We have investigated the growth effects of thyrotropin (TSH) (mimicked by forskolin and acting through cyclic AMP), epidermal growth factor (EGF), serum (10%) and insulin on quiescent dog thyroid epithelial cells in primary culture in a serum-free defined medium. These cells were previously shown to retain the capacity to express major thyroid differentiation markers. In the presence of insulin and after a similar prereplicative phase of 18 +/- 2h, TSH, EGF, and serum promoted DNA synthesis in such quiescent cells only a minority of which had proliferated in vitro before stimulation. The combination of these factors induced more than 90% of the cells to enter S phase within 48 h and near exponetial proliferation. Analysis of the cell cycle parameters of the stimulated cells revealed that the G1 period duration was similar to the length of the prereplicative phase of quiescent thyroid cells; this might indicate that they were in fact in an early G1 stage rather than in G0 prior to stimulation. TSH and EGF action depended on or was potentiated by insulin. Strikingly, nanomolar concentrations of insulin were sufficient to support stimulation of DNA synthesis by TSH, while micromolar concentrations of insulin were required for the action of EGF. This suggests that insulin supported the action of TSH by acting on its own high affinity receptors, whereas its effect on EGF action would be related to its somatomedinlike effects at high supraphysiological concentrations. Insulin stimulated the progression in the prereplicative phase initiated by TSH or forskolin. In addition, in some primary cultures TSH must act together with insulin to stimulate early events of the prereplicative phase. In the presence of insulin, EGF, and forskolin, an adenylate cyclase activator, markedly synergized to induce DNA synthesis. Addition of forskolin 24 h after EGF or EGF 24 h after forskolin also resulted in amplification of the growth response but with a lag equal to the prereplicative period observed with the single compound. This indicates that events induced by the second factor can no longer be integrated during the prereplicative phase set by the first factor. These findings demonstrate the importance of synergistic cooperation between hormones and growth factors for the induction of DNA synthesis in epithelial thyroid cells and support the proposal that essentially different mitogenic pathways--cyclic AMP-dependent or independent--may coexist in one cell.
We have developed serum-free primary cultures of differentiated follicular dog thyroid cells which allow the study of the hormonal control of cell proliferation. The cooperation of insulin and increasing cellular cyclic AMP by thyrotropin triggers the DNA synthesis and the proliferation. Dog thyroid cells are an example of a system in which cyclic AMP is a sufficient signal to stimulate the proliferation in quiescent cells.
Thyroid
Twenty four hours after i.p. injection of 17 beta-estradiol (E2) (500 micrograms/100 g b.w.) to ovariectomized rats, the hepatocytes [3H]-thymidine pulse-labeling index (L.I.) was significantly increased, reaching a value of 4.3 +/- 1.6 percent (i.e. much lower than 32.0 +/- 2.0 percent 24 h. after partial hepatectomy -PH-). E2-treatment was followed by an increase in liver content in c-myc transcripts, with a peak at 650 percent basal value at 8 h, very similar to that observed after PH. In contrast, E2 induced an increase in liver c-Ha-ras expression with a similar time-course evolution but markedly lower amplitude than that seen after PH. These data are consistent with a role of c-myc in proliferative competence i.e. the ability to perform the Go-G1 transition, and with a role of c-ras in further progression of the cells in the cycle.
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