothesis that ClpXP complex activity within the mitochondria may regulate the VSMC phenotype.Employing gain-of-function and loss-of-function strategies, we demonstrated that ClpXP activity significantly influences the VSMC phenotype. Notably, both genetic and pharmacological activation of ClpXP inhibits VSMC plasticity and fosters a quiescent, differentiated, and anti-inflammatory VSMC phenotype. The pharmacological activation of ClpP using TIC10, currently in phase III clinical trials for cancer, successfully replicates this phenotype both in vitro and in vivo and markedly reduces aneurysm development in a mouse model of elastase-induced aortic aneurysms. Our mechanistic exploration indicates that ClpP activation regulates the VSMC phenotype by modifying the cellular NAD+/NADH ratio and activating Sirtuin 1. Our findings reveal the crucial role of mitochondrial proteostasis in the regulation of the VSMC phenotype and propose the ClpP protease as a novel, actionable target for manipulating the VSMC phenotype.

Concentration-Dependent Effects of Boric Acid on Osteogenic Differentiation of Vascular Smooth Muscle Cells.

Vascular calcification can be triggered by oxidative stress and inflammation. Although boron possesses antioxidant and anti-inflammatory properties, its effect on osteogenic differentiation of vascular smooth muscle cells (VSMCs) has yet to be examined. Therefore, we aimed to investigate the effect of boric acid (BA), the main form of boron in body fluids, on the osteogenic differentiation of VSMCs. Following the isolation of VSMCs, the effects of BA on cell proliferation were determined by MTT. The impact of various BA concentrations on the osteogenic differentiation of VSMCs was evaluated by Alizarin red S and alkaline phosphatase (ALP) stainings and the o-cresolphthalein complexone method. In addition, mRNA expressions of osteogenic-related (Runx2 and ALP) and antioxidant system-related genes (Nrf2 and Nqo1) were detected using qRT-PCR analysis. BA treatments did not alter the proliferation of VSMCs. Osteogenic differentiation of VSMCs treated with 100 and 500μM BA (moderate and high plasma concentrations) was no different from untreated cells. However, increased osteogenic differentiation was observed with the lowest blood level (2μM) and extremely high BA concentration (1000μM). Consistent with these results, mRNA expression of Runx2 increased with 2 and 1000μM BA treatments, while Nrf2 and Nqo1 expressions increased significantly with 100 and 500μM BA. BA has different effects on VSMCs at various concentrations. The low blood level and too high BA concentration appear detrimental as they increase the osteogenic differentiation of VSMCs in vitro. We propose to investigate BA's effects and mechanism of action on vascular calcification in vivo.

Chronic Gestational Hypoxia Alters Plasma Exosomal miRNA Profile and Pulmonary Arterial Proteome and Metabolome in Fetal Lambs

Antenatal chronic hypoxia negatively impacts fetal development and increases the risk of cardio-pulmonary dysfunction after birth, including newborn pulmonary hypertension. Previously, we showed that fetal and newborn sheep exposed to chronic hypoxia during gestation exhibit a variety of cardio-pulmonary defects that parallel those of human infants including pulmonary vascular remodeling, heart dysfunction, and pulmonary hypertension. To explore the mechanisms involved in hypoxia-mediated newborn pulmonary hypertension, we test the hypothesis that antenatal chronic hypoxia impairs pathways critical to pulmonary vascular development that are coupled to abnormalities in lung structure and function through dysregulation in cell growth and proliferation. To address this hypothesis, we employed an animal model of pregnant sheep exposed to high altitude hypoxia at the White Mountain Research Station, which has an altitude of 3801 meters. Hypoxic pregnant sheep were housed at altitude during gestation for ~110 days out of 138-141 days of pregnancy while normoxic counterparts were kept at 700 meters. Animals were transferred to Loma Linda at 355 meters and fetal lambs studied at ~140 days of gestation. Fetal plasma samples were collected for exosomal miRNA analysis and pulmonary arteries were collected for proteomic and metabolomic analysis. Ingenuity pathway analysis and other bioinformatic tools were used to interrogate regulatory mechanisms and pathways and the web of molecular interactions affected by hypoxia. Antenatal hypoxic stress caused up and down regulation of a limited number of plasma exosomal miRNAs, pulmonary arterial metabolites and proteins, with discrete interconnections between the various analytes and molecules. There were marked changes in upstream regulators and markers that point to increased oxidative stress and inflammatory response along with pronounced downregulation of matrix proteins and phenotypic markers of vascular smooth muscle cell differentiation. Pathway analyses indicate antenatal chronic hypoxia dysregulates growth and proliferation of vascular cells and impinges on cell migration. While these data require additional study and verification, they provide new insights in the understanding of mechanisms underlying the development of pulmonary hypertension in the newborn following antenatal hypoxia. This work was supported by the National Institutes of Health Grants NIH R01HL155295, R01HL149608, R03HD098477, P01HD083132, and U24DK097154. Additional support was provided by the Loma Linda University School of Medicine, A pilot Project through the West Coast Metabolomics Center, the University of Redlands Summer Research Program, and the Walter E. Macpherson Society. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Abstract 1147: Crosstalk Between Alk5 And Mtorc1 Signaling Promotes VSMC Differentiation And The Therapeutic Effect Of Rapamycin

