Signaling from epithelial to dendritic cells of the thyroid gland: evidence for thyrocyte-derived factors controlling the survival, multiplication, and endocytic activity of dendritic cells.

Intrathyroidal dendritic cells (DC) isolated at the same time and then cultured with thyrocytes in the presence of thyrotropin (TSH) keep a phenotype of immature DC (Croizet et al, 2000). As DC from other sources are known to undergo a rapid maturation in vitro, we hypothesized that the maintenance of thyroid-derived DC in an immature state might be caused by thyrocytes-DC interactions. In this study, we investigated whether thyroid-derived DC could change their phenotype in response to TSH stimulation of thyrocytes. Over an 8-day period of culture, the population of DC increased 2- to 3-fold in the presence of TSH and decreased by more than 75% in the absence of TSH. The increase in the DC population was related to DC proliferation, whereas the reduction of the number of DC was secondary to a loss of cell-substrate adhesion and subsequent cell death. In the presence of TSH, DC acquired and maintained a high capacity for internalizing labeled ligands, expressed the mannose receptor, and exposed MHC class II molecules at the cell surface. On the contrary, DC cultured without TSH were devoid of endocytic activity and mannose receptor and, after 2 days, no longer exposed MHC class II molecules at the cell surface. Using conditioned media and enriched DC populations, we show that thyrocytes, in response to TSH, produce soluble factors capable of activating proliferation and endocytic activity of DC. Exogenous granulocyte/macrophage-colony stimulating factor and transforming growth factor-beta, known to be produced by thyrocytes, reproduced the effects of conditioned media. These data, giving evidence of a hormone-regulated signaling process between epithelial and dendritic cells in vitro, suggest that thyrocytes could promote the maintenance of a population of immature DC within the thyroid gland.

Culture of dendritic cells from a nonlymphoid organ, the thyroid gland: evidence for TNFalpha-dependent phenotypic changes of thyroid-derived dendritic cells.

Because they are sparsely distributed in tissues, dendritic cells (DC) present in nonlymphoid organs are difficult to isolate. Only DC from skin and lung have been successfully studied in culture. The objective of the present work was to investigate the possibility of isolating and culturing DC from an endocrine organ, the thyroid gland, which is particularly susceptible to the development of autoimmune processes. The study was conducted on pig thyroid glands to have sufficient amounts of starting material. This choice required the characterization of immunological reagents capable of recognizing DC markers in the pig species. Using a discontinuous trypsinization procedure, a DC population representing 2% to 3% of the thyroid cell suspension was reproducibly obtained. Isolated DC quantitatively attached to tissue culture-treated dishes and segregated from thyrocytes. DC identified as cells expressing major histocompatibility complex class II molecules, the mannose receptor, and the S100 protein were found to have a high capacity to internalize labeled ligands, dextran, and mannosylated albumin. These cells had a phenotype of immature DC. Secondarily, a fraction of DC detached from culture dishes, and floating DC had low or no endocytic activity, a characteristic of mature DC. Treatment of DC/thyrocytes cocultures with tumor necrosis factor alpha (TNFalpha) activated the transformation of immature DC into mature DC. These data show that DC isolated from the thyroid gland can be maintained immature or activated to undergo maturation in primary culture. The procedure of cell isolation and culture should be adaptable to human thyroid tissue for in vitro analyses of DC-mediated immune responses.

Susceptibility of differentiated thyrocytes in primary culture to undergo apoptosis after exposure to hydrogen peroxide: relation with the level of expression of apoptosis regulatory proteins, Bcl-2 and Bax.

