Histotypic angiogenesis in vitro: light microscopic, ultrastructural, and radioautographic studies

Endothelial cells exhibiting angiogenesis in vitro proliferate in response to TGF-beta 1

Transforming growth factor-beta 1 (TGF-beta 1) has been implicated in the positive regulation of angiogenesis in vivo, whereas it inhibits the proliferation of endothelial cells in vitro. To reconcile these apparently contradictory effects, we have investigated the effect of TGF-beta 1 on bovine aortic endothelial cells that exhibit spontaneous angiogenesis in vitro. We show that concentrations of TGF-beta 1 which stimulate proliferation of cells that form endothelial cords and/or tubes inhibit proliferation of the same cells grown at subconfluent densities. An increase in cell number of 35% over control cultures was achieved with 0.5 ng TGF-beta 1/ml. The proliferative effect was blocked by antibodies against TGF-beta. Immunological detection of BrdU-labeled nuclei revealed an increase greater than 220% in cells treated with TGF-beta 1. Moreover, a population of cells within the cords appeared to be a selective target for this cytokine. The stimulatory effect was not restricted to bovine aortic endothelial cells, as similar results were obtained with endothelial cells derived from rat microvessels. Significant levels of active TGF-beta 1 were detected in cultures containing cords/tubes, whereas only latent TGF-beta 1 was detected in subconfluent cultures. We show further that endothelial cells exhibiting angiogenesis in vitro secrete plasminogen activator, an enzyme that regulates activation of TGF-beta. The major increases in mRNA transcripts for extracellular matrix proteins that are typically associated with TGF-beta 1 were not seen in cells exhibiting angiogenesis in vitro. Since the formation of tubular networks requires both invasion and proliferation, we propose that TGF-beta 1 is a major morphoregulatory factor in angiogenesis that specifically controls endothelial cell proliferation and extracellular matrix turnover.

Thrombin promotes angiogenesis by a mechanism independent of fibrin formation

The role of thrombin in angiogenesis was investigated in the chick chorioallantoic membrane (CAM) system. alpha-Thrombin promoted angiogenesis in a dose-dependent fashion and at 8.4 pmol/disk reached a maximum of 78% above the control. At a higher dose of alpha-thrombin (25 pmol/disk) the angiogenic effect declines and this can be explained by desensitization of the thrombin receptor. The promotion of angiogenesis by alpha-thrombin is specific as evidenced by the reversal of this effect by hirudin, which binds both the catalytic and the anion-binding exosite of thrombin or by heparin, which binds thrombin and accelerates its inactivation by antithrombin III. gamma-Thrombin, which is catalytically active but lacks the anion-binding exosite required for clotting activity, promotes angiogenesis in the CAM in the same fashion and to the same extent as alpha-thrombin, at doses up to 130 pmol/disk. Phenylalanyl-propyl-arginine chloromethyl ketone (P-PACK)-thrombin, the catalytically inactive analogue of alpha-thrombin that retains the anion-binding exosite, had no significant effect on angiogenesis in the CAM. When combined with alpha-thrombin, P-PACK-thrombin abolished the angiogenesis-promoting effect of alpha-thrombin. These results suggest that alpha-thrombin can promote angiogenesis in the CAM through interaction with its catalytic site without the requirement for fibrin formation.

Large-vessel endothelium switches to a microvascular phenotype during angiogenesis in collagen gel culture of rat aorta

The purpose of this study was to investigate the vasoformative behavior in vitro of the native intimal endothelium of the rat aorta. To visualize the intimal surface directly, thoracic aortas were everted using a procedure that sequestered adventitial cells and possible remnant microvessels of periaortic soft tissues inside the aortic tube. Everted aortas embedded in collagen gel and cultured under serum-free conditions generated branching microvessels by a process of sprouting from the aortic intima. The newly formed microvessels originated from patches of activated intimal endothelial cells, which had survived the mechanical damage of the eversion procedure. Activated endothelial cells crawled over each other and engaged in lumen formation forming bilayers or multilayers of cells which became the source of sprouting histotypic microvessels. The endothelium of the newly formed microvessels was positive for factor VIII-related antigen and was partially surrounded by periendothelial cells which expressed alpha-smooth muscle actin. The results of this study indicate that the intimal endothelium of the rat aorta has considerable functional plasticity and can switch to a vasoformative phenotype in response to changes in the surrounding extracellular matrix environment.

Structural biology of epithelial tissue in histophysiologic gradient culture

Epithelial cells proliferate, forming organized tissues, when positioned in the lumen of a thin-walled, transparent, elongated cylindrical, cystlike culture chamber. The closed chamber, 2.5 mm in diameter and 25 mm long, bathed in medium, incubated with continuous gentle agitation, enables the inoculum to exchange metabolites including oxygen by diffusion across the thin, nylon filament-reinforced collagen membrane wall of the chamber. After periods of culture of a week or more, using inocula derived from urothelium, the inner surface of the cystic chamber is lined by a stratified epithelium. Proliferation of cells is seen in the basal zone, which is attached to the collagen substrate. The development of the model is briefly described. Some of the applications of the procedure are illustrated using cell lines, chick embryo tissues, and clinical tissues. Implications of the procedure are considered for studying categories of tissue biology, e.g., problems of aging, neoplasia, and toxicology.

Angiogenesis in wound healing

Angiogenesis is an essential component of wound healing. Vessel growth is controlled by the local actions of chemical mediators, the extracellular matrix, metabolic gradients, and physical forces. Manipulation of some of these factors can improve healing in experimental wounds. The clinical potential and specific application of 'angiomodulatory' strategies are discussed.

