5-Fluorouracil interferes with actin organization, stress fiber formation and cell migration in corneal endothelial cells during wound repair along the natural basement membrane

Corneal endothelial cells respond to a circular freeze wound by undergoing actin cytoskeletal reorganization that is mainly characterized by the disappearance of circumferential microfilament bundles (CMBs) and the subsequent appearance of distinct stress fibers. This cytoskeletal rearrangement is associated with changes in cell shape as migrating cells lose their polyhedral appearance, spread out, and assume a stellate morphology with cell processes extending outward into the injured area. We report here that in the presence of low concentrations (0.01-0.l mM) of the anti-metabolite 5-fluorouracil (5-FU), characteristic actin organization becomes disrupted and migrating cells do not display elongated processes typical of control tissues and translocation into the injury zone is retarded, but not inhibited. Rhodamine phalloidin staining revealed no evidence of stress fiber formation. A higher concentration of 5-FU (1.0 mM) not only prevented formation of discernible stress fibers but also resulted in a more restricted cell movement during wound repair. That this was not a cytotoxic effect was demonstrated by transferring tissues back into standard medium allowing endothelia to reinitiate migration and undergo complete wound healing by 72 h post-transfer. Overnight incubation of endothelia in 4 muM phallacidin resulted in limited CMB disruption the extent of which was dependent on the 5-FU concentration. The effects of 5-FU on the actin cytoskeleton are reversible and by 24 h after placing treated endothelia into medium without 5-FU, actin begins to become re-established and by 48 h microfilament patterns in the tissue resemble those of non-treated endothelia. Similarly, when non-injured tissues are cultured in the presence of 5-FU for 24 h, subsequently injured and returned to standard medium, they exhibit no stress fibers when observed at 24 h post-wounding. However, by 48 h post-injury these cells now display stress fibers and extend processes into the wound area. Biochemical studies on isolated muscle actin demonstrated that actin polymerization is unaffected in the presence of either 0.01 or 1 mM 5-FU as determined by the F-actin sedimentation and falling ball viscosity techniques. Thus, the mechanism(s) by which 5-FU exerts its actions on the actin cytoskeleton appears to be one of an indirect nature.     

Thrombospondin: biosynthesis, distribution, and changes associated with wound repair in corneal endothelium

Thrombospondin is a cell adhesion molecule which interacts via specific domains with a wide array of extracellular matrix components, including fibrinogen, fibrin, fibronectin, collagen, and heparan sulfate proteoglycan. Although this protein has been localized in several human tissues, its presence in corneal tissues had not been previously established. In the present study, we have demonstrated that cultured bovine corneal endothelial cells synthesize thrombospondin and incorporate it into their extracellular matrix. We have also shown immunofluorescently the presence and distribution of thrombospondin in these cultured cells and in the noninjured and injured corneal endothelium in situ. Ultrastructural immunoperoxidase cytochemistry revealed that thrombospondin could be displaced from the cell surface by heparin, but not by keratan sulfate. Confluent cultures of corneal endothelium synthesize and secrete the three cell adhesion proteins laminin, thrombospondin, and fibronectin in the ratios 1:8.2:51.8. Only the laminin B chains were detected in immunoprecipitates. Immunofluorescent studies of these cultured cells, using a polyclonal antiserum raised against purified thrombospondin, revealed a low level of fluorescence associated with the cell layer but a punctate fluorescent pattern at the level of the extracellular matrix. Noninjured corneal endothelium in situ also demonstrated a low level of fluorescence throughout the cell layer. However, this dramatically changed after a circular freeze injury to the tissue. By 24 h after wounding, cells surrounding the injury zone displayed a prominent fluorescence that was still observed at 48 h post-injury. In addition to its increased intracellular fluorescence, thrombospondin was also localized as migration tracks, oriented in the direction of cellular migration into the wound site. Thus, in corneal endothelium, thrombospondin appears to play a major role in injury-induced cell migration in situ along a natural basement membrane.     