Thyrocytes, that generate and use hydrogen peroxide (H2O2) to synthesize thyroid hormones, undergo apoptosis, as do most cell types, when exposed in vitro to H2O2. We have studied 1) the kinetics and the amplitude of the apoptotic response to H2O2 and 2) the relationship between the extent of the apoptosis-inducing effect of H2O2, the H2O2 degradation activity, and the level of expression of apoptosis regulatory proteins, Bcl-2 and Bax, in pig thyrocytes in primary culture. Cells were seeded at high density to obtain confluent monolayers and were cultured in the presence of TSH to maintain the expression of differentiation. H2O2 (10-300 microM) induced the appearance of cells with fragmented DNA (terminal transferase deoxy-UTP-fluorescein isothiocyanate nick end labeling-positive cells) at a maximum of 3-4 h after H2O2 addition and then the detachment of apoptotic cells from the cell monolayer. The proportion of detached cells increased with H2O2 concentration and amounted to up to 30% of the initial cell number after 24 h. The transient effect of H2O2 was related to its rapid degradation by cells and culture medium components (rate constant, approximately 0.1 min(-1)). Iterative additions of H2O2 produced cumulative apoptotic waves. The amplitude of the apoptotic response of thyrocytes to H2O2 progressively increased with the time of culture, up to 4-fold from days 1-8. This was not related to a change in the capacity of thyrocytes to degrade H2O2. During the same period of culture, the Bcl-2 cell content progressively decreased, whereas that of Bax concomitantly increased; thus, the Bcl-2/Bax ratio varied from about 6 on day 1 to 0.5 on day 10. These data show that the susceptibility of thyrocytes to undergo apoptosis increases with the time of culture and that the pronounced changes in the apoptotic status ofthyrocytes might be linked to coordinate modifications of the level of expression of pro- and antiapoptotic regulatory proteins.

Regulation of the three-dimensional organization of thyroid epithelial cells into follicle structures by the matricellular protein, thrombospondin-1.

Thyroid epithelial cells in primary culture have the capacity to organize into thyroid-specific three-dimensional structures, the follicles, in response to TSH. We studied whether thrombospondin 1 (TSP1), which represents, besides thyroglobulin, the main protein secreted by thyroid cells, could play a role in the process of folliculogenesis. TSH promoted follicle formation and inhibited TSP1 production. On the contrary, the phorbol ester, 12-O-tetradecanoyl-phorbol 13-acetate (1-100 nM) prevented TSH-induced follicle formation and strongly increased the synthesis of TSP1. Activation of TSP1 synthesis was dependent upon messenger RNA synthesis. Transforming growth factor-beta, like 12-O-tetradecanoyl-phorbol 13-acetate, increased TSP1 synthesis and prevented TSH-induced follicle formation. Thus, signaling molecules that depressed or conversely activated TSP1 production, respectively promoted or prevented thyroid folliculogenesis. TSP1, purified from platelets, was devoid of effect on cell substratum attachment, but exerted a concentration-dependent inhibition of the TSH-activated reconstitution of thyroid follicles (half-inhibition at 40 microg/ml). TSP1 exhibited the same effect when added to thyroid cell aggregates representing primitive follicle structures. Our data suggest that the control of thyroid follicle formation may operate at least in part through regulation of the production of the matricellular protein TSP1, which acts as a negative modulator of the cell-cell adhesion process involved in thyroid follicle morphogenesis.

H2O2 induces apoptosis of pig thyrocytes in culture.

Apoptosis might be involved in the reduction of the thyroid cell population in physiopathological situations such as goitre involution and autoimmune deleterious processes. Up to now, little attention has been paid to the apoptotic phenomenon in the normal thyroid gland the specialized metabolism of which is expected to generate reactive oxygen species. Indeed, thyroid cells have the capacity to synthesize H2O2. In this study, we have analyzed the capacity of H2O2 to trigger apoptosis of pig thyrocytes in culture to try to determine whether thyrocytes exhibit a particular resistance to apoptosis induced by an oxidative stress. We show that exposure of thyrocytes cultured as monolayers to exogenous H2O2 induced cell death with characteristics of apoptosis. The effect of H2O2 was concentration-dependent; apoptotic cells were already observed after exposure to 50 micro M H2O2. At high concentrations (millimolar range), H2O2 exerted toxic effects leading to rapid cell disruption. Within the first hour after the onset of exposure to 50-300 micro M H2O2, early signs of apoptosis, i.e. DNA fragmentation, appeared in a low (0.1-1%) but definite fraction of thyrocytes. The proportion of adherent cells exhibiting DNA fragmentation remained fairly constant after 6, 15 and 24 h. During the 24-h period, an increasing number of cells detached from the culture dish and up to 30-40% of cells in suspension displayed apoptotic features. The fraction of cells that lost contact with the culture dish amounted to up to 25% 24 h after addition of 300 micro M H2O2. In conclusion, as reported for other cell types, low H2O2 concentrations are capable of triggering apoptosis in thyrocytes cultured as monolayers. Thyrocytes that undergo apoptosis secondarily lose contact with neighbour cells and the substratum; cell detachment from the monolayer probably happens within 1-2 h after initiation of DNA fragmentation. Our data show that the apoptotic commitment can take place many hours after initiation of the oxidative stress.

