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(American Journal of Pathology. 2004;164:1211-1223.)
© 2004 American Society for Investigative Pathology

Assembly and Reorientation of Stress Fibers Drives Morphological Changes to Endothelial Cells Exposed to Shear Stress

Sabrena Noria^*, Feng Xu^*, Shannon McCue^*, Mara Jones^*, Avrum I. Gotlieb^* and B. Lowell Langille^*

From the Toronto General Research Institute,^* University Health Network, Toronto; and the Department of Laboratory Medicine and Pathobiology, University of Toronto, Toronto, Canada

	Abstract

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Fluid shear stress greatly influences the biology of vascular endothelial cells and the pathogenesis of atherosclerosis. Endothelial cells undergo profound shape change and reorientation in response to physiological levels of fluid shear stress. These morphological changes influence cell function; however, the processes that produce them are poorly understood. We have examined how actin assembly is related to shear-induced endothelial cell shape change. To do so, we imposed physiological levels of shear stress on cultured endothelium for up to 96 hours and then permeabilized the cells and exposed them briefly to fluorescently labeled monomeric actin at various time points to assess actin assembly. Alternatively, monomeric actin was microinjected into cells to allow continuous monitoring of actin distribution. Actin assembly occurred primarily at the ends of stress fibers, which simultaneously reoriented to the shear axis, frequently fused with neighboring stress fibers, and ultimately drove the poles of the cells in the upstream and/or downstream directions. Actin polymerization occurred where stress fibers inserted into focal adhesion complexes, but usually only at one end of the stress fiber. Neither the upstream nor downstream focal adhesion complex was preferred. Changes in actin organization were accompanied by translocation and remodeling of cell-substrate adhesion complexes and transient formation of punctate cell-cell adherens junctions. These findings indicate that stress fiber assembly and realignment provide a novel mode by which cell morphology is altered by mechanical signals.

Shear stresses are very small forces that typically cause bulk deformations (strains) of artery walls that are much less than 1%;⁴ however, the endothelium of arteries is directly exposed to flowing blood and these cells have proven to be exquisitely sensitive to shear. This sensitivity may impact on atherogenesis through both modulation of classic functions of endothelium, ie, its role as a nonthrombogenic transport barrier that regulates inflammatory responses, and through regulation of growth and contractile functions of smooth muscle.^5,6 Consequently, much effort has been expended to explore endothelial sensitivity to shear stress. Examination of candidate genes has revealed that many potentially atherosclerosis-related gene products display shear-sensitive expression by endothelium, including VCAM-1, MCP-1, ICAM-1, eNOS, platelet-derived growth factors, transforming growth factor-ß1, and endothelin.^7-11 More recently, microarray-based studies have demonstrated that expression of hundreds of genes display sensitivity to both the duration and nature (eg, laminar versus turbulent) of shear imposed on endothelial cells.¹²

The sensitivity of endothelium to shear forces is most obviously manifest through changes in cell morphology: the cells elongate, the cell outline and its cytoskeleton becomes highly oriented in the direction of shear stress, and the profile of the cells becomes substantially more flattened when they are exposed to shear stress.¹³ Morphological responses also include partial disassembly and then reassembly of adherens junctions, the primary sites of mechanical coupling between endothelial cells.¹³ Consequently, long-term alterations in secondary flow patterns near branch sites, eg, because of circadian fluctuations in tissue perfusion, may contribute to the high endothelial permeability and low-density lipoprotein uptake at atherosclerosis-prone regions near arterial bends and branch sites¹⁴ and thereby contribute to lesion formation. Finally, shear-stressed endothelial cells provide one of the few cases in which all cells in a monolayer undergo a common morphological response to a synchronized stimulus. Sheared endothelial cells therefore provide a unique model system with which to examine control of cell motility and morphology.

Given the importance of shear-induced morphological changes, it is surprising that little is known concerning how reorganization of cellular structures drives these changes. The actin cytoskeleton initiates most changes in cell morphology. Contractile function of actin-myosin complexes is responsible in some cases;¹⁵ however, actin polymerization is most commonly exploited.¹⁶ Usually, cell shape change follows from nucleation and assembly of thin parallel bundles of actin microfilaments at the cell edge that produce filopodia, ie, finger-like projections of the plasma membrane, or from assembly of dendritic arrays of actin that protrude foot-like processes referred to as lamellipodia. Coordinate remodeling of cell-cell and cell-substrate adhesion complexes then allows cell shape change to proceed. Actin also assembles into basal stress fibers but these are generally associated with adhesion to, or reorganization of, extracellular matrix.¹⁷

We have investigated the role of actin assembly, and associated changes in cell adhesion complexes, in endothelial morphological responses to shear stress. The onset and rate of morphological changes to the cells depended greatly on the state and duration of confluence of the cells before initiation of shear stress: much slower morphological responses were observed in cells that were long confluent. As cells changed shape, formation of filopodia or lamellipodia did not occur; instead, a novel mode of cell shape change was driven by coincident extension and reorientation of stress fibers at the basal aspect of the cell, fusion of adjacent stress fibers, and translocation of the focal adhesion complexes into which these stress fibers insert. Ultimately, stress fiber assembly drove protrusion of the cell membrane in the direction of the shear axis to elongate the cells. This process was independent of the zyxin/vasodilator-stimulated phosphoprotein (VASP) complex, which associates with focal adhesions and can assemble G-actin into microfilament bundles, because introduction of peptide sequences that disrupted this complex do not suppress shear-induced actin assembly. Focal adhesion complexes that were associated with stress fibers also translocated with stress fibers and elongated. Simultaneously, cell-cell adherens junctions transiently assumed a punctate pattern and then re-established a linear distribution, in association with sporadic junctional actin assembly.

