Role of shear stress direction in endothelial mechanotransduction

Fluid shear stress due to blood flow can modulate functions of endothelial cells (ECs) in blood vessels by activating mechano-sensors, signaling pathways, and gene and protein expressions. Laminar shear stress with a definite forward direction causes transient activations of many genes that are atherogenic, followed by their down-regulation; laminar shear stress also up-regulates genes that inhibit EC growth. In contrast, disturbed flow patterns with little forward direction cause sustained activations of these atherogenic genes and enhancements of EC mitosis and apoptosis. In straight parts of the arterial tree, laminar shear stress with a definite forward direction has anti-atherogenic effects. At branch points, the complex flow patterns with little net direction are atherogenic. Thus, the direction of shear stress has important physiological and pathophysiological effects on vascular ECs.     

Inhibition of capillary endothelial cell growth by pericytes and smooth muscle cells

Morphological studies of developing capillaries and observations of alterations in capillaries associated with pathologic neovascularization indicate that pericytes may act as suppressors of endothelial cell (EC) growth. We have developed systems that enable us to investigate this possibility in vitro. Two models were used: a co-culture system that allowed direct contact between pericytes and ECs and a co-culture system that prevented physical contact but allowed diffusion of soluble factors. For these studies, co-cultures were established between bovine capillary ECs and the following growth-arrested cells (hereafter referred to as modulating cells): pericytes, smooth muscle cells (SMCs), fibroblasts, epithelial cells, and 3T3 cells. The modulating cell type was growth arrested by treatment with mitomycin C before co-culture with ECs. In experiments where cells were co-cultured directly, the effect of co-culture on EC growth was determined by comparing the mean number of cells in the co-cultures to the mean for each cell type (EC and modulating cell) cultured separately. Since pericytes and other modulating cells were growth arrested, any cell number change in co-cultures was due to EC growth. In the co-cultures, pericytes inhibited all EC proliferation throughout the 14-d time course; similar levels of EC inhibition were observed in SMC-EC co-cultures. Co-culture of ECs with fibroblasts, epithelial cells, and 3T3 cells significantly stimulated EC growth over the same time course (30-192% as compared to EC cultured alone). To determine if cell contact was required for inhibition, cells were co-cultured using Millicell chambers (Millipore Corp., Bedford, MA), which separated the cell types by 1-2 mm but allowed the exchange of diffusible materials. There was no inhibition of EC proliferation by pericytes or SMCs in this co-culture system. The influence of the cell ratios on observed inhibition was assessed by co-culturing the cells at EC/pericyte ratios of 1:1, 2:1, 5:1, 10:1, and 20:1. Comparable levels of EC inhibition were observed at ratios from 1:1 to 10:1. When the cells were co-cultured at a ratio of 20 ECs to 1 pericyte, inhibition of EC growth at 3 d was similar to that observed at other ratios. However, at higher ratios, the inhibition diminished so that by the end of the time course the co-cultured ECs were growing at the same rate as the controls. These results suggest that pericytes and SMCs can modulate EC growth by a mechanism that requires contact or proximity. We postulate that similar interactions may operate to modulate vascular growth in vivo.     

A model for studying the effect of shear stress on interactions between vascular endothelial cells and smooth muscle cells

Vascular endothelial cells (ECs) are constantly subjected to blood flow-induced shear stress and the influences of neighboring smooth muscle cells (SMCs). In the present study, a coculture flow system was developed to study the effect of shear stress on EC-SMC interactions. ECs and SMCs were separated by a porous membrane with only the EC side subjected to the flow condition. When ECs were exposed to a shear stress of 12 dynes/cm2 for 24 h, the cocultured SMCs tended to orient perpendicularly to the flow direction. This perpendicular orientation of the cocultured SMCs to flow direction was not observed when ECs were exposed to a shear stress of 2 dynes/cm2. Under the static condition, long and parallel actin bundles were observed in the central regions of the cocultured SMCs, whereas the actin filaments localized mainly at the periphery of the cocultured ECs. After 24 h of flow application, the cocultured ECs displayed very long, well-organized, parallel actin stress fibers aligned with the flow direction in the central regions of the cells. Immunostaining of platelet endothelial cell adhesion molecule-1 confirmed the elongation and alignment of the cocultured ECs with the flow direction. Coculture with SMCs under static condition induced EC gene expressions of growth-related oncogene-alpha and monocyte chemotactic protein-1, and shear stress was found to abolish these SMC-induced gene expressions. Our results suggest that shear stress may serve as a down-regulator for the pathophysiologically relevant gene expression in ECs cocultured with SMCs.     

