Apelin attenuates the osteoblastic differentiation of vascular smooth muscle cells

Vascular calcification, which results from a process osteoblastic differentiation of vascular smooth muscle cells (VSMCs), is a major risk factor for cardiovascular morbidity and mortality. Apelin is a recently discovered peptide that is the endogenous ligand for the orphan G-protein-coupled receptor, APJ. Several studies have identified the protective effects of apelin on the cardiovascular system. However, the effects and mechanisms of apelin on the osteoblastic differentiation of VSMCs have not been elucidated. Using a culture of calcifying vascular smooth muscle cells (CVMSCs) as a model for the study of vascular calcification, the relationship between apelin and the osteoblastic differentiation of VSMCs and the signal pathway involved were investigated. Alkaline phosphatase (ALP) activity and osteocalcin secretion were examined in CVSMCs. The involved signal pathway was studied using the extracellular signal-regulated kinase (ERK) inhibitor, PD98059, the phosphatidylinositol 3-kinase (PI3-K) inhibitor, LY294002, and APJ siRNA. The results showed that apelin inhibited ALP activity, osteocalcin secretion, and the formation of mineralized nodules. APJ protein was detected in CVSMCs, and apelin activated ERK and AKT (a downstream effector of PI3-K). Suppression of APJ with siRNA abolished the apelin-induced activation of ERK and Akt. Furthermore, inhibition of APJ expression, and the activation of ERK or PI3-K, reversed the effects of apelin on ALP activity. These results showed that apelin inhibited the osteoblastic differentiation of CVSMCs through the APJ/ERK and APJ/PI3-K/AKT signaling pathway. Apelin appears to play a protective role against arterial calcification.     

Neuron-like differentiation of adipose tissue-derived stromal cells and vascular smooth muscle cells

Adipose tissue-derived stromal cells (ADSC) have previously been shown to possess stem cell properties such as transdifferentiation and self-renewal. Because future clinical applications are likely to use these adult stem cells in an autologous fashion, we wished to establish and characterize rat ADSC for pre-clinical tests. In the present study, we showed that rat ADSC expressed stem cell markers CD34 and STRO-1 at passage 1 but only STRO-1 at passage 3. These cells could also be induced to differentiate into adipocytes, smooth muscle cells, and neuron-like cells, the latter of which expressed neuronal markers S100, nestin, and NF70. Isobutylmethylxanthine (IBMX), indomethacin (INDO), and insulin were the active ingredients in a previously established neural induction medium (NIM); however, here we showed that IBMX alone was as effective as NIM in the induction of morphological changes as well as neuronal marker expression. Finally, we showed that vascular smooth muscle cells could also be induced by either NIM or IBMX to differentiate into neuron-like cells that expressed NF70.     

Cell-cell interactions mediate the response of vascular smooth muscle cells to substrate stiffness

The vessel wall experiences progressive stiffening with age and the development of cardiovascular disease, which alters the micromechanical environment experienced by resident vascular smooth muscle cells (VSMCs). In vitro studies have shown that VSMCs are sensitive to substrate stiffness, but the exact molecular mechanisms of their response to stiffness remains unknown. Studies have also shown that cell-cell interactions can affect mechanotransduction at the cell-substrate interface. Using flexible substrates, we show that the expression of proteins associated with cell-matrix adhesion and cytoskeletal tension is regulated by substrate stiffness, and that an increase in cell density selectively attenuates some of these effects. We also show that cell-cell interactions exert a strong effect on cell morphology in a substrate-stiffness dependent manner. Collectively, the data suggest that as VSMCs form cell-cell contacts, substrate stiffness becomes a less potent regulator of focal adhesion signaling. This study provides insight into the mechanisms by which VSMCs respond to the mechanical environment of the blood vessel wall, and point to cell-cell interactions as critical mediators of VSMC response to vascular injury.     

