Modes of remodeling in the cortical cytoskeleton of vascular endothelial cells

The cortical cytoskeleton of vascular endothelial cells plays an important role in responding to mechanical stimuli and controlling the distribution of cell surface proteins. Here, we have used atomic force microscopy to visualize the dynamics of cortical cytoskeleton in living bovine pulmonary artery endothelial cells. We demonstrate that the cortical cytoskeleton, organized as a complex polygonal mesh, is highly dynamic and shows two modes of remodeling: intact-boundary-mode where mesh element boundaries remain intact but move at approximately 0.08 microm/min allowing the mesh element to change shape, and altered-boundary-mode where new mesh boundaries form and existing ones disappear.     

Biphasic effect of danazol on human vascular endothelial cell permeability and f-actin cytoskeleton dynamics

Breakdown of endothelial barrier function is a hallmark event across a variety of pathologies such as inflammation, cancer, and diabetes. It has also been appreciated that steroid hormones impart direct biological activity on endothelial cells at many levels. The purpose of this investigation was to explore the effect of the androgen-like steroid, danazol, on endothelial cell barrier function in vitro. Primary human endothelial cells exposed to 0.01-50 μM danazol were evaluated for changes in permeability. We found that danazol altered endothelial permeability in a biphasic manner in which nanomolar concentrations enhance barrier function while micromolar concentrations are detrimental. Monitoring of trans-endothelial electrical resistance demonstrated that these barrier enhancing effects were rapid (within 5 min) and lasted for over 24h. Analysis of intracellular f-actin organization showed that barrier enhancement also correlated with the formation of a submembranous cortical actin ring. Conversely, at higher danazol concentrations, contractile cell phenotypes were observed, represented by stress fiber formation. Competitive binding studies performed using steroid hormone receptor antagonists proved that this activity is the result of androgen and estrogen receptor ligation. These findings suggest that low dose danazol may provide a therapeutic window for diseases involving vascular leakage.     

Regulation of vascular endothelial cell barrier function and cytoskeleton structure by protein phosphatases of the PPP family

Reversible phosphorylation of cytoskeletal and cytoskeleton-associated proteins is a significant element of endothelial barrier function regulation. Therefore, understanding the mechanisms of phosphorylation/dephosphorylation of endothelial cell cytoskeletal proteins is vital to the treatment of severe lung disorders such as high permeability pulmonary edema. In vivo, there is a controlled balance between the activities of protein kinases and phosphatases. Due to various external or internal signals, this balance may be shifted. The actual balances at a given time alter the phosphorylation level of certain proteins with appropriate physiological consequences. The latest information about the structure and regulation of different types of Ser/Thr protein phosphatases participating in the regulation of endothelial cytoskeletal organization and barrier function will be reviewed here.     

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

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

Occludin regulates actin cytoskeleton in endothelial cells

Occludin is a major membrane component of tight junctions of endothelial cells, though the role of this molecule is not fully understood. RLE cells, derived from rat lung endothelial cells, express a negligible level of occludin with clear expression of E-cadherin and ZO-1 at cell junctions. Introduction of occludin by transfection induced clear junctional expression of occludin with few or no changes of expression of E-cadherin and ZO-1. The paracellular barrier function, as determined by transelectrical resistance and flux of non-ionic small molecules, was not detectably upregulated. When cells expressing occludin were cocultured with RLE cells null for occludin, clear junctional expression of occludin was observed irrespective of the expression of occludin on the apposing cells. Cortical actin was developed at the site of these occludin positive cell junctions. Treatment of cells with an actin depolymerizing agent, mycalolide B, abolished junctional expression of occludin together with E-cadherin and circumferential actin. ZO-1 showed relative resistance to this actin depolymerizing treatment and was maintained at the cell junctions, though fragmentation of immunoreactivity was detectable. Collectively, junctional expression of occludin was not associated with paracellular barrier function in this cell line. There was, however, a close correlation of occludin with the actin cytoskeleton, indicating a role of occludin as an important molecule in the regulation of the actin cytoskeleton in endothelial cells.     

