Adhesive properties and integrin expression profiles of two colonic cancer populations differing by their spreading on laminin.

The mostly undifferentiated parental HT29 (HT29p) human colonic adenocarcinoma cell line and a differentiated subpopulation selected by the anti-cancer drug 5-fluorouracil (HT29-Fu) (Lesuffleur et al. (1991) Int. J. Cancer 49, 721-730) display strikingly different behavior when grown on laminin coatings: the former grows as aggregates while the latter grows as monolayers. In an attempt to explain this difference, we performed a comparative study of cell adhesion properties and of expression, involvement and localization of the alpha 6, beta 1 and beta 4 subunits constituting the integrin family among the two cell populations. HT29p and HT29-Fu cells exhibited a similar adhesion pattern to laminin and laminin fragments E8 and P1. In both cell lines, cell adhesion could be blocked at about 90% with anti-alpha 6 subunit antibodies and around 30-50% with anti-beta 1 antibodies; no inhibition of the cell adhesion was obvious when using anti-beta 4 antibodies. Immunoprecipitations of iodinated membrane-solubilized proteins and immunoblotting experiments showed that all alpha 6 chains expressed in both HT29p and HT29-Fu cell populations exist as alpha 6 beta 4 integrins; beta 1 subunits are associated with alpha 2 and alpha 3 chains. When HT29p or HT29-Fu cells were injected subcutaneously in nude mice, a similar expression pattern of alpha 6, beta 4 and beta 1 integrin subunits was noticeable in the resulting tumors: alpha 6 and beta 4 subunits were localized at the basal surface of the tumor cells facing the stromal elements, and to a lesser extent at the cell-cell contacts within the tumor-cell clumps; beta 1 subunits were mainly found within the cytoplasm of the tumor cells. Despite these overall similarities among the two cell lines, the following changes could account for their different behavior on laminin: less proteolytic processing of the beta 4 integrin subunit occurred in HT29-Fu cells yielding peptidic fragments of 175 kDa, which are absent from the parental cells; the immunostaining pattern of the various subunits demonstrated a segregation of alpha 6, beta 4 and beta 1 integrin subunits on the basal side of the HT29-Fu cells when cultured on laminin to the detriment of their lateral location, a phenomenon that was not obvious in the parental cells. Altogether, these results suggest that the distinct behavior of the undifferentiated versus differentiated HT29 cell populations on laminin is not related to altered adhesion properties of the cells but rather to a deficient stabilization of the adhesion leading to cell spreading.(ABSTRACT TRUNCATED AT 400 WORDS)

Dual and asynchronous deposition of laminin chains at the epithelial-mesenchymal interface in the gut.

The production of laminin by 14-day fetal rat intestinal endoderm and mesenchyme was investigated. The amount of neosynthesized laminin was measured after purification using affinity chromatography. Chain composition of laminin was analyzed by immunoblotting and immunofluorescence staining. The data show that both embryonic intestinal tissue components synthesize laminin and that A and B1/B2 chains were detected in both endodermal and mesenchymal cells. The cellular source of laminin found at the epithelial basement membrane has been studied by immunocytochemistry in rat/chick or mouse/chick interspecies hybrid intestines taken at various stages of development. Immunodetection of the whole laminin molecule and of the individual A and B1/B2 chains by rodent-specific polyclonal and monoclonal antibodies at the basement membrane level in these hybrid intestines revealed (a) laminin molecules, which originate from both mesenchymal and endodermal cells; (b) deposition of A and B1/B2 chains by endodermal cells, regardless of the stage of growth of the hybrid intestines; and (c) asynchronous deposition of the various chains of laminin into the basement membrane by the mesenchyme. B1/B2 chains are deposited concomitant with contact with the epithelium, whereas A chains appear only later (13 days after grafting). These data reinforce the suggestion from previous studies that cooperation between epithelium and mesenchyme is necessary for the formation of a complete basement membrane in the developing intestine.

Changes in the expression of laminin during intestinal development.

