Sequence of human villin: a large duplicated domain homologous with other actin-severing proteins and a unique small carboxy-terminal domain related to villin specificity.

Villin is a calcium-regulated actin-binding protein that caps, severs, and bundles actin filaments in vitro. This 92,500-D protein is a major constituent of the actin bundles within the microvilli of the brush border surface of intestinal and kidney proximal tubule cells. Villin is a very early marker of cells involved in absorption and its expression is highly increased during intestinal cell differentiation. The amino acid sequence deduced from the cDNA sequence revealed that human villin is composed of three domains. The first two domains appear as the result of a duplication: their structural organization is similar. We can then define a basic unit in which a slightly hydrophilic motif is followed by three hydrophobic motifs, similar between themselves and regularly spaced. The duplicated domain is highly homologous to three other actin-severing proteins and this basic structure represents the whole molecule in severin and fragmin, while two basic units compose gelsolin. The third domain which is carboxy terminal is villin specific: it is unique among actin modulating proteins so far known. It could account for its actin-binding properties (dual regulation by calcium of severing and bundling activities). We propose that it may also be related to the subcellular localization of villin in different epithelial cell types.

Conversion by Peyer's patch lymphocytes of human enterocytes into M cells that transport bacteria.

The epithelium that lines the gut is impermeable to macromolecules and microorganisms, except in Peyer's patches (PPs), where the lymphoid follicle-associated epithelium (FAE) contains M cells that transport antigens and microorganisms. A cultured system that reproduces the main characteristics of FAE and M cells was established by cultivation of PP lymphocytes with the differentiated human intestinal cell line Caco-2. Lymphocytes settled into the epithelial monolayer, inducing reorganization of the brush border and a temperature-dependent transport of particles and Vibrio cholerae. This model system could prove useful for intestinal physiology, vaccine research, and drug delivery studies.

Molecular studies of the intestinal mucosal barrier physiopathology using cocultures of epithelial and immune cells: a technical update.

Peyer's patch lymphocytes cocultured with Caco-2 cells trigger the phenotypic conversion of enterocytes into cells that express morphological and functional M-cell properties. We report a technical update for setting up this model, which will enable the study of M-cell biology, the identification by biochemical approaches of molecules involved in the interaction of microorganisms with M cells, and the development of vectors that would efficiently target the mucosal immune system.

Review article: Intestinal epithelia and barrier functions.

The mucosal epithelia of the digestive tract acts as a selective barrier, permeable to ions, small molecules and macromolecules. These epithelial cells aid the digestion of food and absorption of nutrients. They contribute to the protection against pathogens and undergo continuous cell renewal which facilitates the elimination of damaged cells. Both innate and adaptive defence mechanisms protect the gastrointestinal-mucosal surfaces against pathogens. Interaction of microorganisms with epithelial cells triggers a host response by activating specific transcription factors which control the expression of chemokines and cytokines. This host response is characterized by the recruitment of macrophages and neutrophils at the site of infection. Disruption of epithelial signalling pathways that recruit migratory immune cells results in a chronic inflammatory response. The adaptive defence mechanism relies on the collaboration of epithelial cells (resident sampling system) with antigen-presenting and lymphoid cells (migratory sampling system); in order to obtain samples of foreign antigen, these samples must be transported across the barriers without affecting the integrity of the barrier. These sampling systems are regulated by both environmental and host factors. Fates of the antigen may differ depending on the way in which they cross the epithelial barrier, i.e. via interaction with motile dendritic cells or epithelial M cells in the follicle-associated epithelium.

Interaction of microorganisms, epithelium, and lymphoid cells of the mucosa-associated lymphoid tissue.