Expression of alpha- and beta-subunits and activity of Na+K+ ATPase in pig thyroid cells in primary culture: modulation by thyrotropin and thyroid hormones.

Na+ K+ ATPase located at the basolateral pole of thyroid epithelial cells, contributes to thyroid hormone synthesis by generating the driving force for the uptake of the substrate, iodide. We have investigated whether the expression of the alpha- and beta-subunits and activity of Na+ K+ ATPase were subjected to variations in response, (a) to TSH, that controls the expression of differentiation in thyroid cells and (b) to thyroid hormones as potential autocrine factors. Studies were carried out on pig thyroid cells cultured (a) without TSH to obtain thyroid cell monolayers (TCM) in basal state or (b) with TSH in the form of cell monolayers (TCM-T) or as reconstituted thyroid follicles (RTF). Iodide uptake activity, thyroperoxidase protein and thyroglobulin mRNA taken as parameters of thyroid cell differentiation were 6 to 25-fold higher in RTF and TCM-T than in TCM. Western blot analyses of Na+ K+ ATPase subunits revealed that the alpha-subunit (105 kDa) content of TCM-T and RTF was similar but 8-fold higher than that of TCM. In contrast, the beta-subunit (50 kDa) content of TCM-T and RTF was only about twice that of TCM. Similar relative variations were observed at the mRNA level for both alpha- and beta-subunits. Na+ K+ ATPase activity was only 40% higher in RTF and TCM-T than in TCM. A 48 h treatment of RTF by either T4 or T3 (1-100 nM) induced a 3-fold increase of the alpha-subunit but did neither alter the beta-subunit nor the Na+ K+ ATPase activity. In conclusion, Na+ K+ ATPase activity and the level of expression of its beta-subunit, known to control the assembly and targetting of alpha-beta oligomers and thus the amount of functional sodium pump at the plasma membrane, are only moderately altered when thyroid cells undergo major changes in their differentiation status. Our data show that the expression of the alpha-subunit of Na+ K+ ATPase by thyroid cells is up-regulated by TSH and thyroid hormones.

Endocytosis of albumin and thyroglobulin at the basolateral membrane of thyrocytes organized in follicles.

Serum proteins such as albumin are present inside thyroid follicles in both normal and pathological situations. To analyze the mechanism of entry of these proteins, we investigated the ability of polarized thyrocytes to internalize soluble molecules at their basolateral pole. Experiments were conducted on in vitro reconstituted thyroid follicles using BSA and pig thyroglobulin (Tg) coupled to gold particles for electron microscopy, conjugated to fluorescein for conventional and confocal fluorescence microscopy, or radioiodinated for biochemical measurements. Incubations were carried out at 37 C. BSA and Tg coupled to gold particles were rapidly internalized from the culture medium and sequentially found in small vesicles and early endosomes and in late endosomes and lysosomes. Fluorescence microscope analyses revealed that the majority of cells forming reconstituted thyroid follicles are capable of internalizing BSA and Tg, but that Tg was more efficiently endocytosed than BSA. Using radioiodinated ligands, it was observed that the endocytosis of Tg was 10 times higher than that of BSA. The internalization of [125I]Tg was inhibited by increasing concentrations of unlabeled Tg. In contrast, endocytosis of 125I-labeled BSA was independent of the unlabeled BSA concentration. Experiments performed at 4 C indicated the presence of a basolateral membrane binding activity for [125I]Tg; the Tg concentration that reduced the binding of labeled Tg by 50% ranged from 4-6 microM. These data are evidence of a process of internalization of soluble molecules at the basolateral pole of thyrocytes, with BSA being internalized by fluid phase endocytosis and Tg by selective endocytosis. Our findings explain how serum albumin can enter thyroid follicles and disclose a new cellular handling and transport pathway of Tg. We propose that selective uptake of Tg operating on molecules secreted at the basolateral surface of thyrocytes could control the amount of Tg released in the circulation.