EGF-induced adipose tissue mesothelial cells undergo functional vascular smooth muscle differentiation

Recent studies suggested that the post-natal mesothelium retain differentiative potential of the embryonic mesothelium, which generates fibroblasts and vascular smooth muscle cells (VSMCs), in developing coelomic organs via epithelial-to-mesenchymal transition (EMT). Whether adult mesothelial cells (MCs) are able to give rise to functional VSMCs in vitro and which are the factors and mechanisms directing this process remain largely unknown. Here, we isolated adipose tissue MCs (ATMCs) from adult mice, and demonstrated that ATMCs cultured in a serum-containing media supplemented with epidermal growth factor (EGF) efficiently increased both their proliferation and EMT above levels found in only serum-containing media cultures. EGF-induced ATMCs gained phosphorylation of the EGF receptor and activated simultaneously ILK/Erk1/2, PI3K/Akt and Smad2/3-dependent pathways. Sequential subculture onto collagen-I surface efficiently improved their vasculogenic EMT towards cells featuring VSMCs (α-SMA, calponin, caldesmon, SM22α, desmin, SM-MHC, smoothelin-B and PDGFR-β) that could actively contract in response to receptor and non-receptor-mediated vasoactive agonists. Overall, our results indentify EGF signalling as a robust vasculogenic inductive pathway for ATMCs, leading to their transdifferentiation into functional VSMC-like cells.Stem cell-based pro-angiogenic therapies hold great promise to revascularize ischemic tissues in patients with acute myocardial infarction or chronic limb ischemia.^{1, 2, 3, 4} The plasticity of pluripotent embryonic stem cells (ESCs) and induced pluripotent stem (iPS) cells allows their easy derivation towards Isl-1⁺ multipotent cardiovascular progenitors that clonally give rise to cardiomyocytes, vascular smooth muscle cells (VSMCs) and endothelial cells,^{5, 6} the major cell types of cardiovascular tissues. Safety concerns, differentiation efficiency, overcoming immune rejection and the inherent tumourigenicity of pluripotent stem cells, however, remains a major issue hindering their clinical application^{7, 8} and will require the validation of efficient gating strategies allowing the purification of ESC- and iPS-derived multipotent cardiovascular progenitors for future use in cardiovascular regenerative medicine.Adult tissues retain a small subset of resident undifferentiated stem cells that can self-renew asymmetrically to generate committed progenitors for the replenishment of the different cellular phenotypes that are lost during normal tissue turnover. Although adult stem cells display restricted lineage differentiation potential and limited proliferative capacities, their lack of tumourigenicity has attracted great attention for establishing safe cell-based regenerative therapies.^{9, 10, 11} Stromal mesenchymal stem cells (MSCs) are multipotent stem cells residing around the vasculature of virtually all organs and vascularized tissues.^{12, 13} It is now widely accepted that MSCs display significant immunosuppressive activity¹⁴ and angiogenic potential and improve long-term neovascularization outcomes of ischemic tissues⁴ mainly through their paracrine secretion of pro-angiogenic factors such as bFGF, EGF, PDGF-BB, VEGF and TGFβ1, rather by a direct incorporation into the neovasculature as it was initially thought.¹⁵ Despite the extensive focus on the pro-angiogenic potential of MSCs, the identification of new sources of adult stem cells with neovascularization potential remains a goal that is under research.The adult mesothelium is a squamous epithelial layer of mesoderm origin lining coelomic cavities and the visceral organs housed within. Cumulating evidence indicates that the adult mesothelium is a rich reservoir of mesothelial cells (MCs) with pro-vasculogenic potential.^{16, 17, 18, 19} The adult mesothelium was thought to be a ‘quiescent tissue'' solely endowed with physiological functions such as to maintain serosal integrity and inflammation and to secrete large amounts of ‘lubricants'' to favour the correct sliding of opposite serosal layers (i.e., for the beating heart). A recent report, however, set a breakthrough in this concept showing that the post-natal mesothelium remains a source of progenitor cells giving rise to fibroblasts and VSMCs in visceral organs of healthy mice.¹⁹ Furthermore, it was also shown that MCs give rise to hepatic stellate cells and myofibroblasts in injured liver.²⁰ Another striking example recently demonstrates that the mesothelium is a source for adipocytes that often physically attach to the visceral organs.²¹The findings that adult MCs of human and rodent origin can recapitulate in vitro an epithelial-to-mesenchymal transition (EMT) and acquire SMCs markers in response to provasculogenic and morphogenic growth factors (i.e, TGF-β1, PDGF-BB, bFGF and EGF)^{10, 16, 17, 22, 23, 24} led to the hypothesis that adult MCs may retain the differentiative potential of embryonic MCs, which were shown to generate fibroblasts and VSMCs in the developing heart, lung, gut and liver.^{25, 26, 27, 28, 29, 30} We recently pushed onward this concept by demonstrating that adult mouse uterine MCs (UtMCs) subjected to provasculogenic culture undergo EMT towards progenitors that can subsequently acquire properties of differentiated VSMCs upon sequential subculture.¹⁸ Despite these exiting findings uncovering an unexpected mesodermal plasticity and vasculogenic potential for adult MCs, the factors and mechanisms inducing and directing their vasculogenic differentiation towards a functional VSMCs phenotype remain largely unknown.The visceral adipose tissue (AT) is composed of several adipose depots, including mesenteric, epididymal white AT and perirenal depots. In humans, the major visceral AT depot corresponds to the greater omentum, a large fold of the peritoneum.³¹ In mice, the major visceral AT depots are attached to the uterus and ovaries in females and the epididyme and testes in males. Its tremendous remodelling capacity allows its rapid adaptation to an excess food intake through adipocyte hyperplasia, a process that is closely coupled with neovascularization.^{32, 33}The expansion and neovascularization potential of the visceral AT is likely to indicate that its surrounding mesothelium retain strong vasculogenic potential, a particularity that should make this tissue a valuable source of cells for cardiovascular regenerative therapy.Herein, we show that a gentle trypsinization of the adult mouse uterine AT can efficiently and reliably detach a highly enriched population of AT mesothelial cells (ATMCs) from its covering mesothelium. ATMCs cultured in a high glucose-based media (BMe) with serum and 50 ng/ml of epidermal growth factor (EGF; termed BMe+50EGF) could actively proliferate and acquire EMT, progenitor and cardiovascular developmental markers. Upon repeated subculture onto collagen type I-coated surface, ATMCs drastically reduced their proliferation rate while improving in turn their transdifferentiation towards fibroblastic cells displaying molecular and functional characteristics of differentiated VSMCs.     