Connexin43 modulates cell polarity and directional cell migration by regulating microtubule dynamics

Knockout mice deficient in the gap junction gene connexin43 exhibit developmental anomalies associated with abnormal neural crest, primordial germ cell, and proepicardial cell migration. These migration defects are due to a loss of directional cell movement, and are associated with abnormal actin stress fiber organization and a loss of polarized cell morphology. To elucidate the mechanism by which Cx43 regulates cell polarity, we used a wound closure assays with mouse embryonic fibroblasts (MEFs) to examine polarized cell morphology and directional cell movement. Studies using embryonic fibroblasts from Cx43 knockout (Cx43KO) mice showed Cx43 deficiency caused cell polarity defects as characterized by a failure of the Golgi apparatus and the microtubule organizing center to reorient with the direction of wound closure. Actin stress fibers at the wound edge also failed to appropriately align, and stabilized microtubule (Glu-tubulin) levels were markedly reduced. Forced expression of Cx43 with deletion of its tubulin-binding domain (Cx43dT) in both wildtype MEFs and neural crest cell explants recapitulated the cell migration defects seen in Cx43KO cells. However, forced expression of Cx43 with point mutation causing gap junction channel closure had no effect on cell motility. TIRF imaging revealed increased microtubule instability in Cx43KO cells, and microtubule targeting of membrane localized Cx43 was reduced with expression of Cx43dT construct in wildtype cells. Together, these findings suggest the essential role of Cx43 gap junctions in development is mediated by regulation of the tubulin cytoskeleton and cell polarity by Cx43 via a nonchannel function.     

Effects of corticosteroid-induced apoptosis on airway epithelial wound closure in vitro

Damage to the airway epithelium is common in asthma. Corticosteroids induce apoptosis in and suppress proliferation of airway epithelial cells in culture. Whether apoptosis contributes to impaired epithelial cell repair after injury is not known. We examined whether corticosteroids would impair epithelial cell migration in an in vitro model of wound closure. Wounds (approximately 0.5-1.3 mm2) were created in cultured 1HAEo- human airway epithelial cell monolayers, after which cells were treated with up to 10 microM dexamethasone or budesonide for 24 h. Cultured cells were pretreated for 24 or 48 h with dexamethasone to observe the effect of long-term exposure on wound closure. After 12 h, the remaining wound area in monolayers pretreated for 48 h with 10 microM dexamethasone was 43+/-18% vs. 10+/-8% for untreated control monolayers. The addition of either corticosteroid immediately after injury did not slow closure significantly. After 12 h the remaining wound area in monolayers treated with 10 microM budesonide was 39+/-4% vs. 43+/-3% for untreated control monolayers. The proportion of apoptotic epithelial cells as measured by terminal deoxynucleotidyltransferase-mediated dUTP biotin nick end labeling both at and away from the wound edge was higher in monolayers treated with budesonide compared with controls. However, wound closure in the apoptosis-resistant 1HAEo-.Bcl-2+ cell line was not different after dexamethasone treatment. We demonstrate that corticosteroid treatment before mechanical wounding impairs airway epithelial cell migration. The addition of corticosteroids after injury does not slow migration, despite their ability to induce apoptosis in these cells.     