Differentiation of specific epithelial cell lineages during development, as well as epithelial plasticity in response to heterologous cell-to-cell cross talk during adult life, accounts for the large variety of functions which are performed by the mucosal surfaces found in the human body. Among its functions, the digestive mucosa is able to sample antigens and microorganisms through M cells of Peyer's patches' follicle-associated epithelium, in order to trigger the development of either tolerance or immune responses. At least in the gut, M-cell formation is immunoregulated. Close contact between immune cells and intestinal epithelium modifies the permeability of the epithelial barrier by inducing the conversion of enterocytes into M cells, offering at the same time an opportunistic way of invasion for pathogens. These lympho-epithelial interactions triggering M-cell formation have now been modeled in culture.

Plasticity of the gastrointestinal epithelium: the M cell paradigm and opportunism of pathogenic microorganisms.

The maintenance during adult life of a large spectrum of pluripotency by stem cells originating from the endoderm seems to be the grounds for the striking plasticity of the digestive epithelium, which is able to drastically modify its differentiation pattern depending on the microenvironment. As a paradigm, Peyer's patch M cell development appears to be induced by crosstalk between lymphoid cells and/or microorganisms. Examples of pathological transdifferentiation of epithelia, also described as 'metaplasia' and affecting various organs, support the concept of intestinal plasticity. Though, the molecular processes involved in epithelial transdifferentiation have not been identified, histological analyses of these metaplastic tissues and experimental induction of transdifferentiation of normal epithelia provide lines of evidence suggesting that a modification of the local environment, such as occurs during contact of the epithelium with lymphoid cells or microorganisms, plays a key role in this process.

Differences in degradation processes for insulin and its receptor in cultured foetal hepatocytes.

Binding and degradation of 125I-labelled insulin were studied in cultured foetal hepatocytes after exposure to the protein-synthesis inhibitors tunicamycin and cycloheximide. Tunicamycin (1 microgram/ml) induced a steady decrease of insulin binding, which was decreased by 50% after 13 h. As the total number of binding sites per hepatocyte was 20000, the rate of the receptor degradation could not exceed 13 sites/min per hepatocyte. Cycloheximide (2.8 micrograms/ml) increased insulin binding by 30% within 6 h, an effect that persisted for up to 25 h. This drug had a specific inhibitory effect on the degradation of proteins prelabelled for 10 h with [14C]glucosamine, without affecting the degradation of total proteins. Chronic exposure to 10 nM-insulin neither decreased insulin binding nor modified the effect of the drugs. The absence of down-regulation of insulin receptors cannot be attributed to rapid receptor biosynthesis in foetal hepatocytes. Cellular insulin degradation, which is exclusively receptor-mediated, was determined by two different parameters. First, the rate of release of degraded insulin into the medium was 600 molecules/min per hepatocyte with 1 nM labelled hormone, and increased (preincubation with cycloheximide) or decreased (tunicamycin) as a function of the amount of cell-bound insulin. Secondly, the percentage of cell-bound insulin degraded was not changed by the presence of protein-synthesis inhibitors (25-30%). The stability of insulin degradation suggested that this process was dependent on long-life proteinase systems. Such differences in degradation rates and cycloheximide sensitivity imply that hormone- and receptor-degradation processes utilize distinct pathways.

Cell-surface insulin receptor cycling and its implication in the glycogenic response in cultured foetal hepatocytes.

The insulin-receptor cycle was investigated in cultured foetal rat hepatocytes by determining the variations in insulin-binding sites at the cell surface after short exposure to the hormone. Binding of 125I-insulin was measured at 4 degrees C after dissociation of prebound native insulin. Two protocols were used: exchange binding assay and binding after acid treatment; both gave the same results. Cell-surface 125I-insulin-receptor binding decreased sharply (by 40%) during the first 5 min of 10 nM-insulin exposure (t1/2 = 2 min) and remained practically constant thereafter; subsequent removal of the hormone restored the initial binding within 10 min. This fall-rise sequence corresponded to variations in the number of insulin receptors at the cell surface, with no detectable change in receptor affinity. The reversible translocation of insulin receptors from the cell surface to a compartment not accessible to insulin at 4 degrees C was hormone-concentration- and temperature-dependent. SDS/polyacrylamide-gel electrophoresis after cross-linking of bound 125I-insulin to cell-surface proteins with disuccinimidyl suberate showed that these variations were not associated with changes in Mr of binding components, in particular for the major labelled band of Mr 130,000. The insulin-receptor cycle could be repeated after intermittent exposure to insulin. Continuous or intermittent exposure to the hormone gave a similar glycogenic response, contrary to the partial effect of a unique short (5-20 min) exposure. A relationship could be established between the repetitive character of the rapid insulin-receptor cycle and the maximal expression of the biological effect in cultured foetal hepatocytes.