	Materials and Methods

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In Vitro Shear Stress

Porcine aortic endothelial cells, at passages four to six, were maintained at 37°C in medium 199 plus 5% fetal bovine serum (Gibco, Invitrogen, Barlington, Canada), 1% amphotericin B (Fungizone), and 2% penicillin/streptomycin, and equilibrated with humidified 95% air and 5% CO₂. At 2 days after confluence, cells were subjected to laminar shear stress of 15 dynes/cm² in a parallel plate flow chamber.^13,18 In some cases, subconfluent or just confluent cultures were exposed to shear stress to assess the effects of monolayer stabilization on responses to shear. Cells maintained in static culture served as controls (n 3 for each experiment).

Immunostaining

Cells were fixed with 3% paraformaldehyde as described,¹³ permeabilized with 0.2% Triton X-100 and washed 3 times for 5 minutes with phosphate-buffered saline (PBS). Cells were then incubated with primary antibody for 1 hour, and then washed with PBS followed by incubation with secondary antibody. Primary antibodies included mouse monoclonal antibodies to paxillin (1:200; Transduction Laboratories, Lexington, KY), vinculin (1:50; Sigma BioSciences, Oakville, Canada), tensin or VASP (1:50; Transduction Laboratories). Primary antibodies were detected using Alexa Fluor 488 goat anti-mouse antibody (1:50; Molecular Probes, Eugene, OR). Staining frequently was done in the presence of rhodamine phalloidin (1:20; Molecular Probes), which labels F-actin.

In Situ Staining of Adherens Junctions

Animal experiments were conducted in accord with the guidelines of the Canadian Council of Animal Care and were approved by the Animal Care Committee of the Toronto General Hospital. Rabbits were killed by intravenous infusion of 1.0 ml of euthanasia solution (T-61; Hoechst, Montreal, Canada).⁹ The carotid arteries were fixed and immunostained⁹ using a goat polyclonal antibody to ß-catenin (1:800; Jackson ImmunoResearch Laboratories, West Grove, PA) and a fluorescein isothiocyanate-conjugated donkey anti-goat secondary antibody (1:50, Jackson ImmunoResearch Laboratories). The arteries were viewed en face by confocal microscopy.⁹

F-Actin Polymerization

The protocol for visualizing actin assembly was based on studies by Symons and Mitchison,¹⁹ with modifications.²⁰ Cultures were gently washed with rinsing buffer (20 mmol/L Hepes, pH 7.5, 138 mmol/L KCl; 4 mmol/L MgCl₂, 3 mmol/L EGTA) and then incubated for up to 10 minutes with fluorescently labeled G-actin in permeabilization buffer [20 mmol/L Hepes, pH 7.5, 138 mmol/L KCl, 4 mmol/L MgCl₂, 3 mmol/L EGTA, 0.01% saponin, 0.5 µmol/L Alexa 488-conjugated G-actin from rabbit muscle (Molecular Probes, Eugene, OR)]. After washing with buffer, cells were fixed for 20 minutes with 3% paraformaldehyde followed by a 3 x 5-minute wash with PBS. To detect endogenous F-actin, cells were incubated with rhodamine-labeled phalloidin for 30 minutes.

In separate experiments, endothelial cells were triple stained for newly polymerized F-actin, endogenous F-actin, and with monoclonal anti-vinculin antibody (1:50; Sigma BioSciences) and a CY5-conjugated donkey anti-mouse secondary antibody, in the presence of rhodamine-labeled phalloidin.

Microinjection of Fluorescently Labeled G-Actin

To visualize the cellular actin pool in live cells, subconfluent cells grown on coverslips were microinjected with Alexa Fluor 488-conjugated actin (6 mg/ml, Molecular Probes) using an Eppendorf transjector 5246. Cells were exposed to shear stress 24 hours after injection. Time-lapse images were collected using a fluorescence microscope (TE300; Nikon, Melville, NY) equipped with a cooled charge-coupled device camera (ORCA ER; Hamamatsu).

Cell Membrane Labeling

To label cell membrane, cells were incubated for 10 minutes with 20 mmol/L DiI (1.1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate; Molecular Probes). Cells were fixed as described above.

Fluorescence Microscopy

Fixed endothelial cells were examined using a Bio-Rad MRC 1024 laser scanning confocal microscope (Nikon x60 oil-immersion objective; NA = 1.4). The peak excitation/emission wavelengths for the fluorescent probes, and the detection filters used were: fluorescein isothiocyanate = 492/520 nm and detected at 522 nm; CY5 = 650/680 nm and detected at 680 nm; rhodamine = 554/573 nm and detected at 605 nm. For each experiment, at least10 fields per slide were collected.

