Long-term iodination of thyroglobulin by porcine thyroid cells cultured in porous-bottomed culture chambers: regulation by thyrotrophin.

Thyroid cells cultured as monolayers on the porous bottom of culture chambers have been shown to express some specific functions of thyroid follicles. This system, which allows independent access to apical and basal media, is suitable for the long-term study of polarized processes, as the cells maintain their polarized organization. Iodination of thyroglobulin has been investigated under different culture conditions in the presence or absence of TSH. Apical thyroglobulin accumulation, apical iodide concentration and thyroglobulin iodination have been followed simultaneously. Iodide (0.5 mumol/l) was added to basal medium at various stages: only once for 4-day incubations and at each medium change or daily for longer experiments. TSH increased the amount of thyroglobulin secreted into the apical medium by five- to sixfold, whereas high basal iodide concentrations (greater than 5 mumol/l) inhibited thyroglobulin secretion by TSH-stimulated cells. TSH increased iodide uptake giving an iodide concentration ratio between apical and basal media of about 5. Thyroglobulin iodination was dependent upon TSH. Thyroglobulin was iodinated only in the apical compartment. Secretion and iodination of thyroglobulin were polarized phenomena, but the polarity of iodination was total whereas the polarity of secretion was only partial (10% basal secretion). This functional asymmetry was maintained for up to 29 days. The maximal incorporation of iodine into thyroglobulin obtained was never higher than 3.5 atoms/mol. Apical iodide concentrations from 1 to 15 mumol/l, depending on culture conditions, did not increase this value. These results suggest that cells cultured in this culture system are able to reproduce several steps of thyroidal iodide metabolism although there may be unknown factors which could interfere and reduce the efficiency of thyroglobulin iodination.

Absence of fodrin (spectrin-like protein) under the pseudopod membrane in stimulated thyroid cells.

A fodrin-like protein purified from porcine thyroid cells and characterized by its properties identical to those of pig brain spectrin (F. Regnouf et al., Eur. J. Biochem. 153, 313-319 (1985)) has been localized by immunofluorescence and electron immunocytochemistry in porcine and rat thyroid. Fodrin-like polypeptides were detected in subplasmalemmal meshworks of microfilaments attached to isolated or in situ plasma membranes. In resting cells, fodrin was found under apical and basolateral membrane domains, whereas it was always absent under the pseudopod membrane domain induced by acute TSH stimulation in vitro, using monolayers of porcine cultured cells attached to collagen permeable substrates, as well as in vivo, using rats intravenously treated with TSH. Thyroid fodrin could be involved in exocytosis and membrane stabilization which occurs during the formation of pseudopods induced by TSH stimulation.

Thyrotrophin regulation of apical and basal exocytosis of thyroglobulin by porcine thyroid monolayers.

Exocytosis, the ultimate step in thyroglobulin secretion, has been studied in porcine thyroid cells cultured in monolayers on the permeable bottom of culture chambers. We have previously demonstrated, using this culture system, that apical secretion accounts for 85-95% of total secretion of newly synthesized thyroglobulin. When cells were cultured for several days with bovine TSH (25 microU/ml) in the basal medium, the rate of glycoprotein accumulation in the upper compartment was three times higher than that in the absence of TSH. In contrast, the rate of thyroglobulin released into the basal medium (5-15% of total secreted thyroglobulin) appeared unmodified by chronic TSH stimulation. To investigate the effect of acute TSH stimulation on thyroglobulin exocytosis in the apical and basal compartments, pulse-chase experiments were carried out with the same culture system. The release of radiolabelled thyroglobulin (1.5-h pulse) into the apical medium was increased threefold during the 2-h chase period under TSH stimulation. The radiolabelled thyroglobulin released into the basal medium was increased only 1.5- to 2-fold, and stimulation disappeared after 1 h. The effect of TSH was maximal when the chase medium contained 50 microU TSH/ml. However, cells cultured for several days in the presence of 25 microU TSH/ml before the pulse-chase experiment, appeared desensitized to acute TSH stimulation. Similar responses were observed when the chase medium contained 8-chloro-cyclic AMP or cholera toxin. This study provides another example of the pleiotropic effect of TSH, mediated by cyclic AMP, on the sequential steps of thyroglobulin gene expression in cultured thyroid cells in which the polar character of the epithelial cells is well preserved.