The expression of laminin, a major glycoprotein constituent of basement membranes, was investigated in the rat developing intestine. The biosynthesis of laminin was studied after metabolic labeling of intestinal segments taken at various stages of development; the neosynthesized laminin was purified by affinity chromatography on heparin-Sepharose. Immunoblotting and immunoprecipitation experiments allowed us to analyze its constitutive chains. The data show that laminin is synthesized in very large amounts at 16-18 days of gestation concomitant with the onset of intestinal morphogenetic movements, i.e. villus emergence. Evaluation of the relative proportion of individual laminin polypeptides shows that laminin B1/B2 chains are produced in excess of A chains whatever the developmental stage considered. Interestingly at 17 days of gestation, levels of laminin A subunits are maximal. A second rise in the A/B chain ratio starts around birth and continues until adulthood. These quantitative data are corroborated by the immunocytochemical detection of laminin A and B chains, which revealed a specific spatiotemporal pattern. The finding that laminin A chains are located in the basement membrane of growing villi and of adult crypts raises the possibility that they may be involved in the process of cell growth and/or in the establishment of cell polarity by creating a specialized extracellular microenvironment.

Altered deposition of basement-membrane molecules in co-cultures of colonic cancer cells and fibroblasts.

Two human colon carcinoma cell lines, HT29 and Caco-2 were co-cultured with fetal rat or human skin fibroblasts. Their morphological features, ultra-structural characteristics at the heterologous cell interface, and the deposition of basement-membrane molecules [laminin, type-IV collagen, heparan sulfate proteoglycan (HSPG)] at the epithelial-stromal junction were analyzed. The 2 cell lines behaved differently. HT29 cells did not spread on the fibroblasts and grew as clusters, while Caco-2 cells formed a monolayer over the fibroblastic feeder layer. Only the latter carcinoma cells exhibited cytoplasmic processes towards the fibroblasts and, after 5 days in co-cultures, a structured basement membrane (BM). The immunocytochemical analysis of the BM constituents revealed the absence of the molecules studied at the sites of heterologous contacts in the case of HT29 cells. In contrast, in the co-cultures comprising Caco-2 cells, laminin and type-IV collagen were progressively deposited in a polar fashion at the epithelial-fibroblastic interface which, however, remained devoid of HSPG molecules. Together with earlier data indicating a dual origin of the BM molecules located at the epithelial-fibroblastic interface in normal intestine, the present study shows that the cancer cells as well as the fibroblastic ones under the influence of carcinoma cells display an altered capacity to synthesize and/or secrete BM molecules. The extent of such abnormalities correlates with the differentiation of the cells. Finally, these modifications occur concomitantly with alterations in cell interactions which vary among cell lines.

Changes in glycosaminoglycan expression in the rat developing intestine.

Synthesis of glycosaminoglycan (GAG) chains was studied in the developing rat intestine. Intestinal segments, taken at various developmental stages, were exposed to 3H-glucosamine and 35S-sulfate for 6 hours. The amounts of 3H-GAGs (total GAGs) and of 35S-GAGs (sulfated GAGs) showed a clear age-dependence, with a broad maximum in the fetal period when dramatic growth and morphogenesis occur. Characterization of individual GAG species indicated that hyaluronic acid (HA), heparan and chondroitin sulfate (HS and CS) synthesis was modified quantitatively or qualitatively during development: decrease of HA with age; production of undersulfated HS molecules during embryonic life; shift towards a lower hydrodynamic form of HA and HS molecules after birth. We postulate that these alterations are crucial in the elaboration of an age-related specific extracellular microenvironment allowing intestinal growth and differentiation.

Changes in glycosaminoglycan synthesis and in heparan sulfate deposition in human colorectal adenocarcinomas.

