In Vitro Model of Tumor Cell Extravasation

Tumor cells that disseminate from the primary tumor and survive the vascular system can eventually extravasate across the endothelium to metastasize at a secondary site. In this study, we developed a microfluidic system to mimic tumor cell extravasation where cancer cells can transmigrate across an endothelial monolayer into a hydrogel that models the extracellular space. The experimental protocol is optimized to ensure the formation of an intact endothelium prior to the introduction of tumor cells and also to observe tumor cell extravasation by having a suitable tumor seeding density. Extravasation is observed for 38.8% of the tumor cells in contact with the endothelium within 1 day after their introduction. Permeability of the EC monolayer as measured by the diffusion of fluorescently-labeled dextran across the monolayer increased 3.8 fold 24 hours after introducing tumor cells, suggesting that the presence of tumor cells increases endothelial permeability. The percent of tumor cells extravasated remained nearly constant from1 to 3 days after tumor seeding, indicating extravasation in our system generally occurs within the first 24 hours of tumor cell contact with the endothelium.     

Fibrin contact increases endothelial permeability to albumin.

We studied the effects of contact of bovine pulmonary artery endothelial cell monolayers with fibrin on the endothelial barrier function. Fibrin formed by clotting purified fibrinogen (0.5 to 3.0 mg/ml) with alpha-thrombin (1 U/ml) was added to endothelial monolayers and permeability measurements were made after fibrin removal. Fibrin incubation for 3 hours resulted in 2- to 5-fold increases in transendothelial 125I-albumin permeability. Permeability returned to baseline value within 3 hours after fibrin removal. Direct contact with fibrin was necessary for the response, since fibrin separated from the endothelium did not increase permeability. Contact with agarose (2 mg/ml) or fibrinogen (0.5 to 3.0 mg/ml) also did not increase endothelial permeability. Transmission electron microscopic examination indicated normal appearance of interendothelial junctions at a time when albumin permeability was increased and no overt evidence of endothelial injury. Incubation of fibrin with endothelial monolayers at 4 degrees C prevented the increase in albumin permeability. We examined the possibility that increased albumin transcytosis was responsible for fibrin's effect using 14C-sucrose (Mr = 342D), a lipid insoluble tracer. Fibrin increased sucrose flux by 1.5-fold compared to 2- to 5-fold increases in albumin flux. The results indicate that fibrin contact with the endothelial cell increases endothelial permeability. The effect of fibrin may involve activation of temperature-sensitive bulk phase transcytosis of albumin.     

Modulation of microvascular growth and morphogenesis by reconstituted basement membrane gel in three-dimensional cultures of rat aorta: A comparative study of angiogenesis in Matrigel,collagen, fibrin,and plasma clot

Summary Rings of rat aorta cultured in Matrigel, a reconstituted gel composed of basement membrane molecules, gave rise to three-dimensional networks composed of solid cellular cords and occasional microvessels with slitlike lumina. Immunohistochemical and ultrastructural studies showed that the solid cords were composed of endothelial sprouts surrounded by nonendothelial mesenchymal cells. The angiogenic response of the aortic rings in Matrigel was compared to that obtained in interstitial collagen, fibrin, or plasma clot. Morphometric analysis demonstrated that the mean luminal area of the microvascular sprouts and channels was significantly smaller in Matrigel than in collagen, fibrin, or plasma clot. The percentage of patent microvessels in Matrigel was also markedly reduced. Autoradiographic studies of³H-thymidine-labeled cultures showed reduced DNA synthesis by developing microvessels in Matrigel. The overall number of solid endothelial cords and microvessels was lower in Matrigel than in fibrin or plasma clot. A mixed cell population isolated from Matrigel cultures formed a monolayer in collagen or fibrin-coated dishes but rapidly reorganized into a polygonal network when plated on Matrigel. The observation that gels composed of basement membrane molecules modulate the canalization, proliferation, and organization into networks of vasoformative endothelial cells in three-dimensional cultures supports the hypothesis that the basement membrane is a potent regulator of microvascular growth and morphogenesis. This work was supported by grants from the W. W. Smith Charitable Trust and grants CA14137 and HL43392 from the National Institutes of Health, Bethesda, MD.     

