K Domain CR9 of Low Density Lipoprotein (LDL) Receptor-related Protein 1 (LRP1) Is Critical for Aggregated LDL-induced Foam Cell Formation from Human Vascular Smooth Muscle Cells

Low density lipoprotein receptor-related protein (LRP1) mediates the internalization of aggregated LDL (AgLDL), which in turn increases the expression of LRP1 in human vascular smooth muscle cells (hVSMCs). This positive feedback mechanism is thus highly efficient to promote the formation of hVSMC foam cells, a crucial vascular component determining the susceptibility of atherosclerotic plaque to rupture. Here we have determined the LRP1 domains involved in AgLDL recognition with the aim of specifically blocking AgLDL internalization in hVSMCs. The capacity of fluorescently labeled AgLDL to bind to functional LRP1 clusters was tested in a receptor-ligand fluorometric assay made by immobilizing soluble LRP1 “minireceptors” (sLRP1-II, sLRP1-III, and sLRP1-IV) recombinantly expressed in CHO cells. This assay showed that AgLDL binds to cluster II. We predicted three well exposed and potentially immunogenic peptides in the CR7–CR9 domains of this cluster (termed P1 (Cys¹⁰⁵¹–Glu¹⁰⁶⁶), P2 (Asp¹⁰⁹⁰–Cys¹¹⁰⁴), and P3 (Gly¹¹²⁷–Cys¹¹⁴⁰)). AgLDL, but not native LDL, bound specifically and tightly to P3-coated wells. Rabbit polyclonal antibodies raised against P3 prevented AgLDL uptake by hVSMCs and were almost twice as effective as anti-P1 and anti-P2 Abs in reducing intracellular cholesteryl ester accumulation. Moreover, anti-P3 Abs efficiently prevented AgLDL-induced LRP1 up-regulation and counteracted the down-regulatory effect of AgLDL on hVSMC migration. In conclusion, domain CR9 appears to be critical for LRP1-mediated AgLDL binding and internalization in hVSMCs. Our results open new avenues for an innovative anti-VSMC foam cell-based strategy for the treatment of vascular lipid deposition in atherosclerosis.     

GLP-1 promotes mitochondrial metabolism in vascular smooth muscle cells by enhancing endoplasmic reticulum–mitochondria coupling

Incretin GLP-1 has important metabolic effects on several tissues, mainly through the regulation of glucose uptake and usage. One mechanism for increasing cell metabolism is modulating endoplasmic reticulum (ER)–mitochondria communication, as it allows for a more efficient transfer of Ca²⁺ into the mitochondria, thereby increasing activity. Control of glucose metabolism is essential for proper vascular smooth muscle cell (VSMC) function. GLP-1 has been shown to produce varied metabolic actions, but whether it regulates glucose metabolism in VSMC remains unknown. In this report, we show that GLP-1 increases mitochondrial activity in the aortic cell line A7r5 by increasing ER–mitochondria coupling. GLP-1 increases intracellular glucose and diminishes glucose uptake without altering glycogen content. ATP, mitochondrial potential and oxygen consumption increase at 3 h of GLP-1 treatment, paralleled by increased Ca²⁺ transfer from the ER to the mitochondria. Furthermore, GLP-1 increases levels of Mitofusin-2 (Mfn2), an ER-mitochondria tethering protein, via a PKA-dependent mechanism. Accordingly, PKA inhibition and Mfn2 down-regulation prevented mitochondrial Ca²⁺ increases in GLP-1 treated cells. Inhibiting both Ca²⁺ release from the ER and Ca²⁺ entry into mitochondria as well as diminishing Mfn2 levels blunted the increase in mitochondrial activity in response to GLP-1. Altogether, these results strongly suggest that GLP-1 increases ER–mitochondria communication in VSMC, resulting in higher mitochondrial activity.     

5-Lipoxagenase deficiency attenuates L-NAME-induced hypertension and vascular remodeling

BackgroundAbnormalities of the L-arginine-nitric oxide pathway induce hypertension. 5-Lipoxygenase (5-LO) is the key enzyme involved in synthesis of leukotrienes (LTs). However, whether nitricoxide synthase dysfunction induces hypertensive vascular remodeling by regulating 5-LO activity and its downstream inflammatory metabolites remains unknown.Methods and resultsSix-week L-NAME treatment significantly induced hypertension and vascular remodeling in both wild-type (WT) and 5-LO–knockout (5-LO–KO) mice, and blood pressure in caudal and carotid arteries was lower in 5-LO–KO than WT mice with L-NAME exposure. On histology, L-NAME induced less media thickness, media-to-lumen ratio, and collagen deposition and fewer Ki-67–positive vascular smooth muscle cells (VSMCs) but more elastin expression in thoracic and mesenteric aortas of 5-LO–KO than L-NAME–treated WT mice. L-NAME significantly increased LT content, including LTB4 and cysteinyl LT (CysLTs), in plasma and neutrophil culture supernatants from WT mice. On immunohistochemistry, L-NAME promoted the colocalization of 5-LO and 5-LO–activating protein on the nuclear envelope of cultured neutrophils, which was accompanied by elevated LT content in culture supernatants. In addition, LTs significantly promoted BrdU incorporation, migration and phenotypic modulation in VSMCs.ConclusionL-NAME may activate the 5-LO/LT pathway in immune cells, such as neutrophils, and promote the products of 5-LO metabolites, including LTB4 and CysLTs, which aggravate vascular remodeling in hypertension. 5-LO deficiency may protect against hypertension and vascular remodeling by reducing levels of 5-LO downstream inflammatory metabolites.     