Regulation of angiogenesis in vitro by collagen metabolism

The role of collagen in microvascular growth was investigated using the aortic ring model of angiogenesis. Collagen production by vasoformative outgrowths in plasma clot culture of rat aorta was either stimulated with ascorbic acid or inhibited with the proline analogue cis-hydroxyproline. Microvessels proliferating in the absence of ascorbic acid supplements became ecstatic and developed large lumina. In contrast, newly formed microvessels in the presence of ascorbic acid remained small and maintained thin lumina throughout the angiogenic process. Biochemical studies demonstrated enhanced collagen production and deposition in cultures treated with ascorbic acid. Ultrastructural studies of these cultures showed a marked increase in newly formed interstitial collagen in the perivascular matrix and in regions of the plasma clot containing nonendothelial mesenchymal cells. Small microvessels with thin lumina similar to the ones observed in ascorbic acid-treated plasma clot cultures were obtained by growing aortic explants in gels of interstitial collagen in the absence of ascorbic acid. Inhibition of collagen production with the proline analogue cis-hydroxyproline had a marked anti-angiogenic effect in both plasma clot and collagen gel cultures. The anti-angiogenic effect of cis-hydroxyproline was abolished by adding L-proline to the culture medium, thereby restoring normal metabolism. These results support the hypothesis that angiogenesis is regulated by collagen production and suggest that the size of newly formed microvessels is influenced by the degree of collagenization of the extracellular matrix.

Modulation of extracellular matrix proteins by endothelial cells undergoing angiogenesis in vitro

Angiogenesis results in part from the response of endothelial cells to the integrated action of morphogenic factors and extracellular matrix proteins. In this study we identified specific components of the extracellular matrix that were modulated in endothelial cells derived from bovine aorta and rat cerebral microvessels, both of which spontaneously form cords and tubes under standard culture conditions. SPARC (secreted protein, acidic and rich in cysteine) was upregulated 4.2-fold in aortic and 10-fold in microvascular cultures that had organized into cords and/or tubes. This Ca(2+)-binding glycoprotein was synthesized primarily by endothelial cells in the process of cord formation. Transcription of type I collagen was initiated in aortic endothelial cells undergoing angiogenesis in vitro and showed a 12-fold increase in similar cultures of microvascular cells. Type VIII collagen protein was upregulated to a lesser degree (4.3-fold in aortic and 1.8-fold in microvascular cells). Dense cytoplasmic staining for these two collagen types was seen in cells directly participating in the organization of cords. In contrast, the disparate levels of fibronectin observed in both types of endothelium indicated an indirect or secondary role for this glycoprotein in cord/tube formation in vitro. These results identify SPARC, type I collagen, and type VIII collagen as extracellular matrix components that are actively synthesized by endothelial cells undergoing angiogenesis in vitro. Moreover, expression of these proteins during the formation of tubes and cords appears to follow a biosynthetic program that is common to endothelial cells from both the macrovasculature and microvasculature.

Angiogenesis in arteries: review

The inner parts of the walls of large blood vessels do not normally contain intrinsic vasculature. In pathologic conditions such as arteriosclerosis or thrombosis, angiogenesis occurs, and may have significant clinical consequences. This review attempts to relate the little that is known about the factors specific to vascular walls which regulate angiogenesis to more general knowledge of the phenomenon.

Actions of TNF and IFN-gamma on angiogenesis in vitro

We have developed a model system for studying angiogenesis in which microvascular fragments and myofibroblasts (Mf) isolated from lipid tissues are grown in co-culture. We have found that Mf induce capillary formation by producing an endothelial cell growth factor and by secreting an extracellular matrix that causes endothelial cells to form a cordlike structure. This system appeared to be well suited for examining the effects of vasoactive substances such as the TNF and INF-gamma on capillary growth. TNF-alpha,beta, and IFN-gamma not only significantly inhibited capillary growth induced by Mf, but also blocked capillary development induced by fibroblast growth factors (FGF), well-known potent angiogenic factors. Recently, we have found that platelet-derived growth factor (PDGF) enhances in vitro capillary formation, probably at least in part by acting on Mf. Just as with FGF, capillary growth in the presence of PDGF was almost completely blocked by IFN-gamma. We examined the mode by which IFN-gamma inhibits angiogenesis and found that IFN-gamma inhibits both the proliferation of endothelial cells and collagen(s) synthesis by Mf. These actions of TNF or IFN-gamma could limit vascular formation in solid tumors.

A novel mechanism of capillary growth in the rat pulmonary microcirculation

Postnatally, the rat lung parenchyma undergoes impressive growth. Within four months of birth, lung volume and alveolar and capillary surface areas increase over 20-fold and capillary volume 35-fold. Investigation of methacrylate casts of the pulmonary microvasculature revealed that, with age, lung capillaries were not only growing in surface and volume but also increasing their network density. We proposed that the capillary bed grows by formation of slender intravascular tissue pillars and termed this type of growth intussusceptive microvascular growth (Caduff et al., Anat. Rec., 216:154-164, 1986). The aim of this investigation was to detect the presence and to analyze the ultrastructure of slender tissue posts (diameter 1-2.5 microns) extending across the capillary lumina in serial electron microscopic sections of rat lung parenchyma (age 44 days). Computer-assisted three-dimensional reconstruction of the capillary lumen confirmed that tissue posts were matching the holes previously observed in casts. Post ultrastructure varied with size from a simple area of interendothelial contact to tissue pillars with a core of interstitial tissue. Based on the changing morphology of the pillars, a hypothesis for their development can be proposed: phase I, creation of a zone of contact between opposite capillary walls (formation of an interendothelial bridge); phase II, reorganization of the intercellular junctions of the endothelium, with central perforation of the capillary layer; phase III, formation of an interstitial post core, with successive invasion by cytoplasmic extensions of myofibroblasts, pericytes, and finally interstitial fibers; and phase IV, growth of the slender pillar to a normal full size capillary mesh. These findings support the new concept of intussusceptive growth of the lung capillary system.

Increased proteolytic activity is responsible for the aberrant morphogenetic behavior of endothelial cells expressing the middle T oncogene

Expression of the polyoma virus middle T (mT) oncogene in vivo is associated with a profound subversion of normal vascular development, which results in the formation of endothelial tumors (hemangiomas). In an attempt to understand the molecular mechanisms responsible for this phenomenon, we have investigated, in an in vitro system, the morphogenetic properties of endothelial cells expressing this oncogene. mT-expressing endothelioma (End) cells grown within fibrin gels formed large hemangioma-like cystic structures. All End cell lines examined expressed high levels of fibrinolytic activity resulting from increased production of urokinase-type plasminogen activator and decreased production of plasminogen activator inhibitors. Neutralization of excess proteolytic activity by exogenously added serine protease inhibitors corrected the aberrant in vitro behavior of End cells and allowed the formation of capillary-like tubules. These results suggest that tightly controlled proteolytic activity is essential for vascular morphogenesis and that physiological protease inhibitors play an important regulatory role in angiogenesis.

