Thyroid hormone regulation of rat hepatocyte proliferation and polyploidization.

The liver of adult mammals contains various classes of polyploid hepatocytes produced by a process that is partially regulated by hormones. However, it is not well understood how the hormones affect the rate of hepatocyte proliferation under physiological conditions. Here we have studied the specific roles of 3,5,3'-triiodothyronine (T3), growth hormone (GH), and sex steroids on the percentage of diploid nuclei in S phase and on the population of liver tetraploid (4C) cell nuclei in several rat model systems. Gonadal steroids had no effect on the S phase but account for gender differences in the 4C nuclei. Hypophysectomy in adult male rats produced a moderate decrease in 4C nuclei that was reversed by treatment with 25 micrograms T3. kg-1. day-1, whereas treatment with 200 micrograms human recombinant GH (hGH). kg-1. day-1 was ineffective. Rats made hypothyroid by methimazole treatment of dams and pups until death showed a low S phase and only 5% of 4C nuclei at 70 days of age. T3 significantly increased the S phase 24 h after administration and restored the adult normal level of 4C nuclei after 10 days of treatment. hGH did not affect the 4C nuclei or the S phase in the hypothyroid rats. These results suggest that the processes of hepatocyte proliferation and polyploidization of the rat liver are under endocrine control, with thyroid hormones playing the essential regulatory role.

Estrogen antagonism on T3 and growth hormone control of the liver microsomal low-affinity glucocorticoid binding site (LAGS).

Male rat liver microsomes contain a low-affinity glucocorticoid binding site (LAGS) capable of binding all natural glucocorticoids and progesterone with a Kd from 20 to 100 nM. The LAGS level is under endocrine control by T3, glucocorticoids and GH. These hormones act synergistically at physiological concentrations to increase the LAGS level. Since female rats show a LAGS level that is much lower than the males (0.15 vs 23 pmol/mg protein, respectively), here we investigated whether estradiol could decrease the LAGS in the male rat. Orchiectomized (OX) male rats showed a higher LAGS level than intact rats. This effect was reversed by implanting a Sylastic capsule containing testosterone. When the OX rats were implanted for 20 days with estrogen capsules that provided an estradiol level in serum of 40 pg/ml, their LAGS level decreased from 23 to 0.2 pmol/mg protein. This effect was not observed in intact male rats and can be partially reversed by testosterone implants into OX rats. Both hypophysectomized male rats and hypothyroid-orchiectomized male rats showed very low levels of LAGS. Administration of physiological doses of GH and/or T3 to these rats greatly increased their LAGS level (from 0.3 to 15 and 16 pmol/mg protein, respectively). Implantation of estrogen capsules to these rats two weeks prior to starting treatment completely inhibited the increase in the LAGS level in response to T3, and significantly decreased the response to hGH, and to a combination of hGH and T3. These results suggest that physiological estradiol levels can antagonize the LAGS induction by T3 and hGH in the male rat, and could be responsible for the low level of LAGS in the female rat. Moreover, estrogen capsules also inhibited the increase in the body and hepatic weights observed after hGH treatment, which suggests a powerful inhibitory effect of low estradiol levels on the male rat liver functions under regulation by T3 and/or GH.

Age-related changes in the induction of tyrosine aminotransferase by dexamethasone: correlation with the low-affinity glucocorticoid binding sites.

Rat liver membranes contain Low-affinity glucocorticoid binding sites (LAGS), capable of binding with low affinity (Kd approximately 100 nM) endogenous glucocorticoids. Unlike the glucocorticoid receptor (GR), the LAGS level undergoes abrupt changes throughout life. The investigation of these changes may be useful in determining whether the LAGS are involved in the cellular response to glucocorticoids. For this purpose, we have studied glucocorticoid induction of tyrosine aminotransferase (TAT), and its relationship with the LAGS level in adrenalectomized and fasted rats of different ages. No significant differences in the GR level, or in its Kd and activation, were observed among rats of 1, 3, and 12 months of age. On the other hand, the LAGS level showed an important variation with age, from almost undetectable in 1-month-old rats, to a maximum value in 3-month-old rats. With respect to TAT activity, an increase with age in the threshold of response to dexamethasone (DEX) administration was observed. The smallest dose of DEX capable of provoking a significant TAT induction rose from 0.1 microgram/kg body wt. in 1-month-old rats to 10 micrograms/kg body wt. in 12-month-old rats. However, the smallest dose of DEX able to elicit the maximal response was 10 micrograms/kg body wt. in all the assayed ages. This dose provoked a 40% decrease in the GR level, but did not significantly modify the LAGS content. From these results, we conclude that there is an age-related change in the threshold of response to DEX that cannot be explained by the GR-glucocorticoid interaction. The possibility that the LAGS modulate the cell response to glucocorticoids arises from the coincidence of this change with that observed in the LAGS concentration throughout life.

The role of growth hormone in regulation of low affinity glucocorticoid-binding sites from male rat liver microsomes.

GH participates in the regulation of the expression of several hepatic proteins, some of which are subject to multihormonal control. We have previously shown the participation of glucocorticoids and thyroid hormones in the regulation of the hepatic low affinity glucocorticoid-binding sites (LAGS). Here, we provide evidence that also implicates GH in the endocrine control of the LAGS through the use of several animal models, all of them having a very low or undetectable plasma GH level: the hypothyroid (TX), the hypophysectomized, and the GH-deficient Lewis-derived dwarf rat. In dwarf rats, the level of LAGS was only 35% of that found in normal Lewis rats. Treatment of these rats with human (h) GH significantly increased the LAGS level in a dose-response manner. In TX rats, hGH treatment provoked a significant increase in the LAGS level (from 0.9 +/- 0.2 to 7.2 +/- 0.8 pmol/mg protein), so that it represented about 65% of the level found in intact animals. In both hypothyroid-adrenalectomized and hypophysectomized rats, the isolated effect of hGH was not as pronounced as in TX or dwarf rats; however, a potentiation of the effect of hGH was observed when this hormone was injected together with corticosterone acetate. On the other hand, when hGH, T3, and corticosterone acetate were given in combination to hypophysectomized rats, hGH and T3 behaved as agonists of the LAGS induction at T3 doses lower than or equal to 0.1 microgram/100 g BW and as antagonists at T3 doses higher than this. When T4 was used instead of T3, this hormone was capable of potentiating the effect of hGH at doses lower than or equal to 1.5 micrograms/100 g BW. From these results we conclude that 1) GH as well as thyroid and glucocorticoid hormones participate in the endocrine regulation of the LAGS; and 2) under physiological conditions, it is conceivable that GH, thyroid hormones, and glucocorticoids act synergistically in the endocrine regulation of the LAGS.