Microtopography and flow modulate the direction of endothelial cell migration

The migration of vascular endothelial cells under flow can be modulated by the addition of chemical or mechanical stimuli. The aim of this study was to investigate how topographic cues derived from a substrate containing three-dimensional microtopography interact with fluid shear stress in directing endothelial cell migration. Subconfluent bovine aortic endothelial cells were seeded on fibronectin-coated poly(dimethylsiloxane) substrates patterned with a combinatorial array of parallel and orthogonal microgrooves ranging from 2 to 5 microm in width at a constant depth of 1 microm. During a 4-h time-lapse observation in the absence of flow, the majority of the prealigned cells migrated parallel to the grooves with the distribution of their focal adhesions (FAs) depending on the groove width. No change in this migratory pattern was observed after the cells were exposed to moderate shear stress (13.5 dyn/cm(2)), irrespective of groove direction with respect to flow. After 4-h exposure to high shear stress (58 dyn/cm(2)) parallel to the grooves, the cells continued to migrate in the direction of both grooves and flow. By contrast, when microgrooves were oriented perpendicular to flow, most cells migrated orthogonal to the grooves and downstream with flow. Despite the change in the migration direction of the cells under high shear stress, most FAs and actin microfilaments maintained their original alignment parallel to the grooves, suggesting that topographic cues were more effective than those derived from shear stress in guiding the orientation of cytoskeletal and adhesion proteins during the initial exposure to flow.     

Oriented Schwann cell growth on microgrooved surfaces

Silicon wafers bearing microgrooved surfaces with various groove width, spacing, and depth were fabricated using microlithography. The orientation of rat Schwann cells along the direction of the grooves was measured at 24 h after seeding the cells. When the width/spacing of the grooves was fixed at 10/10 microm, the mean percentage of aligned cells was 12% for grooves of 0.5 microm depth, 15% for those of 1 microm depth, and 26% for those of 1.5 microm depth (P < 0.05). When the depth of grooves was fixed at 1.5 microm, the mean percentage of aligned cells increased from 26% for width/spacing 10/10 microm, to 33% for 10/20 microm or 20/10 microm, and up to 41% for 20/20 microm (P < 0.05). On the surface with grooves of width/spacing/depth = 20/20/1.5 microm and modified by laminin, the alignment at 24 h approached 60%, versus 51% for collagen-coated surface and 41% for uncoated surface (P < 0.05). At 48 h after seeding, about 66% of the cells were aligned on the above laminin-modified surface. The groove depth influenced orientation of Schwann cells significantly. The cell alignment on 20/20/3 microm microgrooved poly(D,L-lactide-co-glycolide) 90:10 (PLGA) surfaces transferred from silicon reached 72% at 48 h and 92% at 72 h (P < 0.05). Coating this surface with laminin enhanced cell alignment only in short term (67% vs. 62% at 24 h, P < 0.05). The cell alignment guided by surface microgrooves was time dependent.     

Fibroblast responses to cyclic mechanical stretching depend on cell orientation to the stretching direction

Fibroblasts in intact tendons align with stretching direction, but they tend to orient randomly in healing tendons. Therefore, a question arises: Do fibroblast responses to mechanical stretching depend on their orientation? To address this question, human patellar tendon fibroblasts were grown in custom-made silicone dishes that possess microgrooved culture surfaces. The direction of the microgrooves was either parallel or normal to the direction of cyclic uniaxial stretching. Fibroblasts grown in these microgrooves had a polar morphology and oriented along the direction of the microgrooves regardless of the stretching conditions. Tendon fibroblasts expressed higher levels of alpha-smooth muscle actin when they were oriented parallel to the stretching direction than when they were oriented normal to the stretching direction. Also, cyclic stretching of the fibroblasts perpendicular to their orientation induced a higher activity level of secretory phospholipase A(2) compared with stretching of the cells parallel to their orientation. Thus, these results show that fibroblast responses to mechanical stretching depend on cell orientation to the stretching direction.     