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

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 of 3H-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.

Morphological behavior of cultured bovine adrenal medulla capillary endothelial cells

Bovine adrenal medulla capillary endothelial cells were isolated and cloned, and their morphological behaviors in vitro were examined. In the culture of primary or early passage, one type of colony formed intracellular lumina both on the dish and in the three dimensional collagen gel. Another type proliferated well and showed morphology ranging from slender-shape to cobblestone shape, and were easily cloned. Cloned cells which showed slender-shapes formed tubular network on plastic dish after addition of PMA, OAG or vanadate, and these cells also formed multicellular tubules in the three dimensional collagen gel. However, the formation of diaphragmed fenestrae by these slender-shape clones was rare. One clone which showed cobblestone shape formed diaphragmed fenestrae, when cultured on collagen gel for more than one month. Isolated colonies or clones showed heterogeneity of cell shape, angiogenic behaviors and fenestrae formation.

Recognition of distinct adhesive sites on fibrinogen by related integrins on platelets and endothelial cells

Endothelial cells and activated platelets express integrin-type receptors responsible for adhesion to fibrinogen. We have located distinct integrin-directed endothelial cell and platelet attachment sites on immobilized fibrinogen using a combination of synthetic peptides, fibrinogen fragments, and specific anti-peptide monoclonal antibodies. Endothelial cells exclusively recognize an Arg-Gly-Asp-containing site near the C-terminus of the alpha chain (alpha residues 572-574) but fail to recognize the Arg-Gly-Asp sequence in the N-terminal region of the same chain (alpha residues 95-97). In contrast, platelets do not require either Arg-Gly-Asp sequence for binding to intact fibrinogen and are capable of recognizing, in addition to the alpha 572-574 sequence, a site at the C-terminus of the gamma chain (gamma residues 400-411). These data suggest a molecular mechanism whereby platelets and endothelial cells interact with distinct sites on the fibrinogen molecule during hemostasis and wound healing.

Mechanochemical switching between growth and differentiation during fibroblast growth factor-stimulated angiogenesis in vitro: role of extracellular matrix

The angiogenic factor, basic fibroblast growth factor (FGF), either stimulates endothelial cell growth or promotes capillary differentiation depending upon the microenvironment in which it acts. Analysis of various in vitro models of spontaneous angiogenesis, in combination with time-lapse cinematography, demonstrated that capillary tube formation was greatly facilitated by promoting multicellular retraction and cell elevation above the surface of the rigid culture dish or by culturing endothelial cells on malleable extracellular matrix (ECM) substrata. These observations suggested to us that mechanical (i.e., tension-dependent) interactions between endothelial cells and ECM may serve to regulate capillary development. To test this hypothesis, FGF-stimulated endothelial cells were grown in chemically defined medium on bacteriological (nonadhesive) dishes that were precoated with different densities of fibronectin. Extensive cell spreading and growth were promoted by fibronectin coating densities that were highly adhesive (greater than 500 ng/cm2), whereas cell rounding, detachment, and loss of viability were observed on dishes coated with low fibronectin concentrations (less than 100 ng/cm2). Intermediate fibronectin coating densities (100-500 ng/cm2) promoted cell extension, but they could not completely resist cell tractional forces. Partial retraction of multicellular aggregates resulted in cell shortening, cessation of growth, and formation of branching tubular networks within 24-48 h. Multicellular retraction and subsequent tube formation also could be elicited on highly adhesive dishes by overcoming the mechanical resistance of the substratum using higher cell plating numbers. Dishes coated with varying concentrations of type IV collagen or gelatin produced similar results. These results suggest that ECM components may act locally to regulate the growth and pattern-regulating actions of soluble FGF based upon their ability to resist cell-generated mechanical loads. Thus, we propose that FGF-stimulated endothelial cells may be "switched" between growth, differentiation, and involution modes during angiogenesis by altering the adhesivity or mechanical integrity of their ECM.

Identification of vascular endothelial cells in murine omentum using the lectin, Dolichos biflorus agglutinin: possible applications in the study of angiogenesis

The purpose of this study was to determine whether the plant lectin, Dolichos biflorus agglutinin (DBA), can be used to recognize capillary endothelial cells and their processes during angiogenesis. By means of a peroxidase conjugate of DBA, blood vessels were visualized in whole mounts and ultrathin sections of mouse omentum. A part of this mesentery normally comprises an avascular membrane that is approximately 30 microns in thickness. Changes in the vascular plexus bordering this membrane were induced by intraperitoneal injection of irradiated Landschutz cells. Vascular endothelial cells were precisely and intensely stained, and vasculogenic processes were reliably distinguished from those of other cells. This technique permitted observation of the structure and distribution of capillary sprouts, and their relationship to each other and to pre-existing blood vessels. It was discovered that filiform projections extend from sprout apices. These projections may fuse allowing adjacent sprouts to form a new capillary loop.

Culture of human corpus cavernosum endothelium

A method for culturing endothelial cells (HCC-EC) from surgical specimens of human corpus cavernosum has been developed. The approach involves selective endothelial outgrowth from explants and may be generally applicable to tissues whose endothelium is not amenable to isolation by routine mechanical or enzymatic methods. The tissue is minced into pieces which are placed onto gelatin- or fibronectin-coated tissue culture plastic, and grown in medium suitable for microvascular endothelial cell growth (Carson and Haudenschild, In Vitro 22:344-354, 1986). By Days 5 to 7 EC colonies are found. Within a day or two after the appearance of the EC colonies, a non-EC cell type appears and, if undisturbed, quickly overgrows the EC. An exploitable temporal separation between the emergence of EC and non-EC is obtained when both conditioned medium (from bovine aortic endothelium) and retinal extract are present during the outgrowth period. Explants are removed by pipetting at the first sign of the emergence of the non-EC cell type. Once isolated, HCC-EC do not require conditioned medium but do require either retinal extract or acidic fibroblast growth factor for survival and growth. Approximately 60% of the first passage cultures are at least 80% EC as judged by DiI-Ac-LDL labeling. One corpus (0.3 x 0.3 x 0.5 cm) usually produces 120 cm2 of primary culture within 2 wk. These EC form contact-inhibited monolayers and stain positively for Factor VIII. They have a doubling time at 6th passage of 48 h and a plateau density of 5 to 7 x 10(4) cells/cm2. The availability of such cultures should facilitate the study of endothelium-mediated responses which play an important role in the erectile function of human penile corpus cavernosum.

