Expression of sodium/iodide symporter (NIS) by thyroid epithelial cells is primarily regulated by TSH, which acts at the level of NIS gene transcription. Knowledge of the mechanisms governing NIS expression mainly comes from studies of rat thyroid-derived cell lines forming cell monolayers. In this study we investigated the impact of the three-dimensional organization of thyroid cells into follicles on the regulation of NIS expression. We used porcine thyrocytes in primary culture that, depending on cell density and the moment TSH is added, either predominantly form a cell monolayer (CM) or reconstitute thyroid follicles (RTF). NIS expression analyzed at transcript and protein levels was remarkably high in RTF compared with CM. Cells forming RTF were NIS positive, whereas in CM, NIS was only detected in the limited number of cells forming follicle-like structures. When thyrocytes were cultured at increasing cell density to obtain a gradual shift from CM to RTF, the progressive increase in the proportion of cells enrolled in RTF was accompanied by a parallel increase in NIS expression. Other TSH-regulated genes, thyroperoxidase, Na(+),K(+)-adenosine triphosphatase alpha-subunit, and thyroglobulin, were expressed at similar levels whatever the organization of thyrocytes in culture. The transcription factor, Pax-8, was equally expressed in NIS-negative CM and NIS-positive RTF. We show that TSH highly activates NIS expression only when thyrocytes have undergone histiotypic morphogenesis. This finding suggests that TSH activation of NIS gene transcription might involve, in addition to Pax-8, a regulatory factor(s) whose synthesis and/or activity are triggered by cell-cell interaction(s) occurring in the course of folliculogenesis.
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.
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)
SUMMARY: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 ␣ (TNF␣) 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. (Lab Invest 2000, 80:1215-1225.
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 H 2 O 2 . In this study, we have analyzed the capacity of H 2 O 2 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 H 2 O 2 induced cell death with characteristics of apoptosis. The effect of H 2 O 2 was concentration-dependent; apoptotic cells were already observed after exposure to 50 µM H 2 O 2 . At high concentrations (millimolar range), H 2 O 2 exerted toxic effects leading to rapid cell disruption. Within the first hour after the onset of exposure to 50-300 µM H 2 O 2 , 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 µM H 2 O 2 .In conclusion, as reported for other cell types, low H 2 O 2 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.
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