Sympathetic innervation promotes vascular smooth muscle differentiation

The sympathetic nervous system (SNS) is an important modulator of vascular smooth muscle (VSM) growth and function. Several lines of evidence suggest that the SNS also promotes VSM differentiation. The present study tests this hypothesis. Expression of smooth muscle myosin (SM2) and alpha-actin were assessed by Western analysis as indexes of VSM differentiation. SM2 expression (normalized to alpha-actin) in adult innervated rat femoral and tail arteries was 479 +/- 115% of that in noninnervated carotid arteries. Expression of alpha-actin (normalized to GAPDH or total protein) in 30-day-innervated rat femoral arteries was greater than in corresponding noninnervated femoral arteries from guanethidine-sympathectomized rats. SM2 expression (normalized to alpha-actin) in neonatal femoral arteries grown in vitro for 7 days in the presence of sympathetic ganglia was greater than SM2 expression in corresponding arteries grown in the absence of sympathetic ganglia. In VSM-endothelial cell cultures grown in the presence of dissociated sympathetic neurons, alpha-actin (normalized to GAPDH) was 300 +/- 66% of that in corresponding cultures grown in the absence of neurons. This effect was inhibited by an antibody that neutralized the activity of transforming growth factor-beta2. All of these data indicate that sympathetic innervation increased VSM contractile protein expression and thereby suggest that the SNS promotes and/or maintains VSM differentiation.     

