Connexin-32 acts as a downregulator of growth of thyroid gland.

Thyroid epithelial cells communicate through gap junctions formed from connexin (Cx)32, Cx43, and Cx26. We previously reported that reexpression of Cx32 in "gap junction-deficient" FRTL-5 and FRT thyroid cell lines induces a reduction of cell proliferation rate and an activation of expression of cell differentiation. The present study aimed at determining whether Cx32 could exert similar regulatory functions in vivo.

The porcine sodium/iodide symporter gene exhibits an uncommon expression pattern related to the use of alternative splice sites not present in the human or murine species.

The sodium/iodide symporter (NIS) is a membrane protein mediating the active transport of iodide into the thyroid gland. NIS, expressed by human, rat, and mouse thyrocytes, is encoded by a single transcript. We identified NIS mRNA species of 3.

Thyroid cell proliferation in response to forced expression of gap junction proteins.

Gap junctions are known to play a role in the control of cell proliferation, and connexins (Cx) are considered to be tumor suppressors. However, the effects of Cx on cell proliferation are dependent on the Cx which is expressed and on the cell type under consideration. We previously found that restoration of cell-to-cell communication by stable transfection of two independent thyroid-derived cell lines, FRTL-5 and FRT cells, with the Cx32 gene induced a marked reduction of their proliferation rate.

Connexin 32 fused to the green fluorescent protein retains its ability to control the proliferation of thyroid cells.

Cell-to-cell exchanges of signaling molecules are thought to be involved in the control of cell proliferation. Connexins, which are encoded by a family of genes expressed in a cell type-specific manner, are considered as tumor suppressors. Thyroid epithelial cells co-express connexin 32 (Cx32) and connexin 43 (Cx43) that form distinct and delocalized gap junctions in vivo.

Formation of three-dimensional thyroid follicle-like structures by polarized FRT cells made communication competent by transfection and stable expression of the connexin-32 gene.

Pig thyrocytes, either in the intact gland or cultured under conditions leading to thyroid follicle reconstitution, coexpress two gap junction proteins, connexin-32 (Cx32) and connexin-43 (Cx43). As thyrocytes cultured in the form of a monolayer only express Cx43, we hypothesized that Cx32 could play a role in thyroid folliculogenesis. In the present work, we analyzed the ability of polarized FRT cells (that are gap junction deficient) to form follicle-like structures after stable transfection with either Cx32 or Cx43 genes.

Rho and Rac exert antagonistic functions on spreading of macrophage-derived multinucleated cells and are not required for actin fiber formation.

Multinucleated giant cells (MNGC) derived from avian blood monocytes present, like osteoclasts, an unusual cytoskeletal organization characterized by (1) cortical rings of actin filaments, (2) unique adhesion structures called podosomes and (3) vinculin containing focal complexes which are not visibly connected to F-actin structures. The Rho family of small GTPases plays an essential role in the regulation and organization of cellular cytoskeletal structures including F-actin and vinculin associated structures. Using bacterial toxins such as modified exoenzyme C3 (C3B) and toxin B or overexpression of constitutively active Rac and Rho proteins fused to the green fluorescent protein (GFP), we show that Rac and Rho play antagonistic roles in regulating the morphology of osteoclast-like cells.

Restoration of cell-to-cell communication in thyroid cell lines by transfection with and stable expression of the connexin-32 gene. Impact on cell proliferation and tissue-specific gene expression.

Normal thyroid epithelial cells coexpress connexin-32 and connexin-43, which form distinct gap junctions. In primary culture, connexin-43 is expressed by thyrocytes in monolayers or reorganized into follicles, whereas the expression of connexin-32 is dependent upon the reconstitution of follicles. To study the functional impact of connexin-32 gap junctions in thyroid cells, we transfected connexin-32 cDNA in two thyroid-derived communication-deficient cell lines, FRT and FRTL-5.

Cell-to-cell communication in the anterior pituitary: evidence for gap junction-mediated exchanges between endocrine cells and folliculostellate cells.

The ability of rat anterior pituitary cells to communicate through gap junctions (GJ) was studied using a fluorescent molecule, Lucifer Yellow (LY), which freely passes through GJ channels. The probe was introduced into the cell cytoplasm by using either the cut-end loading method on intact tissue, or cell microinjection on cultured cells. The identification of communicating cells was performed by immunofluorescence labeling of specific hormones in endocrine cells and of S100 protein in folliculostellate (FS) cells.

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.

[Gap junctions in the thyroid gland: distribution, regulation, function].

