Direct measurement of shear strain in adherent vascular endothelial cells exposed to fluid shear stress

Functional and morphological responses of endothelial cells (ECs) to fluid shear stress are thought to be mediated by several mechanosensitive molecules. However, how the force due to fluid shear stress applied to the apical surface of ECs is transmitted to the mechanosensors is poorly understood. In the present paper, we performed an analysis of an intracellular mechanical field by observation of the deformation behaviors of living ECs exposed to shear stress with a novel experimental method. Lateral images of human umbilical vein ECs before and after the onset of flow were obtained by confocal microscopy, and image correlation and finite element analysis were performed for quantitative analyses of subcellular strain due to shear stress. The shear strain of the cells changed from 1.06 ± 1.09% (mean ± SD) to 4.67 ± 1.79% as the magnitude of the shear stress increased from 2 to 10 Pa. The nuclei of ECs also exhibited shear deformation, which was similar to that observed in cytoplasm, suggesting that nuclei transmit forces from apical to intracellular components, as well as cytoskeletons. The obtained strain-stress relation resulted in a mean shear modulus of 213 Pa for adherent ECs. These results provide a mechanical perspective on the investigation of flow-sensing mechanisms of ECs.     

Adhesion of nonmetastatic and highly metastatic breast cancer cells to endothelial cells exposed to shear stress

The mechanical stimulus of shear stress has to date been neglected when studying the adhesion of cancer cells to the endothelium. Confluent monolayers of endothelial cells were subjected to either 4 or 15 hours of arterial shear stress. Adhesion of nonmetastatic (MCF-7) and highly metastatic (MDA-MB-435) human breast cancer cells was then quantified using a detachment assay carried out inside the parallel plate flow chamber. Four hours of shear stress exposure had no effect on adhesion. However, 15 hours of shear stress exposure led to marked changes in the ability of the endothelial monolayer to bind human breast cancer cells. An increase in adhesive strength was observed for nonmetastatic MCF-7 cells, while a decrease in adhesive strength was observed for highly metastatic MDA-MB-435 cells. Hence, endothelial shear stress stimulation does influence the adhesion of cancer cells to the endothelium and can have different effects on the adhesion of cancer cells with different metastatic potentials. Furthermore, adhesion of nonmetastatic and highly metastatic human breast cancer cells may be controlled by two different endothelial cell adhesion molecules that are differentially regulated by shear stress. Immunohistochemistry confirmed that shear stress did in fact differentially regulate endothelial cell adhesion molecule expression.     

Micropatterned polymer surfaces improve retention of endothelial cells exposed to flow-induced shear stress

The use of synthetic polymeric vascular grafts is limited by the thrombogenecity of most biomaterials. Efforts to reduce thrombogenicity by seeding grafts with endothelial cells, the natural non-thrombogenic lining of blood vessels, have been thwarted by flow-induced cell detachment. We hypothesized that by creating well-defined micro-textured patterns on a surface, fluid flow at the surface can be altered to create discrete regions of low shear stress. We further hypothesized that, due to reduced shear stress, these regions will serve as sanctuaries for endothelial cells and promote their retention. To test these hypotheses, well-defined micro-textured polyurethane (PU) surfaces consisting of arrays of parallel 95-micron wide and 32-micron deep channels were created using an etched silicon template and solvent casting techniques. Based on computational fluid dynamics, under identical bulk flow conditions, the average local shear stress in the channels (46 dyn/cm2) was 28% lower than unpatterned surfaces (60 dyn/cm2). When PU surfaces pre-seeded with endothelial cells (EC) were exposed to the same bulk flow rate, EC retention was significantly improved on the micropatterned surfaces relative to un-patterned surfaces (92% vs. 58% retention).     