Structure of the human villin gene.

We have isolated and characterized the complete human villin gene. The villin gene is located on chromosome 2q35-36 in humans and on chromosome 1 in mice. Villin belongs to a family of calcium-regulated actin-binding proteins that share structural and functional homologies. The villin gene is expressed mainly in cells that develop a brush border, such as mucosal cells of the small and large intestine and epithelial cells of the kidney proximal tubules. Villin gene expression is strictly regulated during adult life and embryonic development in the digestive and urogenital tracts and, thus, may be used as a marker of the digestive and renal cell lineages. The human villin gene has one copy per haploid genome, encompasses about 25 kilobases, and contains 19 exons. Analysis of the structural organization of this gene shows that the two mRNAs that encode villin in humans arise by alternative choice of one of the two polyadenylylation signals located within the last exon. The overall organization of the exons reflects the gene duplication event from which this family of actin-binding proteins originated.

Regulatory sequences on the human villin gene trigger the expression of a reporter gene in a differentiating HT29 intestinal cell line.

To develop a molecular tool for tissue-specific targeting of gene expression in immature and differentiated epithelial cells of the small and large intestinal mucosa, we have isolated the 2-kb 5'-flanking region of the human villin gene. This region contains numerous short sequences that are conserved among other tissue-specific promoters of genes expressed in differentiated enterocytes. This DNA fragment promotes the transcription and expression of the luciferase reporter gene in villin-positive intestinal, renal, and hepatoma cell lines but not in a villin-negative keratinocyte cell line. The pattern of expression corresponds that of the endogenous gene, indicating that this sequence can direct intestine-specific transcription. In the differentiating HT29 intestinal cell line, expression of the reporter gene is already detectable in undifferentiated cells, and dramatically increases when terminal differentiation is induced. Thus, as previously reported for the endogenous gene the isolated 5'-flanking region of the villin gene responds positively to conditions known to stimulate terminal differentiation of these cultured epithelial intestinal cells. The reported results indicate that this genomic fragment contains sufficient regulatory elements to recapitulate the expression pattern of the villin promoter during intestinal differentiation.

Antigen sampling across epithelial barriers and induction of mucosal immune responses.

Epithelial barriers on mucosal surfaces at different sites in the body differ dramatically in their cellular organization, and antigen sampling strategies at diverse mucosal sites are adapted accordingly. In stratified and pseudostratified epithelia, dendritic cells migrate to the outer limit of the epithelium, where they sample antigens for subsequent presentation in local or distant organized lymphoid tissues. In simple epithelia, specialized epithelial M cells (a phenotype that occurs only in the epithelium over organized lymphoid follicles) deliver samples of foreign material by transepithelial transport from the lumen to organized lymphoid tissues within the mucosa. Certain pathogens exploit the M cell transport process to cross the epithelial barrier and invade the mucosa. Here we review the features of M cells that determine antigen and pathogen adherence and transport into mucosal lymphoid tissues.

Reutilization of insulin receptor and hormonal response in cultured foetal hepatocytes: the effects of chloroquine and vinblastine.