Polarity reversal of inside-out thyroid follicles cultured within collagen gel: structure of the junctions assessed by freeze-fracture and lanthanum permeability.

The organization of tight junctional complexes (TJs) was studied in cultured porcine thyroid cells during the inversion of polarity induced by collagen-embedding of inside-out follicles, using freeze-fracture replicas and lanthanum penetration. During the early steps of polarity reversal, freeze-fractures showed that TJs generally persisted. They increased in width and progressively branched out into the basolateral surfaces, towards the basal pole. Later, the number of TJ strands decreased and gap junctions inserted within TJ networks were found between cells in reversed follicles, in the same manner as in typically polarized follicles, embedded in collagen or in suspension. The de novo formation of TJ complexes was rarely found in the reversing structures. Despite the heterogeneity of TJs assessed by freeze-fracture, impermeability to lanthanum tracer was noted in inside-out structures. During the reversal process, some TJs remained unstained, whereas others displayed permeability to lanthanum. This heterogeneity might be due to the "opening" of a small number of junctions (perhaps only one by aggregate). When the process was achieved after 48 hr in collagen, the tightness of the junctions was complete, confirmed by the absence of lanthanum in luminal cavities of newly formed follicles.

Cholesterol-rich microdomains in rat and porcine thyroid membranes involved in TSH-induced endocytotic processes.

Filipin, a polyene antibiotic, was used to detect cholesterol in thyroid membranes in vivo and in culture during TSH stimulation. We found that apical and basolateral plasma membranes were heterogeneously modified by filipin which induced abundant lesions in apical membranes, whereas Golgi apparatus, endoplasmic reticulum, nuclear membranes were unmodified. Small apical vesicles and colloid droplets were generally highly enriched in these complexes, suggesting a high cholesterol concentration in their membranes. Pseudopod membranes, known to be highly specialized domains in the apical plasma membrane, appeared enriched in cholesterol. Consequently, we suggest that an increased cholesterol content may be involved in the stabilization of thyroid membranes during endocytotic processes.

Thyrotrophin and cyclic AMP regulation of thyroglobulin gene expression in cultured porcine thyroid cells.

The effects of thyrotrophin, cholera toxin and 8-chloro-cyclic AMP on thyroglobulin gene expression in cultured porcine thyroid cells were compared. Cells organized either into monolayers in culture chambers with porous bases or into inside-out follicles in suspension were used. Thyroglobulin mRNA content was measured by dot-blot hybridization, and thyroglobulin synthesis rate was determined by immunoprecipitation of [35S]thyroglobulin after 2 h labelling with [35S]methionine. Cholera toxin and 8-chloro-cyclic AMP increased the thyroglobulin mRNA content and thyroglobulin synthesis rate in the same ratio (approximately 3) as did thyrotrophin, showing that cyclic AMP mediates the effect of thyrotrophin on thyroglobulin gene expression. The culture chamber system provides for contact of the effectors with either the apical or the basolateral membrane. The addition of 0.02-0.1 mU thyrotrophin/ml on the basolateral side of the cell layer gave a maximal response whereas this response was not reached on the apical side even with the addition of 5 mU/ml. In contrast, cholera toxin and 8-chloro-cyclic AMP stimulated thyroid cells equally on both sides.

Synthesis and apical and basolateral secretion of thyroglobulin by thyroid cell monolayers on permeable substrate: modulation by thyrotropin.