A new approach to study fibroblast migration

This paper presents a new approach to study cell migration. Human tendon fibroblasts were plated on silicone membranes coated with 10 microg/ml ProNectin-F. The silicone surfaces were micro-fabricated with parallel microgrooves, with 10 microm ridge and groove width, and 3 microm groove depth. Fibroblasts grown in the microgrooves had an elongated shape and oriented along the microgroove direction. They also moved along the same direction instead of "random walk" when cells migrate on smooth culture surfaces. In response to TGF-beta1 (5 ng/ml) treatment, these fibroblasts on the microgrooved surfaces were differentiated into myofibroblasts, as judged by an elevated expression of alpha-smooth muscle actin (alpha-SMA), a specific marker for myofibroblasts. Moreover, these myofibroblasts were found to be approximately 30% less motile compared to that of untreated fibroblasts. Thus, use of microgrooved surface may be an effective approach to detect difference in cell motility because cell migration on the microgrooved surface is one dimensional and hence easier to be quantified than two-dimensional random movement on conventional smooth culture surfaces.     

Alignment and proliferation of MC3T3-E1 osteoblasts in microgrooved silicone substrata subjected to cyclic stretching

Previous studies have shown that many types of cells align in microgrooves in static cultures. However, whether cells remain aligned and also proliferate in microgrooves under stretching conditions has not been determined. We grew MC3T3-E1 osteoblasts in deformable silicone dishes containing microgrooves oriented in the stretch direction. We found that with or without 4% stretching, cells aligned in microgrooves of all sizes, with the groove and ridge widths ranged from 1 to 6microm, but the same groove depth of about 1.6microm. In addition, actin cytoskeleton and nuclei became highly aligned in the microgrooves with and without 4% cyclic stretching. To further examine whether MC3T3-E1 osteoblasts proliferate in microgrooves with cyclic stretching, we grew the cells in six-well silicone dishes containing microgrooves in three wells and smooth surfaces in other three wells. After 4% cyclic stretching for 3, 4, and 7 days, we found that cell numbers in the microgrooves were not significantly different (p>0.05) from those on the smooth surface (p>0.05). Taken together, these results show that MC3T3-E1 osteoblasts can align and proliferate in microgrooves with 4% cyclic stretching. We suggest that the silicone microgrooves can be a useful tool to study the phenotype of MC3T3-E1 osteoblasts under controlled substrate strains. The silicone microgrooves can also be useful for delivering defined substrate strains to other adherent cells in cultures.     

Cell orientation determines the alignment of cell-produced collagenous matrix

In healing ligaments and tendons, the cells are not aligned and collagen matrix is not organized as in normal tissues. In addition, the mechanical properties of the tissues are abnormal. We hypothesized that the lack of alignment of the collagen matrix results from random orientation of the cells seen in the healing area. To test this hypothesis, a novel in vitro model was used in which the orientation of cells could be controlled via microgrooves, and alignment of the collagen matrix formed by these cells could be easily observed. It is known that cells align uniformly along the direction of microgrooves; therefore MC3T3-E1 cells, which produce large amounts of collagen, were grown on silicone membranes with parallel microgrooves (10 microm wide x 3 microm deep) in the surface. As a control, the same cells were also grown on smooth silicone membranes. Cells on both the microgrooved and smooth silicone surfaces produced a layer of readily visible collagen matrix. Immunohistochemical staining showed that the matrix consisted of abundant type I collagen. Polarized light microscopy of the collagen matrix revealed the collagen fibers to be parallel to the direction of the microgrooves, whereas the collagen matrix produced by the randomly oriented cells on the smooth membranes was disorganized. Thus, the results of this study suggest that the orientation of cells affects the organization of the collagenous matrix produced by the cells. The results also suggest that orienting cells along the longitudinal direction of healing ligaments and tendons may lead to the production of aligned collagenous matrix that more closely represents the uninjured state. This may enhance the mechanical properties of healing ligaments and tendons.     

