Intracellular proteolytic activity of cathepsin B is associated with capillary-like tube formation by endothelial cells in vitro

The lysosomal cysteine protease cathepsin B is implicated in degradation of extracellular matrix (ECM), a crucial step in a variety of physiological and pathological processes, including tumor dissemination and angiogenesis. In this study, we analyzed the contribution of extracellular and intracellular cathepsin B activity on the formation of capillary-like tubular structures by human umbilical vein endothelial cells (HUVECs) grown on Matrigel matrix, using general and specific cysteine protease inhibitors. We demonstrated, by confocal assay using quenched fluorescent protein substrate DQ-collagen IV, that endothelial cells degrade ECM both intracellularly and pericellularly. Intracellular cathepsin B activity detected by degradation of Z-Arg-Arg cresyl violet substrate was co-localized with the products of DQ-collagen IV degradation in the perinuclear region and in the capillary-like tubular structures. Treatment of cells with membrane-permeable CA-074 Me effectively abolished intracellular cathepsin B activity, and resulted in reduced tube length (32.3+/-9.4% at 10 microM), total tubule area (49.6+/-12.4% at 10 microM), and the number of branch points of tubules (47.5+/-7.7% at 10 microM) in a dose-dependent manner. In contrast, CA-074 (0.1-10 microM), a membrane-impermeable cathepsin B specific inhibitor, general cysteine protease inhibitors chicken cystatin (5 microM) and E-64 (10 microM), and the metalloprotease inhibitor Minocycline (10 microM) showed no significant inhibitory effect in our angiogenesis model. These results show that, besides multiple regulatory molecules, intracellular cathepsin B also contributes to the neovascularization process and should be considered as a potential therapeutic target.     

The formation of capillary-like tubes by calf aortic endothelial cells grown in vitro

Cloned, large vessel endothelial cells derived from fetal bovine and bovine calf aortas formed three-dimensional structures in vitro without tumor-conditioned medium or special substrata. Transmission electron microscopy showed the structures to be hollow tubes composed of typical endothelial cells with overlapping and interdigitating cytoplasmic processes typical of those seen in in vivo capillaries. The putative lumen of these tubes generally contained abundant electron-dense fibrous material, which by ruthenium red and indirect immunofluorescent staining appeared to be extracellular matrix. This suggests that the endothelial cell orientation in the tubes is the reverse of that normally found in in vivo vessels.     

Mitogen-induced disorganization of capillary-like structures formed by human large vessel endothelial cells in vitro

Endothelial cells (EC) from human aorta, umbilical vein and pulmonary artery were grown in Medium 199 supplemented with 20% human serum (HS), endothelial cell growth factor (ECGF) from bovine and human brain (200 micrograms/ml) and heparin (100 micrograms/ml) in gelatin-coated flasks. Under these conditions cells rapidly proliferated and survived 15-25 passages (40-60 cumulative population doublings). When cells were cultured on plastic substrate and without growth factors a capillary-like network appeared after 3-4 weeks of growth. According to TEM, this network consisted of tubes with the lumen encircled by one or several cells. The reduction of serum concentration in the medium or the replacement of plasma-derived serum (PDS) for HS reduced the time of network formation to 3-5 days. S-180 conditioned medium mitogenic for EC induced a rapid spreading of the cells and a partial reversion to a two-dimensional monolayer structure. Trypsin inhibitor did not abolish the effect of tumour conditioned medium. Other EC mitogens, e.g. ECGF and fibroblast growth factor (FGF), also disorganized the capillary-like network. In a day or two the network was completely restored. In contrast, culturing EC on gelatin-coated substrate is a sufficient condition for monolayer formation from tubes and long-term maintenance. We suggest that mitogens can influence the EC morphology but that it is the nature of the substrate that determines the stage of large vessel EC differentiation.     

Astrocytes induce neural microvascular endothelial cells to form capillary-like structures in vitro

Astrocytes maintain a unique association with the central nervous system microvasculature and are thought to play a role in neural microvessel formation and differentiation. We investigated the influence of astroglial cells on neural microvascular endothelial differentiation in vitro. Using an astroglial-endothelial coculture system, rat brain astrocytes and C6 cells of astroglial lineage are shown to induce bovine retinal microvascular endothelial (BRE) cells to form capillary-like structures. Light microscopic evidence for endothelial reorganization began within 48 hours and was complete 72-96 hours following the addition of BRE cells to 1-day-old astroglial cultures. The extent of BRE reorganization was quantitated by computer-assisted analysis and shown to be dependent upon the density of both the BRE and C6 cells within the cocultures. Coculture conditions in which BRE cells were separated from C6 cells by porous membranes failed to generate this endothelial cell change. Likewise, C6-conditioned media and C6-endothelial coculture conditioned media did not induce BRE cell reorganization. Extracellular laminin within the C6-endothelial cocultures, identified by indirect immunofluorescence, was concentrated at the endothelial-astroglial interface of capillary-like structures consistent with incipient basement membrane formation. Astroglial cells accumulated adjacent to capillary-like structures suggesting the presence of bidirectional influences between the reorganized endothelial cells and astroglia. This is the first demonstration of astroglial induction of angiogenesis in vitro and these findings support a functional role for perivascular astrocytes in the vascularization of neural tissue such as retina and brain.     