Gap junctions and cell polarity: connexin32 and connexin43 expressed in polarized thyroid epithelial cells assemble into separate gap junctions, which are located in distinct regions of the lateral plasma membrane domain.

Epithelial cells of the thyroid gland present an uncommon connexin expression pattern, they coexpress connexin32 and connexin43. In the present work, we have analyzed the membrane distribution of these two connexins to determine: (i) whether they co-assemble in the same gap junctions or form separate gap junctions; and (ii) whether their location is somehow related to the thyroid cell polarity. Immunofluorescence analyses of the localization of the two connexins in thyroid tissue sections revealed that connexin32 and connexin43 are located in different regions of the plasma membrane. We further analyzed the location of each of the two connexins with regard to that of the tight junction-associated protein, ZO1. Laser scanning confocal microscope observations of connexin32 or connexin43 and ZO1 double-immunolabelled thyroid cells, gave evidence for a separate localization of gap junctions made of each of these two connexins. Connexin32 gap junctions appeared as fluorescent spots scattered over the lateral membrane domain, while connexin43 gap junctions formed a meshed network superimposable with that of tight junctions in the subapical region of the cells. Western blot analyses of the distribution of connexins in thyroid plasma membrane subfractions obtained by ultracentrifugation on a sucrose gradient led to the identification of membrane sub-populations enriched in either connexin32 gap junctions or connexin43 gap junctions. Connexin32 gap junctions and connexin43 gap junctions were found to differ in their resistance to solubilization by N-lauroylsarcosine. Increasing concentrations of this detergent from 0.12% to 0.42% caused a progressive solubilization of connexin43 while connexin32 remained membrane-bound.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential control of connexin-32 and connexin-43 expression in thyroid epithelial cells: evidence for a direct relationship between connexin-32 expression and histiotypic morphogenesis.

Thyroid epithelial cells cultured either as a monolayer or in the form of follicles, rapidly reconstitute functional gap junctions (Gj). We previously reported that the thyroid Gj gating is regulated by TSH. We have now performed molecular analyses of Gj proteins 1) to detect the connexin(s) (Cx) that is expressed in thyroid epithelial cells, 2) to determine whether the expression of Cx is hormonally regulated, and 3) to analyze the relationship between Cx expression and histiotypic morphogenesis, i.e. folliculogenesis. Studies were carried out on thyrocytes freshly isolated from the gland and on corresponding thyrocytes after 1-7 days in culture as monolayers or in the form of reconstituted follicles. The Cx gene transcription products were analyzed by Northern blot using specific complementary DNA probes for Cx26, Cx32, and Cx43. Cx proteins were identified and estimated by Western blot and indirect immunofluorescence using polyclonal antipeptide antibodies. Cx32 and Cx43 proteins and their corresponding messenger RNA (mRNA) were detected in thyrocytes freshly isolated from the gland. Thyrocytes contained a high amount of the 1.6-kilobase Cx32 mRNA and only traces of the 3-kilobase Cx43 transcript. No Cx26 transcripts could be detected. Thyrocytes cultured at a density of 0.2-0.5 x 10(6) cells/cm2 in the absence of TSH formed monolayers. Surprisingly, monolayer cells lost Cx32 protein within 24 h, and their Cx32 mRNA content decreased from high to barely detectable levels; Cx32 protein was no longer detected throughout the 1-week culture period. On the contrary, Cx43 mRNA and Cx43 protein rapidly increased in monolayer cells to reach very high levels within 2-4 days. Thyrocytes cultured at the same density, but in the presence of TSH also rapidly lost Cx32, but as soon as they reorganized into follicular structures, reexpressed Cx32 at a level (in terms of protein and mRNA) comparable to that found in cells freshly extracted from the gland. As observed for cell monolayers, reconstituted follicles overexpressed Cx43. The Cx43 protein and Cx43 mRNA contents of cultured thyrocytes were 20- to 50-fold higher than those found in isolated thyrocytes at the outset of culture. When thyrocytes were cultured with TSH, but at a low density (< 0.2 x 10(6) cells/cm2) to prevent follicle formation, a TSH-dependent increase in Cx43 was observed in monolayer cells. However, TSH did not cause any reexpression of Cx32.(ABSTRACT TRUNCATED AT 400 WORDS)

Thyroglobulin molecules internalized by thyrocytes are sorted in early endosomes and partially recycled back to the follicular lumen.