Native extracellular matrix orientation determines multipotent vascular stem cell proliferation in response to cyclic uniaxial tensile strain and simulated stent indentation

Cardiovascular disease is the leading cause of death worldwide, with multipotent vascular stem cells (MVSC) implicated in contributing to diseased vessels. MVSC are mechanosensitive cells which align perpendicular to cyclic uniaxial tensile strain. Within the blood vessel wall, collagen fibers constrain cells so that they are forced to align circumferentially, in the primary direction of tensile strain. In these experiments, MVSC were seeded onto the medial layer of decellularized porcine carotid arteries, then exposed to 10%, 1 Hz cyclic tensile strain for 10 days with the collagen fiber direction either parallel or perpendicular to the direction of strain. Cells aligned with the direction of the collagen fibers regardless of the orientation to strain. Cells aligned with the direction of strain showed an increased number of proliferative Ki67 positive cells, while those strained perpendicular to the direction of cell alignment showed no change in cell proliferation. A bioreactor system was designed to simulate the indentation of a single, wire stent strut. After 10 days of cyclic loading to 10% strain, MVSC showed regions of densely packed, highly proliferative cells. Therefore, MVSC may play a significant role in in-stent restenosis, and this proliferative response could potentially be controlled by controlling MVSC orientation relative to applied strain.     

Dependence of alignment direction on magnitude of strain in esophageal smooth muscle cells

The response of cells in vitro to mechanical forces has been the subject of much research using devices to exert controlled mechanical stimulation on cultured cells or isolated tissue. In this study, esophageal smooth muscle cells were seeded on flexible polyurethane membranes to form a confluent cell layer. The cells were then subjected to uniform cyclic stretch of varying magnitudes at a frequency of approximately five cycles per minute in a custom made mechatronic bioreactor, providing similar strains experienced in the in vivo mechanical environment of the esophagus. The results show that the orientation response is dependent on the magnitude of cyclic stretch applied. Smooth muscle cells showed parallel alignment to the force direction at low cyclic strains (2%) compared to the hill‐valley morphology of static controls. At higher strains (5% and 10% magnitude), the cells exhibited a consistent alignment perpendicular to the strain. To our knowledge, this is the first time that the alignment direction's dependence on strain magnitude has been demonstrated. MTS analysis indicated that cell metabolism was reduced when mechanical strain was applied, and proliferation was inhibited by mechanical strain. Protein expression indicates a decrease in smooth muscle α‐actin, indicative of changes in cell phenotype, an increase in vimentin, which is associated with increased cell motility, and an increase in desmin, indicating differentiation in stimulated cells. Biotechnol. Bioeng. 2009;102: 1703–1711. © 2008 Wiley Periodicals, Inc.     

The effects of continuous and discontinuous groove edges on cell shape and alignment

Nanofabricated model surfaces and digital image analysis of cell shape were used to address the importance of a continuous sharp edge in the alignment of cells to shallow surface grooves. The grooved model surfaces had either continuous or discontinuous edges of various depths (40-400 nm) but identical surface chemistry and groove/ridge dimensions (15 microm wide). Epithelial cells were cultured on the model surfaces for 10 and 24 h. Fluorescence microscopy combined with image analysis were used to quantify cell area and alignment and to make cell shape classifications of individual cells. The degrees of alignment of cells and the percentages of elongated cell classes increased with groove depth on samples with continuous grooves. Two main differences, with regard to cell response, were observed between the continuous and discontinuous grooved surfaces. First, significantly fewer cells aligned to surface grooves with discontinuous edges than to grooves with continuous edges. Second, there were lower percentages of the elongated cell classes on discontinuous grooves than on continuous ones. We concluded that grooved surfaces with continuous edges are more potent in aligning and inducing elongated cells. The results from the present study suggest that a mechanism of alignment involving orientation along a continuous edge is likely.     

Fibroblasts on micromachined substrata orient hierarchically to grooves of different dimensions

