Heat stress and hydrocortisone are independent stimulators of triiodothyronine-induced growth hormone production in cultured rat somatotrophic tumour cells.

We have reported that, in cultured GC cells, the stress of incubation at 41 degrees C enhances thyroid hormone stimulation of growth hormone (GH) in a manner similar to the effects observed in a model of nonthyroidal disease in rats. Since glucocorticoids are potentially involved in stress responses both in vivo and in cell culture, we studied the role of glucocorticoid in the enhancement of (which are rat somatotrophic tumor cells) triiodothyronine (T3)-induced GH synthesis due to heat stress. Hydrocortisone addition increased T3-induced GH synthesis and GH mRNA content in cultured GC cells at both 37 degrees C and 41 degrees C. Depletion of glucocorticoid endogenous to serum supplement of the tissue culture medium did not prevent the enhancement of T3-induced GH synthesis that occurred during incubation at 41 degrees C. The levels and affinity of glucocorticoid cytosolic receptors were not enhanced during incubation at 41 degrees C. Lastly, no change in the sedimentation coefficient of the cytosolic glucocorticoid receptor or in its translocation into the nucleus occurred during incubation at 41 degrees C. Thus, the enhancement of T3-induced GH production in GC cells by heat stress appeared independent of the effect of glucocorticoids and not mediated through glucocorticoid receptors.

Differential response to L-triiodothyronine of anterior pituitary growth hormone messenger ribonucleic acid (mRNA) and beta-thyrotropin mRNA in a hypothyroid Walker 256 carcinoma-bearing rat model of nonthyroidal disease.

To continue our studies on the influence of T3 on TSH regulation in the Walker 256 carcinoma-bearing rat model of nonthyroidal disease, we measured the effect of T3 on pituitary content of beta TSH mRNA and rat (r) TSH in hypothyroid control (C) and tumor-bearing (T) rats. The effect of T3 on TSH regulation was compared to effects on GH mRNA and rGH in the same animals. mRNA content was normalized to a pool of pituitaries from euthyroid rats (= 1.0). beta TSH mRNA increased 18-fold in both hypothyroid C and T rats and then decreased similarly with increasing T3 infusion to a value of 0.1. GH mRNA content decreased to 0.11 +/- 0.01 in hypothyroid C rats, but to only 0.38 +/- 0.02 in T rats (P less than 0.001). The pituitary contents of GH mRNA and rGH in hypothyroid T rats was significantly greater than those in C rats at all T3 infusion rates. These data together with our previous report of decreased nuclear T3 in T rats suggest that regulation of beta TSH mRNA by T3 is intact in T rats, but occurs at a lower concentration of nuclear T3. In contrast, the GH mRNA response is enhanced, displaying differential regulation of these two T3-responsive gene products in this model of nonthyroidal illness.

Decreased anterior pituitary T3 nuclear receptors in a Walker 256 carcinoma-bearing rat model of nonthyroidal disease.

Rats bearing the Walker 256 carcinoma have decreased pituitary nuclear T3 but normal pituitary TSH content and response to experimental hypothyroidism. To elucidate further the role of T3 receptor occupancy and biological response in the tumor-bearing rat model of nonthyroidal disease, we measured the concentration of T3 nuclear receptors, rTSH and rGH and beta-TSH mRNA and GH mRNA in the anterior pituitary of euthyroid rats bearing the Walker 256 carcinoma. The abundance of T3 nuclear receptors was decreased in tumor-bearing rats and was associated with a decrease in mRNA content for beta-TSH and GH. alpha-tubulin mRNA was decreased to a comparable degree. The pituitary content of rTSH and rGH was, however, the same as in control animals. Since tumor rats have normal regulation of TSH secretion by thyroid hormone, the present findings suggest that TSH secretion in T rats is maintained by a lower T3 nuclear receptor occupancy than in controls. The decrease in beta-TSH mRNA may precede a decrease in TSH synthesis and changes in pituitary TSH stores. Since the decrease in GH mRNA was comparable to the decrease in alpha-tubulin mRNA, it does not appear to be specifically related to decreased T3 nuclear receptor occupancy. We conclude that, in the tumor-bearing rat model of nonthyroidal disease, decreases in beta-TSH mRNA occur despite a decreased T3 receptor occupancy. Both thyroid-dependent and thyroid-independent factors may be involved in regulating beta-TSH mRNA.