The effects of chloroquine and vinblastine (10-100 microM) on insulin degradation and biological action were studied in cultured foetal rat hepatocytes. Insulin degradation, as measured by the release of trichloroacetic acid-soluble radioactivity from 125I-insulin into the medium, was strictly cell-associated, saturable with respect to insulin concentrations and linearly related to the amount of cell-associated hormone. The maximal rate of insulin degradation was 4,700 molecules/min per cell, and its KM about 5 nM. Thus, insulin receptors (30,000 sites/cell; half-life close to 13 hr) must be reutilized 450-fold before being degraded with an average time of reutilization inferior to 10 min. In the presence of 70 microM chloroquine or 100 microM vinblastine, insulin degradation was inhibited by 80% and the amount of cell-associated hormone enhanced 2-3-fold. Nearly total inhibition of insulin-stimulated glycogenesis was obtained with 70 microM chloroquine and 45 microM vinblastine. When hepatocytes were preincubated with chloroquine or vinblastine, insulin binding remained high for up to 4 hr, then progressively decreased thereafter. The addition of 10 nM native insulin during preincubation with the drugs resulted in an earlier and more pronounced decrease in insulin binding, whereas native insulin alone did not induce any change. Both the inhibition of insulin degradation and onset of receptor down-regulation suggest a drug-induced impairment in the receptor reutilization. This defect is correlated to a loss of the glycogenic effect of insulin in cultured foetal rat hepatocytes.

[Expression of the glycogenic response to insulin in cultured fetal hepatocytes]. / Expression de la réponse glycogénique à l'insuline dans les hépatocytes foetaux en culture.

In the present study, we used primary cultures of fetal rat hepatocytes which are highly suitable for studying the glycogenic effect of insulin and its regulation. After a lag in the period of culture in the presence of cortisol, glycogenic response to insulin developed together with a progressive accumulation of glycogen. When insulin was added, the rate of glycogen synthesis increased, becoming maximal after 2-3 h, due to the activation of the glycogen synthase system already present. Modification of glycogen precursors in the medium did not alter the amplitude of the insulin effect. The glycogenic effect of insulin was unrelated to that of glucose load and occurred after the formation of glucose-1-phosphate. This only happened when the cyclic AMP-dependent glycogenolytic system was not stimulated, since it was suppressed by low doses of glucagon. Insulin effect, which was time-dependent, ceased after 4 h. This corresponded to a desensitization of hepatocytes without any alteration in the specific binding of insulin. These variations in the glycogenic effect of insulin were likely due to different causes; one of these could be the first events following the interaction of insulin with its receptor.

From the structure to the function of villin, an actin-binding protein of the brush border.

Villin, a calcium-regulated actin-binding protein, modulates the structure and assembly of actin filaments in vitro. It is organized into three domains, the first two of which are homologous. Villin is mainly produced in epithelial cells that develop a brush border and which are responsible for nutrient uptake. Expression of the villin structural gene is precisely regulated during mouse embryogenesis and is restricted in adults, to certain epithelia of the gastrointestinal and urogenital tracts. The function of villin has been assessed by transfecting CV1 cells with a human cDNA encoding wild-type villin or mutant villin. Synthesis of large amounts of villin in cells which do not normally produce this protein induces the growth of microvilli on the cell surface and the redistribution of F-actin, concomitant with the disappearance of stress fibers. The complete villin sequence is required for the morphogenic effect. These results suggest that villin plays a key role in the morphogenesis of microvilli.

Translocation of ribosomal immunostimulant through an in vitro-reconstituted digestive barrier containing M-like cells.

Ribosomal preparations of pathogenic micro-organisms of the upper respiratory tract can be delivered orally for the prevention of recurrent infectious episodes, because they induce mucosal and protective immune responses. The mechanism of mucosal barrier translocation is difficult to study in animal models, little is therefore known about this process. In order to circumvent these problems, we have examined the uptake of ribosomal preparations in three experimental systems that model human intestinal cells. We found that M-like cells displayed a 8.7-fold increase in the uptake of a ribosomal immunostimulant when compared to absorptive or crypt enterocyte-like cells. The product was taken up, translocated, and delivered in the basolateral compartment by cultured M-like cells. No translocation was observed across monolayers of T84 cells (model of crypt cells). Only minimal translocation occured through monolayers of Caco-2 cells (model of absorptive enterocytes). This suggests that, in vivo, colyophilisat is delivered mainly through the M cells overlying lymphoid follicles (Peyer's patches) or nodules of the gut-associated mucosal lymphoid tissue, which are the major inductor sites of mucosal responses. Use of the M-like cell cultured model could be a key step for the development of even more efficient immunostimulators in animals and human.