Contact guidance was studied by light, scanning (SEM) and transmission electron microscopy (TEM) in cultures of human gingival fibroblasts cultured on grooved surfaces. The grooves were originally produced in silicon wafers by micromachining, a process which is based on the methods used to fabricate microelectronic components, and the grooved surfaces were then replicated in Epon. Micromachining enables precise control of groove depth, groove spacing, and groove shape to be obtained. In silicon wafers with appropriate crystal orientation, a second smaller set of grooves, called the minor grooves, is found on the floor of the major grooves. The minor grooves are oriented at a 54 degree angle to the major grooves, so that cells cultured on such surfaces are concurrently exposed to grooves of different dimensions which direct cell migration in different directions. Marked fibroblast alignment with the major grooves was observed both within the grooves and in the intervening flat ridges between the grooves. In addition, shallow and closely spaced grooves in epon or titanium-coated polymer or silicon were also capable of orienting fibroblasts. Although the minor grooves were able to orient fibroblasts in the absence of any other orienting influence, when fibroblasts were concurrently exposed to major and minor grooves the cells aligned themselves with the major grooves. TEM showed that the cellular filamentous cytoskeletal elements reflected the orientation of the cell as a whole. Fibroblasts on grooved substrata appeared to have more filopodia and to round up more frequently than fibroblasts cultured on flat substrata. It is suggested that both the mechanical properties of the cytoskeleton as well as the durability of the cellular attachment to groove edges may play a role in the contact guidance effected by grooved surfaces produced by micromachining.     

Biophysical regulation of histone acetylation in mesenchymal stem cells

Histone deacetylation and acetylation are catalyzed by histone deacetylase (HDAC) and histone acetyltransferase, respectively, which play important roles in the regulation of chromatin remodeling, gene expression, and cell functions. However, whether and how biophysical cues modulate HDAC activity and histone acetylation is not well understood. Here, we tested the hypothesis that microtopographic patterning and mechanical strain on the substrate regulate nuclear shape, HDAC activity, and histone acetylation. Bone marrow mesenchymal stem cells (MSCs) were cultured on elastic membranes patterned with parallel microgrooves 10 μm wide that kept MSCs aligned along the axis of the grooves. Compared with MSCs on an unpatterned substrate, MSCs on microgrooves had elongated nuclear shape, a decrease in HDAC activity, and an increase of histone acetylation. To investigate anisotropic mechanical sensing by MSCs, cells on the elastic micropatterned membranes were subjected to static uniaxial mechanical compression or stretch in the direction parallel or perpendicular to the microgrooves. Among the four types of loads, compression or stretch perpendicular to the microgrooves caused a decrease in HDAC activity, accompanied by the increase in histone acetylation and slight changes of nuclear shape. Knocking down nuclear matrix protein lamin A/C abolished mechanical strain-induced changes in HDAC activity. These results demonstrate that micropattern and mechanical strain on the substrate can modulate nuclear shape, HDAC activity, and histone acetylation in an anisotropic manner and that nuclear matrix mediates mechanotransduction. These findings reveal a new mechanism, to our knowledge, by which extracellular biophysical signals are translated into biochemical signaling events in the nucleus, and they will have significant impact in the area of mechanobiology and mechanotransduction.     

The response of primary articular chondrocytes to micrometric surface topography and sulphated hyaluronic acid-based matrices

Understanding the response of chondrocytes to topographical cues and chemical patterns could provide invaluable information to advance the repair of chondral lesions. We studied the response of primary chondrocytes to nano- and micro-grooved surfaces, and sulphated hyaluronic acid (HyalS). Cells were grown on grooves ranging from 80 nm to 9 microm in depth, and from 2 microm to 20 microm in width. Observations showed that the cells did not spread appreciably on any groove size, or alter morphology or F-actin organization, although cells showed accelerated movement on 750 nm deep grooves in comparison to flat surfaces. On chemical patterns, the cells migrated onto, and preferentially attached to, HyalS and showed a greater degree of spreading and F-actin re-arrangement. This study shows that 750 nm deep grooves and sulphated hyaluronic acid elicit responses from primary chondrocytes, and this could have implications for the future direction of cartilage reconstruction and orthopaedic treatments in general.     

Motor Responses to Polarized Light and Gravity Sensing in Euglena gracilis*†

SYNOPSIS. Euglena gracilis strain Z has a motor response which results in orientation with respect to the polarization of a light stimulus. Cells swim preferentially in a direction perpendicular to the plane of polarization of the stimulus. If 2 polarized stimuli are given from opposite directions, the preferred direction is, under certain circumstances, at right angles to the directions of both stimuli. Euglena also preferentially assumes an orientation that is at right angles to the force of gravity. The relationships between these responses and phototactic movements oriented with respect to the direction of the stimulus are discussed.     