Fibrin II induces endothelial cell capillary tube formation

We studied the formation of capillary tubes by endothelial cells which were sandwiched between two fibrin gels under serum-free conditions. After formation of the overlying fibrin gel, the endothelial cell monolayer rearranged into an extensive net of capillary tubes. Tube formation was apparent at 5 h and was fully developed by 24 h. The capillary tubes were vacuolated, and both intracellular and intercellular lumina were present. Maximal tube formation was observed with fibrin II (which lacks both fibrinopeptide A and B), minimal tube formation with fibrin I (which lacks only fibrinopeptide A), and complete absence of tube formation with fibrin 325 (which lacks the NH2- terminal beta 15-42 sequence, in addition to fibrinopeptides A and B). The inability of fibrin 325 to stimulate capillary tube formation supports the idea that beta 15-42 plays an important role in this process, and its importance was confirmed by the finding that exogenous soluble beta 15-42 inhibited fibrin II-induced capillary tube formation. This effect was specific for fibrin, since beta 15-42 did not inhibit tube formation by endothelial cells sandwiched between collagen gels. The interaction of the apical surface of the endothelial cell with the overlying fibrin II gel, as opposed to the underlying fibrin gel upon which the cells were seeded, was necessary for capillary tube formation. These studies suggest that the beta 15-42 sequence of fibrin interacts with a component of the apical cell surface and that this interaction plays a fundamental role in the induction of endothelial capillary tube formation.     

The effect of fibrin on endothelial cell migration in vitro

Endothelial cells are known to migrate and come into contact with fibrin during numerous physiological processes, such as in wound healing and in tumor growth. The present study was initiated to investigate the effect of fibrin on endothelial cell migration in vitro. Endothelial cell migration was assayed by wounding confluent monolayers of bovine aortic endothelial cells with a razor blade and counting the number of cells crossing the wound per unit time. Wound-induced proliferation of endothelial cells was inhibited by mitomycin C-treatment without affecting endothelial cell migration, indicating that in this assay migration could be measured independent of proliferation. Migration of endothelial cells in vitro was inhibited by fibrin in a concentration dependent manner. Endothelial cell migration under fibrin was further reduced by plasminogen depletion of the serum, and fibrin still inhibited the migration of mitomycin C-treated endothelial cells. Kadish et al. (Tissue and Cell, 11, 99, 1979) previously reported that fibrin did not affect EC migration in vitro. The inability to inhibit EC migration with fibrin appears to be due to their assay system which employed agarose, since pre-treating the wounded monolayer with agarose eliminated the inhibition of EC migration by fibrin. The present results indicate that EC migration in vitro can be used as a model system for studying the interaction of fibrin with EC.     

Vascular endothelial cells maintained in the absence of fibroblast growth factor undergo structural and functional alterations that are incompatible with their in vivo differentiated properties

Vascular endothelial cells cultured in the presence of fibroblast growth factor (FGF) adopt at confluence a morphological appearance similar to that of the vascular endothelium in vivo. Similarly, their apical cell surface is, as in vivo, nonthrombogenic. In contrast, when the cultures are maintained in the absence of FGF, the cells undergo within two to three passages structural and functional alterations that are incompatible with their in vivo morphological appearance and physiological function. Cultures maintained in the absence of FGF no longer adopt, upon reaching confluence, the configuration of a monolayer composed of small closely apposed and nonoverlapping, cuboidal cells. Instead, confluent cultures deprived of FGF consist of large, overlapping cells which have lost the polarity of cell surface characteristic of the vascular endothelium. The apical cell surface becomes thrombogenic, as reflected by its ability to bind platelets, whereas fibronectin, which at confluence is normally associated only with the basal cell surface, can be found both on top of and underneath the cell layer. Among other changes, both sparse and confluent cultures maintained in the absence of FGF showed a greatly increased production of fibronectin. CSP-60, a cell surface protein whose appearance is correlative with the adoption of a cell monolayer configuration, can no longer be detected in cultures maintained in the absence of FGF. Overlapping endothelial cells maintained in the absence of FGF can also no longer function as a protective barrier against the uptake of ligands such as low density lipoprotein. Exposure of the culture to FGF induces a restoration of the normal endothelial characteristics concomitant with the adoption of a flattened cell monolayer morphology. These results demonstrate that, in addition to being a mitogen. FGF is involved in controlling the differentiation and phenotypic expression of the vascular endothelium. This is reflected by its effect on the morphological appearance, polarity of cell surfaces, platelet binding capacity, and barrier function of the vascular endothelium.     