Role of boundary conditions in an experimental model of epithelial wound healing

Coordinated cell movements in epithelial layers are essential for proper tissue morphogenesis and homeostasis, but our understanding of the mechanisms that coordinate the behavior of multiple cells in these processes is far from complete. Recent experiments with Madin-Darby canine kidney epithelial monolayers revealed a wave-like pattern of injury-induced MAPK activation and showed that it is essential for collective cell migration after wounding. To investigate the effects of the different aspects of wounding on cell sheet migration, we engineered a system that allowed us to dissect the classic wound healing assay. We studied Madin-Darby canine kidney sheet migration under three different conditions: 1) the classic wound healing assay, 2) empty space induction, where a confluent monolayer is grown adjacent to a slab of polydimethylsiloxane and the monolayer is not injured but allowed to migrate upon removal of the slab, and 3) injury via polydimethylsiloxane membrane peel-off, where an injured monolayer migrates onto plain tissue culture surface, as in the case of empty space induction allowing for direct comparison. By tracking the motion of individual cells within the sheet under these three conditions, we show how the dynamics of the individual cells' motion is responsible for the coordinated migration of the sheet and is coordinated with the activation of ERK1/2 MAPK. In addition, we demonstrate that the propagation of the waves of MAPK activation depends on the generation of reactive oxygen species at the wound edge.     

The Role of Microtubules and Their Dynamics in Cell Migration

Although microtubules have long been implicated in cell locomotion, the mechanism of their involvement remains controversial. Most studies have concluded that microtubules play a positive role by regulating actin polymerization, transporting membrane vesicles to the leading edge, and/or facilitating the turnover of adhesion plaques. Here we used wild-type and mutant CHO cell lines with alterations in tubulin to demonstrate that microtubules can also act to restrain cell motility. Tubulin mutations or low concentrations of drugs that suppress microtubule dynamics without affecting the amount of microtubule polymer inhibited the rate of migration by preventing microtubule reorganization in the trailing portion of the cells where the more dynamic microtubules are normally found. Under these conditions, cells along the edge of a wound still extended lamellipodia and elongated toward the wound but were inhibited in their ability to retract their tails, thus retarding forward progress. The idea that microtubules normally act to restrain cell locomotion was confirmed by treating cells with high concentrations of nocodazole to depolymerize the microtubule network. In the absence of microtubules, wild-type CHO and HeLa cells could still move at near normal speeds, but the movement became more random. We conclude that microtubules act both to restrain cell movement and to establish directionality.     

Shear stress enhances human endothelial cell wound closure in vitro

Repair of the endothelium occurs in the presence of continued blood flow, yet the mechanisms by which shear forces affect endothelial wound closure remain elusive. Therefore, we tested the hypothesis that shear stress enhances endothelial cell wound closure. Human umbilical vein endothelial cells (HUVEC) or human coronary artery endothelial cells (HCAEC) were cultured on type I collagen-coated coverslips. Cell monolayers were sheared for 18 h in a parallel-plate flow chamber at 12 dyn/cm(2) to attain cellular alignment and then wounded by scraping with a metal spatula. Subsequently, the monolayers were exposed to a laminar shear stress of 3, 12, or 20 dyn/cm(2) under shear-wound-shear (S-W-sH) or shear-wound-static (S-W-sT) conditions for 6 h. Wound closure was measured as a percentage of original wound width. Cell area, centroid-to-centroid distance, and cell velocity were also measured. HUVEC wounds in the S-W-sH group exposed to 3, 12, or 20 dyn/cm(2) closed to 21, 39, or 50%, respectively, compared with only 59% in the S-W-sT cells. Similarly, HCAEC wounds closed to 29, 49, or 33% (S-W-sH) compared with 58% in the S-W-sT cells. Cell spreading and migration, but not proliferation, were the major mechanisms accounting for the increases in wound closure rate. These results suggest that physiological levels of shear stress enhance endothelial repair.     

Regulation of stomatal movement by cortical microtubule organization in response to darkness and ABA signaling in <Emphasis Type="Italic">Arabidopsis</Emphasis>