A mechanistic motor-clutch model that explains cell shape dynamics to cyclic stretch

Many cells in the body experience cyclic mechanical loading, which can impact cellular processes and morphology. In vitro studies often report that cells reorient in response to cyclic stretch of their substrate. To explore cellular mechanisms involved in this reorientation, a computational model was developed by adapting previous computational models of the actin–myosin–integrin motor-clutch system developed by others. The computational model predicts that under most conditions, actin bundles align perpendicular to the direction of applied cyclic stretch, but under specific conditions, such as low substrate stiffness, actin bundles align parallel to the direction of stretch. The model also predicts that stretch frequency impacts the rate of reorientation and that proper myosin function is critical in the reorientation response. These computational predictions are consistent with reports from the literature and new experimental results presented here. The model suggests that the impact of different stretching conditions (stretch type, amplitude, frequency, substrate stiffness, etc.) on the direction of cell alignment can largely be understood by considering their impact on cell–substrate detachment events, specifically whether detachments preferentially occur during stretching or relaxing of the substrate.     

A thermodynamically motivated model for stress-fiber reorganization

We present a model for stress-fiber reorganization and the associated contractility that includes both the kinetics of stress-fiber formation and dissociation as well as the kinetics of stress-fiber remodeling. These kinetics are motivated by considering the enthalpies of the actin/myosin functional units that constitute the stress fibers. The stress, strain and strain rate dependence of the stress-fiber dynamics are natural outcomes of the approach. The model is presented in a general 3D framework and includes the transport of the unbound stress-fiber proteins. Predictions of the model for a range of cyclic loadings are illustrated to rationalize hitherto apparently contrasting observations. These observations include: (1) For strain amplitudes around 10 % and cyclic frequencies of about 1 Hz, stress fibers align perpendicular to the straining direction in cells subjected to cyclic straining on a 2D substrate while the stress fibers align parallel with the straining direction in cells constrained in a 3D tissue. (2) At lower applied cyclic frequencies, stress fibers in cells on 2D substrates display no sensitivity to symmetric applied strain versus time waveforms but realign in response to applied loadings with a fast lengthening rate and slow shortening. (3) At very low applied cyclic frequencies (on the order of mHz) with symmetric strain versus time waveforms, cells on 2D substrates orient perpendicular to the direction of cyclic straining above a critical strain amplitude.     

Articular chondrocyte passage number: influence on adhesion, migration, cytoskeletal organisation and phenotype in response to nano- and micro-metric topography

The isolation and culture of articular chondrocytes is a prerequisite of their use in tissue engineering, but prolonged culture and passaging is associated with de-differentiation. In this paper we studied the influence of nanometric and micrometric grooves (85 nm to 8 microm in depth and 2 microm to 20 microm in width) on 1st and 2nd passage ovine chondrocytes since our earlier findings indicate that primary cells are not affected by such features. 1st and 2nd passage chondrocytes cultured on grooved substrata showed a polarisation of cell shape parallel to the groove long axis and F-actin condensations were evident at groove ridge boundaries. An increase in cell migration with increasing groove depth was observed. Both passages of chondrocytes maintained type II collagen expression, but to a lesser degree in 2nd. This study demonstrates that passage number alters the response of chondrocytes to micrometric and nanometric topography, and could be important in ex vivo cartilage engineering.     

Regulation of stretch-induced JNK activation by stress fiber orientation

Cyclic mechanical stretch associated with pulsatile blood pressure can modulate cytoskeletal remodeling and intracellular signaling in vascular endothelial cells. The aim of this study was to evaluate the role of stretch-induced actin stress fiber orientation in intracellular signaling involving the activation of c-jun N-terminal kinase (JNK) in bovine aortic endothelial cells. A stretch device was designed with the capability of applying cyclic uniaxial and equibiaxial stretches to cultured endothelial cells, as well as changing the direction of cyclic uniaxial stretch. In response to 10% cyclic equibiaxial stretch, which did not result in stress fiber orientation, JNK activation was elevated for up to 6 h. In response to 10% cyclic uniaxial stretch, JNK activity was only transiently elevated, followed by a return to basal level as the actin stress fibers became oriented perpendicular to the direction of stretch. After the stress fibers had aligned perpendicularly and the JNK activity had subsided, a 90-degree change in the direction of cyclic uniaxial stretch reactivated JNK, and this activation again subsided as stress fibers became re-oriented perpendicular to the new direction of stretch. Disrupting actin filaments with cytochalasin D blocked the stress fiber orientation in response to cyclic uniaxial stretch and it also caused the uniaxial stretch-induced JNK activation to become sustained. These results suggest that stress fiber orientation perpendicular to the direction of stretch provides a mechanism for both structural and biochemical adaptation to cyclic mechanical stretch.     