TUMOR ANGIOGENESIS : Rapid Induction of Endothelial Mitoses Demonstrated by Autoradiography

Walker ascites tumor cells and an extract derived from such cells (tumor angiogenesis factor, TAF) were injected into the subcutaneous tissue of rats by using a dorsal air sac technique. At intervals thereafter, thymidine-³H was injected into the air sac and the tissues were examined by autoradiography and electron microscopy. Autoradiographs of 1µ thick Epon sections showed thymidine-³H labeling in endothelial cells of small vessels 1–3 mm from the site of implantation, as early as 6–8 hr after exposure to live tumor cells At this time interval endothelial cells appeared histologically normal. DNA synthesis by endothelium subsequently increased and within 48 hr new blood vessel formation was detected. The presence of thymidine-³H-labeled endothelial nuclei, endothelial mitoses, and regenerating-type endothelium was confirmed by electron microscopy. TAF also induced neovascularization and endothelial cell DNA synthesis after 48 hr. A similar response was not evoked in saline controls. Formic acid, which elicited a more intense inflammatory response, was associated with less endothelial labeling and neovascularization at the times studied. Pericytes and other connective tissue cells were also stimulated by live tumor cells and TAF. The mechanism of new blood vessel formation induced by tumors is still unknown but our findings argue against cytoplasmic contact or nonspecific inflammation as prerequisites for tumor angiogenesis.     

A pathway of coagulation on endothelial cells

Although the endothelial cell is considered antithrombogenic, endothelium has recently been shown to participate in procoagulant reactions. Factor IX bound to specific endothelial cell sites can be activated by the intrinsic and extrinsic pathways of coagulation. Perturbation of endothelium results in induction of tissue factor which promotes factor VIIa-mediated activation of factors IX and X, thus initiating procoagulant events on the endothelial surface. Cell bound factor IXa, in the presence of factor VIII, promotes activation of factor X. The factor Xa formed can interact with endothelial cell factor V/Va, resulting in prothrombin activation. Thrombin then cleaves fibrinogen and a fibrin clot closely associated with the endothelial cell forms. The perturbed endothelial cell thus provides a focus of localized procoagulant events. This model suggests a simple endothelial-cell-dependent mechanism for initiation of coagulation at the site of an injured or pathological vessel.     

Proinflammatory and procoagulant effects of herpes simplex infection on human endothelium

Atherosclerotic lesions have been reported to contain herpes simplex virus (HSV) genomic material. This and other evidence suggests that latent viral infection may be an atherogenic trigger. Moreover, active HSV lesions manifest histologically marked fibrin deposition in microvessels. Our laboratory tested in vitro whether HSV infection would cause human umbilical vein endothelial cells to become procoagulant and attract inflammatory cells. Early infection of human endothelial cells with HSV-1 alters the surface conformation as detected by merocyanine 540 staining. The efficiency of prothrombinase complex assembly increases, resulting in a two- to threefold accelerated rate of thrombin generation on the cell surface of virally infected endothelium. HSV infection of endothelium results in a marked increase in thrombin-induced platelet adhesion with a concomitant decrease in prostacyclin secretion in response to thrombin. Viral infection enhances coagulation by decreasing endothelial thrombomodulin expression and subsequent activation of protein C. Viral infection also induces tissue factor in human endothelial cells within 4 hours of infection. Not only does the endothelial monolayer become procoagulant when infected with HSV, it also becomes a more adherent surface for granulocytes. Resting and stimulated granulocyte adherence is enhanced twofold on virally infected endothelium. Enhanced adhesion is accompanied by excessive granulocyte-mediated lysis of 51Cr-labeled HSV-infected endothelium and endothelial cell detachment from its substrate. Exaggerated endothelial detachment correlated with poor binding of infected endothelial cells to substratum matrix proteins. Resuspended virus-infected cells bound significantly less well to tissue culture containers coated with fibronectin, laminin, and type IV collagen. HSV-infected endothelium alters the anticoagulant properties of the endothelium causing it to become procoagulant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conditioned medium from endothelial cell cultures can restore the normal phenotypic expression of vascular endothelium maintained in vitro in the absence of fibroblast growth factor