Biosynthesis of glycosaminoglycans (GAGs) was studied in morphologically normal colonic mucosa, in peritumoral and tumoral areas, and in colorectal polyps of tumor-bearing patients. After GAG purification, overall biosynthesis was determined: the general trend was a decrease in GAG production in neoplastic colon, lowest GAG synthesis being observed in Dukes' stage C tumors. Separation by ion-exchange chromatography of various GAG species and further characterization revealed the presence of hyaluronic acid (HA) and heparan sulfate (HS) molecules in all specimens studied. Chondroitin-4 sulfate (CS4) was occasionally found in tumor samples. The relative proportion of HA and HS was modified in tumor tissue: i.e. increased HA and decreased HS were observed. Differences in DEAE-chromatographic behavior were obvious in pathological samples as compared to controls, the hydrodynamic form of HA and the charge density of HS being decreased. The latter could be attributed to undersulfatation of HS molecules. Immunocytochemical detection of HS proteoglycan molecules revealed regular and bright labelling at epithelial-stromal interface in control samples. In pathological samples, staining was patchy and discontinuous, showing large areas of basement membrane interruption.

Smooth muscle actin expression during rat gut development and induction in fetal skin fibroblastic cells associated with intestinal embryonic epithelium.

Cytodifferentiation of smooth muscle cells has been analyzed immunocytochemically during rat intestinal development and in chimaeric intestines by using monoclonal antibodies reacting specifically with smooth muscle actin species (CGA7 [10] and anti-alpha SM-1 [40]). As development proceeds, the various intestinal muscle layers differentiate in the following order: (1) cells expressing smooth muscle actin appear within the mesenchyme of the 15-day fetal rat intestine, in the circular muscle-forming area, the differentiation of cells in the presumptive longitudinal muscle layer starting with a 48-h delay; (2) smooth muscle fibers appear within the connective tissue core of the villi shortly after birth, in parallel with a progressive formation of the muscularis mucosae, which becomes clear-cut only in the course of the 2nd week after birth; (3) a distinct cell layer in the innermost part of the circular muscle layer arises during the perinatal period. Thereafter, the fluorescence pattern remains unchanged until the adult stage. Chimaeric intestines were constructed by the association of 14-day fetal intestinal epithelium and cultured fetal rat or human skin fibroblasts. These fibroblastic cells did not express actin at the time at which they were associated. The immunocytochemical analysis of smooth muscle actin in the hybrid intestines, which had developed as intracoelomic grafts for 12 days, revealed that the skin fibroblastic cells had been induced by the intestinal epithelial cells to differentiate into smooth muscle cells. Such a result was also obtained with allantoic endoderm. It was not obvious in cocultures of intestinal epithelium with skin fibroblastic cells. However, when intestinal epithelial cells were cocultured with intestinal mesenchymal cells, actin expression was stimulated in the latter cell population.

Development of the vertebrate small intestine and mechanisms of cell differentiation.

The intestinal epithelium represents an attractive biological model of differentiation from stem cells to highly differentiated epithelial cells, not only during particular developmental events depending upon the vertebrate species considered but also throughout adult life. The ontogenic maturation of the intestinal epithelium arises from both a programmed expression of specific genes and epigenetic influences mainly due to epithelial and mesenchymal interactions and hormonal participation. In the present paper we review the structural and functional changes that occur in the amphibian, avian and mammalian intestine during embryonic and/or post-embryonic development. Furthermore, we review the data concerning the mechanisms which control the cytodifferentiation of the intestinal epithelium.

Type IV collagen mRNA accumulates in the mesenchymal compartment at early stages of murine developing intestine.

The expression of type IV collagen mRNA during mouse intestinal morphogenesis was examined by in situ hybridization using a cDNA probe corresponding to mRNA for alpha 1 (IV) chain. Type IV collagen mRNA is detected in the embryonic mesenchymal cells at early stages of development (12 d of gestation). A segregation of mesenchymal cells expressing high levels of type IV collagen mRNA in close vicinity of the epithelium occurs just before villus formation. During villus outgrowth, type IV collagen mRNA, still confined to mesenchyme-derived tissues, is progressively restricted to the mucosal connective tissue (the lamina propria) and to a lesser extent to the muscular layers. In the adult, the amount of messenger is quite low as compared to the level found in the developing intestine and the in situ hybridization signal, indistinguishable from the background, is uniform throughout the whole intestinal wall. At all developmental stages no detectable specific hybridization signal is virtually observed over the epithelium cell layer. These results show that high amounts of the type IV collagen messenger are detected during phases of intensive morphogenetic events. Furthermore, they reinforce the notion already gained previously (Simon-Assmann et al. 1988) that the mesenchymal compartment is the principal endogenous source of type IV collagen. They also indicate that the continuous migration of epithelial cells along the basement membrane of intestinal villi in the mature organ is not accompanied by a significant remodeling of the collagen IV network.