Microtubule dynamics are essential for plant cell development and in producing responses to external stimuli. However, little is known about the regulation of microtubule dynamics or crosstalk between microtubule and stomatal movement. Here we identified microtubule reorganization as a crucial factor determining guard cell responses to dark and abscisic acid (ABA) signaling. As stomata opened, guard cells exhibited radially arranged cortical microtubules, which depolymerized into the cytosol when exposed to darkness and ABA. Suppression of microtubule disassembly by paclitaxel, a microtubule-stabilizing drug, significantly enhanced stomatal aperture under light, and partially blocked ABA- or darkness-induced stomatal closure. However, treatment with only the anti-microtubule drug, oryzalin, did not affect stomatal movement with or without external stimuli. Phosphatidic acid (PA) bound to a clade A type 2C protein phosphatase (PP2C), PP2CA, and deletion of PP2CA partially inhibited PA-induced microtubule depolymerization and stomatal closure. Moreover, microtubule reorganization was altered in the ABA-insensitive mutant pldα1, but not in the ABA-hypersensitive mutant pp2ca. We propose that a faithfully balanced reorganization of microtubules fulfills fundamental functions to enable the fast change of stomata in plant adaptive responses to developmental and environmental cues.     

支架蛋白IQGAP1参与气道上皮细胞损伤修复过程

气道上皮损伤修复过程包括细胞延伸、迁移和增殖.IQGAP1 (IQ domain GTPase-activating protein 1)是一个在许多细胞生命活动中非常有意义的蛋白,但其在肺上皮细胞中的作用尚未阐述清楚.本文采用目前广泛应用的刮伤气道上皮细胞的体外模型来研究IQGAP1的功能.结果显示,IQGAP1在小鼠、大鼠、猪和人气道上皮细胞中有丰富表达.它与微管骨架共定位,可被微管解聚剂nocodazole破坏.刮伤6～9h后,IQGAP1 mRNA及蛋白表达上调.过表达外源性IQGAP1导致β-catenin核转位,从而活化Tcf/Lef信号.此外,刮伤还影响IQGAP1与β-catenin、结肠腺瘤病(adenomatous polyposis coli, APC)蛋白及细胞质连接蛋白-170 (cytoplasmic linker protein-170, CLIP-170)之间的相互作用.通过小干扰RNA (small interference RNA, siRNA)沉默IQGAP1表达则明显延迟损伤愈合.结果提示,IQGAP1信号参与气道上皮细胞损伤修复过程.     

VEGF-A165 Potently Induces Human Blood–Nerve Barrier Endothelial Cell Proliferation, Angiogenesis, and Wound Healing In Vitro

Several mitogens such as vascular endothelial growth factor (VEGF) have been implicated in mammalian vascular proliferation and repair. However, the molecular mediators of human blood-nerve barrier (BNB) development and specialization are unknown. Primary human endoneurial endothelial cells (pHEndECs) were expanded in vitro and specific mitogen receptors detected by western blot. pHEndECs were cultured with basal medium containing different mitogen concentrations with or without heparin. Non-radioactive cell proliferation, Matrigel^?-induced angiogenesis and sterile micropipette injury wound healing assays were performed. Proliferation rates, number and total length of induced microvessels, and rate of endothelial cell monolayer wound healing were determined and compared to basal conditions. VEGF-A₁₆₅ in the presence of heparin, was the most potent inducer of pHEndEC proliferation, angiogenesis, and wound healing in vitro. 1.31 nM VEGF-A₁₆₅ induced ~110 % increase in cell proliferation relative to basal conditions (～51 % without heparin). 2.62 pM VEGF-A₁₆₅ induced a three-fold increase in mean number of microvessels and 3.9-fold increase in total capillary length/field relative to basal conditions. In addition, 0.26 nM VEGF-A₁₆₅ induced ～1.3-fold increased average rate of endothelial wound healing 4–18 h after endothelial monolayer injury, mediated by increased cell migration. VEGF-A₁₆₅ was the only mitogen capable of complete wound closure, occurring within 30 h following injury via increased cell proliferation. This study demonstrates that VEGF-A₁₆₅, in the presence of heparin, is a potent inducer of pHEndEC proliferation, angiogenesis, and wound healing in vitro. VEGF-A₁₆₅ may be an important mitogen necessary for human BNB development and recovery in response to peripheral nerve injury.     