Expression of synaptopodin in endothelial cells exposed to laminar shear stress and its role in endothelial wound healing

We examined the hypothesis that certain actin binding proteins might be upregulated by laminar shear stress (LSS) and could contribute to endothelial wound healing. Analysis of mRNA expression profiles of human umbilical vein endothelial cells under static and LSS-exposed conditions provided a list of LSS-induced actin binding proteins including synaptopodin (SYNPO) whose endothelial expression has not been previously reported. Additional studies demonstrated that SYNPO is a key mediator of endothelial wound healing because small interfering RNA-mediated suppression of SYNPO attenuated wound closure under LSS whereas overexpression of exogenous SYNPO enhanced endothelial wound closure in the absence of LSS. This study suggests that LSS-induced actin binding proteins including SYNPO may play a critical role in the endothelial wound healing stimulated by LSS.     

Regulation of VE-cadherin linkage to the cytoskeleton in endothelial cells exposed to fluid shear stress

Endothelial cells exposed to shear stress realigned and elongated in the direction of flow through the coordinated remodeling of their adherens junctions and actin cytoskeleton. The elaborate networks of VE-cadherin complexes in static cultures became more uniform and compact in response to shear. In contrast, the cortical actin present in static cultures was reorganized into numerous stress fiber bundles distributed parallel to the direction of flow. Exposure to shear did not significantly alter the expression of the junctional proteins VE-cadherin, beta-catenin, and alpha-catenin, but the composition of the junctional complexes did change. We detected a marked decrease in the alpha-catenin associated with VE-cadherin complexes in endothelial monolayers subjected to shear. This loss of alpha-catenin, the protein that links beta-catenin-bound cadherin to the actin cytoskeleton, was not due to decreased quantities of beta-catenin associated with VE-cadherin. Instead, the loss of alpha-catenin from the junctional complexes coincided with the increased tyrosine phosphorylation of beta-catenin associated with VE-cadherin. The change in beta-catenin phosphorylation closely correlated with the shear-induced loss of the protein tyrosine phosphatase SHP-2 from VE-cadherin complexes. Thus, the functional interaction of alpha-catenin with VE-cadherin-bound beta-catenin is regulated by the extent of tyrosine phosphorylation of beta-catenin. This, concomitantly, is regulated by SHP-2 associated with VE-cadherin complexes.     

Perinuclear translocation of hsp 27 in shear stress exposed human endothelial cells

Expression of hsp 27 in human umbilical vein endothelial cells exposed to a shear stress was investigated. Using immunostaining, it was concluded that shear stress results in perinuclear translocation of hsp 27. Polymerization of actin microfilaments plays an important role in this process.Revisions requested 11 October 2004; Revisions received 2 February 2005     

Unusual transduction response of progenitor-derived and mature endothelial cells exposed to laminar pulsatile shear stress

Progenitor-derived endothelial cells (PDECs) isolated from human umbilical cord blood generate a great hope in the fields of vascular tissue engineering. Endothelial cells subjected to shear stress convert mechanical stimuli into intracellular signals that affect cellular functions. It is essential to ensure that PDECs are able to sense shear stress as mature endothelial cells from human saphenous veins (HSVECs) do with mitogen-activated protein (MAP) kinase and nuclear factor (NF)-kappaB signal transduction pathways. HSVECs and PDECs were seeded on glass slides coated with gelatin and exposed to 12dyn/cm(2) in a parallel-plate flow chamber. In both cell types, shear stress activated extracellular signal-related kinase (ERK)1/2 with a rapid time course (maximum 5min) followed by a reduced phosphorylation, and p38 pathway. c-Jun N-terminal protein kinase (JNK) phosphorylation is observed only in PDECs. With respect to NF-kappaB translocation to the nucleus, the NF-kappaB pathway is not activated by flow in HSVECs and PDECs although interleukin-1alpha (IL-1alpha) activates this pathway in both cell types. In our experimental conditions, shear stress does not modify the nuclear translocation of NF-kappaB in HSVECs after IL-1alpha stimulation. It can be stated that PDECs are shear stress sensitive and capable of signal transduction as mature HSVECs are, despite the unusual transduction response of both cell types.     

