Cyclic nucleotide metabolism in differentiated and undifferentiated epithelial thyroid cells in culture

Effects of sodium ions on rat thyrocyte (FRTL-5 cells) swelling- and thyrotropin-activated taurine efflux dependent on cAMP and Epac

Cellular osmolyte release is important in preventing water accumulation and swelling. However, the signaling pathways that detect volume increase and activate solute efflux are still not fully understood. We investigated efflux activation of the osmolyte taurine which is actively accumulated in rat thyrocytes (FRTL-5). Efflux of accumulated [(3)H]taurine was stimulated by cellular swelling and thyrotropin (TSH). These effects were significantly diminished in cells having reduced TSH receptor concentrations. Phosphodiesterase inhibitors (IBMX, Rolipram) enhanced both responses. An analog of forskolin (FSK; 7-deacetyl-7-[O-(N-methylpiperazino)-γ-butyryl] dihydrochloride) and an analog of cAMP, specific for activating exchange protein activated directly by cAMP (Epac; 8-(4-chlorophenylthio)-2'-O-methyladenosine-3',5'-cyclic monophosphate, acetoxymethyl ester), significantly stimulated [(3)H]taurine efflux. A cAMP analog specific for activating protein kinase A (PKA; N6-benzoyladenosine-3',5'-cyclic monophosphate, acetoxymethyl ester) had no significant stimulatory effect on [(3)H]taurine efflux rate. The amiloride analog, 5-(N-ethyl-N-isopropyl)-amiloride, which inhibits a TSH-stimulated Na(+)/H(+) exchanger, enhanced (100 %) and ouabain inhibited (50 %) the TSH-stimulated [(3)H]taurine efflux rate. The effect of FSK on efflux was strongly potentiated by Na(+)-free iso-osmotic conditions and by osmolality/cell volume that affected also the db-cAMP-stimulated efflux. The TSH receptors and downstream elements of the signaling pathway comprising adenylyl cyclase, cAMP and Epac appeared to mediate the hormone-induced signal for [(3)H]taurine efflux from FRTL-5 cells. With less evidence, the cell volume/osmolality-induced [(3)H]taurine efflux cascade appeared to share some of the hormone signaling elements and to modulate the hormone signaling pathway at two levels through cellular Na(+).

Transfection with the cDNA of the human thyrotropin receptor of a poorly differentiated rat thyroid cell line (FRT)

A cell line derived from the Fisher rat thyroid (FRT), that does not have functional TSH receptor, was stably transfected with the cDNA of the human TSH receptor (h TSH-R). In wild FRT cells TSH (1-1000 mU/l) was unable to increase cAMP production, while 10-10000 nmol/l forskolin elicited a 10-30 fold cAMP stimulation. Two of the transfected clones were responsive to TSH in terms of cAMP production. In particular, the FRT-R3 transfected clone showed the highest sensitivity to the hormone with a 10 fold cAMP increase over the basal at 100 mU/l TSH. The Northern blot analysis using a 2.4 kbp cDNA probe for the hTSH-R showed a band corresponding to the mRNA of TSH receptor in FRT-R3 cells, but not in wild FRT cells. In both cell types TSH was ineffective in stimulating growth assayed by 3H-thymidine incorporation into DNA. Hybridization with a probe for thyroperoxidase on polymerase chain reaction products after reverse transcription of mRNA showed that FRT-R3, as well as FRT cells, do not have a transcript for thyroperoxidase. In conclusion, the data reported in this paper show that the insertion of the hTSH-R cDNA in the genome of poorly differentiated rat thyroid cells results in the recovery of TSH-dependent adenylate cyclase, but not other differentiated thyroid cell functions.

Adenylate cyclase activity of v-ras-k transformed rat epithelial thyroid cells

The regulation of adenylate cyclase has been analyzed in normal rat thyroid cells as well as in the same cells transformed by the v-ras-k oncogene. In both cell types the adenylate cyclase complex consists of the two GTP-binding proteins, Gi and Gs, as demonstrated by the specific ADP-ribosylation induced by pertussis and cholera toxin, respectively. The response of adenylate cyclase of the transformed cells to forskolin, pertussis toxin and cholera toxin is attenuated with respect to the control cell line. The thyrotropic hormone (TSH), that acts on normal thyroid cells in culture as a growth factor by stimulating the adenylate cyclase activity, is not able to induce DNA synthesis nor does it stimulate adenylate cyclase in v-ras-k transformed cells.