Hydrogen peroxide induces endothelial cell atypia and cytoskeleton depolymerization

Reactive oxygen intermediates induce cell injury in a variety of pathophysiological conditions. Human umbilical cord vein endothelial cell (HUVEC) cultures were exposed to 1 or 200 microM H2O2 for 15 min, and observed after 15 min, or 1, 4, 24, or 120 h. Factor VIII and the cytoskeletal proteins vimentin and tubulin were visualized immunocytochemically. Release of lactate dehydrogenase (indices of cell membrane injury) did not increase after H2O2 exposure; nor was cellular expression of factor VIII affected. 200 microM H2O2 induced cell contraction after 15 min which disappeared after 1 and 4 h, but was evident again after 24 h. Immediately after exposure, the filamentous structure of vimentin and tubulin disappeared, but normalized after 1 h. After 120 h, the cytoskeleton filaments were coarsened and disorganized, and an abundance of multinucleated giant cells were observed. Catalase (150 U/ml) abolished all effects of H2O2. One microM H2O2 did not induce any changes in HUVEC. Thus, the present concentrations of H2O2 did not induce cell necrosis or altered expression of factor VIII. Early, reversible cell contraction and depolymerization of cytoskeletal proteins were observed, followed by a delayed contraction and cell atypia after 200 microM H2O2.     

Role of CPI-17 in the regulation of endothelial cytoskeleton

We have previously shown that myosin light chain (MLC) phosphatase (MLCP) is critically involved in the regulation of agonist-mediated endothelial permeability and cytoskeletal organization (Verin AD, Patterson CE, Day MA, and Garcia JG. Am J Physiol Lung Cell Mol Physiol 269: L99-L108, 1995). The molecular mechanisms of endothelial MLCP regulation, however, are not completely understood. In this study we found that, similar to smooth muscle, lung microvascular endothelial cells expressed specific endogenous inhibitor of MLCP, CPI-17. To elucidate the role of CPI-17 in the regulation of endothelial cytoskeleton, full-length CPI-17 plasmid was transiently transfected into pulmonary artery endothelial cells, where the background of endogenous protein is low. CPI-17 had no effect on cytoskeleton under nonstimulating conditions. However, stimulation of transfected cells with direct PKC activator PMA caused a dramatic increase in F-actin stress fibers, focal adhesions, and MLC phosphorylation compared with untransfected cells. Inflammatory agonist histamine and, to a much lesser extent, thrombin were capable of activating CPI-17. Histamine caused stronger CPI-17 phosphorylation than thrombin. Inhibitory analysis revealed that PKC more significantly contributes to agonist-induced CPI-17 phosphorylation than Rho-kinase. Dominant-negative PKC-alpha abolished the effect of CPI-17 on actin cytoskeleton, suggesting that the PKC-alpha isoform is most likely responsible for CPI-17 activation in the endothelium. Depletion of endogenous CPI-17 in lung microvascular endothelial cell significantly attenuated histamine-induced increase in endothelial permeability. Together these data suggest the potential importance of PKC/CPI-17-mediated pathway in histamine-triggered cytoskeletal rearrangements leading to lung microvascular barrier compromise.     

Hemodynamics mediated epigenetic regulators in the pathogenesis of vascular diseases

Molecular and Cellular Biochemistry - Endothelium of blood vessels is continuously exposed to various hemodynamic forces. Flow-mediated epigenetic plasticity regulates vascular endothelial...     

Regulation of endothelial nitric oxide synthase by the actin cytoskeleton

In the present study, the association ofendothelial nitric oxide synthase (eNOS) with the actin cytoskeleton inpulmonary artery endothelial cells (PAEC) was examined. We found thatthe protein contents of eNOS, actin, and caveolin-1 were significantly higher in the caveolar fraction of plasma membranes than in the noncaveolar fraction of plasma membranes in PAEC. Immunoprecipitation of eNOS from lysates of caveolar fractions of plasma membranes in PAECresulted in the coprecipitation of actin, and immunoprecipitation ofactin from lysates of caveolar fractions resulted in thecoprecipitation of eNOS. Confocal microscopy of PAEC, in which eNOS waslabeled with fluorescein, F-actin was labeled with Texasred-phalloidin, and G-actin was labeled with deoxyribonuclease Iconjugated with Texas red, also demonstrated an association betweeneNOS and F-actin or G-actin. Incubation of purified eNOS with purifiedF-actin and G-actin resulted in an increase in eNOS activity. Theincrease in eNOS activity caused by G-actin was much higher than thatcaused by F-actin. Incubation of PAEC with swinholide A, an actinfilament disruptor, resulted in an increase in eNOS activity, eNOSprotein content, and association of eNOS with G-actin and in a decrease in the association of eNOS with F-actin. The increase in eNOS activitywas higher than that in eNOS protein content in swinholide A-treatedcells. In contrast, exposure of PAEC to phalloidin, an actin filamentstabilizer, caused decreases in eNOS activity and association of eNOSwith G-actin and increases in association of eNOS with F-actin. Theseresults suggest that eNOS is associated with actin in PAEC and thatactin and its polymerization state play an important role in theregulation of eNOS activity.