Synergistic and Hierarchical Adhesive and Topographic Guidance of BHK Cells

Guided cell movement is a fundamental process in development and regeneration. We have used microengineered culture substrates to study the interaction between model topographic and adhesive guidance cues in steering BHK cell orientation. Grooves 0.1, 0.5, 1.0, 3.0, and 6.0 μm deep together with pitch-matched aminosilane tracks 5, 12, 25, 50, and 100 μm wide were fabricated on fused silica substrates using photolithographic and dry-etching techniques. The cues were presented to the cells individually, simultaneously in parallel and orthogonally opposed. Cells aligned most strongly to 25-μm-wide adhesive tracks and to 5-μm-wide, 6-μm-deep grooves. Stress fibers and vinculin were found to align with the adhesive tracks and to the grooves and ridges. Cell alignment was profoundly enhanced on all surfaces that presented both cues in parallel. Cells were able to switch alignment from ridges to grooves, and vice versa, depending on the location of superimposed adhesive tracks. Cells aligned preferentially to adhesive tracks superimposed orthogonally over grooves of matched pitch, traversing numerous grooves and ridges. The strength of the cues was more closely matched on narrower 3- and 6-μm-deep gratings with cells showing evidence of alignment to both cues. Confocal fluorescence microscopy revealed two groups of mutually opposed f-actin stress fibers within the same cell, one oriented with the topographic cues and the other with the adhesive cues. However, the adhesive response was consistently dominant. We conclude that cells are able to detect and respond to multiple guidance cues simultaneously. The adhesive and topographic guidance cues modeled here were capable of interacting both synergistically and hierarchically to guide cell orientation.     

基底周期拉伸引起ECV-304细胞形态学变化的分析

对ECV-304细胞施以最大应变10％、0.67Hz的周期拉伸,利用计算机图像处理系统,对周期拉伸过程中ECV-304细胞的取向调整进行了形态学分析,结果显示：周期拉伸能引起细胞长轴取向垂直于最大主应变方向;加载12h内细胞长短径比增加,12-24h之间长短径比下降,随后趋于稳定;细胞在周期拉伸最大主应变方向上的最大截距缩短,而在垂直于最大主应变方向上的最大截距延长;取向调整的过程与长短径比增大的过程有显著的相关性。表明在周期拉伸过程中的取向调整是一个细胞具有方向差异性的变形过程,而不是刚性的旋转或位移。     

Contact guidance of smooth muscle cells is associated with tension-mediated adhesion maturation

Contact guidance is a cellular phenomenon observed during wound healing and developmental patterning, in which adherent cells align in the same direction due to physical cues. Despite numerous studies, the molecular mechanism underlying the consistent cell orientation is poorly understood. Here we fabricated microgrooves with a pitch of submicrons to study contact guidance of smooth muscle cells. We show that both integrin-based cell–substrate adhesions and cellular tension are necessary to achieve contact guidance along microgrooves. We further show through analyses on paxillin that cell–substrate adhesions are more prone to become mature when they run along microgrooves than align at an angle to the direction of microgrooves. Because cellular tension promotes the maturation of cell–substrate adhesions, we propose that the adhesions aligning across microgrooves are not physically efficient for bearing cellular tension compared to those aligning along microgrooves. Thus, the proposed model describes a mechanism of contact guidance that cells would finally align preferentially along microgrooves because cellular tensions are more easily borne within the direction, and the direction of resulting mature adhesions determines the direction of the whole cells.