Trophic support of the developing cochleovestibular ganglion by its peripheral target in vitro does not depend on neuronal cell division

A trophic effect on the development of the cochleovestibular ganglion in the presence of its synaptic target tissue, the embryonic otocyst, has been shown in organ cultures. The basis for this trophic effect could be increased neuronal proliferation or enhanced postmitotic survival and differentiation. In order to determine if the trophic effect influenced neuronal proliferation, organ cultures of combined otocyst and cochleovestibular ganglion (embryonic stages 23-24) were grown 14 days in vitro in the continuous presence of [3H]thymidine. Serial sections of the explants made at each stage were assayed for autoradiographic labeling of cell nuclei and for numbers of cochleovestibular ganglion neurons. Explants were well developed morphologically and contained numbers of ganglionic neurons within the same range as previously reported. Many other well differentiated cell types were also present, including hair cells, supporting cells, other epithelial cells, cartilage, connective tissue, and perineuronal satellite cells. All of these non-neuronal cell types had undergone DNA synthesis in vitro, as evidenced by their heavily labeled nuclei. The cochleovestibular ganglion neurons were the only cell type with unlabeled nuclei, indicating that they had not divided or synthesized DNA during the two-week incubation. Thus all of the identifiable cochleovestibular ganglion neurons must have become postmitotic in the explants. Since ganglion cell division is still occurring in situ when the neurons are explanted, neuroblasts either failed to divide or failed to produce neuronal progeny in the culture conditions used. Therefore, the dependence of the cochleovestibular ganglion neurons on their normal target tissues most likely reflects a trophic effect on their postmitotic survival and differentiation.

Tumor-related angiogenesis

In recent years, tumor-related angiogenesis has become an important field of research in oncology. It could be stated that growth of solid tumors is completely dependent on neovascularization to provide the tumor with all required nutrients. Special compounds (tumor angiogenesis factor[s]) are released by tumor cells into the environment to stimulate different types of normal cells to become active for the tumor. In particular, endothelial cells of neighboring capillaries are induced to react. They disintegrate their own basal lamina, detach from their neighbors, enter the extracellular matrix, and migrate toward the tumor mass. Cell divisions occur within such sprouts, thereby increasing the number of migrating endothelial cells. Strands of such cells are formed, and inter- and intracellular lumina develop. Loops of these hollow strands anastomose to form a network of new vessels which become connected with the blood circulation. The tumor mass thus becomes vascularized and can continue to grow. The prevention of neoangiogenesis has an enormous impact on cancer treatment by inhibiting the growth of the tumor. In this review, all important aspects of tumor-related angiogenesis are presented.

Capillary growth from reversed rat aortic segments cultured in collagen gel

The process of angiogenesis from aortic segments turned inside out and embedded in collagen gel was studied. Two to three days after inoculation, fibroblastic cells migrated from both ends of the segments. Later, capillary sprouts also appeared from both ends of the segments but not from the outer surface, even though there was a covering of endothelial cells. If the outer surface was injured, capillaries sometimes appeared at the damaged site. This may suggest that endothelial cells have more affinity for basement membrane than collagen gel and that they migrate only from an injured site. Immunohistochemical staining demonstrated factor VIII-related antigen in the capillary structures but not in the fibroblastic cells. Electron microscopically, capillary lumina were lined with several endothelial cells, and fibroblastic cells had the characteristics of smooth muscle cells. Since these fibroblastic cells have been known to appear under angiogenetic conditions in vivo, they may play an important role in angiogenesis, and the present culture technique may be a useful model for studying this process.

Human endothelial cells synthesize and express an Arg-Gly-Asp-directed adhesion receptor involved in attachment to fibrinogen and von Willebrand factor

Human umbilical vein endothelial cells express a heterodimeric adhesion receptor complex consisting of noncovalently associated alpha and beta subunits that under reducing conditions have molecular masses of 135 kDa and 115 kDa, respectively. This complex can be isolated in pure form from an affinity matrix consisting of an Arg-Gly-Asp-containing heptapeptide and is specifically immunoprecipitated with monoclonal antibodies (mAbs) directed against the vitronectin receptor of human melanoma cells. These data suggest that this complex is one member of a large family of cell adhesion receptors. One of the mAbs, LM609, inhibits the attachment of human endothelial cells to fibrinogen, von Willebrand factor, and vitronectin yet has no effect on the attachment of these cells to fibronectin, collagen, or laminin. In addition, mAb LM609 inhibits attachment of endothelial cells to an immobilized synthetic peptide containing the Arg-Gly-Asp sequence. This adhesion receptor appears structurally similar to the IIb/IIIa glycoprotein complex expressed on platelets yet is antigenically distinct, since mAb LM609 fails to recognize IIb/IIIa glycoproteins. This receptor organizes in clusters on endothelial cells during their attachment to von Willebrand factor, vitronectin, or the Arg-Gly-Asp-containing heptapeptide. The data presented in this report suggest that Arg-Gly-Asp recognition may play a significant role in biological events associated with vascular proliferation.