125I uptake by FRTL5 cells: a screening test to detect pregnant women at risk of giving birth to hypothyroid infants

Thyroid-growth-blocking antibodies are present in large proportion of mothers who give birth to hypothyroid infants. In order to devise a prenatal screening test to replace the time-consuming cytobiochemical assay for measurement of the maternal antibodies, a cloned rat-thyroid cell-line (FRTL5) was used. Several approaches that had been tried previously had proved fruitless--eg, in FRTL5 cells immunoglobulin of mothers of affected infants did not displace 125I-labelled TSH from its receptor, did not block TSH-induced increase of cyclic AMP, and did not block TSH-induced 3H-thymidine incorporation. By use of 125I uptake by the cells, mothers of the hypothyroid children were readily distinguished from normal female subjects and normal pregnant women.

Monoclonal antibodies to the thyrotropin receptor: the identification of blocking and stimulating antibodies

Monoclonal antibodies to the thyrotropin (TSH) receptor have been obtained from fusions of mouse myeloma cells with spleen cells immunized with solubilized thyroid membrane preparations. Two monoclonal antibodies which inhibit 125I-TSH binding and are reactive with the glycoprotein component of the bovine TSH receptor (11E8 and 13D11), are shown to inhibit basal and TSH stimulated adenylate cyclase activity in bovine thyroid membranes and human thyroid cells. Both antibodies also inhibit 125I-TSH binding in vitro, whether binding is measured at pH 6.0 in low salts and at 0-4 C or at pH 7.4 in 50 mM NaCl and at 37 C. The glycoprotein component is thus a portion of the physiologic TSH receptor in vivo and 125I-TSH binding studies apparently measure the high affinity glycoprotein component under nonphysiologic conditions and conditions more representative of the physiologic milieu. A third monoclonal antibody whose interaction with thyroid membranes is prevented by TSH is shown to stimulate adenylate cyclase activity in bovine thyroid membranes and human thyroid cells. This stimulating antibody only weakly inhibits 125I-TSH binding to thyroid membranes or to the glycoprotein component of the TSH receptor. The 22A6 antibody does, however, immunoprecipitate mixed brain gangliosides, in distinct contrast to the monoclonal antibodies to the glycoprotein receptor component, i.e., 11E8 and 13D11. The results support the speculation that autoimmune antibodies which inhibit TSH binding to thyroid membranes are not necessarily identical to antibodies which stimulate function; that antibodies directed at the high affinity initial site of TSH interaction with a cell can behave as blocking rather than stimulating antibodies and that a possible relationship exists between stimulating antibodies and the low affinity TSH binding sites (gangliosides) on thyroid membranes.

Interferon interactions with thyroid cells

Iodide uptake by functioning rat thyroid (FRTL) cells is increased by mouse interferon. The effect is detectable using purified interferon; it is not accompanied by an increase in intracellular cyclic AMP levels, is measurable within 20 min, and is prevented by cholera toxin, an agent which inhibits interferon's antiviral activity. The effect of interferon is biphasic with maximally increased iodide uptake (approximately 2-fold) evident at about 300 international mouse units per ml (U/ml) and lesser effects evident at higher concentrations (greater than 1000 U/ml). The effect of mouse interferon on iodide uptake is accompanied by an extremely sensitive antiviral response. Thus, significant antiviral protection is evident at 1 U/ml with FRTL cells, as opposed to 1000 U/ml for nonfunctioning rat thyroid (FRT) cells. Functioning FRTL thyroid cells are also more sensitive to mouse interferon (10-fold) with respect to 2',5'-polyadenylate (An) synthetase activity or to 125I-thyrotropin binding to membrane preparations than are nonfunctioning FRT cells. Antiviral protection in FRTL cells is evident as early as 1 h after exposure to mouse interferon, and is accompanied by a nearly 100-fold increase in the measurable titer of 2'5'-An synthetase activity. Actinomycin D blocks the antiviral effect of interferon, but not its effect on iodide uptake. The results are discussed with respect to the unusually sensitive response of heterologous (rat) cells to mouse interferon: a possible relationship between thyrotropin and interferon receptors; and, the difference in interferon sensitivity exhibited by differentiated (functioning) as opposed to undifferentiated (nonfunctioning) thyroid cells.