Peptide Inhibitor of Zyxin-VASP Interaction

Peptide sequences comprising a domain of zyxin that mediates binding to VASP (PPEDFPLPPPPLAGD),²¹ or a scrambled version of this peptide (control, PPEDAPLPPPPLAGD), in tandem with a Trojan peptide sequence (a string of nine arginines)²² to facilitate cell entry, were synthesized by the Biotechnology Service Centre (Hospital for Sick Children, Toronto, Canada). The peptide (300 µmol/L) was introduced into the flow loop at 15.5 hours of shear stress and then incorporation of fluorescently labeled monomeric actin into microfilaments was assessed 30 minutes later, as described above. Four replicate experiments were performed.

Statistics

Actin most often assembled at one end of stress fibers. To assess bias in the direction of actin assembly, cells were classified according to whether actin assembly was predominantly in the upstream, downstream, or both ends of stress fibers (bipolar), or directed away from the nucleus (anti-podal). At least 30 cells per time point were scored by an unbiased (blinded) observer and the cells to be counted were defined from a predefined grid using the Vernier scales on the stage drives, so that cell selection was unbiased. Statistical analysis was analysis of variance followed by a Tukey’s post hoc test.

	Results

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Shear-Induced Changes to Endothelial Cell Shape and the Endothelial Cell-Cell Interface

Endothelial cells in healthy arteries are permanently confluent; therefore, cells generally were not exposed to shear until 2 days after confluence was achieved. Throughout these 2 days, stress fibers became less prominent and a junctional dense peripheral band of F-actin was established (Figure 1) , then no further changes in actin distribution were detectable. This stabilization proved important because subconfluent or just confluent cells initiate reorganization of actin very quickly after shear stress is imposed (not shown), whereas only very modest shear-related F-actin reorganization occurred in cells that were 2 days postconfluent until 8 hours of shear (Figure 1) .¹³ Partial loss of the dense peripheral band of actin was then followed by elongation of cells and alignment of actin microfilaments with shear throughout 8 to 24 hours. No further changes in cell shape or actin distribution were observed.

View larger version (160K): [in this window] [in a new window]   Figure 1. Postconfluency affects actin organization in endothelial cell responses to shear stress. Endothelial cells that have just achieved confluence (top left) display randomly oriented microfilament bundles and actin staining fails to delineate individual cells. At 2 days after confluence, a dense peripheral band of actin assembles at the cell-cell junctions and only sparse central stress fibers are seen. When shear is initiated at 2 days after confluence, no changes in cell shape or actin distribution are detectable at 4 hours and only modest and sporadic loss of the dense peripheral band of actin is detected at 8 hours. Cell elongation and actin alignment with shear stress becomes apparent during the next 8 hours and cells complete shape change after 24 hours of shear stress.

View larger version (109K): [in this window] [in a new window]   Figure 2. Shear-induced changes to endothelium. Cell membranes of endothelial cells in static cultures (left) or after 16 hours of shear stress (right) were labeled with the DiI. Areas of cell-cell overlap are brighter because multiple layers of plasma membrane are detected. a: In static cultures, linear cell-cell junctions were interrupted by pad-like regions of cell overlap (arrow) that were separated by linear cell-cell junctions (arrowhead). b: Shear induced elongation of endothelial cells in the direction of shear vector (right to left) that occurred between 8 hours and 24 hours. During elongation, regions of cell-cell overlap that are neither filopodia-like or lamellipodia-like were observed; instead, triangle-shaped projections of cell membranes became oriented in the upstream and downstream directions (arrow). Each finding is representative of at least three replicate experiments.

To assess actin assembly during changes in cell shape, we permeabilized endothelial cell membranes after varying periods of shear stress and then incubated the cells with Alexa 488-labeled monomeric actin (G-actin) briefly (up to 10 minutes) to define sites of actin assembly, then cells were fixed and stained for total F-actin. When it occurred, actin incorporation into microfilaments was detectable at 3 minutes of incubation, but optimal labeling was seen with 8 to 10 minutes of incubation. Uptake of G-actin into microfilaments was readily detected in subconfluent endothelial cells (not shown), which are highly motile, but little or no incorporation of labeled G-actin was detected in cultures 2 days after confluence that were not exposed to shear stress (Figure 3A) . Approximately 50% of cells displayed incorporation of exogenous G-actin at ends of randomly oriented stress fibers after 8 hours of shear (Figure 3B , green). Most frequently, actin assembly occurred at only one end of the stress fibers (see below). Less prominent, punctate staining of exogenous actin was also observed along the lengths of microfilaments.

View larger version (140K): [in this window] [in a new window]   Figure 3. Shear stress induces assembly of actin at the ends of stress fibers. Endothelial cells were incubated briefly with fluorescently labeled G-actin (green) after exposure to shear stress for 0 hours (A), 8 hours (B), 16 hours (C), or 96 hours (D). Cells were then fixed and filamentous actin was stained with rhodamine phalloidin (red). Little or no actin assembly occurred in postconfluent cells not exposed to shear stress (A). In contrast, exposure to shear stress induced actin assembly at the ends of stress fibers (B–D). Initially, actin assembly was randomly oriented, but assembly became aligned with shear stress by 16 to 24 hours. Shear stress is directed from right to left. Each finding is representative of at least three replicate experiments.