Different alpha-adrenoceptors mediate migration of vascular smooth muscle cells and adventitial fibroblasts in vitro

Norepinephrine directly induces growth of the vascular wall, which may involve not only proliferation of smooth muscle cells (SMCs) and adventitial fibroblasts (AFBs) but also augmentation of their migration. To test this hypothesis, growth-arrested SMCs and AFBs from rat aorta were exposed to norepinephrine. Norepinephrine caused dose-dependent migration of both cell types that was dependent on chemotaxis. In contrast, platelet-derived growth factor (PDGF)-BB, used as a positive control, stimulated both chemotaxis and chemokinesis. Only alpha(1D)-adrenoceptors (AR) and alpha(2)-AR antagonists inhibited norepinephrine migration of SMCs, whereas norepinephrine migration of AFBs was only inhibited by alpha(1A)-AR and alpha(1B)-AR antagonists; beta-AR blockade was without effect. Norepinephrine and PDGF-BB were additive for AFB, but not SMC, migration. Stimulation of migration was reversed at high norepinephrine concentrations (10 microM); this inhibition was mediated by alpha(2)- and beta-ARs in AFBs but not in SMCs. Thus norepinephrine induces migration of SMCs and AFBs via different alpha-ARs. This action may participate in wall remodeling and norepinephrine potentiation of injury-induced intimal lesion growth.     

Taurine inhibits osteoblastic differentiation of vascular smooth muscle cells via the ERK pathway

Vascular calcification develops within atherosclerotic lesions and results from a process similar to osteogenesis. Taurine is a free β-amino acid and plays an important physiological role in mammals. We have recently demonstrated that vascular smooth muscle cells (VSMCs) express a functional taurine transporter. To evaluate the possible role of taurine in vascular calcification, we assessed its effects on osteoblastic differentiation of VSMCs in vitro. The results showed that taurine inhibited the β-glycerophosphate-induced osteoblastic differentiation of VSMCs as evidenced by both the decreasing alkaline phosphate (ALP) activity and expression of the core binding factor α1 (Cbfα1). Taurine also activated the extracellular signal-regulated protein kinase (ERK) pathway. Inhibition of ERK pathway reversed the effect of taurine on ALP activity and Cbfα1 expression. These results suggested that taurine inhibited osteoblastic differentiation of vascular cells via the ERK pathway.     

Linking phospholipase C isoforms with differentiation function in human vascular smooth muscle cells

The phosphoinositol-phospholipase C (PLC) family of enzymes consists of a number of isoforms, each of which has different cellular functions. PLCγ₁ is primarily linked to tyrosine kinase transduction pathways, whereas PLCδ₁ has been associated with a number of regulatory proteins, including those controlling the cell cycle. Recent studies have shown a central role of PLC in cell organisation and in regulating a wide array of cellular responses. It is of importance to define the precise role of each isoform, and how this changes the functional outcome of the cell. Here we investigated differences in PLC isoform levels and activity in relation to differentiation of human and rat vascular smooth muscle cells. Using Western blotting and PLC activity assay, we show that PLCδ₁ and PLCγ₁ are the predominant isoforms in randomly cycling human vascular smooth muscle cells (HVSMCs). Growth arrest of HVSMCs for seven days of serum deprivation was consistently associated with increases in PLCδ₁ and SM α-actin, whereas there were no changes in PLCγ₁ immuno-reactivity. Organ culture of rat mesenteric arteries in serum free media (SFM), a model of de-differentiation, led to a loss of contractility as well as a loss of contractile proteins (SM α-actin and calponin) and PLCδ₁, and no change in PLCγ₁ immuno-reactivity. Taken together, these data indicate that PLCδ₁ is the predominant PLC isoform in vascular smooth muscle, and confirm that PLCδ₁ expression is affected by conditions that affect the cell cycle, differentiation status and contractile function.     