     

Dose-dependent effect of nocodazole on endothelial cell cytoskeleton

The endothelium lining the inner surface of blood vessels fulfils an important barrier function and specifically, it controls vascular membrane permeability as well as nutrient and metabolite exchange in circulating blood and tissue fluids. Disturbances in vascular endothelium barrier function (vascular endothelium dysfunction) are coupled to cytoskeleton rearrangements, actomyosin contractility, and as a consequence, formation of paracellular gaps between endothelial cells. Microtubules constitute the first effector link in the reaction cascade resulting in vascular endothelium dysfunction. Increased vascular permeability associated with many human diseases is also manifested as a side effect in anticancer mitosis-blocking therapy. The aim of this study was to examine the possibility of preventing side effects of mitostatic drugs in patients with vascular endothelium dysfunction and to establish effective doses able to disrupt the microtubular network without interfering with the endothelial barrier function. Previously, it was found that the population of endothelial cell microtubules is heterogeneous. Along with dynamic microtubules, cell cytoplasm contains a certain amount of post-translationally modified microtubules that are less active and less susceptible to external influences than dynamic microtubules. We have shown that the area occupied with stable microtubules is relatively large (approx. one third of the total cell area). We assume that it can account for a higher resistance of the endothelial monolayer to factors responsible for vascular endothelium dysfunction. This hypothesis was validated in this study, in which nocodazole was used to induce vascular endothelium dysfunction in lung endothelial cells. The effect of nocodazole on endothelial cell cytoskeleton was found to be dose-dependent. Nocodazole in micromolar concentrations not only irreversibly changed the barrier function, but also upset the viability of endothelial cells and induced their death. Nanomolar concentrations of nocodazole also increased the permeability of the endothelial monolayer; this effect was reversible at the drug concentration ranging from 100 to 200 nM. At 100 nM, nocodazole induced partial disruption of the microtubule network near the cell margin without any appreciable effect on acetylated microtubules and actin filaments. At 200 nM, nocodazole exerted a pronounced effect on the system of dynamic (but not acetylated) microtubules and increased the population of actin filaments in the central region of the cell. Our data suggest that disruption of peripheral microtubules triggers a cascade of reactions culminating in endothelial barrier dysfunction; however, the existence of a large population of microtubules resistant to nanomolar concentrations of the drug provides higher viability of endothelial cells and restores their functional activity.     

Gravisensitivity of endothelial cells: the role of cytoskeleton and adhesion molecules

The review addresses the effect of microgravity on the endothelial cells, an important mechanosensory element of the cardiovascular system that is known to undergo functional changes in space flight. The chalanges that arise in performing space flight experiments are presented, as well as approaches used to simulate microgravity effects in vitro. The role of cytoskeletal elements as the putative gravity sensors in the cells is demonstrated. The changes in the expression of adhesion molecules that may underlie the mechanisms of gravity sensing by endothelial cells are described. The possible reasons for the discrepancies between the results obtained, such as the differences between the cell lines and experimental design, the variation in time of cultivation, and the specific spaceflight related factors, are analyzed.     