Bovine vascular endothelial cells continuously maintained and grown in the presence of FGF adopt at confluence the configuration of a cell monolayer composed of contact-inhibited cells which do not overgrow each other and which are highly flattened and closely apposed. Such cultures exhibit structural and morphological characteristics similar to those observed with their in vivo counterparts. These include the production of an extracellular matrix consisting mostly of basement membrane collagen and fibronectin localized exclusively beneath the cell monolayer, but not on top of it, as well as a nonthrombogenic, blood-compatible apical cell surface. Removal of fibroblast growth factor (FGF) from adult bovine aortic endothelial cell (ABAE) cultures results within three passages in the loss by the cells of their characteristic contact-inhibited morphology. The cells, which during their logarithmic growth phase divide with a greatly increased doubling time, become larger and more elongated. Confluent cultures, instead of adopting the morphology of a contact inhibited cell monolayer, are now composed of overgrowing cells. Parallel with the morphological alterations taking place within the culture, the cells also lose the polarity of cell surfaces characteristics of the vascular endothelium. Formation of an extracellular matrix composed primarily of fibronectin and collagen types I, III, and IV is observed on both the apical and basal cell surfaces. Platelets which previously did not bind to the apical cell surface now become capable of binding to it. CSP-60, a major cell surface protein present in highly confluent and contact-inhibited vascular endothelial cell cultures, can no longer be detected. Exposure of confluent endothelial cell cultures, maintained in the absence of FGF to medium conditioned by cells which had been grown in the presence of FGF, but maintained in its absence upon reaching confluence led, within four to eight days, to a reversion of the altered phenotype. This medium has little or no mitogenic activity and retains a full activity in the absence of serum or after depletion of its fibronectin content by affinity chromatography on a gelatin-Sepharose column. Cultures which were previously composed of cells growing in multiple layers reorganized into a single cell monolayer composed of closely apposed and highly flattened cells. The cultures thereby regained the contact-inhibited morphology characteristic of the vascular endothelium. Concomitant with this cellular reorganization, the extracellular matrix disappeared from the apical cell surface, the cells regained their nonthrombogenic properties, and CSP-60 reappeared as one of the major cell surface proteins. These results suggest that vascular endothelial cells secrete a soluble factor(s) which can restore the normal morphology and function lost following removal of FGF from the medium. Such a factor(s) may be involved in maintaining the differentiated state of the vascular endothelium.     

Lectin binding to injured corneal endothelium mimics patterns observed during development

Fluorochrome conjugated lectins were used to observe cell surface changes in the corneal endothelium during wound repair in the adult rat and during normal fetal development. Fluorescence microscopy of non-injured adult corneal endothelia incubated in wheat-germ agglutinin (WGA), Concanavalin A (Con A), and Ricinus communis agglutinin I (RCA), revealed that these lectins bound to cell surfaces. Conversely, binding was not observed for either Griffonia simplicifolia I (GS-I), soybean agglutinin (SBA) or Ulex europaeus agglutinin (UEA). Twenty-four hours after a circular freeze injury, endothelial cells surrounding the wound demonstrated decreased binding for WGA and Con A, whereas, RCA binding appeared reduced but centrally clustered on the apical cell surface. Furthermore, SBA now bound to endothelial cells adjacent to the wound area, but not to cells near the tissue periphery. Neither GS-I nor UEA exhibited any binding to injured tissue. By 48 h post-injury, the wound area repopulates and endothelial cells begin reestablishing the monolayer. These cells now exhibit increased binding for WGA, especially along regions of cell-to-cell contact, whereas, Con A, RCA and SBA binding patterns remain unchanged. Seventy-two hours after injury, the monolayer is well organized with WGA, Con A and RCA binding patterns becoming similar to those observed for non-injured tissue. However, at this time, SBA binding decreases dramatically. By 1 week post-injury, binding patterns for WGA, ConA and RCA closely resemble their non-injured counterparts while SBA continues to demonstrate low levels of binding. In early stages of its development, the endothelium actively proliferates and morphologically resembles adult tissue during wound repair.(ABSTRACT TRUNCATED AT 250 WORDS)     

Invasion of mesenchyme into three-dimensional collagen gels: a regional and temporal analysis of interaction in embryonic heart tissue