Methoxyestradiols mediate the antimitogenic effects of estradiol on vascular smooth muscle cells via estrogen receptor-independent mechanisms

Estrogen receptors (ERs) are widely held to mediate the ability of 17 beta-estradiol (estradiol) to attenuate injury-induced proliferation of vascular smooth muscle cells (VSMCs) leading to vascular lesions. However, recent findings that estradiol prevents injury-induced vascular lesion formation in knock-out mice lacking either ER alpha or ER beta seriously challenge this concept. Here we report that the local metabolism of estradiol to methoxyestradiols, endogenous metabolites of estradiol with no affinity for ERs, is responsible for the ER-independent inhibitory effects of locally applied estradiol on rat VSMC growth. These finding imply that local vascular estradiol metabolism may be an important determinant of the cardiovascular protective effects of circulating estradiol. Thus, interindividual differences, either genetic or acquired, in the vascular metabolism of estradiol may define a given female's risk of cardiovascular disease and influence the cardiovascular benefit she receives from estradiol replacement therapy in the postmenopausal state. These findings also imply that nonfeminizing estradiol metabolites may confer cardiovascular protection in both women and men.     

27nt-miRNA对间充质干细胞向血管平滑肌细胞分化的影响

为探讨27nt-miRNA对间充质干细胞向血管平滑肌细胞分化影响,构建27nt-miRNA过表达、反义序列Anti-27nt-miRNA以及阴性对照的表达质粒,慢病毒包装后分别转染人脐带间充质干细胞(hUCMSC),加入Ⅳ型胶原诱导hUCMSC定向分化为血管平滑肌细胞。四唑盐(MTT)比色法检测分化后细胞活力,免疫细胞化学染色法检测分化后细胞SM22α(兔抗平滑肌22α,smooth muscle 22α)的表达,Western印迹法和RT-PCR检测分化后细胞内的SMA (兔抗平滑肌肌动蛋白,smooth muscle actin) mRNA、SM 22α mRNA及其蛋白质表达情况。经检测,27nt-miRNA过表达分化组与阴性对照组相比,细胞活力下降20.48%(P0.05),SMA mRNA、SM22α mRNA及其蛋白质表达量明显升高(P0.05);而Anti-27nt-miRNA分化组细胞活力上升了18.07%(P0.05),SMA mRNA、SM22α mRNA及其蛋白质表达量下降(P0.05)。综上所述,27nt-miRNA能够促进间充质干细胞向血管平滑肌细胞分化,并且抑制分化后的细胞活力。     

RANKL is a downstream mediator for insulin-induced osteoblastic differentiation of vascular smooth muscle cells

Several reports have shown that circulating insulin level is positively correlated with arterial calcification; however, the relationship between insulin and arterial calcification remains controversial and the mechanism involved is still unclear. We used calcifying vascular smooth muscle cells (CVSMCs), a specific subpopulation of vascular smooth muscle cells that could spontaneously express osteoblastic phenotype genes and form calcification nodules, to investigate the effect of insulin on osteoblastic differentiation of CVSMCs and the cell signals involved. Our experiments demonstrated that insulin could promote alkaline phosphatase (ALP) activity, osteocalcin expression and the formation of mineralized nodules in CVSMCs. Suppression of receptor activator of nuclear factor κB ligand (RANKL) with small interfering RNA (siRNA) abolished the insulin-induced ALP activity. Insulin induced the activation of extracellular signal-regulated kinase (ERK)1/2, mitogen-activated protein kinase (MAPK) and RAC-alpha serine/threonine-protein kinase (Akt). Furthermore, pretreatment of human osteoblasts with the ERK1/2 inhibitor PD98059, but not the phosphoinositide 3-kinase (PI3K) inhibitor, LY294002, or the Akt inhibitor, 1L-6-hydroxymethyl-chiro-inositol 2-(R)-2-O-methyl-3-O-octadecylcarbonate (HIMO), abolished the insulin-induced RANKL secretion and blocked the promoting effect of insulin on ALP activities of CVSMCs. Recombinant RANKL protein recovered the ALP activities decreased by RANKL siRNA in insulin-stimulated CVSMCs. These data demonstrated that insulin could promote osteoblastic differentiation of CVSMCs by increased RANKL expression through ERK1/2 activation, but not PI3K/Akt activation.     

