Expression of galectins on microvessel endothelial cells and their involvement in tumour cell adhesion.

Lactoside-binding lectins (galectins) with molecular weights of about 14.5 kDa (galectin-1) and 29-35 kDa (galectin-3) bind preferentially to polylactosaminoglycan-containing glycoconjugates and have been found on the surface of tumour cells and implicated in cell-cell and cell-extracellular matrix adhesion and metastasis. We have demonstrated by immunoblotting that both galectin-1 and galectin-3 are present in extracts of endothelial cells cultured from bovine aorta, rat lung, mouse lung and mouse brain microvessels, whereas mouse hepatic sinusoidal endothelial cells expressed primarily galectin-1. These galectins were also localized by indirect immunofluorescent labelling on the surface of the different endothelial cells in culture and by immunohistochemical staining in human tissues in vivo. Anti-galectin-1 antibodies inhibited the adhesion of liver-preferring murine RAW117-H10 large-cell lymphoma cells to hepatic sinusoidal endothelial cells or lung microvessel endothelial cells in vitro. The data indicate that galectin-1 is expressed on the extracellular surface of endothelial cells and can mediate in part the adhesion of RAW117-H10 cells to liver microvessel endothelial cells.

Effect of hypoxia on endothelial cell surface glycoprotein expression: modulation of glycoprotein IIIa and other specific surface glycoproteins.

Exposure to hypoxia alters many aspects of endothelial cell metabolism and function; however, changes in surface glycoconjugates under these conditions have not been extensively evaluated. In the current studies, we examined surface glycoproteins of cultured bovine aortic (BAEC) and pulmonary arterial (BPAEC) endothelial cells under standard culture conditions (21% oxygen) and following exposure to hypoxia (0% oxygen) for varying time periods (30 min to 18 h) using a system of biotinylation, lectin binding (concanavalin A, Con A; Griffonia simplicifolia, GSA; Arachis hypogaea, PNA; Ricinus communis, RCA; or Triticum vulgaris, WGA), subsequent strep-avidin binding, and staining. Using these methods, we identified differences in lectin binding between the two cell types cultured in 21% oxygen with all lectins except PNA. With exposure to 0% oxygen, there was no change in lectin binding to most surface glycoproteins. Several surface glycoproteins, including glycoprotein IIIa on both cell types, demonstrated a time-dependent decrease in lectin binding; in addition, there was an increase in lectin binding to a few specific surface glycoproteins on each cell type within 30-60 min of exposure to 0% oxygen. These changes in specific surface glycoproteins were confirmed in both cell types by 125I labeling. Increased lectin binding was observed for Con A binding BAEC glycoproteins at molecular weight (MW) 116, 130, and 205 kDa, GSA binding BAEC glycoproteins at MW 120 and 205 kDa, and RCA binding BPAEC glycoproteins at MW 140 and 205 kDa. Increased binding of WGA or PNA was not observed during exposure to hypoxia. The specificity of lectin binding was further confirmed by competitive inhibition with the appropriate sugar. These studies demonstrate that there are baseline differences between BAEC and BPAEC cell surface glycoproteins and that exposure to hypoxia is associated with little change in lectin binding to most surface glycoproteins. There is, however, increased surface expression of a few glycoproteins that differ depending of the origin of the endothelial cell. Although the mechanism of this increase in lectin binding is not yet clear, subsequent studies suggested that it is due to increased availability of select carbohydrate moieties. The time course of these alterations suggests a possible role in the endothelial cell response to decreases in ambient oxygen tension.

Culture and characterization of pulmonary microvascular endothelial cells.

Surface proteins were compared in endothelial cells (EC) obtained from bovine peripheral lung, pulmonary artery and vein, and dorsal aorta using sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis. Galactose-containing glycoproteins [molecular weight (M(r)) 160-220 and 40 kDa] binding to the Ricinus communis agglutinin (RCA) and peanut agglutinin (PNA) were selectively observed on pulmonary microvessel EC as compared to EC from pulmonary artery, pulmonary vein, and dorsal aorta. The unique RCA- and PNA-binding profiles of EC from the pulmonary artery and microvessels may be important in characterizing EC from different sites in the pulmonary circulation. The pulmonary microvessel EC monolayer was also 15-fold more restrictive to transendothelial flux of [14C]sucrose (M(r) = 342 Da) than the pulmonary artery EC monolayer. In contrast, the microvessel EC were only six- and twofold more restrictive to the flux of larger tracer molecules, ovalbumin (M(r) 43 kDa) and albumin (M(r) = 69 kDa) than pulmonary artery EC. The greater restrictiveness of pulmonary microvessel EC monolayer indicates a major phenotypic difference in the cultured pulmonary microvessel EC barrier function.