In normal heart development the endothelium of the atrioventricular canal, but not the ventricle, produces mesenchymal cells which seed (invade) into the intervening extracellular matrix toward the myocardium at around 64-69 hr of development. We have utilized three-dimensional collagen substrates to examine the initiation of seeding by atrioventricular canal endothelia in vitro and to compare and contrast the responses of the ventricular endothelia. Explants of atrioventricular canals and ventricles from staged embryos were placed on the surfaces of collagen gels prior to the onset of seeding in situ. At varied intervals of incubation, the explant was removed, leaving behind a monolayer on the surface of the gel which consisted of endothelial cells. Subsequently, the endothelial outgrowths were examined for seeded cells. The results confirm the regional endothelial differences seen in vivo. They also show that invasion of the collagen gels is due to an alteration in phenotype mediated by interaction with other components of embryonic heart explant. Lastly, the time course of this tissue interaction in vitro mimics the onset of seeding in vivo.     

Proliferation of pulmonary endothelial cells: Time-lapse cinematography of growth to confluence and restitution of monolayer after wounding

A fundamental characteristic of vascular endothelium is that it exists as a monolayer, a condition that must be met in both vascular growth and repair. Maintenance of the monolayer is important both for the exchange of nutrients and for interactions between blood solutes and endothelial enzymes and transport systems. We have used time-lapse cinematography to compare proliferative behavior of bovine pulmonary endothelial cells in (1) establisment of a monolayer from a low-density seed (7.5 × 10⁴ cells in a 60 mm dish) and (2) restitution of a confluent monolayer (approx. 2.9 × 10⁶ cells in a 60 mm dish) following a mechanical wound (removal of cells from an area 5 × 15 mm by scraping). Culture 2 was not refed after wounding. In culture 2, approx. 30% of the cells accounted for repopulation (confluence in 40 hr). In culture I, all cells entered into division. Participating cells of culture 2 began division immediately (69 divisions/filmed area in 10 hr, vs. four divisions in culture I). Interdivision times (IDT) were longer and relatively constant in culture I until near confluence; none were < 10 h, whereas in 2, 24% of the IDT's were ≤ 10 hr. Remarkably, IDTs of culture 2 decreased steadily until confluence was re-established. Cell migration in culture 1 was multidirectional while direction of migration in culture 2 was always into the wound area. Mean migration rate (MIG) in culture 2 was related to the site of origin of the cells, those dividing farthest from the unwounded area had fastest MIGs. Neither culture formed more than a single layer of cells. Although the cell kinetics of cultures 1 and 2 differed, the same goal, confluence, was achieved in either case.     

Effects of prolonged exposure to hypoxia on morphological changes of endothelial cells plated on fibrin gel

Since tissue oxygenation has a profound effect on capillary growth, the effect of pO2 on endothelial cell functions was studied. Under normoxic conditions, EA.hy926 endothelial cells and HUVEC plated onto fibrin gels in low-serum culture medium underwent rapid and profound morphological changes within 12 to 48 hours depending on the cell line used. Their characteristic cobblestone organisation was transformed into a network of cord-like or tube-like structures. We showed that when exposed to low oxygen concentrations for 3 days, HUVEC and EA.hy926 have their ability to rearrange reduced to around 50 %. With EA.hy926 this effect was amplified by 79% after 9 days of hypoxia. The altered behaviour of hypoxia-adapted cells was not caused by a loss in their fibrinolytic activity. In fact, the fibrin degradation rate and the generated fibrin fragments appeared identical in normoxia and hypoxia. Confocal microscopy and gel densitometry showed that in normoxia the remaining undegraded fibrin gel underwent a dynamic remodeling whereas in hypoxia it remained undisturbed. It is likely that hypoxia induces modification in the factors that integrate matrix information and cytoskeletal organisation in order to contract fibrin.     