Ghrelin attenuates the osteoblastic differentiation of vascular smooth muscle cells through the ERK pathway

Vascular calcification results from osteoblastic differentiation of vascular smooth muscle cells (VSMCs) and is a major risk factor for cardiovascular events. Ghrelin is a newly discovered bioactive peptide that acts as a natural endogenous ligand of the growth hormone secretagog receptor (GHSR). Several studies have identified the protective effects of ghrelin on the cardiovascular system, however research on the effects and mechanisms of ghrelin on vascular calcification is still quite rare. In this study, we determined the effect of ghrelin on osteoblastic differentiation of VSMCs and investigated the mechanism involved using the two universally accepted calcifying models of calcifying vascular smooth muscle cells (CVSMCs) and beta-glycerophosphate (beta-GP)-induced VSMCs. Our data demonstrated that ghrelin inhibits osteoblastic differentiation and mineralization of VSMCs due to decreased alkaline phosphatase (ALP) activity, Runx2 expression, bone morphogenetic protein-2 (BMP-2) expression and calcium content. Further study demonstrated that ghrelin exerted this suppression effect via an extracellular signal-related kinase (ERK)-dependent pathway and that the suppression effect of ghrelin was time dependent and dose dependent. Furthermore, inhibition of the growth hormone secretagog receptor (GHSR), the ghrelin receptor, by siRNA significantly reversed the activation of ERK by ghrelin. In conclusion, our study suggests that ghrelin may inhibit osteoblastic differentiation of VSMCs through the GHSR/ERK pathway.     

Involvement of BK channel in differentiation of vascular smooth muscle cells induced by mechanical stretch

The differentiation of vascular smooth muscle cells (VSMCs), which are exposed to mechanical stretch in vivo, plays an important role in vascular remodeling during hypertension. Here, we demonstrated the mechanobiological roles of large conductance calcium and voltage-activated potassium (BK) channels in this process. In comparison with 5% stretch (physiological), 15% stretch (pathological) induced the de-differentiation of VSMCs, resulting in significantly decreased expressions of VSMC markers, i.e., α-actin, calponin and SM22. The activity of BK channels, assessed by patch clamp recording, was significantly increased by 15% stretch and was accompanied by an increased alternative splicing of BK channel α-subunit at the stress axis-regulated exons (STREX). Furthermore, transfection of whole BK or STREX-deleted BK plasmids revealed that STREX was important for BK channels to sense mechanical stretch. Using thapsigargin (TG) which induces endoplasmic reticulum (ER) stress, and xbp1-targeted siRNA transfection which blocks ER stress, the results revealed that ER stress was contribute to stretch-induced alternative splicing of STREX. Our results suggested that during hypertension, pathological stretch may induce the ER stress in VSMCs, which affects the alternative splicing and activity of BK channels, and subsequently modulates VSMC differentiation.     

Impedance analysis of renal vascular smooth muscle cells

Impedance of renal vascular smooth muscle cells (VSMCs) cultured on microelectrodes was measured by electric cell-substrate impedance sensing. Changes in measured impedance as a function of frequency were compared with the calculated values obtained from an extended cell-electrode model to estimate the junctional resistance, distance between the ventral cell surface and the substratum, and apical and basolateral membrane capacitances of renal VSMCs. This cell-electrode model was derived to accommodate the slender and rectangular shape of VSMCs. The calculated changes in impedance (Z_cal) based on the model agreed well with the experimental measurement (Z_exp), and the percentage error defined as |(Z_cal – Z_exp)/Z_exp| was 1.0%. To test the sensitivity of the new model for capturing changes in cell-cell and cell-substrate interactions induced by changes in cellular environment, we then applied this model to analyze timpedance changes induced by an integrin binding peptide in renal VSMCs. Our result demonstrates that integrin binding peptide decreases junctional resistance between cells, increases the distance between the basolateral cell surface and substratum, and increases the apical membrane capacitance, whereas the basolateral membrane capacitance stays relatively stable. This model provides a generic approach for impedance analysis of cell layers composed of slender, rectangular cells. electric cell-substrate impedance sensing; cell attachment; cell adhesion; extracellular matrix; integrin     