Optical sectioning with confocal microscopy and double staining for actin assembly and the focal adhesion proteins, vinculin and paxillin, demonstrated that actin assembly occurred at the basal aspect of the cells, where microfilament bundles insert into focal adhesion complexes (Figure 4) . Notably, both ends of stress fibers terminated in adhesion complexes, but actin assembly most often occurred at only one of these sites (Figure 4 , arrows). Importantly, actin assembly was constrained to subdomains of focal adhesion complexes, as indicated by only partial overlap of G-actin fluorescence with immunostaining for vinculin (Figure 4 , insets). This finding probably reflects remodeling and translocation of the focal adhesion/stress fiber complex during adaptation to shear stress, as described below.

View larger version (90K): [in this window] [in a new window]   Figure 4. Actin assembly occurs at focal adhesion complexes at one end of stress fibers and localizes to subdomains of these complexes. Endothelial cells were exposed to fluorescently labeled G-actin (green) after exposure to shear stress for 8 hours (A) or 16 hours (B), then stained for filamentous actin with rhodamine phalloidin (red) and immunostained for vinculin (blue). Actin assembly usually occurred at only one end of stress fibers (arrows in A). At these sites, newly assembled actin was excluded from subdomains of the focal adhesion complex, as indicated by overlap of vinculin and F-actin only (fuscia, insets). Shear stress is directed from right to left. Findings are representative of three replicate experiments.

View larger version (12K): [in this window] [in a new window]   Figure 5. Shear stress determines orientation but not direction of actin assembly. Graph displays percentage of cells in which actin assembly was predominantly at the upstream, downstream, or both ends (bipolar) of stress fibers, or when assembly was directed away from the nucleus at both ends of the cells (anti-podal). Numbers at the base of each bar indicate hours of shear stress. Also shown is the percentage of cells in which assembly was randomly distributed between the two ends of the stress fibers, which never occurred after 24 hours. The only other statistically significant temporal change was an increase in bipolar assembly at 48 hours.

The scaffolding protein, zyxin, can link VASP to the actin-bundling protein, -actinin, which concentrates at focal adhesions.²³ VASP interaction with cytoplasmic G-actin-profilin complexes can then incorporate actin monomer into microfilaments. VASP localized to focal adhesions in endothelium (Figure 6, A and B) but it did not mediate shear-induced actin assembly at these sites. Accordingly, a peptide sequence that was designed to interfere with zyxin-VASP interaction successfully dislodged VASP from focal adhesions (Figure 6, A and B) but had no impact on shear-induced actin assembly (Figure 6, C and D) . VASP was not dislodged from focal adhesions by control peptide (not shown).

View larger version (83K): [in this window] [in a new window]   Figure 6. VASP does not mediate shear-induced actin assembly. Shear-induced stress fiber assembly was not VASP (green immunostaining) localized to focal adhesion complexes in endothelium (A) but was dislodged from these sites by a zyxin peptide sequence designed to interfere with zyxin-VASP interaction (B). VASP association with ends of stress fibers remained suppressed at 1 hour (not shown). Incorporation of Alexa 488-labeled monomeric actin (green) into the end of stress fibers (red) after 16 hours of shear stress (C) was not suppressed by peptides that disrupt association of VASP with focal adhesion complexes (D), or by control (scrambled) peptide (not shown).

By 16 to 24 hours, actin assembly in all cells became oriented with the shear axis and frequently extended to the upstream and/or downstream poles of the cell (Figures 3 and 4) . We therefore hypothesized that stress fiber reorientation and assembly protruded the cell membrane along the shear axis to achieve elongation. To test this hypothesis, we microinjected endothelial cells with fluorescently labeled G-actin and then exposed the cells to shear stress 24 hours later, when the labeled G-actin was distributed throughout the cellular pool, so that microfilaments in live cells could be visualized.

Individual stress fibers extended and changed their orientation, most often toward the shear axis, but excursion away from this direction also occurred. During and after alignment of stress fibers in the direction of shear, assembling stress fibers extended to the cell periphery and further actin assembly drove protrusion of the cell membrane in the direction of cell elongation (Figure 7) . Stress fibers originated proximal to the cell periphery then extended to the cell-cell junction and advanced the adjacent cell membrane. In no cells did we see evidence of actin nucleation at the cell edge that would characterize filopodia. Interestingly, when assembling and reorienting stress fibers encountered adjacent stress fibers, they often merged to produce larger microfilament bundles (Figure 7 , arrows).