Thyroglobulin (Tg) molecules stored in thyroid follicle lumens are heterogeneous in terms of iodine and hormone contents. It has been suggested that thyroid hormone is preferentially produced from the most highly iodinated Tg molecules and that thyrocytes are capable of selecting these molecules. The cellular localization as well as the molecular basis of such a selection process are not known. The present work was undertaken to determine whether there is selectivity at the step of endocytosis and, if not, to discover other possible mechanisms. Studies were conducted on reconstituted thyroid follicles (RTF) in culture. We compared the ability of thyrocytes to internalize Tg and an exogenous protein, BSA, which is neither iodinated nor glycosylated. To identify the protein, Tg and BSA were coupled to gold particles of different size and microinjected in a fixed ratio into the lumen of RTF. Neither of the two protein gold probes detected by transmission electron microscope bound at the cell surface, and both entered the cells at a similar rate and were concentrated in early endosomes. After 20 min, both Tg-G and BSA-G were segregated into distinct vacuolar structures. At 60 min, the intracellular content of BSA-G (mainly in prelysosomes and lysosomes) was 2- to 3-fold higher than that of Tg-G. At the same time, there was a marked reduction in the BSA-G/Tg-G ratio in the lumen. The differences between the Tg-G and BSA-G distribution patterns that were amplified in TSH-treated RTF are in keeping with a back-transfer of internalized Tg toward the lumen. The existence of a cell to lumen transport of previously endocytosed Tg was further documented using intralumenal [125I]Tg as a marker. RTF pulse labeled with tracer amounts of [125I]iodide were shortly incubated with TSH to induce [125I]Tg endocytosis, and the fate of internalized [125I] Tg was studied in a chase incubation period of up to 4 h. At 20 C, where the degradation of internalized Tg is blocked, we observed a time-dependent decrease in intracellular [125I]Tg and a corresponding increase in the lumenal [125I]Tg content. This cell to lumen [125I]Tg transfer was inhibited by primaquine. In conclusion, our data show that 1) the thyroid apical endocytic process does not exhibit selectivity for Tg; 2) the thyrocyte possesses a sorting machinery for endocytosed ligands; and 3) internalized Tg molecules can be recycled back to the follicular lumen.(ABSTRACT TRUNCATED AT 400 WORDS)

Analysis of the thyroglobulin internalization process using in vitro reconstituted thyroid follicles: evidence for a coated vesicle-dependent endocytic pathway.

We have designed a new experimental system based on in vitro reconstituted thyroid follicles (RTF) to study the relative implication of macropinocytosis and micropinocytosis processes in the internalization of thyroglobulin (Tg). Thyrocytes cultured in the presence of TSH reorganize in histiotypic and functional follicles. Tg, which accumulates into the newly formed intrafollicular lumen (IL), was pulse labeled with [125I]iodide. Basal or TSH-activated Tg internalization, i.e. transfer from IL to cells, was assessed by measuring [125I]Tg in the cells and the IL; the IL fraction was collected after selective opening of lumina by a short treatment of RTF in a calcium-free medium. We used the ratio between cellular and IL labeled Tg contents as an endocytic index. TSH caused a very rapid increase in the cellular uptake of labeled Tg; the endocytic index increased by a factor of 4-8. The TSH effect was maximum after 15-20 min. TSH had no effect when the chase-incubation was performed at 4 C, but exhibited the same stimulatory action in terms of both time course and amplitude of action at 20 and 37 C. The macropinocytosis-related cellular structures, the pseudopods, were never observed in RTF maintained at 20 C; they were rare at 37 C and only found after 30 min of TSH treatment. At 20 as well as 37 C, the action of TSH on Tg endocytosis was concentration dependent in the range of 0.05-10 mU/ml. A fraction of Tg internalized by thyrocytes was found in coated vesicles. The labeled Tg content of purified coated vesicles varied with the temperature of the chase-incubation and was increased in TSH-treated RTF. Taken together, these data show that endocytosis of Tg by thyroid follicular cells in resting or moderately activated states does not proceed via the pseudopod formation-dependent mechanism, also termed macropinocytosis. Tg internalization would be related to what is referred as micropinocytosis and would involve a coated vesicle-dependent endocytic pathway.

