Françoise Lamy

General inhibition by transforming growth factor β1 of thyrotropin and cAMP responses in human thyroid cells in primary culture

Transforming growth factor beta 1 (TGF beta 1) mRNA has previously been identified in human thyroid cells and this agent has been shown to inhibit DNA synthesis in thyroid cells of some other species. In normal human thyroid cells in primary culture, TGF beta 1 inhibited inconstantly the low basal DNA synthesis and strongly the stimulation of DNA synthesis by epidermal growth factor (EGF) and serum, and by thyroid-stimulating hormone (TSH) acting through cAMP. This inhibition, by TGF beta 1, of the TSH and cAMP-dependent DNA synthesis was associated with an inhibition of PCNA (proliferating cell nuclear antigen) synthesis. TGF beta 1 almost completely abolished the cAMP induced stimulation of iodide uptake and thyroperoxidase synthesis. It thus, like EGF, also acts as a dedifferentiating agent. Investigation of the pattern of protein synthesis by two-dimensional gel electrophoresis revealed that while TGF beta 1, by itself, increased the synthesis of only one protein, a tropomyosin isoform, it inhibited most of the effects of cAMP on protein synthesis (35 out of 45 cAMP-regulated proteins were affected). It also reversed the effect of cAMP on the morphology of the thyrocytes. The fact that TGF beta 1 did not affect the increase in cAMP provoked by TSH in human thyroid cells while inhibiting most of the effects of dibutyryl cAMP in these cells suggests an action at a step distal to cAMP generation.(ABSTRACT TRUNCATED AT 250 WORDS)

Thyrotropin via Cyclic AMP Induces Insulin Receptor Expression and Insulin Co-stimulation of Growth and Amplifies Insulin and Insulin-like Growth Factor Signaling Pathways in Dog Thyroid Epithelial Cells

Despite the similarity of their receptors and signal transduction pathways, insulin is regarded as a regulator of glucose, protein, and lipid metabolism, whereas insulin-like growth factors (IGF-I and IGF-II) mainly act as mitogenic hormones. In the dog thyroid primary culture model, the triggering of DNA synthesis by thyrotropin (TSH) through cAMP, or by cAMP-independent factors including epidermal growth factor, hepatocyte growth factor and phorbol esters, requires insulin or IGFs as comitogenic factors. In the present study, in TSH-treated cells, IGF-I receptors and insulin receptors were paradoxically equivalent in their capacity to elicit the comitogenic pathway, which, however, was mediated only by IGF-I receptors in dog thyroid cells stimulated by cAMP-independent mitogens. Moreover, prior cell exposure to TSH or forskolin increased their responsiveness to insulin, IGF-I, and IGF-II, as seen on DNA synthesis and activation of a common insulin/IGF signaling pathway. To understand these observations, binding characteristics and expression of insulin and IGF-I receptors were examined. To analyze IGF-I receptor characteristics, the unexpected interference of a huge presence of IGF-binding proteins at the cell membrane was avoided using labeled Long R3 IGF-I instead of IGF-I. Strikingly, TSH, through cAMP, time-dependently induced insulin binding and insulin receptor mRNA and protein accumulation without any effect on IGF-I receptors. These findings constitute a first example of an induction of insulin receptor gene expression by a cAMP-mediated hormone. In dog thyroid cells, this allows low physiological insulin concentrations to act as a comitogenic factor and might explain in part the enhanced responsiveness to IGFs in response to TSH. This raises the possibility that TSH-insulin interactions may play a role in the regulation of thyroid growth and function in vivo.

Differential protein phosphorylation in induction of thyroid cell proliferation by thyrotropin, epidermal growth factor, or phorbol ester.