As in most organized tissues, cells of the thyroid gland, thyrocytes, are connected by various types of intercellular junctions, among which gap junctions. Gap junctions are composed of channels that allow the direct cell-to-cell exchange of small cytoplasmic molecules (Mr < 1000). Proteins forming gap junction channels are the connexins (Cx).

Cell adhesion receptors and gap junctions in normal and neoplastic transformed thyrocytes.

In the thyroid cell adhesion receptors and gap junctions establish a complex modular network defining the structural properties of cells, their interactions with neighboring cells and the extracellular matrix. Neoplastic alterations of this network can lead to an imbalance of cell to cell communication and allows transformed cells to escape from the tissue to generate metastases. The present manuscript summarizes general and thyroid-specific aspects of the molecular basis of cell-cell contacts, an expanding field of tumor biology.

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.

Gap junction-mediated cell-to-cell communication in bovine and human adrenal cells. A process whereby cells increase their responsiveness to physiological corticotropin concentrations.

We have studied the role of gap junction-mediated intercellular communication on the steroidogenic response of bovine (BAC) and human (HAC) adrenal fasciculo-reticularis cells in culture to corticotropin (ACTH). Indirect immunofluorescence analyses showed that intact human and bovine adreno-cortical tissue as well as HAC and BAC in culture expressed the gap junction protein connexin43 (also termed alpha 1 connexin). Both HAC and BAC were functionally coupled through gap junctions as demonstrated by microinjection of a low molecular mass fluorescent probe, Lucifer yellow.

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.

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.

Dynamic analysis of drug action on in vitro reconstituted thyroid follicle by microinjection of tracer molecules and videomicroscopy.

Thyroid cells isolated from the gland by trypsinization are capable in culture of reconstituting histiotypic structures, the thyroid follicles. This morphological differentiation requires the presence of the main thyroid regulator; thyrotropin. We have analyzed some structural and functional aspects of in vitro reconstituted thyroid follicles (RTF) using microinjection of fluorescent probes and videomicroscopy.

Thyroglobulin internalized by thyrocytes passes through early and late endosomes.

We have tried to characterize the intracellular compartments involved in the traffic of the thyroid prohormone thyroglobulin (Tg) from the site of storage, the follicular lumen, to the expected site(s) of proteolytic degradation, lysosomes. Electron microscope immunogold labeling with antibodies against Tg, cation-independent mannose-6-phosphate receptor (MPR), or arylsulfatase-A (ArS-A) was used to identify endocytic structures. The implication of these structures in the transport of Tg was analyzed by following the internalization and intracellular fate of Tg-colloidal gold complexes microinjected into the thyroid follicular lumen.

Hormonal control of cell to cell communication: regulation by thyrotropin of the gap junction-mediated dye transfer between thyroid cells.

By microinjection of Lucifer yellow (LY) and analysis of the cell to cell transfer of the fluorescent probe, we have examined 1) the ability of thyroid cells in primary culture to reconstitute gap junctions and 2) the effects of extracellular signals on the functional activity of these junctions. Isolated thyrocytes cultured in tissue culture-treated petri dishes either formed monolayers or reorganized in follicular structures in the presence of the glycoprotein hormone TSH. In both culture conditions, LY-coupled cells were evident after 24-36 h.

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).

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).

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.

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.

Flavonoid modulation of protein kinase C activation.

The flavonoid quercetin exhibited a biphasic effect on calcium and phospholipid-dependent protein kinase (protein kinase C) activity from rat brain and pig thyroid. At a low concentration (10(-7) M) quercetin stimulated the enzyme activity whereas at higher concentrations quercetin was inhibitory. By contrast the synthetic penta-0-ethylquercetin stimulated protein kinase C activity in a dose-dependent manner.

Protein kinase C in pig thyroid cells: activation, translocation and endogenous substrate phosphorylating activity in response to phorbol esters.

The phorbol ester, TPA, induced the intracellular redistribution of protein kinase C in intact thyroid cells; it caused within 5 min of incubation a 90% decrease of the cytosolic protein kinase C and an increase of the membrane-associated enzyme activity which appeared to be fully activated by TPA. TSH at concentrations which gave the maximal stimulation on various parameters of iodine metabolism induced the translocation of only 10-15% of protein kinase C from the cytosol to the membrane fraction. TPA induced a 2-fold increase in the incorporation of [32P]phosphate into cellular proteins and selectively activated the phosphorylation of two molecular species: a 180,000 Da protein and to a lesser extent a 170,000 Da protein in dispersed pig thyroid cells prelabeled with [32P]orthophosphate.