智力低下相关蛋白(FXR1P)与CMAS相互作用的生物学效应研究

脆性X综合征(FXS)是一种遗传性智力低下疾病,其发病率仅次于21三体综合征．脆性X智力低下蛋白(FMRP)是FXS的关键性致病因子,该蛋白由脆性X智力低下基因1(FMR1)编码所得．FMR1在神经肌肉和睾丸组织中广泛表达．脆性X相关蛋白1(FXR1P)则是由FMR1的同源基因脆性X相关基因1(FXR1)编码所得,并且与蛋白质和RNAs之间存在着相互作用．许多疾病都涉及到FXR1表达的改变．为了了解FXR1P与CMAS(胞嘧啶单核苷酸-N-乙酰神经氨酸合成酶)相互作用所产生的的生物学效应,我们构建了FXR1的过表达载体,并观察其在PC12细胞(大鼠鼠肾上腺嗜铬细胞瘤细胞)和VSMC(血管平滑肌细胞)中的表达以及继而对于细胞形态和CMAS活性相关的许多细胞指标的效应．我们证实,FXR1基因的过表达可以提高PC12细胞中CMAS的活性,并对于该类细胞的生长提供一定程度的保护作用．PC12细胞是一种较为常见的用于研究神经系统疾病的细胞系．结论：我们推测FXR1P是一个组织特异调节因子,可以改变PC12细胞而非VSMC细胞中神经节苷酯(GM1)的浓度．     

Magnolol inhibits migration of vascular smooth muscle cells via cytoskeletal remodeling pathway to attenuate neointima formation

BackgroundIncreased proliferation and migration of vascular smooth muscle cells (VSMCs) contribute importantly to the formation of both atherosclerotic and restenotic lesions. The objective of this study was to investigate the effect of magnolol on VSMC migration.MethodsThe proteolytic activity of matrix metalloproteinases (MMPs) in tumor necrosis factor alpha (TNF-α) stimulated VSMCs was performed by gelatin zymography. VSMC migration was assessed by wound healing and Boyden chamber methods. Collagen induced VSMC adhesion was determined by spectrofluorimeter and stress fibers formation was evaluated by fluorescence microscope. The expression of signaling molecules involved in stress fibers formation was determined by western blot. The phosphorylation of myosin light chain (MLC20) was determined by urea-glycerol polyacrylamide gel electrophoresis. Immunohistochemistry was performed to determine the expression of β1-integrin and collagen type I in the injured carotid arteries of rats on day 35 after vascular injury.ResultsVSMC migration was strongly inhibited by magnolol without affecting MMPs expression. Also, magnolol inhibited β1-integrin expression, FAK phosphorylation and RhoA and Cdc42 activation to inhibit the collagen induced stress fibers formation. Moreover, magnolol inhibited the phosphorylation of MLC20. Our in vivo results showed that magnolol inhibited β1-integrin expression, collagen type I deposition and FAK phosphorylation in injured carotid arteries without affecting MMP-2 activity.ConclusionsMagnolol inhibited VSMC migration via inhibition of cytoskeletal remodeling pathway to attenuate neointima formation.General significanceThis study provides a rationale for further evaluation of magnolol for the management of atherosclerosis and restenosis.     

Effect of Lyso-phosphatidylcholine and Schnurri-3 on Osteogenic Transdifferentiation of Vascular Smooth Muscle Cells to Calcifying Vascular Cells in 3D Culture

Background

In vitro cell culture is a widely used technique for investigating a range of processes such as stem cell behavior, regenerative medicine, tissue engineering, and drug discovery. Conventional cell culture is performed in Petri dishes or flasks where cells typically attach to a flat glass or plastic surface as a cell monolayer. However, 2D cell monolayers do not provide a satisfactory representation of in vivo conditions. A 3D culture could be a much better system for representing the conditions that prevail in vivo.

Methods and results

To simulate 3D conditions, vascular smooth muscle cells (VSMCs) were loaded with gold–polyvmer–iron oxide hydrogel, enabling levitation of the cells by using spatially varying magnetic fields. These magnetically levitated 3D cultures appeared as freely suspended, clustered cells which proliferated 3–4 times faster than cells in conventional 2D cultures. When the levitated cells were treated with 10 nM lysophosphatidylcholine (LPC), for 3 days, cell clusters exhibited translucent extensions/rods 60–80 μm wide and 200–250 μm long. When 0.5 μg/μl Schnurri-3 was added to the culture containing LPC, these extensions were smaller or absent. When excited with 590–650 nm light, these extensions emitted intrinsic fluorescence at > 667 nm. When the 3D cultures were treated with a fluorescent probe specific for calcium hydroxyapatite (FITC-HABP-19), the cell extensions/rods emitted intensely at 518 nm, the λ_max for FITC emission. Pellets of cells treated with LPC were more enriched in calcium, phosphate, and glycosaminoglycans than cells treated with LPC and Schnurri-3.