Phorbol ester induces cultured endothelial cells to invade a fibrin matrix in the presence of fibrinolytic inhibitors

We have previously shown that the tumor promoter 4 beta-phorbol 12-myristate 13-acetate (PMA) induces capillary endothelial cells grown to confluency on the surface of three-dimensional collagen gels to invade the underlying matrix and to form capillary-like tubular structures, a phenomenon mimicking angiogenic processes that occur in vivo (Montesano and Orci: Cell, 42:469-477, 1985). Since angiogenesis frequently occurs within a fibrin-rich extracellular matrix, we have examined the ability of PMA-treated endothelial cells to invade fibrin gels. Control endothelial cells grown on fibrin gels formed a confluent monolayer on the gel surface and did not invade the underlying matrix. Treatment of the cultures with PMA resulted in a progressive lysis of the substrate without invasion of the fibrin matrix. However, if the cells were treated with PMA either in the presence of fibrinolytic inhibitors (Trasylol, epsilon-aminocaproic acid) or in the absence of detectable plasminogen, dissolution of the substrate was prevented, and the endothelial cells invaded the fibrin gel, forming vessel-like tubular structures similar to those previously observed with collagen gels. These results demonstrate that the invasive and morphogenetic events induced by PMA do not necessarily require an interaction between endothelial cells and collagen fibrils but can also occur with other biologically relevant substrata. They also suggest (1) that invasion may occur via a plasmin-independent mechanism and (2) that in vivo, neutralization of excess proteolytic activity may play an important permissive role in angiogenesis and other invasive processes by preventing uncontrolled matrix degradation.

Fibrinogen induces adhesion, spreading, and microfilament organization of human endothelial cells in vitro

Human umbilical vein endothelial cells (ECs) have been shown to attach to a substratum of fibrinogen (fg). Later, ECs undergo spreading, organization of thick microfilament bundles of the stress fiber type, and formation of focal contacts (adhesion plaques) that correspond to accumulation of vinculin at the cytoplasmic aspect of the ventral membrane. The rate of attachment to fg and the type of spreading is virtually identical to that obtained on substrata coated with fibronectin (FN). Antibodies to fg, but not to FN, prevent EC adhesion to fg; conversely, antibodies to FN, but not to fg, prevent adhesion of ECs to a FN-coated substratum. The removal of residual FN contamination from fg preparations by means of DEAE-cellulose chromatography does not result in any difference in EC adhesion on fg. Moreover, pretreatment of cells with inhibitors of synthesis and release of proteins does not impair their adhesion capacity on an fg-coated substratum. In contrast, human arterial smooth muscle cells do not adhere and spread on fg substrata but do so on FN. The synthetic peptides (Gly-Arg-Gly-Asp[GRGD] and Gly-Arg-Gly-Asp-Ser-Pro[GRGDSP]) containing the tripeptide Arg-Gly-Asp (RGD), originally found to be responsible for the cell binding activity of FN, have been found to inhibit EC spreading and the redistribution of their cytoskeleton, including the formation of stress fibers and the localization of vinculin either on fg or on FN. Conversely, the synthetic peptide Arg-Gly-Gly (RGG) was completely uneffective in inhibiting the adhesion and the sequence of events leading to spreading and cytoskeletal organization. These results indicate that ECs, but not smooth muscle cells, specifically adhere and spread on an fg substratum and this occurs by recognition mechanisms similar to those reported for FN.

Adhesion of Erysipelothrix rhusiopathiae to cultured rat aortic endothelial cells. Role of bacterial neuraminidase in the induction of arteritis

The adhesion of Erysipelothrix rhusiopathiae (E. rhusiopathiae) to the cultured confluent monolayer of rat aortic endothelial cells (EC) and the role of neuraminidase in the interaction between EC and E. rhusiopathiae were examined. One EC line was obtained by collagenase treatment of rat aorta. The EC showed a typical cobblestone appearance and possessed the factor VIII related antigen. When cultured more than two weeks after reaching confluence, the EC formed a vascular plexus-like appearance. E. rhusiopathiae began to adhere to EC within 2 minutes after the beginning of culture and adhered at a constant rate for 20 minutes. The adhesion of bacteria to EC was closely related to the release of sialic acid from the EC. Significantly more bacteria adhered to neuraminidase treated EC, and bacterial adhesion was inhibited dose-dependently by N-acetylneuraminic-lactose, which is the substrate of bacterial neuraminidase. It is concluded that bacterial neuraminidase plays an essential role in initiating the interaction between EC and E. rhusiopathiae, which would contribute to the genesis of arteritis.

Development of capillary networks from rat microvascular fragments in vitro: the role of myofibroblastic cells

A new model useful for studying capillary growth in vitro is described. When the microvessel fragments and accompanying single cells (myofibroblastic cells) from rat epididymal fat pads were co-cultivated, the myofibroblastic cells initially began to grow and reached confluence. A few days later, endothelial cells started to sprout from the vessel fragments, forming cellular cord networks on and in the multilayered myofibroblastic cells. Ultrastructurally, the lumina, surrounded by the endothelial cells having intercellular junctions, were observed at cross-sectioned cellular cords. The growth of cellular cords from the fragments always occurred after the myofibroblastic cells had reached confluence. The medium conditioned to isolated rat myofibroblastic cells stimulated not only the proliferation of the endothelial cells from the bovine capillary and human vein but also the migration of bovine capillary endothelial cells in vitro. Moreover, the extracellular matrix produced by rat myofibroblastic cells modulated the morphology of bovine capillary endothelial cells to a cordlike shape. These observations strongly suggest that the formation of the capillary in vitro is induced by myofibroblastic cells.

Angiogenesis and the formation of lymphaticlike channels in cultures of thoracic duct

Segments of rat thoracic duct cultured in plasma clot or in collagen gel produced microvascular and fibroblastic outgrowths. Lymphaticlike channels (LLC) with a highly attenuated endothelium, which was barely visible by light microscopy, were found in 8 out of 25 cultures (32%). Serial histologic sections revealed that the endothelium of the LLC was continuous with the intimal endothelium of the thoracic duct and was therefore of lymphatic origin. In addition to the LLC, vascular channels lined by a thick endothelium with hump-shaped, cross-sectional profiles were found in 10 cultures (40%). These channels were indistinguishable from the microvessels of blood vascular origin that formed in parallel cultures of rat aorta or periductal adipose tissue and were termed hematiclike channels (HLC). Contrary to the LLC, the HLC did not originate from the lymphatic endothelium of the thoracic duct. The frequent association of the HLC with the adventitia of the thoracic duct and with the surrounding adipose tissue suggested that they probably developed from the hematic microvessels of the periductal soft tissues.