Synthesis of basement membrane proteins in the small intestine.

Are the basement membrane (BM) molecules involved in epithelial-mesenchymal cell interactions known to be instrumental in intestinal development and differentiation? Several findings argue in favor of this assumption. First, quantitative and/or qualitative changes in type IV collagen, laminin-nidogen and heparan sulfate proteoglycan (HSPG) are obvious at the phases of intensive morphogenesis. Second, BM molecules deposited at the epithelial-mesenchymal interface are of dual origin: HSPG being produced by the epithelial cell population, while others like type IV collagen and laminin are mainly produced by the mesenchymal compartment. Third, the formation of the BM requires an actual contact between the epithelial and mesenchymal cells and always precedes the expression of differentiation markers in the epithelial cells. These data suggest that BM molecules display an instructive role in intestinal cell interactions.

Origin and deposition of basement membrane heparan sulfate proteoglycan in the developing intestine.

The deposition of intestinal heparan sulfate proteoglycan (HSPG) at the epithelial-mesenchymal interface and its cellular source have been studied by immunocytochemistry at various developmental stages and in rat/chick interspecies hybrid intestines. Polyclonal heparan sulfate antibodies were produced by immunizing rabbits with HSPG purified from the Engelbreth-Holm-Swarm mouse tumor; these antibodies stained rat intestinal basement membranes. A monoclonal antibody (mAb 4C1) produced against lens capsule of 11-d-old chick embryo reacted with embryonic or adult chick basement membranes, but did not stain that of rat tissues. Immunoprecipitation experiments indicated that mAb 4C1 recognized the chicken basement membrane HSPG. Immunofluorescent staining with these antibodies allowed us to demonstrate that distribution of HSPG at the epithelial-mesenchymal interface varied with the stages of intestinal development, suggesting that remodeling of this proteoglycan is essential for regulating cell behavior during morphogenesis. The immunofluorescence pattern obtained with the two species-specific HSPG antibodies in rat/chick epithelial/mesenchymal hybrid intestines developed as grafts (into the coelomic cavity of chick embryos or under the kidney capsule of adult mice) led to the conclusion that HSPG molecules located in the basement membrane of the developing intestine were produced exclusively by the epithelial cells. These data emphasize the notion already gained from previous studies, in which type IV collagen has been shown to be produced by mesenchymal cells (Simon-Assmann, P., F. Bouziges, C. Arnold, K. Haffen, and M. Kedinger. 1988. Development (Camb.). 102:339-347), that epithelial-mesenchymal interactions play an important role in the formation of a complete basement membrane.

Glycosaminoglycan expression in intestinal epithelial skin-fibroblastic cell cocultures. Fibroblastic cell-mediated effects of glucocorticoids.

The nature and distribution of newly synthesized glycosaminoglycans (GAGs) were studied in foetal rat skin fibroblasts, in rat intestinal endodermal cells and in cocultures of both cell types. The data show that fibroblasts synthesize and secrete hyaluronic acid (HA), heparan sulphate (HS) and chondroitin sulphate molecules (CS). Our data focus on HA, which is found as two different molecular forms, the smallest hydrodynamic-sized species being mostly recovered within the cell or associated with the cell surface, and the largest one secreted into the medium, whatever the cell type. Endodermal cells synthesize only two types of GAGs: the low molecular weight form of HA and HS. Cocultures of rat intestinal endodermal and skin fibroblastic cells in the presence of dexamethasone (Dx), allow optimal epithelial cytodifferentiation (Kedinger et al. 1987a). The main changes in the GAGs synthesized under these conditions as compared to skin fibroblastic cell cultures concern: (1) the enhancement of the lowest molecular weight form of HA to the detriment of the highest form in the cellular, pericellular and extracellular compartments; (2) the increase in the proportion of HS molecules associated with the cell surface. Interestingly, similar modifications are obtained by addition of Dx to the skin fibroblastic cell cultures. The data are discussed with reference to the constitution of a basement membrane at the epithelial-fibroblast interface in the cocultures, to the fibroblastic-dependent induction of epithelial differentiation and to the glucocorticoid response.