View larger version (84K): [in this window] [in a new window]   Figure 7. Stress fiber extension protrudes the endothelial cell membrane at the cell poles. Endothelial cells were microinjected with fluorescently labeled G-actin 24 hours before exposing the cells to shear stress for 20 hours. Top horizontal line joins the ends of stress fibers that do not advance during the observation time. The middle line joins stress fibers that advance between t = 20:15 hours and t = 21:45 hours. The bottom line is in the vicinity of three stress fibers that advance substantially throughout the period of observation. Note the advance of the cell membrane in the latter two cases. Frequently, two or more adjacent stress fibers fused throughout the period of observation (arrows). Shear stress is directed from top to bottom. Findings are representative of three replicate experiments.

Reorganization of cell-substrate adhesion complexes accompanied realignment of stress fibers. In static cultures, focal adhesions were large, ovoid, or arrowhead complexes, whereas shear stress caused most of these complexes to assume an extended, linear morphology (Figures 8 and 9) . These changes may reflect conversion from classical focal adhesions (focal contacts),²⁴ seen in many stable cultures, to the fibrillar adhesions that characterize motile cells;²⁴ however, not all of our data were consistent with this interpretation. We immunostained adhesion complexes with antibodies to vinculin, paxillin, and tensin, because the former two proteins preferentially localize to focal contacts whereas tensin preferentially concentrates at fibrillar adhesions.^25,26 Some depletion of vinculin and paxillin at focal adhesions was seen with shear but there was also a dramatic loss of tensin that persisted until after shape change had gone to completion (Figure 9) .

View larger version (101K): [in this window] [in a new window]   Figure 8. Focal adhesion complexes become extended and linear under the influence of shear stress. The figure shows vinculin and paxillin immunostaining after 0 hours, 16 hours, and 96 hours of shear stress, which is directed from right to left. Shear stress induces the formation of long, linear adhesion complexes that are aligned with shear stress. Findings are representative of three replicate experiments.

View larger version (69K): [in this window] [in a new window]   Figure 9. Focal adhesion complexes become depleted of tensin under the influence of shear stress. Endothelium in postconfluent cultures was immunostained for tensin and viewed by confocal microscopy. Tensin localized to focal adhesion complexes in static cultures (left) but dramatic decreases in tensin contents of focal adhesions were observed at 24 hours of shear (middle) as well as at 8 hours, 16 hours, and 48 hours (not shown). Recovery of tensin at focal adhesions was detected at 96 hours. Images were captured in the same microscopy session with identical settings on the microscope and identical conditions for figure production. Shear stress is directed from right to left. Findings are representative of three replicate experiments.

Chronic Shear Stress and Organization of Adherens Junctions

We previously reported¹³ that shear caused adherens junctions to convert from a generally linear distribution to extended junctional plaques that were often associated with peripheral actin (Figure 10A) . This pattern persisted at 48 hours, ie, 24 hours after cell shape changes was completed.¹³ Nonetheless, adherens puncta proved to be transitory because these junctional complexes returned to a primarily linear distribution at 96 hours (Figure 10C) . This latter distribution apparently reflects junctions in vivo, because immunostaining of adherens junctions (-catenin) in rabbit carotid arteries was also linear (Figure 10D) . Actin microfilaments were required for maintenance of puncta because treatment of cells after 48 hours of shear with the microfilament-disrupting agent, cytochalasin D (0.1 µmol/L), caused junctions to revert to a linear distribution (Figure 10B) . Furthermore, actin assembly may participate in conversion of adherens puncta to linear adherens junctions because assembly sporadically localized to the junctional complexes at 48 hours (see white areas in Figure 9A ) and 24 hours (not shown) of shear stress.

View larger version (80K): [in this window] [in a new window]   Figure 10. A punctate distribution of adherens junctions in shear-stressed endothelium is transitory and dependent on actin microfilaments. A: Confocal micrograph shows F-actin (red), exogenous fluorescent actin (newly assembled actin, green), and the adherens junction protein, -catenin, after 48 hours of shear stress. Note the discontinuous distribution of adherens junctions (adherens plaques). (The -catenin signal alone is reproduced as online Figure 6 so that the discontinuous nature of adherens conjunctions can be easily visualized.) B: This distribution was dependent on filamentous actin because cytochalasin, which disperses microfilaments, induced the redistribution of adherens junctions into a linear array at 48 hours of shear stress. C: The punctate pattern that adherens junctions assumed under shear stress was transitory because these structures spontaneously resumed a linear distribution at the cell-cell junction at 96 hours, a distribution that mimicked that observed for ß-catenin in unmanipulated rabbit carotid arteries in situ (D).

	Discussion

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Previous work indicated a potential role for actin assembly in morphological responses of endothelial cells to shear stress. Modulation of the activities of the Rho, Rac, and cdc42 GTPase activities, which are primary regulators of actin assembly,³⁷ have been implicated in these morphological responses;²⁹ furthermore, inhibition of shear activation of p38 MAP kinase blocked downstream activation of the actin uncapping protein, HSP27, and abolished cell shape change.³⁸ Usually cell shape change produced by actin assembly is secondary to formation of filopodia or lamellipodia; however, this was not the case for shear-stressed endothelium. Instead, assembly was concentrated at the ends of stress fibers that were randomly oriented. Subsequently, stress fibers aligned with the shear axis while polymerization continued and then further assembly drove the cell membrane centrifugally at the upstream and/or downstream poles of the cells. We are aware of no other physiological examples in which polymerization of stress fiber proceeds from the cell interior, extends to the cell surface, and then propels the cell membrane forward to elicit shape change.