The role of caldesmon in the regulation of endothelial cytoskeleton and migration

The actin- and myosin-binding protein, caldesmon (CaD) is an essential component of the cytoskeleton in smooth muscle and non-muscle cells and is involved in the regulation of cell contractility, division, and assembly of actin filaments. CaD is abundantly present in endothelial cells (EC); however, the contribution of CaD in endothelial cytoskeletal arrangement is unclear. To examine this contribution, we generated expression constructs of l-CaD cloned from bovine endothelium. Wild-type CaD (WT-CaD) and truncated mutants lacking either the N-terminal myosin-binding site or the C-terminal domain 4b (containing actin- and calmodulin-binding sites) were transfected into human pulmonary artery EC. Cell fractionation experiments and an actin overlay assay demonstrated that deleting domain 4b, but not the N-terminal myosin-binding site, resulted in decreased affinity to both the detergent-insoluble cytoskeleton and soluble actin. Recombinant WT-CaD co-localized with acto-myosin filaments in vivo, but neither of CaD mutants did. Thus both domain 4b and the myosin-binding site are essential for proper localization of CaD in EC. Overexpression of WT-CaD led to cell rounding and formation of a thick peripheral subcortical actin rim in quiescent EC, which correlated with decreased cellular migration. Pharmacological inhibition of p38 MAPK, but not ERK MAPK, caused disassembly of this peripheral actin rim in CaD-transfected cells and decreased CaD phosphorylation at Ser531 (Ser789 in human h-CaD). These results suggest that CaD is critically involved in the regulation of the actin cytoskeleton and migration in EC, and that p38 MAPK-mediated CaD phosphorylation may be involved in endothelial cytoskeletal remodeling.     

Cell rounding in cultured human astrocytes and vascular endothelial cells upon inhibition of CK2 is mediated by actomyosin cytoskeleton alterations

Protein kinase CK2 participates in a wide range of cellular events, including the regulation of cellular morphology and migration, and may be an important mediator of angiogenesis. We previously showed that in the retina, CK2 immunolocalizes mostly to vascular endothelium and astrocytes in association with the cytoskeleton. Additionally, CK2 inhibitors significantly reduced retinal neovascularization and stem cell recruitment in the mouse model of oxygen-induced proliferative retinopathy. We have also shown that CK2 and F-actin co-localized in actin stress fibers in microvascular endothelial cells, and that highly specific CK2 inhibitors caused cell rounding in astrocytes and microvascular endothelial cells, which was alleviated by serum that promotes spreading by Rho/Rho-kinase (RhoK) activation of myosin II. Therefore, we examined a possible role of CK2 in the regulation of actin-myosin II-based contractility. Treatment with CK2 inhibitors correlated with disassembly of actomyosin stress fibers and cell shape changes, including cytoplasmic retraction and process formation that were similar to those occurring during astrocyte stellation. Low doses of specific inhibitors of kinases (RhoK and MLCK) that phosphorylate myosin light chain (MLC) enhanced the effect of suboptimal CK2 inhibition on cell shape. Such striking stellation-like alteration was accompanied by decreased level of phospho-MLC, thus implying a CK2 role in regulation of actomyosin cytoskeleton. Our results suggest an important role of CK2 in the control of cell contractility and motility, which may account for suppressing effect of CK2 inhibition on retinal neovascularization. Together, our data implicate protein kinase CK2 for the first time in stellation-like morphological transformation.     

Characterization of the endothelial cell cytoskeleton following HLA class I ligation

Background

Vascular endothelial cells (ECs) are a target of antibody-mediated allograft rejection. In vitro, when the HLA class I molecules on the surface of ECs are ligated by anti-HLA class I antibodies, cell proliferation and survival pathways are activated and this is thought to contribute to the development of antibody-mediated rejection. Crosslinking of HLA class I molecules by anti-HLA antibodies also triggers reorganization of the cytoskeleton, which induces the formation of F-actin stress fibers. HLA class I induced stress fiber formation is not well understood.

Methodology and Principal Findings

The present study examines the protein composition of the cytoskeleton fraction of ECs treated with HLA class I antibodies and compares it to other agonists known to induce alterations of the cytoskeleton in endothelial cells. Analysis by tandem mass spectrometry revealed unique cytoskeleton proteomes for each treatment group. Using annotation tools a candidate list was created that revealed 12 proteins, which were unique to the HLA class I stimulated group. Eleven of the candidate proteins were phosphoproteins and exploration of their predicted kinases provided clues as to how these proteins may contribute to the understanding of HLA class I induced antibody-mediated rejection. Three of the candidates, eukaryotic initiation factor 4A1 (eIF4A1), Tropomyosin alpha 4-chain (TPM4) and DDX3X, were further characterized by Western blot and found to be associated with the cytoskeleton. Confocal microscopy analysis showed that class I ligation stimulated increased eIF4A1 co-localization with F-actin and paxillin.