The effect of endothelial cell proliferation in vitro

The proliferation of bovine aortic endothelial cells is highly stimulated by using a plasma clot instead of glass or plastic as a substrate. The cells form a dense monolayer which is usually under grown by a second layer of endothelial cells showing a more reticular growth pattern. When endothelial cells attached to a plasma clot are covered with a second layer of coagulated plasma, the cells arrange to shapes which bear a great resemblance to capillary structures. It seems that this endothelial cell property is only expressed when the entire cell surface is forced to interact with a surrounding adhesive matrix.

Interferon-gamma regulates an antigen specific for endothelial cells involved in lymphocyte traffic

One of the most striking examples of localized vascular differentiation is exhibited by specialized lymphoid organ venules that mediate the extravasation of circulating lymphocytes from the blood. These vessels are characterized by cuboidal or "high" endothelial cell morphology and are unique in their functional capacity to interact with migrating lymphocytes, regulating both the rate and specificity of lymphocyte traffic through particular regions of the body. We describe here a monoclonal antibody, MECA-325, that defines an endothelial cell differentiation antigen selectively expressed on high endothelium in the mouse. Thus an antigen defining a specific functional subset of endothelial cells has been found. Furthermore, we demonstrate that the MECA-325 antigen can be induced in mouse lung or bone marrow-derived endothelial cell lines in vitro by interferon-gamma but not by interferon-beta, interleukin-1, or endothelial cell mitogens. The results define a unique marker associated with differentiated endothelial cells mediating lymphocyte traffic from the blood, and they provide evidence that the specialized phenotype of these high endothelial cells may be induced and controlled by local factors associated with immune activity.

Scanning electron microscope study of the developing microvasculature in the postnatal rat lung

During postnatal growth the parenchymal septa of rat lung undergo an impressive restructuring. While immature septa are thick and contain two capillary layers, mature septa are slender and contain a single microvascular network. Using the Mercox casting technique and scanning electron microscopy, we investigated the mode and the timing of the transformation of the pulmonary capillary bed. During the third postnatal week the parenchymal septa rapidly mature to match adult morphology. Even in adult lungs, however, remnants of the immature status are present: A capillary bilayer is regularly found at the base and the tip of the septa. Our observations support the concept that reduction of intervening tissue, partial fusion of the two capillary networks, and preferential growth lead to the mature vascular arrangement. The fact that true mature interalveolar septa show a denser capillary network than alveolar walls abutting onto pleura, bronchi, or larger vessels is consonant with the fusion theory. Towards the nonparenchyma, the capillary network surrounding every airspace had no counterpart to fuse with. From quantitative data it can be calculated that owing to lung growth, mesh size should increase more than four times between birth and adult age. The adult lung network, however, is denser than the one in young animals. This means that new meshes must be added during growth. We propose that small holes observed in sheet-like regions of the microvasculature enlarge to form new capillary meshes. With this mechanism of in-itself or intussusceptional growth, sprouting of individual capillary segments to increase network size is no longer needed.

The isolation and culture of endothelial cells and pericytes from the bovine retinal microvasculature: a comparative study with large vessel vascular cells

Endothelial cells (BREC) and pericytes (BRP) were isolated from the bovine retinal microvasculature. These cells were first identified by morphological criteria and by their differential staining for Factor VIII related antigen. BREC and BRP responded differently to a number of experimental parameters in vitro; for example, the plating efficiency of BREC was enhanced by the use of a gelatin substratum and medium conditioned by either endothelial cells or pericytes; oxygen tension had no effect. In contrast, the plating efficiency of BRP was only enhanced by low oxygen tension. Conditioned media also stimulated the proliferation of BREC, but not that of BRP. The saturation density reached by BREC was dependent on the initial plating density while BRP plated at different initial densities reached the same final density. The in vitro behavior of the retinal microvascular cells was also compared to that of large vessel (aorta) endothelial cells (BAEC) and smooth muscle cells (SMC). Aortic and retinal endothelial cells showed similar morphology and behavior. When initially plated as a homogeneous cell suspension within a collagen matrix, both BREC and BAEC self-associated to form three-dimensional meshworks; this morphogenesis was accomplished by cell migration and did not involve cell proliferation. By contrast, BRP and SMC divided and remained homogeneously distributed when plated within a collagen gel matrix. BRP and SMC did, however, behave differently when plated on the surface of a collagen gel; SMC migrated extensively into the gel while BRP remained confined to the gel surface. BRP grown on any substratum began to retract upon themselves shortly after confluence, producing characteristic nodules interconnected by cellular strands. BRP and SMC were able to contract a collagen gel substratum, while retinal and aortic endothelial cells were unable to do so. These results provide new means for the in vitro characterization of endothelial cells, smooth muscle cells and pericytes.

Interactions between newly formed endothelial channels and carcinoma cells in plasma clot culture

Bovine capillary endothelial cells (BCEC), cultured in suspension on a rotary shaker, formed aggregates ranging from 50 to 300 micron in diameter. In plasma clot these aggregates sprouted in multiple directions and gave rise to vascular channels. Aggregates of the squamous cell carcinoma line of rat bladder NBT-II-81, cultured in plasma clot, formed solid spheroids that grew slowly by expansion. When cultured together with BCEC, however, NBT-II-81 infiltrated the plasma clot extensively. The tumor cells, after establishing contacts with the vascular channels, spread into the fibrin meshwork using the subendothelial space as their path of propagation. Endothelial cells that were separated from the surrounding matrix by invading tumor cells degenerated, leaving behind channels lined only by neoplastic epithelium. The adhesive properties of the subendothelial matrix were studied by seeding NBT-II-81 cells on dishes coated with the extracellular matrix produced by BCEC. Tumor cells attached readily and in large numbers to dishes coated with the subendothelial matrix. In contrast they attached poorly to dishes coated with fibrin. We conclude that the spread of carcinoma cells into plasma clot is markedly enhanced by endothelial channels, developed in the absence of blood flow. The production of a highly adhesive extracellular matrix by the capillary endothelium during angiogenesis may represent an important element in the preferential growth of the tumor along the vascular route.