Cell-cell interactions in the process of differentiation of thyroid epithelial cells into follicles: a study by microinjection and fluorescence microscopy on in vitro reconstituted thyroid follicles.

Thyroid cells, cultured in the presence of thyroid stimulating hormone, reorganized within 36-48 hr into follicular structures, the in vitro reconstituted thyroid follicles or RTF. By microinjection of fluorescent probes either into the neoformed intrafollicular lumen (IL) or into cells forming the follicles, we have studied the development and some functional properties of cell-cell contacts involved in a) the formation of the thyroid follicular lumen and b) the communication between thyrocytes within the follicle. The probes were compounds of either low (Lucifer Yellow: LY) or high molecular weight (Dextran labeled with fluorescein: FITC-Dextran and Cascade Blue conjugated to bovine serum albumin: CB-BSA). LY microinjected into IL of 2-9-day-old RTF was seen to label circular spaces with a diameter ranging from 10 to 100 microns. The cells delimiting the IL remained unlabeled. The fluorescent dye remained concentrated in IL for up to 24 hr. FITC-Dextran or CB-BSA microinjected into IL behaved as LY; the probes were restrained into the lumen. A 2 hr incubation of RTF with iodide induced alterations of the structure of IL; an effect mediated by an organic form of actively trapped iodide. A 15-30 min incubation of RTF in a low CA2+ medium caused the opening of IL visualized by the progressive decrease of the fluorescence of probes preinjected into the lumenal space. The same but more rapid effect was obtained by microinjection of EGTA into the IL. The low Ca2(+)-dependent opening of IL was also demonstrated by the release into the medium of thyroglobulin present in IL. Microinjection of LY in a cell involved in the follicle structure led to the rapid labeling of the other cells forming the follicle but LY did not penetrate the IL. Unlike LY, the distribution of FITC-Dextran or CB-BSA injected into cells delimiting the lumen was restricted to the microinjected cells. Alterations of medium or intralumenal Ca2+ concentration which caused the opening of IL did not affect the cell-to-cell transfer of LY. By using fluorescent probe microinjection, we show that the in vitro thyrocyte histiotypic differentiation leads to the reconstitution of functional intercellular junctions: tight junctions insuring the tightness of the neoformed lumen and gap junctions mediating the cell-to-cell exchange of small molecules. The structure of the thyroid follicles appears to be under the control of both extracellular and intralumenal Ca2+ concentrations.

Coated vesicles from thyroid cells carry iodinated thyroglobulin molecules. First indication for an internalization of the thyroid prohormone via a mechanism of receptor-mediated endocytosis.

We have tried to identify iodinated thyroglobulin molecules in purified thyroid-coated vesicles to determined whether the internalization of the thyroid prohormone could proceed via a mechanism of receptor-mediated endocytosis. Coated vesicles isolated from pig thyroids by differential centrifugation and centrifugation on 2H2O-sucrose cushion were characterized by transmission electron microscopy and analyses of the polypeptide composition by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and Western blot using anti-clathrin heavy chain and anti-thyroglobulin antibodies. Clathrin and thyroglobulin (Tg) appeared as the two major components of the purified thyroid coated vesicles (TCV). Purified TCV fraction was homogeneous when analyzed by isopycnic centrifugation on 30% Percoll gradient. TCV had an apparent buoyant density of 1.035 g/ml. The presence of Tg molecules inside TCV was ascertained by (a) immunogold labeling on cryosections of TCV pellet and (b) identification by gel electrophoresis and radio-immunoassay of a definite fraction of Tg (3-5% of total protein) in TCV treated by Triton X-100. The detergent-treated TCV also contained protein-bound iodine: 0.5-0.7 micrograms of iodine/mg protein. Pulse-chase experiments on in vitro reconstituted thyroid follicles have been used to further document the presence of iodinated Tg molecules in coated vesicles. TCV were isolated from reconstituted thyroid follicles previously labeled with [125I]iodide to radioiodinate Tg of the follicular lumen (the pre-endocytotic compartment) and incubated with or without thyrotropin or dibutyryl cyclic AMP to activate intraluminal 125I-Tg endocytosis. Autoradiographic analyses revealed the presence of 125I-Tg in purified TCV and Triton X-100-treated TCV. 125I-Tg present in TCV represented 1-2% of the total intracellular protein-bound radioactivity. Thyrotropin and dibutyryl cyclic AMP increased 2-3-fold the 125I-Tg content of TCV. Our results clearly show that iodinated Tg, the molecular form of the thyroid prohormone known to be internalized, is present into TCV. The data suggest that coated vesicles are involved in the uptake and transport of Tg from the follicular lumen to the lysosomal compartment and therefore, that the internalization of Tg could proceed, at least for a part, via a mechanism of receptor-mediated endocytosis.