Conclusions/Significance

Colocalization of eIF4A1 with F-actin and paxillin following HLA class I ligation suggests that this candidate protein could be a target for understanding the mechanism(s) of class I mediated antibody-mediated rejection. This proteomic approach for analyzing the cytoskeleton of ECs can be applied to other agonists and various cells types as a method for uncovering novel regulators of cytoskeleton changes.     

肠道病毒A组71型在人脐静脉血管内皮细胞中的增殖及对细胞骨架的影响

目的研究肠道病毒A组71型(Enterovirus group A type 71,EV-A71)在人脐静脉血管内皮细胞(Human umbilical vein endothelial cells,HUVECs)中的增殖及对细胞骨架造成的影响,初步探讨其与病毒血症发生的关系。方法采用qRT-PCR技术及免疫荧光技术检测EV-A71在HUVECs中的复制和增殖,用免疫荧光双染色技术观察三种细胞骨架在EV-A71感染后的变化。结果 EV-A71能够有效感染HUVECs,且感染后24 h在细胞内复制达到高峰。病毒感染后微丝骨架完全解聚,微管骨架排列方式发生改变,而中间纤维结构模糊不清;同时检测到微管及中间纤维与病毒抗原共存。结论 EV-A71可以感染HUVECs并在其内有效复制增殖,同时诱导HUVECs三种细胞骨架发生改变,提示细胞骨架可能参与EV-A71感染HUVECs的过程。     

Theoretical estimates of mechanical properties of the endothelial cell cytoskeleton.

Current modeling of endothelial cell mechanics does not account for the network of F-actin that permeates the cytoplasm. This network, the distributed cytoplasmic structural actin (DCSA), extends from apical to basal membranes, with frequent attachments. Stress fibers are intercalated within the network, with similar frequent attachments. The microscopic structure of the DCSA resembles a foam, so that the mechanical properties can be estimated with analogy to these well-studied systems. The moduli of shear and elastic deformations are estimated to be on the order of 10(5) dynes/cm2. This prediction agrees with experimental measurements of the properties of cytoplasm and endothelial cells reported elsewhere. Stress fibers can potentially increase the modulus by a factor of 2-10, depending on whether they act in series or parallel to the network in transmitting surface forces. The deformations produced by physiological flow fields are of insufficient magnitude to disrupt cell-to-cell or DCSA cross-linkages. The questions raised by this paradox, and the ramifications of implicating the previously unreported DCSA as the primary force transmission element are discussed.     

Structural alteration of the endothelial glycocalyx: contribution of the actin cytoskeleton

The endothelial glycocalyx is a carbohydrate–protein layer that lines the luminal surface of the endothelium. It anchors to the cell membrane via its core proteins that share extended link to the actin cytoskeleton. It is widely accepted that those protein domains and the attached carbohydrates are susceptible to pathological changes. It is unclear, however, to what extent the actin cytoskeleton contributes to the glycocalyx stability. In this study, we investigate the role of the actin cytoskeleton in the maintenance of the glycocalyx under static and laminar flow conditions in vitro. Our results show that in the static culture medium neither rapid actin depolymerisation nor prolonged actin disturbance leads to glycocalyx disruption from the apical surface of human umbilical vein endothelial cells. However, when endothelial cells are exposed to laminar flow for 24 h, the glycocalyx is seen to shift to the downstream peripheral region of the cell surface. The mean fluorescence intensity decreases to \(91.9 \pm 2.5\%\) of the control. When actin depolymerisation is introduced, the intensity decreases significantly to \(54.7 \pm 1.3\%\), indicating a severe disruption of the glycocalyx. Similar changes are observed in human aortic endothelial cells, where the intensity of the glycocalyx is reduced to \(72.8 \pm 1.6\%\) of the control. Collectively, we demonstrate that the actin cytoskeleton contributes to structural stability of the glycocalyx under shear stress. Our results can be used to develop new strategies to prevent shedding of the glycocalyx in cardiovascular diseases.