In the thyroid glands, thyroglobulin (Tg) is specifically synthesized by follicular cells and then secreted into the apical lumen where it is concentrated and used as a substrate for thyroid hormone synthesis. The presence of Tg in the circulation has been reported in normal and pathological situations. To determine the domains of the plasma membrane, apical and/or basolateral, involved in Tg secretion, porcine thyroid epithelial cells were cultured as a monolayer on the porous bottom of a culture chamber in which both apical and basal media are independently accessible. Control experiments using labeled Tg ascertained the tightness of the monolayer and showed that within 48 h only 0.2-0.5% of the Tg introduced in the apical medium was transferred through the cell layer into the basal compartment. For kinetic studies of Tg synthesis and secretion, monolayers were cultured for up to 72 h in the presence of 35S-methionine and with or without 100 microU/ml thyrotropin (TSH) in the basal medium. Labeled Tg was measured by double immunoprecipitation and by fluorography of polyacrylamide gel electrophoresis. We showed that 80-95% of total secreted Tg was recovered in the apical medium. The remainder was secreted through the basolateral membranes in the basal medium. The amount of tg secreted into the apical compartment was stimulated two- to threefold by TSH whereas no TSH effect was observed on secretion in the basal compartment. Moreover, measuring apical and basal volumes, we observed a net water flow from the apical to the basal side. It was stimulated threefold by TSH, increasing the Tg concentration in the apical compartment of the stimulated cell layer. During the culture time, the amount of Tg synthesized and secreted was increased by TSH, as was the Tg mRNA content, as determined by the dot-blot hybridization method.

Polarized properties of thyroid cells: a study with cultured porcine cells.

In primary culture porcine cells form polarized cell layers. We have designed culture conditions in which we can have access to only one side of the cell layer, either the apical or the basal surface. In addition, using culture chambers with permeable bottom we can have access to either side of the cell layer which separates two compartments. Using these organized systems we have shown that the iodide concentrating mechanism and the TSH-receptor adenyl cyclase complex are localized on the basolateral domain of the thyroid cell plasma membrane. We also demonstrated the existence on the apical surface of an amiloride sensitive sodium uptake. Finally we observed that about 10% of newly synthesized thyroglobulin appears to be secreted directly into the basal compartment, 90% being secreted in the apical compartment.

Epithelial cell polarization in culture: orientation of cell polarity and expression of specific functions, studied with cultured thyroid cells.

Isolated porcine thyroid cells reorganize in culture into various types of multicellular structure, which differ in the orientation of cell polarity and in the surface of the cell layer accessible to molecules present in the culture medium. The types of structure are: (1) follicles: the basal pole is oriented toward the medium; (2) inside-out follicles or monolayers: the apical pole is facing the culture medium; (3) monolayers on a permeable substratum: both sides of the cell layer are accessible to the medium. Follicles can be transformed into inside-out follicles or monolayers and vice versa by manipulation of the external cell environment and without dissociating the cells. Cells concentrate iodide and respond to acute stimulation by thyroid-stimulating hormone (TSH) when the basal pole is accessible, and organification occurs only when cells form a closed follicular lumen. In porous-bottomed culture chambers monolayers are formed with the basal surface accessible to the medium and the apical compartment separated from the medium. Under these conditions 85-95% of the thyroglobulin produced is secreted apically and 5-15% basally. Thyrotropin stimulates (X3) apical accumulation without modifying secretion in the basal compartment. Sodium transport across the cell layer has been characterized. An amiloride-sensitive influx occurs at the apical pole whereas the Na+/K+-ATPase, localized in the basolateral membrane, mediates ouabain-sensitive efflux at the basal pole. The thyroid epithelium in culture appears therefore as a Na+-absorbing epithelium. The role of this transport in the stabilization of cell polarity is discussed.

Polarity reversal of inside-out thyroid follicles cultured within collagen gel: an ultrastructural study.