Conclusions

In 3D cultures, VSMCs grow more rapidly and form larger calcification clusters than cells in 2D cultures. Transdifferentiation of VSMC into calcifying vascular cells is enhanced by LPC and attenuated by Schnurri-3.

General significance

The formation of calcified structures in 3D VSMC cultures suggests that similar structures may be formed in vivo.     

Redox state and gender differences in vascular smooth muscle cells

Vascular smooth muscle cells (VSMC) have been isolated from male and female rat aorta and studied to assess their susceptibility to ultraviolet radiation-induced oxidative stress. Interestingly, a gender difference, in terms of reactive oxygen species production, was detected in both basal and irradiated VSMC. Namely, VSMC from male rats were more susceptible to radiation-induced stress and easier underwent apoptosis in comparison to cells from female rats. Conversely, the latter, in the same experimental conditions, clearly displayed signs of premature senescence. These results indicate that a sort of "gender memory" can be conserved in VMSC in primary culture.     

Mitochondrial dysfunction enhances the migration of vascular smooth muscles cells via suppression of Akt phosphorylation

Background

Atherosclerosis is one of the major complications of diabetes, which may result from insulin resistance via mitochondrial dysfunction. Although a strong association between insulin resistance and cardiovascular disease has been suggested, it is not clear yet whether stress-inducing factors damage mitochondria and insulin signaling pathway in cardiovascular tissues.

Methods

We investigated whether stress-induced mitochondrial dysfunction might alter the insulin/Akt signaling pathway in A10 rat vascular smooth muscle cells (VSMC).

Results

The treatment of oxidized low density lipoprotein (oxLDL) decreased ATP contents, mitochondrial respiration activity, mRNA expressions of OXPHOS subunits and IRS-1/2 and insulin-mediated phosphorylations of Akt and AMP-activated protein kinase (AMPK). Similarly, dideoxycytidine (ddC), the mtDNA replication inhibitor, or rotenone, OXPHOS complex I inhibitor, inhibited the insulin-mediated pAkt while increased pAMPK regardless of insulin. Reciprocally, an inhibitor of Akt, triciribine (TCN), decreased cellular ATP contents. Overexpression of Akt dominant positive reversed the oxLDL- or ddC-mediated ATP decrease but AMPK activator did not. Akt activation also normalized the aberrant VSMC migration induced by ddC.

Conclusions

Defective insulin signaling and mitochondrial function may collectively contribute to developing cardiovascular disease.

General significance

Akt may be a possible therapeutic target for treating insulin resistance-associated atherosclerosis.     

Characterization of phospholipase A1, A2, C activity in Ureaplasma urealyticum membranes

Neointimal thickening following catheter injury is characterized, in part, by growth factor-induced vascular smooth muscle cell (VSMC) proliferation. It was hypothesized that a reduction in serum insulin-like growth factor-1 (IGF-1), characteristic of chemically-induced diabetes, would result in decreased VSMC proliferation and attenuate neointimal thickening. It was found that alloxan-treated New Zealand White rabbits exhibit varying degrees of glycemia. Rabbits classified as diabetic (glucose = 400 mg/dL) had significantly decreased serum concentration of IGF-1 (87.4 ± 14 nmol/L vs. 170 ± 14 nmol/L) and significantly decreased intimal/medial (I/M) ratios 2, 4, and 8 weeks after aortic injury compared to euglycemic rabbits (13.7 ± 2, 21.1 + mn; 2, 32.4 ± 3 in euglycemics and 6.6 ± 1, 14 ± 2, 19 ± 5 in diabetics, respectively). The I/M for high hyperglycemic animals (glucose 286-399 mg/dL) was comparable to diabetic animals yet their serum IGF-1 levels were normal rather than depressed. Vascular IGF-1 content similarly increased upon injury in both diabetic and euglycemic animals. In diabetic animals, proliferating cell nuclear antigen (PCNA) immunostaining was present by day 1 peaked by day 5 and returned to control by day 14. In euglycemic animals, staining by day 1 continued to increase through day 14. A similar increase in mitogen-activated protein kinase (MAPK) activity occurred from day 1 through day 5 in both diabetic and euglycemic animals. This is the first demonstration of an association between MAPK activity and VSMC proliferation following vascular injury in diabetic animals as previously reported in euglycemic animals. In conclusion, this study provides evidence against a direct effect of IGF-1 in the reduction in neointimal thickening, VSMC proliferation, and MAPK activity upon catheter injury in chemically-induced diabetic rabbits.