Cultured human vascular endothelial cells acquire adhesiveness for neutrophils after stimulation with interleukin 1, endotoxin, and tumor-promoting phorbol diesters

Cultured human vascular endothelial cells obtained from umbilical cord veins were observed to acquire adhesive properties for purified neutrophils after exposure to IL 1, endotoxin, and tumor-promoting phorbol diesters. Adhesiveness induced by IL1 and endotoxin had similar kinetics of onset, producing no change after 30 min incubation and reaching optimal change by 4 hr of incubation. The phorbol diester TPA induced changes in adhesiveness more rapidly, with half maximal increase induced by a 15- to 30-min exposure. TPA, but not IL 1 or LPS, induced significant morphologic changes in the endothelial cell monolayer. None of the stimuli decreased endothelial cell viability. All stimuli induced increased adhesiveness at relevant concentrations, i.e., endotoxin, 0.01 to 1 microgram/ml; IL 1, 0.5 to 2 U/ml; and TPA, 1 to 30 ng/ml. Structure activity relationships among phorbol diesters indicate that the response occurs through a typical phorbol diester "receptor." A protein synthesis inhibitor (cycloheximide) and an RNA synthesis inhibitor (actinomycin D) prevented the acquisition of adhesiveness stimulated by IL 1 and endotoxin but not by TPA. In addition, TPA showed a differential temperature sensitivity in inducing adhesiveness in endothelial cells. IL 1 and endotoxin did not produce the effect with a 4-hr incubation at 22 degrees or 4 degrees C, whereas TPA was effective at these lower temperatures. Purified human IL 2 and recombinant-derived interferon-gamma failed to induce adhesiveness in vascular endothelial cells, indicating that this is not a general property of lymphokines. We conclude that endothelium may, under some circumstances, play an active role in producing a leukocyte infiltrate at a local tissue site by acquiring adhesive properties. The production of IL 1 by tissue macrophages, etc., may serve as an important initiator of an inflammatory cell infiltrate. Finally, an action of tumor-promoting phorbol diesters in increasing endothelial cell adhesiveness, combined with their known effects in activating leukocytes, may help explain the extraordinary inflammatory potency of these compounds.     

Lectin binding to injured corneal endothelium mimics patterns observed during development

Summary Fluorochrome conjugated lectins were used to observe cell surface changes in the corneal endothelium during wound repair in the adult rat and during normal fetal development. Fluorescence microscopy of non-injured adult corneal endothelia incubated in wheat-germ agglutinin (WGA), Concanavalin A (Con A), and Ricinus communis agglutinin I (RCA), revealed that these lectins bound to cell surfaces. Conversely, binding was not observed for either Griffonia simplicifolia I (GS-I), soybean agglutinin (SBA) or Ulex europaeus agglutinin (UEA). Twenty-four hours after a circular freeze injury, endothelial cells surrounding the wound demonstrated decreased binding for WGA and Con A, whereas, RCA binding appeared reduced but centrally clustered on the apical cell surface. Furthermore, SBA now bound to endothelial cells adjacent to the wound area, but not to cells near the tissue periphery. Neither GS-I nor UEA exhibited any binding to injured tissue. By 48 h post-injury, the wound area repopulates and endothelial cells begin reestablishing the monolayer. These cells now exhibit increased binding for WGA, especially along regions of cell-to-cell contact, whereas, Con A, RCA and SBA binding patterns remain unchanged. Seventy-two hours after injury, the monolayer is well organized with WGA, Con A and RCA binding patterns becoming similar to those observed for non-injured tissue. However, at this time, SBA binding decreases dramatically. By 1 week post-injury, binding patterns for WGA, ConA and RCA closely resemble their non-injured counterparts while SBA continues to demonstrate low levels of binding. In early stages of its development, the endothelium actively proliferates and morphologically resembles adult tissue during wound repair. The 16-day fetal tissue is mitotically active, does not exhibit a well defined monolayer, and demonstrates weak fluorescence binding for WGA, Con A and RCA. Conversely, SBA binding is readily detected on many cell surfaces. By 19 days in utero, the endothelial monolayers becomes organized and cell proliferation greatly diminishes. WGA, Con A and RCA now exhibit binding similar to that seen in the adult tissue. SBA binding is not detected at this time. Thus, changes in lectin binding during wound repair of the adult rat corneal endothelium mimic changes in lectin binding seen during the development of the tissue.Supported by grant EY-06435 from The National Institutes of Health     

Rolling adhesion of leukocytes on soft substrates: Does substrate stiffness matter?