Fibrin-enhanced endothelial cell organization

The formation of cloned bovine endothelial cells into capillary-like tubes is accelerated from 3-7 days to 2-18 h in the presence of fibrin. Indirect immunofluorescence showed the presence of both fibrin and fibronectin in the strands along which the cells organized. Electronmicroscopy revealed the same type of cell structures as form in the absence of fibrin; it also revealed a gradual decrease with time of the fibrin within the putative lumen. Fibrin and fibronectin are commonly present during angiogenesis in vivo, thus these in vitro observations may well have relevance to the in vivo process.

Long-term serial cultivation of arterial and capillary endothelium from adult bovine brain

Cerebrovascular endothelial cells from adult bovine brain were carried successfully in long-term, serial culture. Endothelial cells were obtained from the middle and anterior cerebral arteries and from capillaries isolated from grey matter of the cerebral cortex or caudate nucleus. Capillary cells were found to grow best in RPMI 1640 with 20% fetal bovine serum. They did not require tumor-conditioned medium or matrix-coated surfaces, although fibronectin was used to enhance the initial plating efficiency of the primary cultures. The same conditions were used to support satisfactory growth of arterial endothelial cells; however they did not grow as rapidly as the cells. Retention of endothelial-specific characteristics were shown for capillary-derived cells carried up to Passage 28, arterial-derived cells up to Passage 11, and after frozen storage of both types of cultured cells. Cultures of both arterial and capillary cells stained positively for Factor VIII antigen, exhibited a nonthrombogenic surface, and produced prostacyclin in response to arachidonic acid. Arterial endothelial cells produced more prostacyclin than capillary endothelium. The capillary cells had a unique tendency to assume a ringlike morphology after subculture and sometimes formed capillarylike networks of cell cords in dense cultures. When cultured in a three-dimensional plasma clot, capillary and arterial endothelial cells, but none of the other cell types studied, organized into tubelike structures reminiscent of capillary formation in vivo. The availability of long-term cultures of cerebrovascular endothelial cells provides an opportunity to compare properties of arterial and capillary endothelium from the same tissue and to investigate such processes as angiogenesis and blood-brain barrier induction.

The vasculature and limb development

The developing vascular pattern of the embryonic chick limb results from a combination of two properties: the intrinsic self-assembly and branching properties of the vascular cells and the extrinsic information associated with the expanding mitotic population of mesenchymal cells; and the inhibitory factors which restrict the entrance of vessels into particular domains and/or decrease the branching frequency of such vessels. It is hypothesized that an important component of limb pattern formation is the interplay between the dividing population of mesenchymal cells and the intrinsic properties of the vascular cells. It is further asserted that the presence of particular vascular elements may, indeed, be 'positional information'. Two examples are cited involving aspects of limb duplication to support this possibility; it is suggested that vascular vessel size of a host limb may dictate the polarity of duplication events. The presented hypothesis emphasizes that the interplay between the intrinsic properties of self-assembly into tissues and extrinsic factors which establish boundaries and morphologies is involved in both vascular and limb pattern formation.

Tumor-derived angiogenesis factors from rat Walker 256 carcinoma: an experimental investigation and review

Angiogenesis, the process of developing a hemovascular network, is an essential feature of the growth of solid tumors, and is induced by factors secreted by tumor cells. Assay procedures suitable for the investigation of angiogenesis, and for the screening of angiogenesis factors during purification are reviewed; and a number of reports describing the purification of angiogenesis factors, primarily from the rat Walker 256 carcinoma as starting material, are discussed. Work from the authors' laboratory is also presented. Walker 256 cells grown in large-scale culture were the source of a reproducible and homogeneous source of angiogenic material. Factors secreted by these cells were isolated by a series of chromatographic steps. Ion exchange chromatography on carboxymethyl-Sephadex produced two active fractions, one of which was fractionated into several macromolecular species by lectin affinity and hydrophobic adsorption chromatography. The other gave a high mol.wt, active fraction that was resolved into a low mol.wt, active component and a non-angiogenic but possibly carrier molecule with a mol.wt of 140,000. While none of the angiogenic factors were identified chemically, the results demonstrate the existence of both high and low mol.wt tumor-secreted angiogenic substances, confirming the hypothesis for tumor-induced angiogenesis and predicting potential means to interfere with the process of tumor growth.

Fibrin degradation and angiogenesis: quantitative analysis of the angiogenic response in the chick chorioallantoic membrane

Fibrin deposition and removal is a feature common to major pathological processes such as wound healing, chronic inflammation and tumour invasion: processes involving the ingrowth of new blood vessels. Low molecular weight fibrin degradation products (MW less than 50,000) are now shown to induce angiogenesis in the chick chorioallantoic membrane (CAM). This effect has also been shown by new quantitative assays to be associated with stimulation of both DNA and protein synthesis. Autoradiography indicates that all cell types in the CAM are stimulated to divide, and it is proposed that fibrin degradation products are a pathological growth factor.

