Yvonne Munari-Silem scite author profile

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. Rat anterior pituitary cells in their physiological organization, i.e. in the intact tissue, exhibited a high level of coupling through GJ. LY-labeled cells were found up to 300-microns apart from its site of introduction. The communicating cells were primarily PRL cells, GH cells, and FS cells. Only a few LH, TSH, and ACTH cells were labeled with LY. Anterior pituitary cells, isolated from the rat tissue by mild protease treatment and cultured for 3 days, reestablished functional GJ as demonstrated by microinjection of LY into individual cells. By immunolabeling of specific hormones and/or S100 protein, we found a GJ coupling between FS cells, and between FS cells and endocrine cells, including PRL cells. The communication between FS cells was by far the most frequent. In conclusion, we demonstrate the presence of functional GJ between anterior pituitary cells of the same type and between anterior pituitary cells having distinct differentiated functions.

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Gap junction-mediated cell-to-cell communication in endocrine glands—molecular and functional aspects: a review

Munari-Silem

Rousset

1996

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It is well established that most signals supporting intercellular communication are produced either at distance or in the local environment of the target cells. From the pioneering work of Kanno and Loewenstein (1), it has become clear that, in most tissues, adjacent cells can communicate in a more direct way, without dilution of the signalling molecules in extracellular compartments. This mode of communication is taking place through specialized structures, named gap junctions, that allow the cell-414-27 Munari-Silem Y. Audebet C. Rousset B. Hormonal control of cell to cell communication: regulation by thyrotropin of the gapjunction-mediated dye transfer between thyroid cells. Endocri¬ nology 1991:128:3299-309 Green LM. Lazarus JP, Labue M. Shah MM. Reduced cell-cell communication in a spontaneous murine model of autoimmune thyroid disease. Endocrinology 1995;136:3611-8

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Restoration of Cell-to-Cell Communication in Thyroid Cell Lines by Transfection with and Stable Expression of the Connexin-32 Gene

Statuto

Audebet

Tonoli

et al. 1997

Journal of Biological Chemistry

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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

Munari-Silem

Mesnil

Selmi

et al. 1990

Journal Cellular Physiology

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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.

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