A study on the mechanism of intercellular adhesion. Effects of neuraminidase, calcium, and trypsin on the aggregation of suspended HeLa cells.

Aggregation of suspended HeLa cells is increased on removal of cell surface sialic acid. Calcium ions promote aggregation whereas magnesium ions have no effect. The calcium effect is abolished by previous treatment of the cells with neuraminidase. Trypsinization of the HeLa cells followed by thorough washing diminishes the rate of mutual cell aggregation. Subsequent incubation with neuraminidase restores the aggregation rate to the original value before trypsin treatment. Cells which had acquired a greater tendency for aggregation after removal of peripheral sialic acid lose this property when subsequently treated with trypsin. Calcium ions have no aggregative effect on trypsinized cells. In contrast to HeLa cells, aggregation of human erythrocytes was not increased after treatment with neuraminidase or on addition of calcium. The results with HeLa cells are interpreted as follows: (a) Trypsin-releasable material confers adhesiveness upon the cells. (b) The adhesive property of this material is counteracted by the presence of cell surface sialic acids. (c) Calcium ions exert their effect by attenuating the adverse effect of sialic acid.

Enlarged cell-associated proteoglycans abolish E-cadherin functionality in invasive tumor cells.

Mouse and dog epithelial cell lines, expressing high levels of the Ca(2+)-dependent cell-cell adhesion molecule E-cadherin in vitro, generated invasive and metastatic tumors in athymic mice. From these tumors, neoplastic cell lines were isolated. All ex vivo isolates retained high expression levels of E-cadherin at their surface. Nevertheless, some showed a fusiform morphotype, were defective in Ca(2+)-dependent cell aggregation, and were invasive in vitro, indicating that E-cadherin was not functional. Cell-associated proteoglycans were found to be enlarged in these variants as compared to their counterparts with functional E-cadherin. Treatment of the cells with the drug 4-methylumbelliferyl beta-D-xyloside specifically reduced the amount and size of cell-associated proteoglycans. This same drug induced an epithelial morphotype, increased Ca(2+)- and E-cadherin-dependent cell aggregation, and abrogated invasiveness without influencing E-cadherin expression levels. Our results indicate that enlarged proteoglycans can prevent the homophilic binding of E-cadherin, probably by steric hindrance. This is one more mechanism by which carcinomas may counteract invasion-suppressor genes and acquire malignancy.

Removal of sialic acid from the surface of human MCF-7 mammary cancer cells abolishes E-cadherin-dependent cell-cell adhesion in an aggregation assay.

MCF-7 human breast cancer cells express E-cadherin and show, at least in some circumstances, E-cadherin-dependent cell-cell adhesion (Bracke et al., 1993). The MCF-7/AZ variant spontaneously displays E-cadherin-dependent fast aggregation; in the MCF-7/6 variant, E-cadherin appeared not to be spontaneously functional in the conditions of the fast aggregation assay, but function could be induced by incubation of the suspended cells in the presence of insulinlike growth factor I (IGF-I) (Bracke et al., 1993). E-cadherin from MCF-7 cells was shown to contain sialic acid. Treatment with neuraminidase was shown to remove this sialic acid, as well as most of the sialic acid present at the cell surface. Applied to MCF-7/AZ, and MCF-7/6 cells, pretreatment with neuraminidase abolished spontaneous as well as IGF-I induced, E-cadherin-dependent fast cell-cell adhesion of cells in suspension, as measured in the fast aggregation assay. Treatment with neuraminidase did not, however, inhibit the possibly different, but equally E-cadherin-mediated, process of cell-cell adhesion of MCF-7 cells on a flat plastic substrate as assessed by determining the percentage of cells remaining isolated (without contact with other cells) 24 h after plating.

Thermal transitions in the adhesiveness of HeLa cells: effects of cell growth, trypsin treatment and calcium.

