Christian Huet

Villin induces microvilli growth and actin redistribution in transfected fibroblasts

The function of villin, an actin-binding protein, has been investigated by transfecting fibroblasts with cloned human cDNAs encoding wild-type villin or functional villin domains. Synthesis of large amounts of villin induced the growth of numerous long microvilli on cell surfaces together with the redistribution of F-actin. These microvilli contained a cytoskeleton of F-actin, and their appearance was frequently accompanied by the disappearance of stress fibers. The complete villin gene sequence was required to exert its morphogenic effect. Villin lacking one actin-binding domain (113 amino acids), located at its carboxyterminal end, did not induce growth if microvilli or stress fiber disruption. Our results indicate that villin plays a key role in vivo in the morphogenesis of microvilli.

An actin-binding site containing a conserved motif of charged amino acid residues is essential for the morphogenic effect of villin

The actin-binding protein villin induces microvillus growth and reorganization of the cytoskeleton in cells that do not normally produce this protein. Transfection of mutagenized villin cDNAs into CV-1 cells was used to show that a conserved, COOH-terminally located cluster of charged amino acid residues (KKEK) is crucial for the morphogenic activity of villin in vivo. In vitro experiments with a 22 amino acid synthetic peptide corresponding to this region of villin provide evidence that this motif is part of an F-actin-binding site that induces G-actin to polymerize. Chemical cross-linking of actin to this peptide, the effects of amino acid substitutions in peptides, and the behavior of villin variants further corroborate the participation of the KKEK sequence in actin contacts.

G- to F-actin modulation by a single amino acid substitution in the actin binding site of actobindin and thymosin beta 4.

The actin binding sites of actobindin and thymosin beta 4, two small polypeptides that inhibit actin polymerization by interacting with monomeric actin, have been localized using peptide mimetics. Both sites are functionally similar and extend over 20 residues and are located in the NH2‐terminus of the polypeptides. They can be dissected into two functional entities: a conserved hexapeptide motif (LKHAET or LKKTET), which forms the major contact site through electrostatic interactions with actin, and a non‐conserved NH2‐terminal segment preceding the motif, which exerts the inhibitory activity on actin polymerization probably by steric hindrance. The introduction of a glutamic acid at the third position in the motif, creating LKEAET or LKETET sequences, which are similar to those found in some F‐actin binding proteins, converts the peptides inhibitory phenotype into an F‐actin stimulatory property. These results allow the proposal of a simple model for G‐ to F‐actin modulation.

Differentiation of a clone isolated from the HT29 cell line: polarized distribution of histocompatibility antigens (HLA) and of transferrin receptors

The HT29 cell line, derived from a human colon adenocarcinoma, is able to differentiate if galactose replaces glucose in the culture medium. We have isolated a clone (HT29‐18) from this cell which displays differentiated properties of the parent cell line. HT29‐18 cells grown in glucose‐containing medium form multiple layers of round cells without specific cell‐cell adhesion. In contrast, when grown in galactose‐containing medium, they form a monolayer with tight junctions and exhibit a well differentiated brush border at their apical membrane, which faces the culture medium. The polarized properties of HT29‐18 cells grown galactose‐containing medium were demonstrated by immunofluorescent techniques with antibodies against 2 plasma membrane proteins. Class I histocompatibility antigens (HLA) and transferrin receptors, 2 well characterized integral membrane proteins, are uniformly distributed on the cell surface of undifferentiated HT29‐18 cells, but acquire a polarized distribution during differentiation, localized on the basolateral membranes and absent from the apical surface. Binding of 125I‐labeled transferrin was used to determine transferrin receptor distribution on apical and basolateral membranes. Functional tight junctions in the differentiated cultures were demonstrated, as the monolayer was impermeable to a permeation dye (ruthenium red) as well as to antibodies. The sealing of these tight junctions is, as in vivo, Ca++‐dependent as they could be opened by a short incubation in Ca++‐free medium.

Water handling in Caco-2 cells: effects of acidification of the medium

Caco-2 cells were cultured on permeable supports. At confluence the minute-by-minute net water movement (Jw) was automatically recorded. Simultaneously, unidirectional [14C]mannitol, 22Na+, and/or 36Cl− fluxes and transepithelial resistances were measured. The water and mannitol permeabilities went progressively down between 9 and 16 days after seeding and then stabilized. In this last condition the hydrostatic permeability coefficient (Phydr) was 2.67±0.31 cm s−1 while the osmotic permeability coefficient (Posm) was 0.0017±0.0004 cm s−1. Phydr but not Posm was dependent on the temperature and on the presence of Na+ in the medium. A net secretory Jw was observed 16 days after seeding, in the absence of any osmotic, hydrostatic or chemical gradient. This secretory Jw was associated with net Cl− (1.43±0.43 μequiv h−1 cm−2) and Na+ (1.05±0.35 μequiv h−1 cm−2) secretions. Amiloride reduced, in open-circuit conditions, both Na+ and Cl− apical to basal fluxes, thus enhancing the net Na+ and Cl− exit. Acidification of the medium (pH 6.2) reversibly increased water and mannitol permeabilities in 10-day-old cultures. In 16-day-old cultures the same shift in medium pH did not change mannitol permeability, while stimulating water secretion. These results, obtained in the absence of supracellular structures (villae, crypts) and subepithelial components (muscular, vascular and conjunctive tissues) indicate that paracellular and transport-associated water pathways are sensitive to changes in the pH of the medium in Caco-2 cell layers.

Villin as a structural marker to study the assembly of the brush border

SummaryBrush borders which are localized at the apical face of enterocytes, are composed of thousands of stiff microvilli containing bundles of microfilaments made of actin. Their assembly occurs during terminal differentiation of the enterocytes when these cells migrate along the villus of the intestinal mucosa. The cell line HT 29 derived from a human colonic adenocarcinoma whose differentiation can be induced, can also be used as a model to study in culture the assembly of the intestinal brush border.Villin is one of the actin binding proteins found in microvilli which compose brush borders. Villin is expressed in the adult and in the embryo before the appearance of the brush border. Villin can be used as a tissue-specific marker for normal diffentiated and undifferentiated cells derived from gastrointestinal tractus in the adult as well as in the embryo. Since villin is a good marker for intestinal cells and plays a structural role in the assembly of the brush border we have analysed its expression and its localization in HT 29 cells. In HT 29 cells, as in the tissue, villin is synthesized at low levels before the appearance of the brush border. The high rate of synthesis and the recruitement of villin at the apical pole of the cells can be correlated with the existence of a well developed brush border.

Transferrin Endocytosis and Fluid Phase Uptake in the Differentiable Intestinal Cell Line HT-29

Cells such as epithelial or neuronal cells, when fully differentiated, exhibit a clear functional asymmetry related to morphological asymmetry (Gumbiner & Louvard, 1985).