Protein phosphorylation was studied in primary cultures of thyroid epithelial cells after the addition of different mitogens: thyrotropin (TSH) acting through cyclic AMP, epidermal growth factor (EGF), or 12-O-tetradecanoylphorbol-13-acetate (TPA). EGF or TPA increased the phosphorylation of five common polypeptides. Among these, two 42-kilodalton proteins contained phosphotyrosine and phosphoserine with or without phosphothreonine. Their characteristics suggested that they are similar to the two 42-kilodalton target proteins for tyrosine protein phosphorylation demonstrated in fibroblasts in response to mitogens. No common phosphorylated proteins were detected in TSH-treated cells and in EGF- or TPA-treated cells. The differences in the protein phosphorylation patterns in response to TSH, EGF, and TPA suggested that the newly emerging cyclic AMP-mediated mitogenic pathway is distinct from the better known growth factor- and tumor promoter-induced pathways.

Cloning and sequencing of a calcium-binding protein regulated by cyclic AMP in the thyroid.

p24 is a thyroid protein (Mr 24,000) identified by two‐dimensional gel electrophoresis on the basis that its synthesis and phosphorylation are up‐regulated by thyrotropin and cyclic AMP agonists. p24 cDNA was cloned from a lambda gt11 cDNA library using a polyclonal antibody raised against the protein recovered from a Western blot spot. The encoded polypeptide (189 residues) displays a putative target‐site for phosphorylation by cyclic AMP‐dependent protein kinase and belongs to the superfamily of proteins binding Ca2+ through ‘EF hand’ domains. It presents four such domains of which two agree closely with the consensus. The ability of p24 to bind Ca2+ has been directly confirmed on Western blots. p24 was detected in many tissues including the salivary glands, the lung and the brain. The ubiquitous nature of p24, together with its regulatory and sequence characteristics suggest that it constitutes an important target common to the cyclic AMP and Ca2+‐phosphatidylinositol cascades.

Expression and subcellular localization of CDK2 and cdc2 kinases and their common partner cyclin A in thyroid epithelial cells: comparison of cyclic AMP-dependent and -independent cell cycles.

Dog thyroid epithelial cells in primary culture constitute a model of positive control of DNA synthesis initiation and GO‐S prereplicative phase progression by cyclic AMP as a second messenger for TSH. In its early steps, this mitogenic control is quite distinct from cyclic AMP‐independent mitogenic cascades elicited by growth factors. We demonstrate here that TSH (cyclic AMP) and EGF + serum (cyclic AMP‐independent) stimulations cooperate and finally converge on proteins that control the cell cycle machinery. This convergence included a common induction of the expression of cyclin A and p34cdc2, and to a lesser extent of p33/38cdk2, which was already expressed in quiescent thyroid cells, and common changes of cdc2 and CDK2 phosphorylations as evidenced by electrophoretic mobility shifts. Kinetic differences in these processes after stimulation by TSH or EGF + serum or by these factors in combination correlated with differences in cell cycle kinetics. Moreover, an immunofluorescence analysis of these proteins using the double labeling of PCNA as a marker of each cell cycle phase shows: (1) a previously undescribed nuclear translocation of CDK2 before S phase initiation; (2) a sudden increase of cdc2 nuclear immunoreactivity at G2/mitosis transition. These data support the roles of CDK2 and cdc2 at G1/S and G2/mitosis transitions, respectively. (3) We were unable to demonstrate in individual cells a strict association between the nuclear appearance of cyclin A and G1/S transition, and an association of cyclin A and CDK2 with PCNA‐stained DNA replication sites. On the other hand, the lengthening of G2 phase in the TSH/cyclic AMP‐dependent thyroid cell cycle was associated with a stabilization of Tyr15 inhibitory phosphorylation of cdc2 and an especially high nuclear concentration of cyclin A and CDK2. We hypothesize that high nuclear accumulation of cyclin A and CDK2 during G2 phase could be causative in the cyclic AMP‐dependent delay of mitosis onset.

c-myc expression is controlled by the mitogenic cAMP-cascade in thyrocytes

In dog thyroid epithelial cells in primary culture, thyrotropin (TSH), acting through cAMP, induces proliferation and differentiation expression, whereas epidermal growth factor (EGF) and phorbol esters induce proliferation and dedifferentiation. In these cells, we have detailed the regulation by cAMP of the c‐myc protooncogene mRNA and protein. The cAMP signaling pathway induces a biphasic increase of c‐myc mRNA and protein. c‐Myc protein accumulation follows the abundance and kinetics of its mRNA expression. Using in vitro elongation of nascent transcripts to measure transcription and actinomycin D (AcD) chase experiments to study mRNA stability, we have shown that in the first phase cAMP releases a transcriptional elongation block. No modification of transcriptional initiation was observed. After 30 min of treatment with TSH, c‐myc mRNA was also stabilized. During the second phase, cAMP stabilization of the mRNA disappears and transcription is again shutt off. Thus, in a tissue in which it stimulates proliferation and specific gene expression, cAMP regulates biphasically c‐myc expression by mechanisms operating at the transcriptional and posttranscriptional levels.