Two different laminin domains mediate the differentiation of human endothelial cells into capillary-like structures in vitro

Endothelial cells, both microvascular as well as large vessel, undergo differentiation slowly in culture under most conditions. When endothelial cells are cultured on Matrigel, a solid gel of basement membrane proteins, they rapidly align and form hollow tube-like structures. We show here that tube formation is a multi-step process induced by laminin. An RGD-containing sequence in the A chain of laminin through an integrin receptor on the endothelial cell induces their attachment to the protein while a YIGSR site in the B1 chain induces cell-cell interactions and the resulting tube formation. We also show that the laminin-derived synthetic peptide YIGSR contains sufficient information to induce single endothelial cells to form ring-like structures surrounding a hollow lumen, the basic putative unit in the formation of capillaries.     

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).     

Extracellular matrix deposition by fibroblasts is necessary to promote capillary-like tube formation in vitro

The contribution of the cellular and fibrillar microenvironment to angiogenesis still remains unclear. Our purpose was to evaluate the effect of the extracellular matrix deposited by fibroblasts on the capacity of human endothelial cells to form capillaries in vitro. We have drastically decreased the amount of extracellular matrix surrounding fibroblasts in our model of endothelialized-reconstructed connective tissue (ERCT) by culturing it without ascorbate. Under these conditions, the number of capillary-like tubes (CLT) formed by endothelial cells was reduced by up to 10-fold after 31 days of culture compared to controls. This decrease was due neither to a variation of MMP-2 and MMP-9 secretion, nor to a reduction in the number of fibroblasts and/or endothelial cells, or a diminution of fibroblast growth factor 2 (FGF2) synthesis. The secretion of vascular endothelial growth factor (VEGF) by fibroblasts accounted for 25-70% of the capillary-like tube formation when tissues were cultured in the presence or absence of ascorbate, as demonstrated by VEGF-blocking studies. The culture of endothelial cells on a similar extracellular matrix but in the absence of living fibroblasts did not promote the formation of CLT, even when tissues were fed with fibroblast-conditioned medium. Thus, the deposition of a rich extracellular matrix by living fibroblasts appeared necessary, but not sufficient to promote capillary-like formation. Fibroblasts seem to induce endothelial cells to spontaneously form CLT by secreting and organizing an abundant extracellular matrix, which creates a microenvironment around cells that could in turn trap growth factors produced by fibroblasts and promote three-dimensional cell organization.     

Regulation of alpha 1 (I)-collagen gene expression in response to cell adhesion in Swiss 3T3 fibroblasts

Nonadhesive conditions cause Swiss 3T3 fibroblasts to enter a quiescent state that is reversed upon reattachment to a surface. Previously, we demonstrated that adhesion in serum-free conditions is sufficient to activate suspension-arrested cells out of Go, with the induction of the growth-associated genes, c-fos, c-myc, and actin. In this study, we have employed this system to identify programs of gene expression that respond primarily to the adhesive state of the cell, rather than the growth state. We show that cells in different adhesive states can be distinguished by their patterns of protein synthesis. Analysis of one adhesion-responsive protein led to its identification as pro-alpha 1 (I)-collagen. Pro-alpha 1 (I)-collagen synthesis and mRNA levels are decreased up to 6-fold in suspension-arrested fibroblasts, but are enhanced up to 5-fold as cells approach confluence. This suggests that the reduced expression in suspension-arrested cells is not simply a result of quiescence. In addition, reattachment of suspended cells in serum-free conditions caused a 7-fold induction of collagen mRNA levels and a greater than 20-fold rise in the rate of procollagen synthesis. The expression of c-myc was induced during adhesion in serum-free medium as well as by serum addition to suspension-arrested cells. However, alpha 1 (I)-collagen gene expression was unaffected by serum in the absence of adhesion. These results indicate that collagen gene expression is directly responsive to cell adhesion, independent of the growth state.     

Activation of the human alpha1(I) collagen promoter by leptin is not mediated by transforming growth factor beta responsive elements

Leptin increases human alpha1 (I) collagen mRNA and type I collagen production and enhances hepatic fibrosis in animal models of hepatic fibrosis. These effects of leptin on fibrogenesis may be mediated by TGFbeta1, since leptin increases the TGFbeta type II receptor and augments the effect of TGFbeta1 on collagen production by stellate cells. In this study, leptin increased the activity of the human alpha1 (I) collagen promoter in transfected stellate cells. Leptin did not further enhance the activation of the promoter induced by TGFbeta1. Leptin had no effects on the transfected TGFbeta-responsive p3TP-LUX plasmid, which contains 3 CAGA elements that are essential and sufficient for the induction by TGFbeta. Leptin did not increase significantly the binding of proteins to two TGFbeta1 responsive elements in the human alpha1 (I) collagen promoter. In conclusion, this study shows that leptin activates the alpha1 (I) collagen gene and that this effect is not mediated by TGFbeta responsive elements.     

In vitro formation of triple-stranded DNA structures in the human alpha1-antitrypsin gene

We analyzed the possibility of triplex formation in the human alpha 1-antitrypsin gene. Conditions and nucleotide sequence dependence of triplex formation and thermostability of the product were determined.