Stress fibers aligned with the shear vector within 24 hours of the onset of shear. Nucleation and assembly of new stress fibers must occur because these structures are more numerous and larger in shear-adapted cells.^35,39,40 However, stress fibers tended to display a common orientation within individual cells that were adapting to shear stress even before the cells aligned with shear. It is therefore likely that nascent stress fibers, like pre-existing stress fibers, participated in the elongation, alignment and fusion that we describe.

Microinjection of fluorescently labeled G-actin confirmed both extension and reorientation of stress fibers. Because cellular and stress fiber elongations were initially oblique to the shear vector, we infer that cell elongation is a primary response that is then accompanied and followed by reorientation. Reorientation of basal stress fibers inevitably led to direct contact of some of these structures, and then they fused into larger microfilament bundles. Presumably, actin-bundling proteins, eg, -actinin, participate, but these were not identified in the current study.

Actin assembly continued at 96 hours of shear stress, long after gross morphological changes to the cells was completed. This chronic actin polymerization may be accompanied by treadmilling that preserves cell and stress fiber dimensions but its functional significance is uncertain. Possibly, actin assembly-disassembly is required to maintain an elongated cell morphology. Adaptation to shear involves a high degree of co-alignment of microfilaments, focal adhesion complexes, and microtubules.⁴¹ Because cytoskeletal and adhesive structures display considerable stochastic behavior,^42,43 their continuous, active reorganization may offset an incessant, entropy-driven drift toward randomized orientation of cell structures and, ultimately, cell morphology.

Actin assembly usually localized to only one of the two focal adhesions into which stress fibers inserted; however the polarization of this assembly varied from cell to cell. Although our examination of constituents of focal adhesions was limited, we detected no differences in localization of vinculin, paxillin, or tensin to assembling versus nonassembling ends of stress fibers; therefore, the determinants of polarized actin assembly remain enigmatic.

Translocation of substrate adhesion complexes accompanies reorganization of the stress fibers that insert into them. Translocation of these structures in motile cells can involve the separation of fibronectin-associated ₅ß₁ integrins from large, ovoid, focal adhesion complexes to form long, thin motile fibrillar adhesions that are rich in tensin.¹⁷ Accordingly, we found that adhesion complexes converted to a more extended, linear morphology during adaptation to shear; however, tensin content was dramatically decreased and it only returned to these sites at 96 hours. Thus, these focal adhesions in cells adapting to shear are hybrid complexes and we have not resolved whether they arise from classical focal adhesion complexes in a manner similar to that for the fibrillar adhesions that have been examined in other cells.²⁵ We also observed actin assembly that localized to subdomains of vinculin-containing plaques and we propose that assembly of stress fibers at one subdomain of adhesion plaques, presumably in concert with aggregation of focal adhesion proteins, and disassembly of these structures at another, underlies their translocation toward the shear axis.

The machinery that assembles actin under the influence of shear stress remains unclear. The presence of VASP at focal adhesions, where shear induces assembly, was intriguing because the zyxin-VASP complexes assemble linear arrays of microfilaments at other sites.²⁰ However, displacement of VASP from focal adhesions with synthetic peptides did not disrupt stress fiber assembly. Clearly other protein complexes mediate this process.

Elongation and alignment of endothelial cells also requires reorganization of cell junctional complexes. Adherens junctions are critical in this regard because of their primary role in mechanical coupling of cells. We previously reported that primarily linear adherens junctions become disrupted and discontinuous during adaptation to shear stress.¹³ This phenomenon persisted at 48 hours of shear, long after elongation and reorientation were completed and we inferred that it was a permanent manifestation of shear stress. We now report, however, a return to linear junctions at 96 hours, a distribution that replicates that seen in arteries in situ, thus morphological adaptations to shear stress take up to 4 days to go to completion. The transient puncta depended on an intact F-actin cytoskeleton because the junctions became linear when actin was dispersed; furthermore actin assembly sporadically co-localized to these sites. It is possible that actin assembly participates in conversion of adherens puncta to linear junctions, as it does in newly forming epithelial cell junctions,²⁰ but this was not directly assessable because of the very slow reorganization of these structures under shear stress and the sporadic nature of actin assembly at puncta.

In conclusion, these studies revealed that endothelial cells become elongate and aligned in the direction of shear stress through a novel mechanism that involves growth, fusion, and reorientation of stress fibers that ultimately protrudes the upstream and/or downstream cell membrane. Actin assembly occurs at motile focal adhesion complexes that also elongate in the direction of shear stress and, sporadically, it occurs at cell-cell adherens junctions as these structures undergo the obligatory reorganization that occurs when cells in a confluent monolayer change shape.

	Footnotes

 
Address reprint requests to B. Lowell Langille, Ph.D., Toronto General Research Institute, 200 Elizabeth St., NU 113d, Toronto, ON M5G 2C4, Canada. E-mail: langille{at}uhnres.utoronto.ca

Supported by the Canadian Institutes for Health Research (grant 15044).