Microtubule system in endothelial barrier dysfunction: Disassembly of peripheral microtubules and microtubule reorganization in internal cytoplasm

Endothelial cell barrier dysfunction is associated with dramatic cytoskeletal reorganization, the activation of actomyosin contraction, and, finally, gap formation. Although the role of microtubules in the regulation of endothelial cell barrier function is not fully understood, a number of observations allow for the assumption that the reaction of the microtubule is an extremely important part in the development of endothelial dysfunction. These observations have forced us to examine the role of microtubule reorganization in the regulation of the endothelial cell barrier function. In quiescent endothelial cells, microtubule density is the highest in the centrosome region; however, microtubules are also present near the cell margin. The analysis of microtubule distribution after specific antibody staining using the method of measurement of their fluorescence intensity showed that, in control endothelial cells, the reduction of fluorescence intensity from the cell center to its periphery is described by the equation of exponential regression. The edemagenic agent, thrombin (25 nM), caused the rapid increase of endothelial cell barrier permeability accompanied by a fast decrease in quantity of the peripheral microtubules and reorganization of the microtubule system in the internal cytoplasm of endothelial cells (the decrease of fluorescence intensity is described by the equation of linear regress within as little as 5 min after the beginning of treatment). Both effects are reversible; within 60 min after the beginning of treatment, the microtubule network does not differ from the standard one. Thus, the microtubule system is capable of adapting to the influence of a natural regulator, thrombin. The reorganization of microtubules develops more quickly than the reorganization of the actin filaments system responsible for the subsequent changes of the cell shape during barrier dysfunction. Apparently, the microtubules are the first part in the circuit of the reactions leading to the pulmonary endothelial cell barrier compromise.     

Smooth muscle cell response to mechanical injury involves intracellular calcium release and ERK1/ERK2 phosphorylation

We have investigated possible signaling pathways coupled to injury-induced ERK1/2 activation and the subsequent initiation of vascular rat smooth muscle cell migration and proliferation. Aortic smooth muscle cells were cultured to confluency and subjected to in vitro injury under serum-free conditions. In fluo-4-loaded cells, injury induced a rapid wave of intracellular Ca(2+) release that propagated about 200 microm in radius from the injured zone, reached a peak in about 20 s, and subsided to the baseline within 2 min. The wave was abolished by prior treatment with the sarcoplasmic reticulum ATPase inhibitor thapsigargin, but not by omission of extracellular Ca(2+). ERK1/2 activation reached a peak at 10 min after injury and was inhibited by the MEK1 inhibitor PD98059, as well as by thapsigargin, fluphenazine, genistein, and the Src inhibitor PP2. These inhibitors also reduced [(3)H]thymidine incorporation and migration of cells into the injured area determined at 48 h after injury. These results show that mechanical injury to vascular smooth muscle cells induces a Ca(2+) wave which is dependent on intracellular Ca(2+) release. Furthermore, the injury activates ERK1/2 phosphorylation as well as cell migration and replication.     

Dynamics of cell movement during the wound repair of human surface respiratory epithelium.

Epithelial wound repair represents an important process by which the epithelial barrier integrity recovers after wounding. To evaluate and quantify the dynamics of surface airway cell movement during the wound repair process, we developed an in vitro wounding model of human respiratory cells in culture and we analyzed the wound repair by using videomicroscopic and image analysis techniques. We observed that wound closure occurred within 6 hours, due to the spreading and migration of the cells surrounding the wounded surface. The migration rate of the cells at the leading edge of the wound surface increased progressively up to 26 microns/h during the repair process which was characterized by a uniform centripetal direction of cell movement. The distance travelled by these cells was 2.5 fold longer than the distance travelled by ciliated cells which were located far from the wound area. These results suggest that cell migration after wounding is an important process by which the respiratory epithelial barrier integrity is maintained.     

Vascular endothelial wound closure under shear stress: role of membrane fluidity and flow-sensitive ion channels.