Epithelial-mesenchymal interactions in the production of basement membrane components in the gut.

The production and deposition of extracellular matrix proteins and the cellular origin of type-IV collagen have been analysed immunocytochemically in cocultured or transplanted intestinal epithelial-mesenchymal cell associations. In the first experimental model, rat intestinal endodermal cells were cultured on top of confluent mono-layers of rat intestinal or skin fibroblastic cells. Under these conditions, interstitial matrix and basement membrane proteins were deposited within the fibroblastic layer over the whole culture period; interactions between the epithelial cells and the fibroblastic cell population, whatever their organ of origin, were required for the production of the basement membrane. In addition, its formation was progressive as assessed by the shift of a spot-like labelling to a continuous linear pattern at the epithelial-mesenchymal interface, and paralleled epithelial cell differentiation. In the second experimental model, chick-rat epithelial-mesenchymal recombinants developed as intracoelomic grafts were used, and the immunocytochemical detection of a basement membrane protein, type-IV collagen, was performed with species-specific antibodies. The major role of the mesenchyme in the deposition of type-IV collagen is supported by the fact that anti-chick but not anti-mammalian antibodies stained this antigen in chick mesenchyme-rat endoderm recombinants. These observations emphasize the role of tissue interactions in the formation of a basement membrane and show that the mesenchymal compartment is the principal endogenous source of type-IV collagen.

Epithelial-mesenchymal interactions in intestinal epithelial differentiation.

The complex morphogenetic events and the concomitant structural and functional differentiation of intestinal progenitor cells are dependent on tissue interactions. Several experimental models of hetero-species or -topic recombinants between epithelial and mesenchymal anlagen are described. They enabled us to elucidate the respective roles of these tissue components in morphogenesis, epithelial differentiation, and hormone-elicited responses. Among the mechanisms of tissue interactions, the possible mediation of permissive and instructive information via the extracellular matrix is postulated. Arguments in favor of this are provided by the observation of compositional changes in matrix molecules during intestinal development and differentiation. On the other hand, in vitro experimental data emphasize the role of actual contacts between epithelial and mesenchymal cell populations and the importance of the mesenchyme for basement membrane formation.

Synthesis of glycosaminoglycans by undifferentiated and differentiated HT29 human colonic cancer cells.

Among the extracellular matrix components which have been suggested to be involved in developmental and neoplastic changes are glycosaminoglycans (GAGs). To try to correlate their amount and nature with the process of enterocytic differentiation, we studied glycosaminoglycan synthesis of human colonic adenocarcinoma cells (HT29 cell line) by [3H]glucosamine and [35S]sulfate incorporation. Enterocytic differentiation of the cells obtained in a sugar-free medium (for review, see A. Zweibaum et al. In: Handbook of Physiology. Intestinal Transport of the Gastrointestinal System, in press, 1987) resulted in a marked increase in total incorporation of labeled precursors (20-fold for [3H]glucosamine, 4.5-fold for [35S]sulfate) as well as in uronic acid content (5-fold); most of the synthesized GAGs were found associated with the cell pellet. Chromatographic and electrophoretic analysis of the labeled GAGs revealed that undifferentiated cells synthesized and secreted hyaluronic acid, heparan sulfate, and one class of chondroitin sulfate. Differentiation of HT29 cells because associated with the synthesis of an additional class of chondroitin sulfate (CS4) concomitant to a decrease in heparan sulfate which is no longer found secreted in the medium. Furthermore, the charge density of this latter GAG component varied as assessed by a shift of its affinity on ion-exchange chromatography.