Inside-out porcine thyroid follicles in culture undergo polarity reversal after being embedded in collagen gel. The newly-formed follicles reexpress some specific thyroid functions lost in inside-out follicles (Chambard et al., 1984. We present here an ultrastructural study of the inversion of polarity in this model system. This process takes place within 24 to 48 hr, without any opening of the original tight junctions, as shown by fixation in the presence of ruthenium red. A general shrinkage of cellular aggregates was noted soon after embedding. At the apical pole, three different modifications were observed: structural changes appeared in the kinocilium, microvilli and underlying cytoskeleton as early as 10 min after embedding, mainly when the apical pole of the cells was in close contact with the collagen fibers; large cytoplasmic lamellipod- or pseudopod-like extensions, covering the adjacent apical domain, protruded from outer apical regions; some other apical areas invaginated and formed channels inside the aggregates. The last two processes prevented close contact between apical cell surfaces and collagen fibers and allowed a persistence of the initial polarity in some of the cells. Newly-formed lumens were closed 24 hr after embedding in gel and the outer surface of the cellular aggregates in close contact with collagen fibers looked like a basal membrane. These mechanisms proceeded at different rates and involved different numbers of cells, but they all appeared to be related to the transformation of inside-out follicles into follicular structures.

Polarity reversal of inside-out thyroid follicles cultured within collagen gel: reexpression of specific functions.

Isolated porcine thyroid cells cultured in suspension in Eagle Minimum Essential Medium supplemented with calf serum (5-20%) reorganize to form vesicles, i.e. closed structures in which all cells have an inverted polarity as compared to that found in follicles: the apical membranes are bathed by the culture medium. Under these conditions, cells neither concentrate iodide nor respond to acute thyrotropin (TSH) stimulation. When embedded in collagen gel, these vesicles undergo polarity reversal to form follicles. We describe here the change in the orientation of cell polarity and the subsequent reappearance of specific thyroid functions. Six hr after embedding, membrane areas in contact with collagen fibers show basal characteristics. At this time, cells begin to concentrate iodide and to respond to acute TSH stimulation (iodide efflux and increased cAMP levels). Most cells form follicles 24 hr after embedding, but 48 hr are required for the transformation of all vesicles into follicles. This occurs without opening of the tight junctions. Iodide organification is detected 24 hr after embedding, when periodic acid-Schiff positive material, identified as thyroglobulin by immunofluorescence, accumulates in the lumen. Iodide concentration and organification, as well as response to TSH stimulation reach maximal levels after 3 days in the collagen matrix. After a 5-day culture in the collagen matrix in the absence of TSH, cell activity can be stimulated by chronic treatment with low hormone concentrations (10-100 microU/ml). As shown with thyroid cells grown in monolayer on permeable substrates (Chambard M., et al., 1983, J. Cell Biol. 96, 1172-1177), iodide uptake and cAMP-mediated TSH responses are expressed when the halogen and the hormone have direct access to the basal membrane. Organification, on the contrary, requires a closed apical compartment.

Polarization of thyroid cells in culture: evidence for the basolateral localization of the iodide "pump" and of the thyroid-stimulating hormone receptor-adenyl cyclase complex.

When cultured in collagen gel-coated dishes, thyroid cells organized into polarized monolayers. The basal poles of the cells were in contact with the collagen gel, whereas the apical surfaces were facing the culture medium. Under these culture conditions, thyroid cells do not concentrate iodide nor respond to acute stimulation by thyroid-stimulating hormone (TSH). To allow the free access of medium components to the basal poles, the gel was detached from the plastic dish and allowed to float in the culture medium. After release of the gel, the iodide concentration and acute response to TSH stimulation were restored. Increased cAMP levels, iodide efflux, and formation of apical pseudopods were observed. When the thyroid cells are cultured on collagen-coated Millipore filters glued to glass rings, the cell layer separates the medium in contact with the apical domain of the plasma membrane (inside the ring) from that bathing the basolateral domain (outside the ring). Iodide present in the basal medium was concentrated in the cells, whereas no transport was observed when iodide was added to the luminal side. Similarly, an acute effect of TSH was observed only when the hormone was added to the basal medium. These results show that the iodide concentration mechanism and the TSH receptor-adenylate cyclase complex are present only on the basolateral domain of thyroid cell plasma membranes.

[Collagen gel culture of human thyroid cancers]. / Culture en gel de collagène de cancers thyroïdiens humains.