Testicular Sertoli cells influence the proliferation and immunogenicity of co-cultured endothelial cells

The major problem of the application of endothelial cells (ECs) in transplantation is the lack of proliferation and their immunogenicity. In this study, we co-cultured ECs with Sertoli cells to monitor whether Sertoli cells can influence the proliferation and immunogenicity of co-cultured ECs. Sertoli cells were isolated from adult testicular tissue. ECs were divided into the control group and the experimental group, which included three sub-groups co-cultured with 1 × 10³, 1 × 10⁴ or 1 × 10⁵ cell/ml of Sertoli cells. The growth and proliferation of ECs were observed microscopically, and the expression of vascular endothelial growth factor (VEGF) receptor-2 (KDR) was examined by Western blotting. In another experiment, ECs were divided into the control group, the single culture group and the co-culture group with the optimal concentration of Sertoli cells. After INF-γ and TNF-α were added to the culture medium, MHC II antigen expression was detected by immunofluorescence staining and western blotting; interleukin (IL)-6, IL-8 and soluble intercellular adhesion molecule (sICAM) were measured in the culture medium by ELISA. We demonstrated that 1 × 10⁴ cell/ml Sertoli cells promoted the proliferation of co-cultured ECs more dramatically than that in other groups (P < 0.05). Western blotting showed that 1 × 10⁴ cell/ml of the Sertoli cells was most effective in the up-regulation of KDR expression in the co-cultured ECs (P < 0.05). Sertoli cells can effectively suppress INF-γ-induced MHC II antigen expression in co-cultured ECs compared with single culture group (P < 0.05). TNF-α induced the expression of IL-6, IL-8 and sICAM in ECs. When co-cultured with Sertoli cells, their expressions were significantly lower than in the EC single culture group (P < 0.05). ECs co-cultured with Sertoli cells also did not significantly increase the stimulation index of spleen lymphocytes compared to the single culture group (P < 0.05). Our results suggested that co-culturing with Sertoli cells can significantly promote the proliferation of ECs, accelerate post-transplant angiogenesis, while reduce EC immunogenicity and stimulus to lymphocytes.     

Co-culture of endothelial cells and smooth muscle cells affects gene expression of angiogenic factors

Endothelial cells (EC) are in contact with the underlying smooth muscle cells (SMC). The interactions between EC and SMC in the vessel wall are considered to be involved in the control of growth and function of blood vessels. A co-culture system of EC and SMC and a method for separation of these cells was developed in order to investigate whether the presence of physical contact between EC and SMC affected the gene expression of angiogenic factors. Human EC and SMC were prepared from the great saphenous veins. Autologous EC were added on top of the confluent layer of SMC. After 72 h in co-culture, the EC were magnetically separated from SMC with the use of superparamagnetic beads. RT-PCR products for bFGF, bFGFR, VEGF, PDGF-AA, PDGF-BB, TGF-beta, and beta-actin were analyzed to study the mRNA expressions. The protein level of selected factors was studied by ELISA technique. In co-cultured SMC there was a statistically significant higher gene expression of VEGF, PDGF-AA, PDGF-BB, and TGF-beta and significant lower gene expression of bFGF and its receptor than in single cultured SMC. The protein level of PDGF-BB and TGF-beta was also significantly higher in co-cultured SMC. In co-cultured EC there were no significant differences in gene expression of PDGF-AA, PDGF-BB, and TGF-beta compared with single cultured EC. The gene expression and protein synthesis of VEGF was significantly higher in co-cultured EC. The findings from the present study suggest that cell-cell interactions of EC and SMC affect the gene and protein expression of angiogenic factors.     

Improved arterial wall model by coculturing vascular endothelial and smooth muscle cells

We have constructed an in vitro arterial wall model by coculturing bovine arterial endothelial cells (ECs) and smooth muscle cells (SMCs). When ECs were seeded directly over SMCs and cocultured in an ordinary culture medium, ECs grew sparsely and did not form a confluent monolayer. Addition of ascorbic acid to the culture medium at concentrations greater than 50 μg/ml increased the production of type IV collagen by the SMCs, and ECs formed a confluent monolayer covering the entire surface of SMCs. Histological studies showed that the thickness of the cell layer composed of ECs and SMCs increased with increasing duration of coculture. This arterial wall model, prepared by our method, may serve as a simple and good in vitro model to study the effects of factors such as biological chemicals and shear stress on cell proliferation and other physiological functions of arterial walls.     