Use of electroblotting to detect and analyze phosphotyrosine containing peptides separated by two-dimensional gel electrophoresis

A technique to detect and analyze phosphotyrosine containing peptides after separation of total cellular proteins by two-dimensional gel electrophoresis is described. This is achieved by electroblotting of proteins on nylon membranes followed by alkali treatment. In comparison with direct alkali treatment of the polyacrylamide gel, this procedure is easier to perform; avoids the diffusion of proteins out of the gel during alkali treatment; allows a more precise localization of phosphotyrosine containing peptides on the untreated membrane; and is less time consuming with respect to extraction of proteins for phosphoamino acid analysis.

Intermediate filaments in normal thyrocytes: modulation of vimentin expression in primary cultures

In dog thyrocyte primary cultures, the antagonistic effects of thyrotropin (TSH) and epidermal growth factor (EGF) on differentiation expression were accompagnied by distinct long-term morphological changes: TSH-treated cells showed an epitheloid morphology; EGF reversibly induced a fusiform shape. Using indirect immunofluorescence microscopy and two-dimensional gel electrophoresis, we studied the modifications in the distribution and synthesis of the intermediate filament proteins of the cytoskeleton in response to TSH and EGF. These factors had little effect on the expression of cytokeratins 8 and 18, which were expressed in 98% of cells. However, TSH induced a profound redistribution of cytokeratins (and actin) with the appearance of a marked staining of cell junctions. Vimentin was coexpressed with cytokeratins in about 40% of cells from normal thyroid follicles freshly isolated by collagenase. During culture, immunostained vimentin network progressively developed in 90% of control and EGF-treated cells simultaneously with vimentin synthesis. In contrast, only 20% of TSH-treated cells reacted with vimentin antibody and we observed a marked decrease in vimentin synthesis in response to TSH. Therefore, vimentin synthesis, which should occur in at least some normal thyroid follicles in vivo, was inhibited in vitro by TSH which promotes differentiation expression. However, EGF-treated cells thereafter cultured with TSH regained an epitheloid morphology and differentiation in spite of the persistency of a complete network of vimentin.

The use of L-[35S]methionine and L-[75Se]selenomethionine for double-label autoradiography of complex protein patterns on two-dimensional polyacrylamide gels: a drastic shortening of the exposure time.

Abstract A method of autoradiography that allows discrimination between 35S- and 75Se-labeled material on polyacrylamide gels is described. It involves the incorporation of l -[35S]methionine and l -[75Se]selenomethionine into proteins. The autoradiographic exposure times are decreased at least sixfold with regard to the previously described techniques using 3H- and 14C-labeled proteins.

Transducing Systems in the Control of Human Thyroid Cell Function, Proliferation and Differentiation

Our laboratory has been involved in the study of thyroid regulation at the cellular level for many years. The complex picture emerging from these studies leads to conclusions of general relevance. The regulation of the thyroid cell was once a classical example of the concept one hormone — one cell type — one intracellular secondary messenger with its pleiotypic effects. It should now rather be considered as a network of crosslinked regulatory steps where the extracellular and intracellular signal-molecules act on their receptors as bits of information in an electronic circuit, i.e., express on/off regulations with no definite general physiological meaning per se. Such networks differ from one cell type to another and for a given cell type from one species to another. In the case of the thyroid many apparent discrepancies in the literature are explained if this is taken into account. In this presentation, we wish to draw mainly on the results of our group to illustrate this point with regard to the regulation of function, proliferation and differentiation of the thyroid cell.