Cytosolic distribution of villin in M cells from mouse Peyer's patches correlates with the absence of a brush border.

BACKGROUND & AIMS: The follicle-associated epithelium (FAE) of Peyer's patches mainly consists of two cell types: absorptive enterocytes with a brush border and M cells without this apical specialization. To study the controversial ontogeny of M cells (mesenchymal vs. epithelial origin), the expression pattern of tissue-specific cytoskeletal proteins, markers of cell origin that play a crucial role in the specific shape of epithelial cells and brush border assembly, was investigated. METHODS: The localization of cytokeratins, vimentin, and villin was determined on mouse FAE using immunocytochemistry and electron microscopy. RESULTS: Epithelial-specific cytokeratins were expressed in both absorptive enterocytes and M cells, whereas vimentin was not detected in mouse FAE. Villin, a tissue-specific, actin-binding protein of the brush border, was expressed in the two cell types. This protein had an unusual cytoplasmic distribution in FAE cells lacking a brush border and in cells having an intraepithelial pocket filled with lymphocytes. CONCLUSIONS: The presence of villin and the absence of vimentin in M cells support the intestinal origin of M cells. The cytoplasmic distribution of villin provides a new identification criteria for M cells and reflects the reorganization of the F-actin network, which correlates with the inability of M cells to assemble a brush border.

A human villin cDNA clone to investigate the differentiation of intestinal and kidney cells in vivo and in culture.

Villin, a Ca2+-regulated actin-binding protein is a major component of microvilli of intestinal epithelial cells and kidney proximal tubule cells. Villin expression during assembly of the brush border can be investigated using a human colon adenocarcinoma cell line HT29-18. This cell line is able to differentiate under nutritional control and develops an enterocyte-like phenotype. A cDNA library from a subclone HT29-18-C1 was constructed in an expression vector and a cDNA specific for human villin was isolated. This cDNA codes for the 110 carboxy-terminal residues of villin. Within that region, the 76 carboxy-terminal residues present 65% homology with the chicken villin 'head piece'. We show that two mRNA species 4.0 kb and 3.2 kb long hybridize with this cDNA probe in humans, whereas in rat and chicken only one mRNA species can be detected. The two villin mRNA species are co-expressed in normal human small and large intestinal mucosa and tumoral HT29-18 cells as well as in normal kidney. No villin mRNAs were detected in other normal or malignant epithelial cell types. Finally, we observed an accumulation of the two mRNA species coding for villin when HT29-18 cells become differentiated, suggesting that control of villin expression during terminal differentiation can occur at the transcription level or by RNA stabilization.

Suppression of villin expression by antisense RNA impairs brush border assembly in polarized epithelial intestinal cells.

We have used an antisense RNA strategy to investigate the role of the actin-associated protein, villin, in the brush-border morphogenesis of human intestinal CaCO2 cells. Stable expression of a cDNA encoding antisense villin RNA resulted in the permanent down-regulation of the endogenous villin message and dramatically affected brush-border assembly. Ultrastructural and immunolocalization studies revealed that epithelial cell polarity was largely maintained. However, in contrast to brush-border markers such as dipeptidyl-peptidase IV, the apical localization of sucrase-isomaltase was specifically impaired. Retransfection of the villin antisense-expressing cell line with a cDNA encoding a partial sense villin RNA restored both brush-border assembly and sucrase-isomaltase apical expression. The suggestion that brush-border morphogenesis may be important for the trafficking of certain proteins is discussed.