ET-1 and NOS III gene expression regulation by plaque-free and plaque-prone hemodynamic conditions

Both plaque-free and plaque-prone hemodynamic environments induce an increase in the oxidative state of endothelial cells (ECs), whereas differential gene expression regulation was described in cells exposed to these conditions. In order to investigate the role of the increased oxidative state in flow-regulation of gene expression, we first exposed EC to non-pulsed unidirectional shear stress. These conditions only slightly increases ECs oxidative state and endothelin-1 (ET-1) mRNA expression, whereas endothelial nitric oxide synthase (NOS III) mRNA level were significantly up-regulated. On the contrary, both ET-1 and NOS III gene expression were significantly induced in EC exposed to pulsed-unidirectional flow (plaque-free). Only ET-1 gene expression was up-regulated by oscillatory flow (plaque-prone). Moreover, use of an antioxidant only partially inhibited NOS III gene up-regulation by unidirectional flow, whereas it completely abrogated ET-1 gene up-regulation by unidirectional and oscillatory flows. Thus suggesting that mechanical forces regulate gene expression in ECs both via oxidative stress-dependent and -independent mechanisms.     

Cooperative Effects of Matrix Stiffness and Fluid Shear Stress on Endothelial Cell Behavior

Arterial hemodynamic shear stress and blood vessel stiffening both significantly influence the arterial endothelial cell (EC) phenotype and atherosclerosis progression, and both have been shown to signal through cell-matrix adhesions. However, the cooperative effects of fluid shear stress and matrix stiffness on ECs remain unknown. To investigate these cooperative effects, we cultured bovine aortic ECs on hydrogels matching the elasticity of the intima of compliant, young, or stiff, aging arteries. The cells were then exposed to laminar fluid shear stress of 12 dyn/cm². Cells grown on more compliant matrices displayed increased elongation and tighter EC-cell junctions. Notably, cells cultured on more compliant substrates also showed decreased RhoA activation under laminar shear stress. Additionally, endothelial nitric oxide synthase and extracellular signal-regulated kinase phosphorylation in response to fluid shear stress occurred more rapidly in ECs cultured on more compliant substrates, and nitric oxide production was enhanced. Together, our results demonstrate that a signaling cross talk between stiffness and fluid shear stress exists within the vascular microenvironment, and, importantly, matrices mimicking young and healthy blood vessels can promote and augment the atheroprotective signals induced by fluid shear stress. These data suggest that targeting intimal stiffening and/or the EC response to intima stiffening clinically may improve vascular health.     

Elongation of Confluent Endothelial Cells in Culture: The Importance of Fields of Force in the Associated Alterations of Their Cytoskeletal Structure

Studies using either animal models or in vitro flow systems have shown that the shape of large-vessel endothelial cells (ECs) was sensitive to the amplitude of the flow imposed on them. In order to better understand the morphological changes experienced by ECs when exposed to physical forces such as shear stress, the mechanical integrity of confluent bovine aortic ECs (BAECs) was anisotropically perturbed using the five following types of experiments: (i) slicing and partial scraping of BAEC monolayers; (ii) culture of BAECs on narrow strips of adhesive plastic; (iii) incubation of confluent BAECs with media containing low Ca²⁺ concentrations; (iv) culture of ECs on top of rectangular collagen gels; and (v) exposure of BAECs to laminar steady shear stress. In all five experimental systems, BAECs exhibited an elongated morphology and aligned their major axes in specific directions. In addition, a preferential alignment of actin microfilaments, vimentin intermediate filaments, and streaks of vinculin with the major axes of the cells often occurred concomitantly with BAEC elongation. In all five systems, the elongation of ECs was analyzed in terms of a mechanical deformation borne by the cytoskeleton, and possibly caused by anisotropic distribution of the forces experienced by the cell structure. In addition, the strain-stress and stiffness-stress relationships characterizing the elongation of BAECs exposed to steady flow were qualitatively similar to those computed for the uniaxial deformation of a spherical geodesic. Our findings suggest that the cytoskeleton of ECs plays an important role in the transduction of those forces which cause an elongation of ECs.     