S.N. was a recipient of a Canadian Institutes for Health Research graduate studentship.

Accepted for publication December 9, 2003.

	References

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1. Roach MR, Fletcher J: Effect of unilateral nephrectomy of the localization of aortic sudanophilic lesions in cholesterol-fed rabbits. Atherosclerosis 1977, 24:327-333
2. Zand T, Hoffman AH, Savilonis BJ, Underwood JM, Nunnari JJ, Majno G, Joris IS: Lipid deposition in rat aortas with intraluminal hemispherical plug stenosis. Am J Pathol 1999, 155:85-92[Abstract/Free Full Text]
3. Ku DN, Giddens DP, Zarins CK, Glagov S: Pulsatile flow and atherosclerosis in the human carotid bifurcation. Positive correlation between plaque location and low and oscillating shear stress. Arteriosclerosis 1985, 5:293-302[Abstract/Free Full Text]
4. Langille BL, O’Donnell F: Reductions in arterial diameter produced by chronic decreases in blood flow are endothelium-dependent. Science 1986, 231:405-407[Abstract/Free Full Text]
5. Ross R, Fuster V: The pathogenesis of atherosclerosis. Fuster V Ross R Topol EJ eds. Atherosclerosis and Coronary Artery Disease. 1996:pp 441-460 Lippincott-Raven Publishers, Philadelphia
6. Ross R: Mechanisms of disease—atherosclerosis—an inflammatory disease. N Engl J Med 1999, 340:115-126[Free Full Text]
7. Ando J, Tsuboi H, Korenaga R, Takada Y, Toyama-Sorimachi N, Miyasaka M, Kamiya A: Shear stress inhibits adhesion of cultured mouse endothelial cells to lymphocytes by downregulating VCAM-1 expression. Am J Physiol 1994, 267:C679-C687
8. Ranjan V, Diamond SL: Fluid shear stress induces synthesis and nuclear localization of c-fos in cultured human endothelial cells. Biochem Biophys Res Commun 1993, 196:79-84[Medline]
9. Walpola PL, Gotlieb AI, Cybulsky MI, Langille BL: Expression of ICAM-1 and VCAM-1 and monocyte adherence in arteries exposed to altered shear stress. Arterioscler Thromb Vasc Biol 1995, 15:2-10[Abstract/Free Full Text]
10. Ohno M, Cooke JP, Dzau VJ, Gibbons GH: Fluid shear stress induces endothelial transforming growth factor beta-1 transcription and production. Modulation by potassium channel blockade. J Clin Invest 1995, 95:1363-1369
11. Nagel T, Resnick N, Atkinson WJ, Dewey CF, Jr, Gimbrone MA, Jr: Shear stress selectively upregulates intercellular adhesion molecule-1 expression in cultured human vascular endothelial cells. J Clin Invest 1994, 94:885-891
12. Garcia-Cardena G, Comander J, Anderson KR, Blackman BR, Gimbrone MA, Jr: Biomechanical activation of vascular endothelium as a determinant of its functional phenotype. Proc Natl Acad Sci USA 2001, 98:4478-4485[Abstract/Free Full Text]
13. Noria S, Cowan DB, Gotlieb AI, Langille BL: Transient and steady-state effects of shear stress on endothelial cell adherens junctions. Circ Res 1999, 85:504-514[Abstract/Free Full Text]
14. Caplan BA, Schwartz CJ: Increased endothelial cell turnover in areas of Evans blue uptake in the pig aorta. Atherosclerosis 1973, 17:401-417[Medline]
15. Costa M, Raich W, Agbunag C, Leung B, Hardin J, Priess JR: A putative catenin-cadherin system mediates morphogenesis of the Caenorhabditis elegans embryo. J Cell Biol 1998, 141:297-308[Abstract/Free Full Text]
16. Borisy GG, Svitkina TM: Actin machinery: pushing the envelope. Curr Opin Cell Biol 2000, 12:104-112[Medline]
17. Pankov R, Cukierman E, Katz B-Z, Matsumoto K, Lin DC, Lin S, Hahn CS, Yamada KM: Integrin dynamics and matrix assembly: tension-dependent translocation of ₅ß₁ integrins promotes early fibronectin fibrillogenesis. J Cell Biol 2000, 148:1075-1090[Abstract/Free Full Text]
18. Frangos JA, Eskin SG, McIntire LV, Ives CL: Flow effects on prostacyclin production by cultured human endothelial cells. Science 1985, 227:1477-1479[Abstract/Free Full Text]
19. Symons MH, Mitchison TJ: Control of actin polymerization in live and permeabilized fibroblasts. J Cell Biol 1991, 114:503-513[Abstract/Free Full Text]
20. Vasioukhin V, Bauer C, Yin M, Fuchs E: Directed actin polymerization is the driving force for epithelial cell-cell adhesion. Cell 2000, 100:209-219[Medline]
21. Drees B, Friederich E, Fradelizi J, Louvard D, Beckerle MC, Golysteyn RM: Characterization of the interaction between zyxin and members of the Ena/VASP (vasodilator stimulated phosphoprotein) family of proteins. J Biol Chem 2000, 275:22503-22511[Abstract/Free Full Text]