Role of p120-catenin in the morphological changes of endothelial cells exposed to fluid shear stress

p120-Catenin is known to play important roles in cell-cell adhesion stability by binding to cadherin and morphological changes of cells by regulating small RhoGTPase activities. Although the expression and binding states of p120-catenin are thought to dynamically change due to morphological adaptation of endothelial cells (ECs) to fluid shear stress, these dynamics remain to be explored. In the present study, we examined the time course of changes in p120-catenin expression and its binding to vascular endothelial (VE)-cadherin in ECs exposed to shear stress. Human umbilical vein ECs began to change their morphologies at 3-6 h, and became elongated and oriented to the direction of flow at 24 h after exposure to a shear stress of 1.5 Pa. Binding and co-localization of p120-catenin with VE-cadherin at the foci of cell-cell adhesions were retained in ECs during exposure to shear stress, indicating that VE-cadherin was stabilized in the plasma membrane. In contrast, cytoplasmic p120-catenin that was dissociated from VE-cadherin was transiently increased at 3-6 h after the flow onset. These results suggest that the transient increase of cytoplasmic p120-catenin may stimulate RhoGTPase activities and act as a switch for the morphological changes in ECs in response to shear stress.     

Patterns of living beta-actin movement in wounded human coronary artery endothelial cells exposed to shear stress.

We previously demonstrated that physiologic levels of shear stress enhance endothelial repair. Cell spreading and migration, but not proliferation, were the major mechanisms accounting for the increases in wound closure rate (Albuquerque et al., 2000, Am. J. Physiol. Heart Circ. Physiol. 279, H293-H302). However, the patterns and movements of beta-actin filaments responsible for cell motility and translocation in human coronary artery endothelial cells (HCAECs) have not been previously investigated under physiologic flow. HCAECs transfected with beta-actin-GFP were cultured on type I collagen-coated coverslips. Confluent cell monolayers were subjected to laminar shear stress of 12 dynes/cm(2) for 18 h in a parallel-plate flow chamber to attain cellular alignment and then wounded by scraping with a metal spatula and subsequently exposed to a laminar shear stress of 20 dynes/cm(2) (S-W-sH) or static (S-W-sT) conditions. Time-lapse imaging and deconvolution microscopy was performed during the first 3 h after imposition of S-W-sH or S-W-sT conditions. The spatial and temporal dynamics of beta-actin-GFP motility and translocation during wound closure in HCAEC monolayers were analyzed under both conditions. Compared with HCAEC under S-W-sT conditions, our data show that HCAEC under S-W-sH conditions demonstrated greater beta-actin-GFP motility, filament and clumping patterns, and filament arcs used during cellular attachment and detachment. These findings demonstrate intriguing patterns of beta-actin organization and movement during wound closure in HCAEC exposed to physiological flow.     

Heterogeneous response of microvascular endothelial cells to shear stress

We investigated changes in calcium concentration in cultured bovine aortic endothelial cells (BAECs) and rat adrenomedulary endothelial cells (RAMECs, microvascular) in response to different levels of shear stress. In BAECs, the onset of shear stress elicited a transient increase in intracellular calcium concentration that was spatially uniform, synchronous, and dose dependent. In contrast, the response of RAMECs was heterogeneous in time and space. Shear stress induced calcium waves that originated from one or several cells and propagated to neighboring cells. The number and size of the responding groups of cells did not depend on the magnitude of shear stress or the magnitude of the calcium change in the responding cells. The initiation and the propagation of calcium waves in RAMECs were significantly suppressed under conditions in which either purinergic receptors were blocked by suramin or extracellular ATP was degraded by apyrase. Exogenously applied ATP produced similarly heterogeneous responses. The number of responding cells was dependent on ATP concentration, but the magnitude of the calcium change was not. Our data suggest that shear stress stimulates RAMECs to release ATP, causing the increase in intracellular calcium concentration via purinergic receptors in cells that are heterogeneously sensitive to ATP. The propagation of the calcium signal is also mediated by ATP, and the spatial pattern suggests a locally elevated ATP concentration in the vicinity of the initially responding cells.     