Background: Vascular smooth muscle cells (VSMC) phenotypic switching contributes to vascular repair and remodeling but also to pathologies including intimal hyperplasia. The mTORC1 inhibitor rapamycin is an effective drug-eluting stent agent that promotes VSMC differentiation. TGFβ also promotes VSMC differentiation through SMAD transcription factors. We investigated unexpected convergence between these pathways in VSMC plasticity. Methods: We assessed the interactions between rapamycin and the TGFβ1 (ALK5) signaling in human coronary artery SMCs and in vascular remodeling using inducible SMC-specific knockout mice (ALK5iKO). Results: Genome-wide histone H3K27 acetylation analysis unexpectedly identified SMAD binding elements as the motif most enriched after rapamycin treatment of hCASMCs. Treatment with rapamycin promoted rapid phosphorylation of SMAD2/3. Extensive signaling studies revealed that this phosphorylation required ALK5 activity but not TGF-β ligand. Surprisingly, ALK5 and SMAD2/3 were required for rapamycin-induced differentiation. We determined that rapamycin relieves FKBP12 inhibition of ALK5 to promote ligand independent Smad signaling, and FKBP12 knockdown was sufficient to induce contractile genes. Notably, rapamycin treatment induced an interaction between TET2 and SMAD2/3, and these SMADs were required for differentiation-associated chromatin remodeling, including DNA hydroxymethylation and H3K27 acetylation at contractile genes, suggesting that SMADs and TET2 function in concert at SBE- and CArG-containing promoter regions. Furthermore, ALK5iKO mice exhibited severe intimal hyperplasia after carotid artery injury compared to controls and were entirely resistant to the therapeutic effect of rapamycin, despite persistent inhibition of mTORC1. Consistent with in vitro findings, treatment with rapamycin elevated pSmad3 staining post-injury in the medial layer of control but not ALK5iKO mice. Conclusions: We report the surprising observation that rapamycin requires FKBP12/ALK5/SMAD2/3 signaling in order to promote TET2-dependent chromatin remodeling and SMC differentiation. Understanding these mechanisms may reveal new therapeutic strategies for treating vascular diseases.

Abstract 1053: The Role Of Bile Acid-initiated Signaling In Vascular Smooth Muscle Cell Phenotypic Switching And Atherosclerosis

Atherosclerosis is a chronic inflammatory disease in which foam cells (lipid-laden macrophage-like cells) accumulate in the arterial wall. Vascular smooth muscle cells (VSMCs) are not terminally differentiated; they switch to a foam cell-like phenotype in response to various stimuli, such as cholesterol (CHOL), increasing susceptibility to vascular diseases. Modulated SMCs are the main contributors to atherosclerotic plaque formation. The intracellular metabolism of CHOL via peroxisomes in hepatocytes produces bile acids like cholic or deoxycholic acid, which agonize liver X receptor (LXR). LXR facilitates the first step of reverse CHOL transport. It is unknown if VSMCs synthesize bile acids and whether peroxisomes and the bile acids they produce play a role in VSMC-derived foam cell formation. Using human aortic SMCs (HASMCs), we found that CHOL treatment decreased expression of several peroxisomal proteins. Peroxisomal loss-of-function experiments demonstrated increased intracellular lipid accumulation, as visualized with Oil Red O (ORO) staining. We have shown that HASMCs synthesize bile acids after exposure to CHOL, which led us to hypothesize that bile acid-initiated signaling participates in the phenotypic modulation initiated by CHOL in VSMCs. Treatment of HASMCs with LXR agonists or bile acids increased expression of the efflux CHOL transporter ABCA1, bile acid-related peroxisomal enzymes, and differentiation markers; they decreased expression of macrophage and foam cell markers and ORO staining. These data show that VSMCs have the metabolic capacity to synthesize bile acids, which is impaired if peroxisomes are non-functional or absent. Our data indicates that activation of bile acid receptors upregulates ABCA1, favoring a differentiated VSMC phenotype. Together, these data suggest that activation of LXR plays a role in CHOL-induced VSMC to foam cell transition and that LXR is a potential therapeutic target which promotes VSMC differentiation and decreases atherosclerotic plaque formation.