Interaction between fibrinogen and cultured endothelial cells. Induction of migration and specific binding

It has been suggested that fibrinogen (fg) or its physiological derivatives influence the motility and growth of endothelial cells (ECs), but direct support for this concept is still lacking. In the present study, the capacity of fg to interact with ECs and induce the migration of ECs was examined. The capacity of fg to induce EC migration was studied by means of a modification of the Boyden chamber technique. fg in the lower compartment of the chamber caused a time- and concentration-dependent migration of ECs across filters. fg present in equal concentrations above and below the filter increased EC migration, but the maximal effect invariably occurred in the presence of a gradient between the lower and the upper compartments. Trypsin or plasmin digestion of fg and preincubation of fg with Fab fragments from specific antibody completely abolished fg-induced EC migration. Dialysis of fg to eliminate small peptides that might contaminate the preparation did not modify fg-induced migration. Plasma obtained from healthy donors induced EC migration, but plasma from an afibrinogenemic patient was completely ineffective. The addition of purified fg to afibrinogenemic plasma restored plasma-induced EC migration. Plasmin degradation fragments D and E, of 100,000 and 50,000 mol wt, respectively, did not induce EC migration. However, fragment E caused dose-related inhibition of fg-induced EC migration Direct interaction of highly purified radioiodinated human fg with cultured human and bovine Ecs was observed. The binding was time dependent and plateaued at 10 min. Nonlabeled fg in a large molar excess inhibited the interaction, but unrelated proteins, including fibronectin, ovalbumin, and myoglobin, did not. Monospecific Fab fragments directed to fg inhibited binding by 38% at a 50 to 1 molar ratio whereas nonimmune Fab caused only 2% inhibition at a similar concentration. The binding of 125I-fg with ECs was saturable, and an apparent dissociation constant of 0.23 x 10(-6) M was estimated from binding isotherms. After 30 min of incubation the interaction between 125I-fg and the cells was completely reversible and displaceable by a large molar excess of unlabeled fg. Autoradiography of the display of EC-bound 125I on polyacrylamide gel showed the constitutive B beta- and gamma-chains of the fg molecule, with a partial loss of the A alpha-chain. Purified fragment E and E were tested for their capacity to inhibit fg binding. At a 1 to 400 125I-fg-to-fragment molar ratio, fragment E, which also inhibited migration, competed for binding by 44%, but fragment D was completely ineffective. These data show that fg may specifically associate with ECs and induce migration of these cells; it also appears that the structural requirement of this activity is located in the N-terminal part of the molecule.

An hypothesis on the role of cellular colloid osmotic pressure in determining behavior of cells in vitro including anchorage dependency and maintenance of the differentiated state

The osmotic problems involved when cells are isolated from tissues are analyzed. Evidence is considered which indicates that in vivo the Na pump is operating at maximal or near maximal rates and that this depends on low leak rates for salts and water due to various aspects of the tissues structure. Dispersion of the tissue results in breakdown of these barriers on free diffusion and the isolated cell is subjected to an enormous increase in passive influx due to colloid osmotic pressure without being able to increase its pumping rate to the extent needed to maintain volume control. It is proposed that the primary problem the cell faces in vitro is to compensate for the effective increase in its colloid pressure, e.g. the colloid osmotic pressure excess, emerging with the breakdown of the tissue structure. The finding that most normal cells have to adhere to a surface in order to grow or "anchorage dependency" is analyzed in terms of the way adhesion and spreading result in changes in ion and water movements into cells enabling them to achieve fluid balance in the face of the colloid pressure excess. It is also proposed that the differentiated state is more dependent on colloid osmotic balance than proliferation. The failure of conditions used in tissue culture to compensate adequately for the colloid pressure excess results in limiting the amount of protein which can be synthesized, dissipation of cellular energy, and changes in orientation of cellular components which contribute directly to the loss of differentiation which occurs during growth in vitro.

Control of early embryonic heart morphogenesis: a hypothesis

The early events of looping (rotation and bending) of the embryonic vertebrate heart are deformations. The deformative forces and their regulation are intrinsic to the heart. A model of cardiac morphogenesis is described in this paper. It is proposed that synthesis of extracellular matrix by the myocardium generates an internal pressure. This pressure acts as a deforming force on the myocardium which controls strain by regulating compliance. This model provides an explanation of cardiac morphogenesis at the biochemical and biomechanical levels.

In vitro rapid organization of endothelial cells into capillary-like networks is promoted by collagen matrices

We have studied the behavior of cloned capillary endothelial cells grown inside a three dimensional collagen matrix. Cell monolayers established on the surface of collagen gels were covered with a second layer of collagen. This induced the monolayers of endothelial cells to reorganize into a network of branching and anastomosing capillary-like tubes. As seen by electron microscopy, the tubes were formed by at least two cells (in transverse sections) delimiting a narrow lumen. In addition, distinct basal lamina material was present between the abluminal face of the endothelial cells and the collagen matrix. These results showed that capillary endothelial cells have the capacity to form vessel-like structures with well-oriented cell polarity in vitro. They also suggest that an appropriate topological relationship of endothelial cells with collagen matrices, similar to that occurring in vivo, has an inducive role on the expression of this potential. This culture system provides a simple in vitro model for studying the factors involved in the formation of new blood vessels (angiogenesis).

Tumour angiogenesis

A variety of different factors has been implicated in inducing angiogenesis. Their identity and precise mechanisms of action remain elusive. The present treatise summarises the state of our knowledge not only in relation to tumour-induced capillary growth but also for non-neoplastic situations and mechanisms.

Angiogenesis: initiation and control

From in vivo experiments using new methods such as the rabbit cornea, it is now becoming clear that the growth of a capillary involves an ordered sequence of events that includes lysis of the basement membrane of a parent venule, directional migration of capillary endothelial cells toward the angiogenic stimulus, lumen formation, development of branches, and anastomosis of the tip of one tube with another to form a loop. It is also clear that diffusible angiogenic stimuli can be released not only from most solid tumors, but also from at least three non-neoplastic cells. These include activated macrophages, sensitized lymphocytes, and adipocytes. Other normal tissues can also stimulate angiogenesis, but the type of cell giving rise to the angiogenic stimulus is unknown, and the period of angiogenic stimulation is brief. With the recent ability to clone capillary endothelial cells and to carry them in long-term culture, it has been possible to further delineate the mechanism of capillary growth. In vitro studies have shown that the mast cell seems to behave as a helper cell for capillary endothelial cells, in some way speeding up their rate of directional migration. At this writing, heparin appears to be the principal mast cell factor responsible for this effect on capillary endothelial cells. One theoretical possibility is that mast cells may prepare the matrix, perhaps by slow release of heparin, so that capillary sprouts can more easily move through it toward their angiogenic target. While the study of angiogenesis as a phenomenon is still in an early phase, it has become possible, by using a combination of in vitro and in vivo techniques, to more thoroughly understand the initiation and control of capillary growth.