Progerin-expressing endothelial cells are unable to adapt to shear stress

Hutchinson-Gilford progeria syndrome (HGPS) is a rare premature aging disease caused by a single-point mutation in the lamin A gene, resulting in a truncated and farnesylated form of lamin A. This mutant lamin A protein, known as progerin, accumulates at the periphery of the nuclear lamina, resulting in both an abnormal nuclear morphology and nuclear stiffening. Patients with HGPS experience rapid onset of atherosclerosis, with death from heart attack or stroke as teenagers. Progerin expression has been shown to cause dysfunction in both vascular smooth muscle cells and endothelial cells (ECs). In this study, we examined how progerin-expressing endothelial cells adapt to fluid shear stress, the principal mechanical force from blood flow. We compared the response to shear stress for progerin-expressing, wild-type lamin A overexpressing, and control endothelial cells to physiological levels of fluid shear stress. Additionally, we also knocked down ZMPSTE24 in endothelial cells, which results in increased farnesylation of lamin A and similar phenotypes to HGPS. Our results showed that endothelial cells either overexpressing progerin or with ZMPSTE24 knockdown were unable to adapt to shear stress, experiencing significant cell loss at a longer duration of exposure to shear stress (3 days). Endothelial cells overexpressing wild-type lamin A also exhibited similar impairments in adaptation to shear stress, including similar levels of cell loss. Quantification of nuclear morphology showed that progerin-expressing endothelial cells had similar nuclear abnormalities in both static and shear conditions. Treatment of progerin-expressing cells and ZMPSTE24 KD cells with lonafarnib and methystat, drugs previously shown to improve HGPS nuclear morphology, resulted in improvements in adaptation to shear stress. Additionally, the prealignment of cells to shear stress before progerin-expression prevented cell loss. Our results demonstrate that changes in nuclear lamins can affect the ability of endothelial cells to properly adapt to shear stress.     

Local mechanical properties measured by atomic force microscopy for cultured bovine endothelial cells exposed to shear stress

Morphology and mechanical properties of cultured endothelial cells were measured, using a novel atomic force microscope (AFM) system, developed in our laboratory, in conjunction with an inverted confocal laser scanning microscope. We used this system to examine endothelial cell both in static cultures and exposed to a shear stress of 2 Pa. Initially, the three-dimensional topography of a cell was measured by the AFM and a location was selected for the subsequent measurement of the mechanical response of the cell. The surface of statically cultured cell was smooth. The cell height was not altered by the exposed duration of shear stress. A relationship between external force, F, and the indentation depth, delta, was obtained for several different locations on a cell. This force-indentation response was modelled using a quadratic equation, F = adelta2 + bdelta, indicating that two parameters, a and b, will be constants which are representative of the mechanical response. Endothelial cells cultured at static conditions demonstrated a polygonal shape and less stiff mechanical characteristics around the nucleus compared to those at peripheral regions. The stiffness of the endothelial cells exposed to shear stress increased with the duration time of exposure. At 6-h exposures, the stiffness was higher at upstream side of the cell than the downstream side. However, after 24-h exposure, the stiffness was similar on both sides of the cell. These changes in the stiffness of endothelial cells when exposed to shear stress were suggested to correspond with the distribution of stress fibers in the cell.     

Orientation of apical and basal actin stress fibers in isolated and subconfluent endothelial cells as an early response to cyclic stretching