The intercellular adhesiveness of density-inhibited (D.I.) and fast-growing (F.G.) HeLa cells and of trypsin-treated preparations of these, has been measured at temperatures between 37 and 6 degrees C. In EDTA-containing buffer medium, F.G. cells differ from D.I. cells in that only the former display an increase in adhesiveness below 30 degrees C. This increase is prevented by previous treatment with trypsin. The presence of Ca2+ in the buffer medium causes a narrowing of the thermal transition region of intact F.G. cells. On intact D.I. cells Ca2+ causes an increase in adhesiveness at temperatures below 20 degrees C. Previous trypsinization of F.G. cells diminishes the effect of subsequent Ca2+ addition. The adhesiveness of trypsinized D.I. cells is indifferent to changes in temperature in Ca2+-containing buffer medium. The results are considered evidence for the occurrence of a phase transition in the glycoprotein domains of the plasma membrane of fast-growing cells. The transition is influenced by growth rate, trypsinization and Ca2+. The fluidity of the membrane glycoproteins is considered to be higher on density-inhibited cells than on fast-growing cells. No phase transition could be detected after incorporation of the fluorescent compound 1,6-diphenyl 1,3,5-hexatriene into the lipid domain of the plasma membrane. The fluidity of the membrane lipids is lower on density-inhibited cells than on fast-growing cells.

A correlation between the effects of calcium on intercellular adhesion and electrostatic repulsion between cells.

Calcium ions enchance the mutual adhesiveness of HeLa cells harvested from suspension cultures in which growth is density inhibited. No significant effect of calcium is observed on the mutual adhesiveness of HeLa cells from fast growing suspension cultures. Agglutinative titration of the cells using poly-L-lysine, mol. wt 15000, shows that calcium ions reduce the strength of the repulsive forces on density inhibited HeLa cells. The agglutination curve of the nonrepulsive fast growing HeLa cells is not significantly modified by the addition of calcium. The results support the conclusion that the effect of calcium on the mutual adhesiveness of density inhibited cells is due to a weakening of the repulsive forces on these cells.

Cell size and mutual cell adhesion. I. Increase in mutual adhesivenes of HeLa cells from density-inhibited suspension cultures by hypotonic treatment.

HeLa cells harvested from density-inhibited or fast growing suspension cultures, were incubated in NaCl solutions of different tonicity. Cell size enlargement produced by hypotonicity is accompanied by an increased sedimentation rate of the density-inhibited cells, whereas no appreciable change is observed in the sedimentation rate of fast growing cells. Hypotonicity also has no effect on the sedimentation rate of density-inhibited cells which previously had been treated with neuraminidase or trypsin. It is shown that the effect of hypotonicity on density-inhibited cells cannot be ascribed to release of cell surface sialic acids during hypotonic incubation. Several arguments are presented which indicate that the changes in sedimentation rate, as measured in the rotating suspension system, are not the direct consequence of the alterations in cell size, but rather must be attributed to differences in intercellular adhesiveness resulting from the size alterations. Analogous changes in intercellular adhesiveness and cell size are shown to occur during growth in isotonic suspension culture. The results can be explained by assuming that changes in cell size affect the intercellular adhesiveness by modifying the extent to which cell surface sialic acids counteract adhesion.

Cell size and mutual cell adhesion. II. Evidence for a relation between cell size, long-range electrostatic repulsion and intercellular adhesiveness during density-regulated growth in suspension.

The strength of the long-range electrostatic repulsion forces on HeLa cells is measured by agglutinative titration using low molecular weight polylysine (M.W. 11,000). Repulsion forces, found to be present on the smaller HeLa cells from density-inhibited suspension cultures, are weakened by incubation of the cells in hypotonic NaCl solutions. Repulsion forces, found to be absent on the larger cells from fast growing cultures, can be induced on these cells by incubation in hypertonic NaCl solutions. Both effects of anisotonicity are reversible, and disappear on restoration of the medium to normal tonicity. Induction of repulsion forces on fast growing cells is prevented by previous treatment of the cells with neuraminidase. Neuraminidase also abolishes repulsion on density-inhibited cells. It is proposed that alterations of the cell size, produced by anisotonicity or occurring during growth in isotonic suspension medium, affect mutual cell adhesiveness by modifying the strength of the repulsion forces generated by cell surface sialic acids.