Short-Term Shear Stress Induces Rapid Actin Dynamics in Living Endothelial Cells

Hemodynamic shear stress guides a variety of endothelial phenotype characteristics, including cell morphology, cytoskeletal structure, and gene expression profile. The sensing and processing of extracellular fluid forces may be mediated by mechanotransmission through the actin cytoskeleton network to intracellular locations of signal initiation. In this study, we identify rapid actin-mediated morphological changes in living subconfluent and confluent bovine aortic endothelial cells (ECs) in response to onset of unidirectional steady fluid shear stress (15 dyn/cm²). After flow onset, subconfluent cells exhibited dynamic edge activity in lamellipodia and small ruffles in the downstream and side directions for the first 12 min; activity was minimal in the upstream direction. After 12 min, peripheral edge extension subsided. Confluent cell monolayers that were exposed to shear stress exhibited only subtle increases in edge fluctuations after flow onset. Addition of cytochalasin D to disrupt actin polymerization served to suppress the magnitude of flow-mediated actin remodeling in both subconfluent confluent EC monolayers. Interestingly, when subconfluent ECs were exposed to two sequential flow step increases (1 dyn/cm² followed by 15 dyn/cm² 12 min later), actin-mediated edge activity was not additionally increased after the second flow step. Thus, repeated flow increases served to desensitize mechanosensitive structural dynamics in the actin cytoskeleton.     

内皮细胞生长状态对血管平滑肌细胞增生迁移的影响

实验通过建立细胞共培养体系,探讨内皮细胞生长状态对血管平滑肌细胞增生迁移的影响及机制。检测指标包括~3H-TdR掺入、细胞周期、细胞迁移计数和α-SM-actin mRNA表达。结果显示,融合生长内皮使平滑肌细胞~3H-TdR掺入量明显降低,增加平滑肌细胞停留在G_0/G_1期的比例,上调平滑肌细胞α-SM-actin mRNA表达;而对数生长内皮细胞使平滑肌细胞~3H-TdR掺入量明显升高,促进平滑肌细胞由 G_0/G_1期进入G_2/M和S期,下调平滑肌细胞α-SM-actin mRNA表达。对照组平滑肌细胞在基础状态下存在少量迁移,对数增殖内皮细胞组平滑肌迁移数比对照组增高约4倍(P<0.01),而融合生长内皮细胞组平滑肌迁移数仅为对照组的0.5倍(P<0.05)。结果提示内皮细胞生长状态不同,对平滑肌细胞生物学特性的影响也不同,增殖期内皮明显促进平滑肌细胞增生迁移、下调平滑肌细胞α-SM-actin mRNA表达。     

LXN deficiency regulates cytoskeleton remodelling by promoting proteolytic cleavage of Filamin A in vascular endothelial cells

Endothelial cells (ECs) respond to blood shear stress by changing their morphology is important for maintaining vascular homeostasis. Studies have documented a relationship between endothelial cell shape and the stress flow, and however, the mechanism underlying this cytoskeletal rearrangement due to shear stress remains uncertain. In this paper, we demonstrate that laminar shear stress (LSS) significantly reduces latexin (LXN) expression in ECs. By using siRNA and cell imaging, we demonstrated that LXN knockdown results in the morphologic change and F-actin remodelling just like what LSS does in ECs. We further demonstrate that LXN interacts with Filamin A (FLNA) and regulates FLNA proteolytic cleavage and nuclei translocation. By constructing LXN^-/- mice and ApoE^-/-LXN^-/- double knockout mice, we evaluated the effect of LXN knockout on aortic endothelium damage in mice. We found that LXN deficiency significantly improves vascular permeability, vasodilation and atherosclerosis in mice. Our findings provide confident evidence, for the first time, that LXN is a novel regulator for morphological maintenance of ECs, and LXN deficiency has a protective effect on vascular homeostasis. This provides new strategies and drug targets for the treatment of vascular diseases.     