Cell rolling on vascular endothelium under hydrodynamic blood flow is critical for realization of many physiological and pathological processes, such as inflammatory response and tumor metastasis. The blood-borne cells are in direct contact with the inner layer of endothelium, formed by a highly compliant layer of endothelial cells. The effect of endothelial stiffness on the adhesion and motion of rolling cells is poorly understood. Inspired by recent in vitro studies, here we implemented a computational method to model the specific adhesion of a rolling cell onto a soft substrate, subjected to a creeping shear flow. The substrate is modeled as an elastic half-space, coated with P- and E-selectin receptors with specific affinity for the complementary ligands located on the moving cell. Of particular importance is to predict the effect of substrate stiffness on cell adhesion and its kinematics and kinetics of motion. Simulation results show that the effect of substrate compliance is minimal when coated with P-selectin. Conversely, the trajectory of rolling cells on E-selectin coated substrates is sensitive to the substrate compliance. This is attributed to the moderation of binding forces applied by the soft substrate which leads to a higher average translational velocity of cells.     

Coupling of endothelial injury and repair: an analysis using an in vivo experimental model

The repair of the endothelium after inflammatory injury is essential to maintaining homeostasis. The link between inflammation-induced endothelial damage and repair has not been fully characterized in vivo. We have developed a rat model to evaluate the coupling of lipopolysaccharide (LPS)-induced endothelial injury and repair. Aortic endothelium injury was analyzed by both inmunohistochemistry and flow cytometry to quantify the number of endothelial cells and the percentage of apoptotic endothelial cells. We have also identified the percentage of circulating angiogenic cells capable of repairing the damaged endothelium. Erythropoietin was administered to inhibit LPS-induced endothelial apoptosis. Loss of the normal endothelial structure was observed in the aorta of the animals treated with LPS. Eight hours after LPS administration, the number of endothelial cells decreased by 40%, returning to normal after 24 h. There was a threefold increase in the percentage of circulating angiogenic cells, which did not return to normal levels until 48 h after LPS administration. Circulating angiogenic cell levels did not change when LPS-induced endothelial damage was prevented by erythropoietin. The endothelial injury caused by inflammation activates the mobilization of circulating angiogenic cells, thus completing endothelial repair. Inflammation without endothelial injury does not trigger the mobilization of circulating angiogenic cells.     

Cultured endothelial cell monolayers that restrict the transendothelial passage of macromolecules and electrical current

Bovine microvascular endothelial cells (BMECs) proliferated to confluence on the stromal surface of human amniotic membrane that had been denuded of its natural epithelium. The resulting cultures had the following characteristics: (a) The endothelial cells formed a thin, continuous monolayer and, like their in vivo counterparts, contained basal adhesion plaques and large numbers of cytoplasmic vesicles and 10- nm filaments. In addition, the endothelial cells elaborated a basement membrane-like structure. (b) The borders of the BMECs reacted with AgNO3 to produce the "flagstone" pattern typical of endothelium stained with this reagent in vivo. (c) More than 90% of the zones of contact between endothelial cells examined 8 d after plating prevented passage of a macromolecular probe (wheat germ agglutinin conjugated to horseradish peroxidase) across the BMEC monolayer. (d) 8 d-old cultures displayed a transendothelial electrical resistance that averaged 69 +/- 28 omega X cm2. Monolayers of BMECs maintained on amnion thus resemble in vivo endothelium in several respects and should provide a useful and relevant model for the in vitro study of various phenomena that occur at the microvascular wall.     

Requirements for alpha(5)beta(1) integrin-mediated retraction of fibronectin-fibrin matrices.

Retraction of the blood clot by nucleated cells contributes both to hemostasis and to tissue remodeling. Although plasma fibronectin (FN) is a key component of the clot, its role in clot retraction is unclear. In this report, we demonstrate that the incorporation of FN into fibrin matrices significantly improves clot retraction by nucleated cells expressing the integrin alpha(5)beta(1). Further, we show that FN-fibrin clots support increased cell spreading when compared with fibrin matrices. To determine the structural requirements for FN in this process, recombinant FN monomers deficient in ligand binding or fibrin cross-linking were incorporated into fibrin clots. We show that recombinant FN monomers support clot retraction by Chinese hamster ovary cells expressing the integrin alpha(5)beta(1). This process depends on both the Arg-Gly-Asp (RGD) and the synergy cell-binding sites and on covalent FN-fibrin binding, demonstrating that cross-linking within the clot is important for cell-FN interactions. These data show that alpha(5)beta(1) can bind to FN within a clot to promote clot retraction and support cell shape change. This provides strong evidence that alpha(5)beta(1)-FN interactions may contribute to the cellular events required for wound contraction.