Organ-derived microvessel endothelial cells exhibit differential responsiveness to thrombin and other growth factors.

To investigate the relationship between endothelial cells and organ-associated vascular physiology, microvascular endothelial cells were isolated from murine brain, lung, and liver tissues. During culture, these endothelial cells maintained certain differentiated characteristics common to all endothelial cells, but also showed organ-specific characteristics, with distinct patterns of responsiveness to various growth factors. Microvascular endothelial cells from all organs responded to endothelial cell growth factor (ECGF), but lung (LE-1) and brain (MBE-12) endothelial cells showed different responsiveness to thrombin (10-60 nM), combinations of thrombin and ECGF, or thrombin and extracellular matrix. Liver sinusoidal endothelial cells (HSE) were relatively unresponsive to thrombin, but were the most responsive of the endothelial cells to EGF. Endothelial cells isolated from lung and brain, where fluxes in vascular permeability are observed following injury, showed dramatic morphological alterations in response to nanomolar concentrations of thrombin. These cells also exhibited the highest amount of 125I-thrombin binding at these concentrations. Scatchard analysis of 125I-thrombin binding indicated that LE cells have the highest affinity for thrombin, followed by MBE, with HSE exhibiting significantly lower affinity. The binding of 125I-thrombin to these cells was inhibited by the TR-9 monoclonal antibody directed against fibroblast high-affinity thrombin receptors involved in thrombin-stimulated mitogenesis. The results suggest that the differences in growth stimulation observed between organ-derived endothelial cells in response to thrombin, ECGF, and EGF may relate to differential expression of receptors for these factors. These observations demonstrate yet another aspect of the functional heterogeneity of the microvascular endothelium.

Microvascular endothelial cell heterogeneity: interactions with leukocytes and tumor cells.

Endothelium constitutes a highly specialized organ that lines the vascular system and lymphatic channels. This organ is a complex network of arteries, veins, and microvessels that differ in size, structure, and function. The unique and strategic location imposes functional demands on the endothelium that are far greater than just being a passive barrier. Endothelial cells have the ability to differentiate both in structure and function in response to the needs of diverse tissue environments, making this organ extremely heterogeneous. Although vascular endothelial cells share certain common properties, they differ in regard to structure, antigenic and cell surface determinants, adhesion molecules, and metabolic function. The unique cell surface profiles expressed by endothelial cells in different tissue locations can be recognized by specific populations of circulating leukocytes or tumor cells, which contribute to their arrest and invasion patterns. This article attempts to review our current understanding of endothelial cell heterogeneity and its significance to patterns of leukocyte and tumor cell trafficking.

Adhesive, invasive, and growth properties of selected metastatic variants of a murine large-cell lymphoma.

The adhesive, invasive, and growth properties of parental murine large-cell lymphoma cells of low metastatic potential (RAW117-P) were compared to in-vivo-selected sublines of high metastatic potential to liver (RAW117-H10) or lung (RAW117-L17). Using small (approximately 0.5 mm3) pieces of syngeneic organ tissue (lung, liver, kidney) we found that RAW117-L17 cells selectively attached to and invaded lung tissue, whereas RAW117-H10 cells preferentially attached to and invaded liver tissue. We measured adhesion to microvessel endothelial cells established from syngeneic lung and liver and found that the RAW117-L17 cells bound to lung microvessel endothelial cells at significantly higher rates than the other lines, and RAW117-H10 and -L17 cells attached to hepatic sinusoidal endothelial cells at significantly faster rates than RAW117-P cells. Such organ specificity of adhesion was not found at the level of the subendothelial matrix, and the rates of adhesion of RAW117 cells to subendothelial matrix were lower than to endothelial cells. RAW117 cells of low or high metastatic potential bound to immobilized extracellular matrix components, such as fibronectin, at high rats, but adhesion to laminin or collagen IV was minimal. Previous studies indicated that RAW117 lines could proliferate in vitro in certain organ-conditioned media under limiting serum conditions. We therefore examined the ability of a purified paracrine lung growth factor (LDGF-1) to stimulate growth of RAW117 cells in limiting serum-containing medium. The high lung-colonizing L17 line was stimulated to proliferate by LDGF-1 at faster rates than the other lines. The data support Paget's hypothesis that the organ specificity of tumor metastasis is determined by specific tumor cell and host properties.