We investigated the response of apical and basal actin stress fibers (SFs) and its dependency on cell confluency for endothelial cells subjected to cyclic stretching. Porcine aortic endothelial cells from the 2nd and 5th passages were transferred to a fibronectin-coated silicone chamber with 5000-8000 cells/cm2 (isolated condition), positioning the cells apart, or with 25,000-27,000 cells/cm2 (subconfluent condition), allowing cell-to-cell contact. The substrate was stretched cyclically by 0.5 Hz for 2 h with a peak strain on the substrate that was 15% in the stretch direction and -4% in the transverse direction. The actin filaments (AFs) were stained with rhodamine phalloidin and their orientations were examined under a confocal laser scanning microscope. In the basal region, SFs formed in all of the cells under both the isolated and subconfluent conditions. We observed an average of 5 and 9 SFs per cell under the isolated and subconfluent conditions, respectively, in the fluorescent images of the apical region. We also observed cells that were bush-like without apical AFs or apical SFs. On average, the SFs in the subconfluent cells oriented in the direction of minimal strain, while the SFs in the isolated cells oriented in the direction of a 2% compressive strain. These results suggest that such differential response may be due to differences in the transmission of mechanical stretching to the central and apical regions of the cell through the SFs. We also speculate that cell-to-cell contact might change the strength, orientation, and anchorage of apical AFs and play a critical role in mechanical signal transduction.     

CD34+ cells homing: quantitative expression of adhesion molecules and adhesion of CD34+ cells to endothelial cells exposed to shear stress

To investigate the function of the main adhesion receptors (CD62L, CD49d, CD49e, CD11b and CD18) on CD34+ cells during homing, their expression was quantified by flow cytometry using calibration beads. CD34+ cells were isolated from bone-marrow (BM), cord blood (CB) or peripheral blood (PB) from patients with myeloma. As this process might mimic the mature leukocyte migration, we also observed the effect of exposing endothelial cells to shear stress (7 dyn/cm(2)) on the adhesion of CB CD34+ cells.The proportion of CD34+/CD62L+ cells was greater in PB than in BM (p<0.05). Likewise, we found a significantly greater expression of CD62L receptor on PB cells compared to BM cells (p<0.05) and on BM cells compared to CB cells (p<0.05). The proportions of CD34+/CD49d+ cells and CD34+/CD49e+ cells were significantly higher in the BM and CB than in PB. However, no significant difference in CD49d or CD49e antigen densities was observed. The beta_2 integrins (CD11b and CD18) receptors are also implicated in CD34+ cells homing to BM. No significant variation in CD34+/CD11b+ and CD34+/CD18+ cells frequency was noted. However quantitative analysis revealed that CD18 was more strongly expressed on BM cells than on PB and CB cells.The adhesion assay showed that fluid flow may favour a firm adhesion of CB CD34+ cells to endothelial cells whereas static conditions just allowed CD34+ cells sedimentation.In conclusion, quantitative expression of the main receptors on CD34+ cells indicates that the three main sources of CD34+ cells currently used for transplantation have neither the same phenotype nor the same number of antigenic sites for a receptor. So, we hypothesize that migrational capacity of these cells might be different. Moreover, it seems that shear stress could favor adhesion of CD34+ cells to endothelial cells.     

Secretome of human endothelial cells under shear stress

Endothelial cells are exposed to different types of shear stress which triggers the secretion of subsets of proteins. In this study, we analyzed the secretome of endothelial cells under static, laminar, and oscillatory flow. To differentiate between endogenously expressed and added proteins, isolated human umbilical vein endothelial cells were labeled with l-Lysine-(13)C(6),(15)N(2) and l-Arginine-(13)C(6),(15)N(4). Shear stress was applied for 24 h using a cone-and-plate viscometer. Proteins from the supernatants were isolated, trypsinized, and finally analyzed using LC-MS/MS (LTQ). Under static control condition 395 proteins could be identified, of which 78 proteins were assigned to the secretome according to Swiss-Prot database. Under laminar shear stress conditions, 327 proteins (83 secreted) and under oscillatory shear stress 507 proteins (79 secreted) were measured. We were able to identify 6 proteins specific for control conditions, 8 proteins specific for laminar shear stress, and 5 proteins specific for oscillatory shear stress. In addition, we identified flow-specific secretion patterns like the increased secretion of cell adhesion proteins and of proteins involved in protein binding. In conclusion, the identification of shear stress specific secreted proteins (101 under different flow conditions) emphasizes the role of endothelial cells in modulating the plasma composition according to the physiological requirements.