sepharose and Choriocarcinoma

Gels of glyoxyl agarose (GA) are evaluated as a novel flexible substrate for cell culture with physical properties comparable to extracellular matrix (ECM) gels. We show here that cells adhere well to pure GA gels; in addition, specific interactions involving matrix receptors can be studied when individual matrix molecules are bound to the gel covalently. When cells are grown on such substrates, morphology is comparable to that observed on "natural" matrix gels (reconstituted gels of collagen type I or of Matrigel): rather than being flattened as in monolayer cultures on tissue culture plastic the cells assume a rounded morphology and tend to form tissue-like aggregates. The effects of the artificial matrix gels are discussed in the context of previous publications on cell interactions with the extracellular matrix, suggesting that in addition to specific recognition of matrix molecules the physical properties of ECM by themselves can be decisive for cell differentiation. We conclude that gels of glyoxyl agarose a) provide a useful model to mimic the physical properties of matrix gels without the presence of specific adhesion factors; b) may be useful as a general, non-specific ECM allowing cells to be cultured in vitro under conditions favorable for differentiation; and c) allow to design a variety of "synthetic" ECM models composed of a chemically defined gel matrix, which can be supplemented with covalently bound molecules to be recognized by cell surface receptors.

Topics: Cell Adhesion; Cell Differentiation; Cell Division; Chemical Phenomena; Chemistry, Physical; Choriocarcinoma; Collagen; Culture Media; Extracellular Matrix; Glyoxal; Sepharose; Tumor Cells, Cultured

The role of extracellular matrix (ECM) in directing cell differentiation has been interpreted so far predominantly in terms of chemical signaling from individual matrix molecules. Recent data, however, suggest that the physical properties of ECM contribute signals for differentiation, which can be decisive and possibly even more important than chemical composition. In the present investigation, effects of different artificial matrices on the differentiation of BeWo choriocarcinoma cells were studied systematically. In Series (a) cells were grown on nonspecifically adhesive substrate gels (gels of glyoxyl agarose with or without poly-L-lysine crosslinked to) and on artificial matrix gels (matrix molecules covalently bound to agarose gels). Differentiation in terms of chorionic gonadotropin (hCG) secretion was stimulated on all artificial gel substrates much more than on rigid substrates of the same chemical composition. Concomitantly a change in morphology was observed to a rounded shape of cells in aggregates attached to the substrate. A series (b) of substrates with gradually reduced adhesiveness was created by coating plastic with different concentrations of poly-HEMA. In this sequence, gradual changes in cell morphology (stepwise approximation to a spherical shape) correlated with increased hCG secretion comparable to that on matrix gels. In contrast, in aggregates kept in suspension the increase in secretion of hCG was only marginal. These results clearly support that in addition to chemical recognition of individual matrix molecules, cells respond strongly to physical properties of extracellular matrix and that the physics of interaction of cytoskeleton, cell surface, and ECM can become decisive for cell differentiation.

Topics: Animals; Cell Differentiation; Cell Division; Cell Line; Choriocarcinoma; Chorionic Gonadotropin; Colchicine; Collagen; Cytochalasin B; Dimethyl Sulfoxide; Drug Combinations; Extracellular Matrix; Extracellular Matrix Proteins; Female; Gels; Glyoxylates; Humans; Laminin; Ligands; Pregnancy; Proteoglycans; Sepharose; Tumor Cells, Cultured; Uterine Neoplasms