Correlation of inhibition of adhesion of large cell lymphoma and hepatic sinusoidal endothelial cells by RGD-containing peptide polymers with metastatic potential: role of integrin-dependent and -independent adhesion mechanisms.

Murine RAW117 large-cell lymphoma cells that show organ preferences of metastatic colonization were selected. We examined the role of adhesive systems in determining the organ preference of metastasis using cell lines of low (RAW117-P) and high (RAW117-H10) liver-metastatic potential. Highly metastatic H10 cells adhered at higher rates than low metastatic P cells to target organ microvessel endothelial cells, and these interactions were partially inhibited by RGD-containing polymers but not by small peptides such as GRGDS or GRGES. The most effective polymers, such as (GRGDS)4 and GRGDS(GRGES)2GRGDS, significantly inhibited H10 cell adhesion but had less effect on P cell adhesion to target liver sinusoidal endothelial cell monolayers or on P cell or H10 cell adhesion to bovine aortic endothelial cell monolayers. The (GRGDS)4 polymer reduced the rate of H10 liver sinusoidal endothelial cell adhesion to that of P cells in the absence of inhibitors, suggesting that the quantitative difference in adhesion of H10 cells versus P cells to liver sinusoidal endothelial cells may have been due to integrin-like molecules. Other RGD-containing polymers, such as (GRGES)2(GRGDS)2, GRGES(GRGDS)2GRGES, or (GRGES)4, were less effective, suggesting that the secondary structure of the polymers may be an important consideration. A peptide from the B1 chain of laminin (YIGSR) or its homopolymer, (YIGSR)4, had no effect on endothelial cell adhesion, consistent with the lack of differential laminin adhesion seen with various RAW117 cell lines. The results suggest that integrin-related molecules may play a role in the organ specificity of endothelial cell adhesion seen with RAW117 tumor cells.

Differential adhesion of metastatic rat mammary carcinoma cells to organ-derived microvessel endothelial cells and subendothelial matrix.

The in vitro adhesion rates of rat 13762NF mammary adenocarcinoma cell clones of different spontaneous metastatic potentials to cloned microvessel endothelial cell monolayers and their subendothelial extracellular matrix were investigated. In this system, high rates of adhesion of the cloned tumor cell lines to syngeneic target (lung) organ-derived subendothelial matrix correlated with spontaneous metastatic potential, whereas adhesion to the lung microvessel endothelial cell apical surfaces occurred at lower rates and was not highly significantly different among the tumor cell lines. Adhesion rates to bovine aortic large vessel, and human brain and human meningeal microvessel endothelial cell monolayers were, in general, lower than those found with syngeneic lung microvessel endothelial cells, and did not correlate with spontaneous metastatic potential. Growth of endothelial cells in fetal bovine serum or platelet-poor horse serum did not affect the results, suggesting that in this system metastasis-associated organ-adhesive specificity is determined at the level of the subendothelial matrix.

Differential expression of cell surface glycoproteins on various organ-derived microvascular endothelia and endothelial cell cultures.

Glycoproteins expressed on the luminal surfaces of microvascular endothelium derived from various murine organs were analyzed and compared with those expressed by cultured vascular endothelial cells. Cell-surface vascular proteins were radiolabeled in situ via intracardiac perfusion with lactoperoxidase/Na125I. Autoradiography confirmed that the radiolabel was restricted to the vessel lumen in most tissues. Controls contained 125I-labeled serum proteins to identify adsorbed serum components. Glycoproteins were analyzed by western enzyme-linked lectin analysis using detergent extracts of 125I-labeled microvessels isolated from different organs. The western transfers were probed with a panel of lectin-peroxidase conjugates to determine differences in protein glycosylation. The same transfers were also screened for exposed 125I-labeled cell-surface proteins by autoradiography. This dual analysis detected glycoprotein patterns unique for each organ. At least seven major proteins (Mr approximately 180 K, 130 K, 95 K, 80 K, 75 K, 60 K, 12 K) were common to microvessels derived from each organ; however, certain glycoproteins appeared to be expressed differentially in particular organs. For example, a Mr approximately 135 K WGA-binding glycoprotein was detected in brain microvessels, whereas another WGA-binding glycoprotein of Mr approximately 40 K was detected only in kidney. In lung microvessels, a Mr approximately 140 K WGA binding glycoprotein and a Mr approximately 55 K RCA-I-binding galactoprotein were expressed preferentially, and liver microvessels displayed Mr approximately 220 K protein and a Mr approximately 35 K PNA-binding galactoprotein. The cell-surface-iodinated protein profiles from in situ labeled microvessels were similar to profiles derived from cultured bovine aortic endothelial cells and several short-term endothelial cell cultures isolated from different organs. The results from this study suggest that organ-associated endothelia express glycoprotein fingerprints unique to each organ.