22. Wender PA, Mitchell DJ, Pattabiraman K, Pelkey ET, Steinman L, Rothbard JB: The design, synthesis, and evaluation of molecules that enable or enhance cellular uptake: peptoid molecular transporters. Proc Natl Acad Sci USA 2000, 97:13003-13008[Abstract/Free Full Text]
23. Rottner K, Krause M, Gimona M, Small JV, Wehland J: Zyxin is not colocalized with vasodilator-stimulated phosphoprotein (VASP) at lamellipodial tips and exhibits different dynamics to vinculin, paxillin, and VASP in focal adhesions. Mol Biol Cell 2001, 12:3103-3113[Abstract/Free Full Text]
24. Zamir E, Katz B-Z, Aota S, Yamada KM, Geiger B, Kam Z: Molecular diversity of cell-matrix adhesions. J Cell Sci 1999, 112:1655-1669[Abstract]
25. Zamir E, Katz M, Posen Y, Erez N, Yamada KM, Katz B-Z, Lin S, Lin DC, Bershadsky A, Kam Z, Geiger B: Dynamics and segregation of cell-matrix adhesions in cultured fibroblasts. Nat Cell Biol 2000, 2:191-196[Medline]
26. Geiger B: Cell biology: encounters in space. Science 2001, 294:1661-1663[Free Full Text]
27. Rüdiger M: Vinculin and alpha-catenin: shared and unique functions in adherens junctions. BioEssays 1998, 20:733-740[Medline]
28. Wojciak-Stothard B, Ridley AJ: Shear stress-induced endothelial cell polarization is mediated by Rho and Rac but not Cdc42 or PI 3-kinases. J Cell Biol 2003, 161:429-439[Abstract/Free Full Text]
29. Tzima E, del Pozo A, Shattil SJ, Chien S, Schwartz MA: Activation of integrins in endothelial cells by fluid shear stress mediates Rho-dependent cytoskeletal alignment. EMBO J 2001, 20:4639-4647[Medline]
30. Ukropec JA, Hollinger MK, Woolkalis MJ: Regulation of VE-cadherin linkage to the cytoskeleton in endothelial cells exposed to fluid shear stress. Exp Cell Res 2002, 273:240-247[Medline]
31. Levesque MJ, Nerem RM: The elongation and orientation of cultured endothelial cells in response to shear stress. J Biomech Eng 1985, 107:341-347[Medline]
32. Valiron O, Chevrier V, Usson Y, Breviario F, Job D, Dejana E: Desmoplakin expression and organization at human umbilical vein endothelial cell-to-cell junctions. J Cell Sci 1996, 109:2141-2149[Abstract]
33. Lampugnani MG, Corada M, Caveda L, Breviario F, Ayalon O, Geiger B, Dejana E: The molecular organization of endothelial cell to cell junctions: differential association of plakoglobin, ß-catenin, and -catenin with vascular endothelial cadherin (VE-cadherin). J Cell Biol 1995, 129:203-217[Abstract/Free Full Text]
34. Wong MKK, Gotlieb AI: In vitro reendothelialization of a single-cell wound. Role of microfilament bundles in rapid lamellipodia-mediated wound closure. Lab Invest 1984, 51:75-81[Medline]
35. Kim DW, Gotlieb AI, Langille BL: In vivo modulation of endothelial F-actin microfilaments by experimental alterations in shear stress. Arteriosclerosis 1989, 9:439-445[Abstract/Free Full Text]
36. Langille BL, Graham JJK, Kim D, Gotlieb AI: Dynamics of shear-induced redistribution of F-actin in endothelial cells in vivo. Arterioscler Thromb 1991, 11:1814-1820[Abstract/Free Full Text]
37. Etienne-Manneville S, Hall A: Rho GTPases in cell biology. Nature 2002, 420:629-635[Medline]
38. Azuma N, Akasaka N, Ikeda M, Gahtan V, Sasajima T, Sumpio BE: Role of p38 MAP kinase in endothelial cell alignment induced by fluid shear stress. Am J Physiol 2001, 280:H189-H197
39. Kim DW, Langille BL, Wong MKK, Gotlieb AI: Patterns of endothelial microfilament distribution in the rabbit aorta in situ. Circ Res 1989, 64:21-31[Abstract/Free Full Text]
40. Dewey CF, Jr, Bussolari SR, Gimbrone MA, Jr, Davies PF: The dynamic response of vascular endothelial cells to fluid shear stress. J Biomech Eng 1981, 103:177-185[Medline]
41. Galbraith CG, Skalak R, Chien S: Shear stress induces spatial reorganization of the endothelial cell cytoskeleton. Cell Motil Cytoskeleton 1998, 40:317-330[Medline]
42. Andersen SSL: Balanced regulation of microtubule dynamics during the cell cycle: a contemporary view. BioEssays 1999, 21:53-60[Medline]
43. Davies PF, Robotewskyj A, Griem ML: Quantitative studies of endothelial cell adhesion. Directional remodeling of focal adhesion sites in response to flow forces. J Clin Invest 1994, 93:2031-2038

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