Rac1 mediates laminar shear stress-induced vascular endothelial cell migration

The migration of endothelial cells (ECs) plays an important role in vascular remodeling and regeneration. ECs are constantly subjected to shear stress resulting from blood flow and are able to convert mechanical stimuli into intracellular signals that affect cellular behaviors and functions. The aim of this study is to elucidate the effects of Rac1, which is the member of small G protein family, on EC migration under different laminar shear stress (5.56, 10.02, and 15.27 dyn/cm²). The cell migration distance under laminar shear stress increased significantly than that under the static culture condition. Especially, under relative high shear stress (15.27 dyn/cm²) there was a higher difference at 8 h (P < 0.01) and 2 h (P < 0.05) compared with static controls. RT-PCR results further showed increasing mRNA expression of Rac1 in ECs exposed to laminar shear stress than that exposed to static culture. Using plasmids encoding the wild-type (WT), an activated mutant (Q61L), and a dominant-negative mutant (T17N), plasmids encoding Rac1 were transfected into EA.hy 926 cells. The average net migration distance of Rac1Q61L group increased significantly, while Rac1T17N group decreased significantly in comparison with the static controls. These results indicated that Rac1 mediated shear stress-induced EC migration. Our findings conduce to elucidate the molecular mechanisms of EC migration induced by shear stress, which is expected to understand the pathophysiological basis of wound healing in health and diseases.     

MAPKs (ERK1/2, p38) and AKT can be phosphorylated by shear stress independently of platelet endothelial cell adhesion molecule-1 (CD31) in vascular endothelial cells

PECAM-1 (CD31) is a member of the Ig superfamily of cell adhesion molecules and is expressed on endothelial cells (EC) as several circulating blood elements including platelets, polymorphonuclear leukocytes, monocytes, and lymphocytes. PECAM-1 tyrosine phosphorylation has been observed following mechanical stimulation of EC but its role in mechanosensing is still incompletely understood. The aim of this study was to investigate the involvement of PECAM-1 in signaling cascades in response to fluid shear stress (SS) in vascular ECs. PECAM-1-deficient (KO) and PECAM-reconstituted murine microvascular ECs, 50 and 100% confluent bovine aortic EC (BAEC), and human umbilical vein EC (HUVEC) transfected with antisense PECAM-1 oligonucleotides were exposed to oscillatory SS (14 dynes/cm2) for 0, 5, 10, 30 or 60 min. The tyrosine phosphorylation level of PECAM-1 immunoprecipitated from SS-stimulated PECAM-reconstituted, but not PECAM-1-KO, murine ECs increased. Although PECAM-1 was phosphorylated in 100% confluent BAEC and HUVEC, its phosphorylation level in 50% confluent BAECs or HUVEC was not detected by SS. Likewise PECAM-1 phosphorylation was robust in the wild type and scrambled-transfected HUVEC but not in the PECAM-1 antisense-HUVEC. ERK(1/2), p38 MAPK, and AKT were activated by SS in all cell types tested, including the PECAM-1-KO murine ECs, 50% confluent BAECs, and HUVEC transfected with antisense PECAM-1. This suggests that PECAM-1 may not function as a major mechanoreceptor for activation of MAPK and AKT in ECs and that there are likely to be other mechanoreceptors in ECs functioning to detect shear stress and trigger intercellular signals.     

Heparan sulfate proteoglycan mediates shear stress-induced endothelial gene expression in mouse embryonic stem cell-derived endothelial cells

It has been shown that shear stress plays a critical role in promoting endothelial cell (EC) differentiation from embryonic stem cell (ESC)-derived ECs. However, the underlying mechanisms mediating shear stress effects in this process have yet to be investigated. It has been reported that the glycocalyx component heparan sulfate proteoglycan (HSPG) mediates shear stress mechanotransduction in mature EC. In this study, we investigated whether cell surface HSPG plays a role in shear stress modulation of EC phenotype. ESC-derived EC were subjected to shear stress (5 dyn/cm(2)) for 8 h with or without heparinase III (Hep III) that digests heparan sulfate. Immunostaining showed that ESC-derived EC surfaces contain abundant HSPG, which could be cleaved by Hep III. We observed that shear stress significantly increased the expression of vascular EC-specific marker genes (vWF, VE-cadherin, PECAM-1). The effect of shear stress on expression of tight junction protein genes (ZO-1, OCLD, CLD5) was also evaluated. Shear stress increased the expression of ZO-1 and CLD5, while it did not alter the expression of OCLD. Shear stress increased expression of vasodilatory genes (eNOS, COX-2), while it decreased the expression of the vasoconstrictive gene ET1. After reduction of HSPG with Hep III, the shear stress-induced expression of vWF, VE-cadherin, ZO-1, eNOS, and COX-2, were abolished, suggesting that shear stress-induced expression of these genes depends on HSPG. These findings indicate for the first time that HSPG is a mechanosensor mediating shear stress-induced EC differentiation from ESC-derived EC cells.