Sufficiently rapid healing of vascular endothelium following injury is essential for preventing further pathological complications. Recent work suggests that fluid dynamic shear stress regulates endothelial cell (EC) wound closure. Changes in membrane fluidity and activation of flow-sensitive ion channels are among the most rapid endothelial responses to flow and are thought to play an important role in EC responsiveness to shear stress. The goal of the present study was to probe the role of these responses in bovine aortic EC (BAEC) wound closure under shear stress. BAEC monolayers were mechanically wounded and subsequently subjected to either "high" (19 dyn/cm(2)) or "low" (3 dyn/cm(2)) levels of steady shear stress. Image analysis was used to quantify cell migration and spreading under both flow and static control conditions. Our results demonstrate that, under static conditions, BAECs along both wound edges migrate at similar velocities to cover the wounded area. Low shear stress leads to significantly lower BAEC migration velocities, whereas high shear stress results in cells along the upstream edge of the wound migrating significantly more rapidly than those downstream. The data also show that reducing BAEC membrane fluidity by enriching the cell membrane with exogenous cholesterol significantly slows down both cell spreading and migration under flow and hence retards wound closure. Blocking flow-sensitive K and Cl channels reduces cell spreading under flow but has no impact on cell migration. These findings provide evidence that membrane fluidity and flow-sensitive ion channels play distinct roles in regulating EC wound closure under flow.     

Mesenchymal stem cells promote alveolar epithelial cell wound repair in vitro through distinct migratory and paracrine mechanisms

Background

Mesenchymal stem cells (MSC) are in clinical trials for widespread indications including musculoskeletal, neurological, cardiac and haematological disorders. Furthermore, MSC can ameliorate pulmonary fibrosis in animal models although mechanisms of action remain unclear. One emerging concept is that MSCs may have paracrine, rather than a functional, roles in lung injury repair and regeneration.

Methods

To investigate the paracrine role of human MSC (hMSC) on pulmonary epithelial repair, hMSC-conditioned media (CM) and a selected cohort of hMSC-secretory proteins (identified by LC-MS/MS mass spectrometry) were tested on human type II alveolar epithelial cell line A549 cells (AEC) and primary human small airway epithelial cells (SAEC) using an in vitro scratch wound repair model. A 3D direct-contact wound repair model was further developed to assess the migratory properties of hMSC.

Results

We demonstrate that MSC-CM facilitates AEC and SAEC wound repair in serum-dependent and –independent manners respectively via stimulation of cell migration. We also show that the hMSC secretome contains an array of proteins including Fibronectin, Lumican, Periostin, and IGFBP-7; each capable of influencing AEC and SAEC migration and wound repair stimulation. In addition, hMSC also show a strong migratory response to AEC injury as, supported by the observation of rapid and effective AEC wound gap closure by hMSC in the 3D model.

Conclusion

These findings support the notion for clinical application of hMSCs and/or their secretory factors as a pharmacoregenerative modality for the treatment of idiopathic pulmonary fibrosis (IPF) and other fibrotic lung disorders.     

Distribution of microtubule organizing centers in migrating sheets of endothelial cells

This study was designed to investigate the relationship between the position of the microtubule organizing center (MTOC) and the direction of migration of a sheet of endothelial cells (EC). Using immunofluorescence and phase microscopy the MTOC's of migrating EC were visualized as the cells moved into an in vitro experimental wound produced by mechanical denudation of part of a confluent monolayer culture. Although the MTOC's in nonmigrating EC were randomly positioned in relation to the nucleus, in migrating cells the position of the MTOC's changed so that 80% of the cells had the MTOC positioned in front of the nucleus toward the direction of movement of the endothelial sheet. This repositioning of the MTOC occurred within the first 4 h after wounding and was associated with the beginning of migration of EC's into the wounded area as seen by time-lapse cinemicrophotography. These studies focus attention on the MTOC as a cytoskeletal structure that may play a role in determining the direction of cell movement.