When seeded on collagen gel surface, human thyroid cells from normal tissue or carcinoma form a monolayer. When the isolated cells are embedded inside the collagen gel, they reorganize into three-dimensional structures. The cells isolated from normal tissue, adenoma, or well-differentiated follicular carcinoma show the typical arrangement of follicular thyroid cells: the apical poles, characterized by microvilli, are oriented towards the follicular lumen; intercellular junctions are present. In contrast, in the papillary and moderately-differentiated follicular carcinomas, the cells are hardly ever associated, and ultrastructural nuclear anomalies are often observed.

Influence of collagen gel on the orientation of epithelial cell polarity: follicle formation from isolated thyroid cells and from preformed monolayers.

The influence of collagen gels on the orientation of the polarity of epithelial thyroid cells in culture was studied under four different conditions. (a) Isolated cells cultured on the surface of a collagen gel formed a monolayer. The apical pole was in contact with the culture medium and the basal membrane was attached to the substratum. (b) Isolated cells embedded inside the gel organized within 8 into follicles. The basal pole was in contact with collagen and the apical pole was oriented towards the interior of the follicular lumen. (c) Cells were first organized into floating vesicles, structures in which the apical surface is in contact with the culture medium, and the vesicles were embedded inside the collagen gel. After 3 d, cell polarity was inverted, the apical pole being oriented towards the cavity encompassed by cells. Vesicles had been transformed into follicles. (d) Monolayers formed on collagen gels as in a were overlaid with a second layer of collagen, which was polymerized in contact with the apical cell surface. A disorganization of the continuous pavement occurred within 24 h; cells attached to the upper layer of collagen and reorganized into follicles in the collagen sandwich within 4-8 d. A similar process occurred when the monolayer was grown on plastic and overlaid with collagen, or grown on collagen and covered with small pieces of glass cover slips. No reorganization was observed between two glass surfaces. In conclusion, first, a basal pole was always formed in the area of contact between the cell membrane and an adhesive surface and, second, the interaction of a preformed apical pole with an adhesive surface was not compatible with the stability of this domain of the plasma membrane. The interaction of the cell membrane with extracellular components having adhesive properties appears to be a determinant factor in the orientation and stabilization of epithelial cell polarity.

[Reorganisation of thyroid follicular cells in culture. Effect of collagen on the orientation of cell polarity]. / Réorganisation en culture des cellules folliculaires thyroïdiennes. Influence du collagène sur l'orientation de la polarité cellulaire.

In contact with a collagen gel, thyroid follicular cells form a basal pole. A monolayer, with the apical side facing the culture medium is formed when cells are seeded on a collagen layer. In contrast cells reorganize into follicle-like structures when they are embedded in the collagen gel. If vesicles which have their apical pole in contact with the culture medium are embedded in the gel, collagen-cell interaction induced the inversion of cell polarity giving follicular structures. In addition after being overlaid with a collagen layer, cells forming a monolayer reorgnaize into follicles. The apical pole is formed on the free surface of the monolayer or on the internal side of structures embedded in collagen which differentiate into follicles.

Polarity of three-dimensional structures derived from isolated hog thyroid cells in primary culture.

When cultured in polystyrene dishes subjected to previous treatment and supplied with a serum-containing medium, hog thyroid cells form monolayers displaying dome-like arrangements after three to four days. Cells involved in formation of "domes" are morphologically polarized; the apical microvilli of these cells point toward the culture medium. When the tissue is cultured in untreated polystyrene dishes, thyroid cells remain in suspension; their aggregates swell progressively and form hollow spheres encompassed by a single layer of cells. The polarity of the cells forming such spheres is inverse in comparison to the condition characteristic of the intact thyroid gland. When culture medium is supplemented with TSH, PGE1, PGE2 or dBC, structures resembling true follicles are formed in both types of cultures. Gelatin, added to suspension cultures, is also capable of promoting follicle formation. Cultured thyroid cells regularly form an epithelial layer as a result of the interaction of cellular processes. However, the polarization of this layer depends on culture conditions. Thus, structures with either a normal follicle-like polarization of their cells or showing an inverted type of polarization can be obtained.