Heat shock of cultured GC cells enhances the level of triiodothyronine induced growth hormone (GH) and GH messenger ribonucleic acid.

We have previously proposed that the effects of heat shock on thyroid hormone-responsive rat pituitary tumor (GC) cells may be a model relevant to the in vivo effects of nonthyroidal disease on thyroid hormone action. To determine the effects of heat shock on thyroid hormone responses, GC cells (normally cultured at 37 C) were studied after incubation at 41 C. After 18 h at 41 C there was enhanced synthesis of proteins (mol wt, 70,000 and 90,000) considered to be universal markers of the cellular response to heat shock. Incubation at 41 C also resulted in a significant decrease in GC cell viability and (after 24 h) arrest of GC cell growth. However, the induction of GH synthesis by T3 was significantly enhanced in GC cells stressed by incubation at 41 C. The addition of 5 nM T3 to thyroid hormone-depeleted GC cells resulted in a significantly greater (P less than 0.001) accumulation of GH (2642 +/- 280 ng/18 h) during 41 C incubation than during 37 C incubation (1223 +/- 175 ng/18 h). The enhanced T3-induced production of GH was coincident with a proportional increase (P less than 0.05) in cellular GH mRNA determined by dot hybridization analysis. Thus, the stress of 41 C incubation elicits a heat shock response in GC cells characterized by decreased viability and growth arrest, but enhanced accumulation of GH mRNA in response to T3. Our recent report on the identical effects due to the stress of implantation of the Walker 256 carcinoma on T3-induced rat pituitary GH mRNA in vivo suggests that heat shock of cultured GC cells is a valid in vitro model of nonthyroidal disease.

3,5,3'-Triiodothyronine determines the viability of GC cells after heat shock.

The heat shock (HS) response is a characteristic disruption of protein synthesis which occurs in cells exposed to a variety of noxious stimuli. The effects of HS on thyroid hormone-responsive GC cells were studied in an attempt to devise an in vitro model for the adaptive changes in thyroid hormone action caused by nonthyroidal disease. HS enhanced GC cell synthesis of 70 K and 90 K proteins in a manner previously described as characteristic of the HS response in many tissues. A step-wise decrease in GC cell viability occurred when cells were exposed to 45 C for 10 to 35 min. HS (45 C, 20 min) resulted in a rapid decrease in binding of T3 to nuclear receptors. Two hours after HS, analysis of T3 binding to isolated nuclei showed a 50% fall in binding capacity (240 fmol/100 micrograms DNA) compared to non-HS control cells (540 fmol/100 micrograms DNA); no difference in dissociation constant (Kd) was observed. The effect of thyroid hormone on cell viability after HS was then determined. Thyroid hormone depletion (less than or equal to 0.02 nM T3) resulted in significantly (P less than 0.05) enhanced cell viability compared to cells cultured with physiological T3 (0.2 nM) after incubation at 45 C for intervals of 10-35 min. This inverse relationship between medium T3 content and cell tolerance of HS occurred over a wide range of T3 concentrations. Mean cell viability after exposure to 45 C for 20 min was 44 +/- 3% in T3-depleted cultures (less than or equal to 0.02 nM), 27 +/- 1% to 32 +/- 5% in cultures containing 0.07-0.5 nM T3, and 13 +/- 3% in cultures containing 5 nM T3. Our results thus characterize the response to HS in GC cells and the relationship of this response to medium T3. Similar to the effect of various nonthyroidal diseases on rat hepatocytes in vivo, HS resulted in a decrease in T3 nuclear receptors. Similar to the adverse effect of thyroid hormone on morbidity in animals with experimental diseases or injury, GC cell viability after HS was inversely related to medium T3 content. Thus the HS response in GC cells may be a valuable in vitro model relevant to the effect on thyroid hormone action caused by nonthyroidal disease.