血管平滑肌细胞的分化与血管内壁的构建

血管平滑肌细胞(vascular smooth muscle cells,VSMCs)的发育与血管壁的构建是目前相关领域中的重要学科前沿．国内外同行的工作多集中在血管发育初始阶段内皮细胞及其前体细胞在血管新生中的作用、调节因素及生物学机制．VSMCs参与血管壁早期构建,特别是VSMCs的募集与分化机制已经成为血管新生研究中的一个新领域． 本期发表的《 抑制Rac1蛋白活化阻碍胚胎发育早期血管新生 》(见696～701页)报道了韩雅玲教授及其合作者在这一领域取得的最新研究结果．Rac1是真核细胞内重要的一类信号传递分子,在细胞信号传递过程中发挥分子开关作用．他们采用胚胎干细胞(ESCs)为模型,建立稳定表达持续型Rac1和显性失活型Rac1编码序列的小鼠ESCs并制备胚胎小体,诱导分化后观察其对内皮细胞分化和迁移的影响,发现抑制Rac1可以干扰血管内皮细胞连接成血管网状结构,细胞骨架F-actin排列紊乱,细胞的迁移受到明显抑制,表明Rac1在胚胎早期血管发育过程中与内皮细胞的迁移有关[1]． 近年来,韩雅玲教授及其研究集体在VSMCs发育与血管构建、胚胎干细胞来源的拟胚体血管平滑肌发育与血管新生机制以及胚胎主动脉VSMCs起源等方面开展了研究,取得了一系列有价值的成果[2～11],可能为闭塞性和增生性血管病的发生及防治提供理论依据和候选基因．详见“相关链接”．     

Regulation of vascular smooth muscle cells by micropatterning

Vascular smooth muscle cells (SMCs) undergo morphological and phenotypic changes when cultured in vitro. To investigate whether SMC morphology regulates SMC functions, bovine aortic SMCs were grown on micropatterned collagen strips (50-, 30-, and 20-microm wide). The cell shape index and proliferation rate of SMCs on 30- and 20-microm strips were significantly lower than those on non-patterned collagen (control), and the spreading area was decreased only for cells patterned on the 20-microm strips, suggesting that SMC proliferation is dependent on cell shape index. The formation of actin stress fibers and the expression of alpha-actin were decreased in SMCs on the 20- and 30-microm collagen strips. SMCs cultured on micropatterned biomaterial poly-(D,L-lactide-co-glycolide) (PLGA) with 30-microm wide grooves also showed lower proliferation rate and less stress fibers than SMCs on non-patterned PLGA. Our findings suggest that micropatterned matrix proteins and topography can be used to control SMC morphology and that elongated cell morphology decreases SMC proliferation but is not sufficient to promote contractile phenotype.     

Stem cells, vascular smooth muscle cells and atherosclerosis

Stem cells have the ability to differentiate into a variety of cells to replace dead cells or to repair tissue. Recently, accumulating evidence indicates that mechanical forces, cytokines and other factors can influence stem cell differentiation into vascular smooth muscle cells (SMCs). In developmental process, SMCs originate from several sources, which show a great heterogenicity in different vessel walls. In adult vessels, SMCs display a less proliferative nature, but are altered in response to risk factors for atherosclerosis. Traditional view on SMC origins in atherosclerotic lesions is challenged by the recent findings that stem cells and smooth muscle progenitors contribute to the development of atherosclerotic lesions. Vascular progenitor cells circulating in human blood and the presence of adventitia in animals are recent discoveries, but the source of these cells is still unknown. The present review gives an update on the progress of stem cell and SMC research in atherosclerosis, and discusses possible mechanisms of stem/progenitor cell differentiation that contribute to the disease process.