Thyroid hormone residues are released from thyroglobulin with only limited alteration of the thyroglobulin structure.

We have tried to characterize thyroglobulin (Tg) degradation products in purified pig thyroid lysosomes to determine whether the release of thyroid hormone residues from Tg involves a random proteolytic attack or discrete and selective cleavage reactions. The intralysosomal soluble protein fraction was prepared by osmotic pressure-dependent lysis of lysosomes purified by isopycnic centrifugation on Percoll gradients. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate revealed the presence of a fraction of Tg (5-10% of total lysosomal protein) with the same molecular weight as that of the intact Tg subunit. This high molecular weight Tg was the only intralysosomal species detected by Western blot using antipig Tg antibodies. In nondenaturing conditions, lysosomal Tg (LTg) identified by radioimmunoassay was in the form of a dimer with a sedimentation coefficient lower than that of either iodinated Tg (colloid Tg) or noniodinated Tg (microsomal Tg). LTg had a lower iodine content than colloid Tg:9-12 versus 39-42 iodine atoms/molecule. Pronase hydrolysates of LTg did not contain any 3,5,3',5'-tetraiodo-L-thyronine or 3,3',5-triiodo-L-thyronine residues detectable by reverse-phase high pressure liquid chromatography; iodine present in LTg was in the form of iodotyrosines. Under reducing conditions, LTg almost completely disappeared and gave rise to various polypeptides of smaller size. These results suggest that Tg transferred to lysosomes is subjected to selective proteolytic cleavage reaction(s) that release thyroid hormone residues. This early step would lead to the formation of hormone-depleted Tg molecules that are cleaved at discrete sites, the resulting polypeptides remaining bound through disulfide bonds to yield Tg molecules with an apparently normal size and a slightly altered structure.

In vitro studies of the thyroglobulin degradation pathway: endocytosis and delivery of thyroglobulin to lysosomes, release of thyroglobulin cleavage products--iodotyrosines and iodothyronines.

UNLABELLED: Iodinated thyroglobulin stored in the thyroid follicular lumen is subjected to an internalization process and thought to be transferred into the lysosomal compartment for proteolytic cleavage and thyroid hormone release. In the present study, we have designed in vitro models to study: 1) the transfer of endocytosed thyroglobulin into lysosomes, and 2) the intracellular fate of free thyroid hormones and iodinated precursors generated by intralysosomal proteolysis of thyroglobulin. Open follicles prepared from pig thyroid tissue by collagenase treatment were used to probe the delivery of exogenous thyroglobulin to lysosomes via the differentiated apical cell membrane. Open follicles were incubated with pure [125I]thyroglobulin with or without unlabeled thyroglobulin in the presence or in the absence of chloroquine. Subcellular fractionation on a Percoll gradient showed that [125I]thyroglobulin was internalized and present in low (for the major part) and high density thyroid vesicles. In chloroquine-treated open follicles, we observed the appearance of a definite fraction of [125I]thyroglobulin in a lysosome subpopulation having the expected properties of phagolysosomes or secondary lysosomes. In contrast, in control open follicles, the amount of [125I]thyroglobulin or degradation products found in high density vesicles was lower and associated with the bulk of lysosomes, i.e., primary lysosomes. The content in thyroglobulin and degradation products of lysosomes at steady-state was analyzed by Western blot using polyclonal anti-pig thyroglobulin antibodies. Under reducing conditions, immunoreactive thyroglobulin species correspond to polypeptides with molecular weights ranging from 130,000 to less than 20,000. The presence of free thyroid hormones and iodotyrosines inside lysosomes and their intracellular fate was studied in dispersed thyroid cells labeled with [125I]iodide. Neo-iodinated [125I]thyroglobulin gave rise to free [125I]T4 which was secreted into the medium. In addition to released [125I]T4, a fraction of free [125I]T4 was identified inside the cells. Lysosomes isolated from dispersed thyroid cells did not contain significant amounts of free [125I]T4. The free intracellular [125I]T4 fraction seems to represent an intermediate 'hormonal pool' between thyroglobulin-bound T4 and secreted T4. Evidence for such a precursor-product relationship was obtained from pulse-chase experiments. IN CONCLUSION: 1) open thyroid follicles have the ability to internalize thyroglobulin by a mechanism of limited capacity and to address the endocytosed ligand to lysosomes.(ABSTRACT TRUNCATED AT 400 WORDS)