Degradation of basement membrane type IV collagen and lung subendothelial matrix by rat mammary adenocarcinoma cell clones of differing metastatic potentials.

A series of rat 13762NF mammary adenocarcinoma cell clones and subclones of various lung metastatic potentials were examined for their abilities to degrade rat lung subendothelial matrix and purified basement membrane type IV collagen. Metastatic potentials were simultaneously determined based on the ability to form "spontaneous" lung metastases after s.c. injection or "experimental" lung metastases after i.v. injection of cells. Microvessel endothelial cells isolated from rat lung were grown in vitro, and the subendothelial matrix containing type IV collagen was metabolically labeled with [3H]proline. When mammary adenocarcinoma cells were placed on the isolated subendothelial matrix, fragmentation and solubilization of [3H]proline-labeled components were observed; highly metastatic 13762NF cells solubilized the matrix at higher rates than did poorly metastatic cells. The 13762NF cells were assayed for type IV collagenolytic activity using [3H]proline-labeled type IV collagen purified from Engelbreth-Holm-Swarm tumor as a substrate. We found excellent correlation between the type IV collagenolytic activities of living cells and their "spontaneous" lung metastatic potentials (r = 0.993). The levels of type IV collagenolytic activity in the conditioned medium depended on the cell culture conditions. In the presence or absence of acid-treated fetal bovine serum, highly metastatic cells secreted higher amounts of type IV collagenolytic enzymes in active and latent forms than did poorly metastatic cells. Incubation of procollagen type IV with medium conditioned by highly metastatic 13762NF cells and treated with trypsin resulted in the production of several large fragments characteristic of type IV collagen. The results suggest that enzymatic degradation of basement membrane type IV collagen is important in lung metastasis of 13762NF mammary adenocarcinoma cells.

Characterization of extracellular matrix-associated glycosaminoglycans produced by untransformed and transformed bovine corneal endothelial cells in culture.

A cloned bovine corneal endothelial cell line was transformed in vitro by simian virus 40, and the subendothelial extracellular matrix-associated sulfated glycosaminoglycans synthesized by the cells were isolated and compared with their untransformed counterpart. The transformed endothelial cells grew at faster rates to higher stationary cell densities in the absence of fibroblast growth factor than did the untransformed cells. On a per-cell basis, the transformed cells produced slightly lower amounts of sulfated glycosaminoglycans. The rate of production of sulfated glycosaminoglycans in extracellular matrix increased during seven days of culture. At confluency the extracellular matrix-associated sulfated glycosaminoglycans synthesized by the untransformed endothelial cells consisted of about 80% heparan sulfate and about 20% chondroitin sulfate. Extracellular matrix-associated sulfated glycosaminoglycans of transformed endothelial cells were composed of about 70% heparan sulfate and about 30% chondroitin sulfate plus dermatan sulfate. High-speed gel permeation chromatography profiles on Fractogel TSK HW-55(S) of matrix-associated heparan sulfate from untransformed and transformed endothelial cells were very similar, and gave single peaks (Kav = 0.19). Apparent Mr estimated from the eluting position of the peaks were approximately 47000. Heparan sulfate from both untransformed and transformed endothelial cells was degraded by incubation with a metastatic B16 melanoma cell lysate containing heparanase (heparan-sulfate-specific endo-beta-glucuronidase). The eluting position of the heparan sulfate degradation products on gel permeation column were similar (Kav = 0.43). Size analysis and anion-exchange chromatography of the degradation products after nitrous acid deamination at low pH indicated that the degree of N-sulfation of heparan sulfate was similar in untransformed and transformed endothelial cells. The results indicated that transformation of endothelial cells only slightly changes the molecular nature of subendothelial matrix-associated sulfated glycosaminoglycans.