Evidence for anti-tubulin autoantibodies in the form of immune complexes in human sera.

Anti-tubulin antibodies were studied in normal human serum either maintained at neutral pH to measure the free antibody activity (FAA) or treated at pH 2.8 to measure the total antibody activity (TAA): FAA + the antibody activity in the form of immune complexes (ICAA). Anti-tubulin antibody activities were assessed by measurements of the capacity of serum immunoglobulins to bind pure 125I-labelled tubulin in a liquid phase radioimmune assay or to immunoprecipitate unlabelled tubulin revealed by Western blot using anti-alpha- or anti-beta-tubulin monoclonal antibodies. Acid buffer-treated serum and untreated serum at a 1:200 dilution immunoprecipitated about 35% and 4% of labelled tubulin, respectively. TAA was therefore 8- to 10-fold higher than FFA. Anti-tubulin antibody titres corresponding to TAA and FAA were about 1:20,000 and 1:500, respectively. The Western blot analysis confirmed that the acid buffer-treatment of the serum dramatically increased the capacity of serum immunoglobulins to immunoprecipitate tubulin. TAA was studied in patients with Graves' disease with elevated FAA. TAA of the sera of control subjects and patients with Graves' disease were not significantly different, so an increase of FAA was related to a decrease of ICAA. These results indicate that (a) normal human serum contains high levels of anti-tubulin antibodies in the form of immune complexes which are dissociated by an acid buffer treatment, (b) these immune complexes exist in the presence of a small excess of free anti-tubulin antibodies, (c) the equilibrium between free and immune complex-bound anti-tubulin antibodies could be altered in patients with autoimmune diseases.

Cyclic AMP-dependent phosphorylation of high molecular mass proteins in pig thyroid cells.

Four high molecular mass (H Mr) proteins were found to be phosphorylated in a cyclic AMP-dependent manner in both partially purified pig thyroid membrane fractions and in pig thyroid cells in culture. These phosphoproteins did not correspond to major cellular proteins; they were found in both soluble and particulate subfractions of homogenates from cultured thyroid cells. The molecular mass of the 4 proteins named HMr1 to HMr4 determined by polyacrylamide gel electrophoresis in the in the presence of sodium dodecylsulfate was about 310 000 for HMr1, 250 000 for HMr2, 240 000 for Hmr3 and 220 000 for HMr4. HMr1 comigrated with brain MAP1, whereas HMr3 and HMr4 had the same mobility as alpha-and beta-spectrins, respectively. The 4 high molecular mass phosphoproteins are substrates of cyclic AMP-dependent protein kinase(s) since (a) their phosphorylation was increased by cyclic AMP and not by cyclic GMP or calcium alone or calcium in the presence of calmodulin or phospholipid; (b) the effect of cyclic AMP was prevented by the thermostable inhibitor of cyclic AMP-dependent protein kinases; (c) the purified catalytic subunit of cyclic AMP-dependent protein kinases markedly phosphorylated the 4 HMr proteins. The 32P-labeling of HMr proteins using either endogenous cyclic AMP-dependent protein kinase or the purified catalytic subunit was always lower in cells cultured in the presence of TSH (reassociated in follicle-like structures) than in freshly dispersed cells or cells cultured in basal conditions (cells in monolayer). These results suggest that the 4 high molecular mass thyroid phosphoproteins represent structural components, the phosphorylation of which could vary with the cellular organization.