Thyroid hormone stimulation of NADPH P450 reductase expression in liver and extrahepatic tissues. Regulation by multiple mechanisms.

The role of thyroid hormone in regulating the expression of the flavoprotein NADPH cytochrome P450 reductase was studied in adult rats. Depletion of circulating thyroid hormone by hypophysectomy, or more selectively, by treatment with the anti-thyroid drug methimazole led to a 75-85% depletion of hepatic microsomal P450 reductase activity and protein in both male and female rats. Thyroxine substantially restored P450 reductase activity at a dose that rendered the thyroid-depleted rats euthyroid. Microsomal P450 reductase activity in several extrahepatic tissues was also dependent on thyroid hormone, but to a lesser extent than in liver (30-50% decrease in kidney, adrenal, lung, and heart but not in testis from hypothyroid rats). Hepatic P450 reductase mRNA levels were also decreased in the hypothyroid state, indicating that the loss of P450 reductase activity is not a consequence of the associated decreased availability of the FMN and FAD cofactors of P450 reductase. Parallel analysis of S14 mRNA, which has been studied extensively as a model thyroid-regulated liver gene product, indicated that P450 reductase and S14 mRNA respond similarly to these changes in thyroid state. In contrast, while the expression of S14 and several other thyroid hormone-dependent hepatic mRNAs is stimulated by feeding a high carbohydrate, fat-free diet, hepatic P450 reductase expression was not increased by this lipogenic diet. Injection of hypothyroid rats with T3 at a supraphysiologic, receptor-saturating dose stimulated a major induction of hepatic P450 reductase mRNA that was detectable 4 h after the T3 injection, and peaked at approximately 650% of euthyroid levels by 12 h. However, this same treatment stimulated a biphasic increase in P450 reductase protein and activity that required 3 days to reach normal euthyroid levels. T3 treatment of euthyroid rats also stimulated a major induction of P450 reductase mRNA that was maximal (12-fold increase) by 12 h, but in this case no major increase in P450 reductase protein or activity was detectable over a 3-day period. Together, these studies establish that thyroid hormone regulates P450 reductase expression by pretranslational mechanisms. They also suggest that other regulatory mechanisms, which may involve changes in P450 reductase protein stability and/or changes in the translational efficiency of its mRNA, are likely to occur.     

Regulation of 3-hydroxy-3-methylglutaryl coenzyme A reductase mRNA levels by L-triiodothyronine

In hypophysectomized rats, hepatic 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase activity, immunoreactive 97-kilodalton (97-kDa) protein, and mRNA were all reduced to undetectable levels. Administration of triiodothyronine (T3) resulted in large increases in all three after a 36-h lag period. HMG-CoA reductase activity, immunoreactive 97-kDa protein levels, and reductase mRNA levels were tightly correlated. Feeding hypophysectomized rats diets containing the bile acid sequestrant colestipol, together with the potent reductase inhibitor mevinolin, resulted in an increase in HMG-CoA reductase activity similar to that seen with T3 but a lesser stimulation of reductase mRNA levels. These results suggest that agents which cause depletion of mevalonate-derived products may share in part with T3 a common mechanism for increasing levels of HMG-CoA reductase activity in order to satisfy cellular needs for these products. Dexamethasone treatment, which is known to prevent the T3-mediated stimulation of reductase activity, caused a marked decrease in 97-kDa immunoreactive material but had little effect on reductase mRNA levels.     

Diurnal rhythm of rat liver mRNAs encoding 3-hydroxy-3-methylglutaryl coenzyme A reductase. Correlation of functional and total mRNA levels with enzyme activity and protein

Rat liver 3-hydroxy-3-methylglutaryl coenzyme A reductase exhibits a diurnal rhythm of activity which coincides with a diurnal rhythm of reductase protein and reductase mRNA levels. This diurnal rhythm of reductase activity, polypeptide mass, and mRNA exists in rats fed a normal diet (unsupplemented rat chow) and in rats fed a diet supplemented with cholestyramine plus or minus mevinolin. Levels of reductase protein were determined by 8 M urea/sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting. Reductase mRNA was measured by in vitro translation or blot hybridization of liver RNA. Functional reductase mRNA levels in rats fed a normal diet were approximately 10-fold higher during the middle of the dark cycle than during the middle of the light cycle. Maximum induction of functional reductase mRNA was observed in rats fed cholestyramine and mevinolin. This latter level was 157-fold higher than the level measured at the diurnal low point in rats fed a normal diet. Blot hybridization of liver RNA showed two predominant mRNAs of 4.6 and 4.2 kilobase pairs and a minor species at 6.9 kilobase pairs. These mRNAs exhibited a diurnal rhythm for rats on all three diets and reached peak levels during the 12-h dark period. These data indicate that the diurnal rhythm of reductase mass and activity is closely paralleled by the level of its mRNA.     

Thyroid hormone regulation of messenger ribonucleic acid encoding thyrotropin (TSH)-releasing hormone is independent of the pituitary gland and TSH

Cellular levels of mRNA encoding pro TRH in the rostral paraventricular nucleus are reduced by thyroid hormones. To determine whether this regulatory effect of thyroid hormones requires a functional pituitary gland or, specifically, TSH, we examined the effect of T3 on proTRH mRNA in hypophysectomized, thyro-parathyroidectomized male rats with or without bovine TSH replacement. Hypophysectomy plus thyro-parathyroidectomy reduced serum T4 and TSH to undetectable levels in all animals and elevated TRH mRNA in the paraventricular nucleus over that of sham-operated animals. Eleven consecutive daily injections of T3 significantly reduced TRH mRNA levels in both sham controls and thyro-parathyroidectomized rats. However, 11 daily injections of bovine TSH (1 U/day) failed to alter the effect of T3 on TRH mRNA levels. These results demonstrate that the regulatory influence of thyroid hormones on the biosynthesis of TRH within the thyrotropic center of the brain is independent of the pituitary gland and of TSH.     

Multihormonal regulation of hepatic sinusoidal Ntcp gene expression

Bile acids are efficiently removed from sinusoidal blood by a number of transporters including the Na+-taurocholate-cotransporting polypeptide (Ntcp). Na+-dependent bile salt uptake, as well as Ntcp, are expressed twofold higher in male compared with female rat livers. Also, estrogen administration to male rats decreases Ntcp expression. The aims of this study were to determine the hormonal mechanism(s) responsible for this sexually dimorphic expression of Ntcp. We examined castrated and hypophysectomized rats of both sexes. Sex steroid hormones, growth hormone, thyroid, and glucocorticoids were administered, and livers were examined for changes in Ntcp messenger RNA (mRNA). Ntcp mRNA and protein content were selectively increased in males. Estradiol selectively decreased Ntcp expression in males, whereas ovariectomy increased Ntcp in females, confirming the importance of estrogens in regulating Ntcp. Hypophysectomy decreased Ntcp mRNA levels in males and prevented estrogen administration from decreasing Ntcp, indicating the importance of pituitary hormones. Although constant infusion of growth hormone to intact males reduced Ntcp, its replacement alone after hypophysectomy did not restore the sex differences. In contrast, thyroid hormone and corticosterone increased Ntcp mRNA in hypophysectomized rats. Sex differences in Ntcp mRNA levels were produced only when the female pattern of growth hormone was administered to animals also receiving thyroid and corticosterone. Thyroid and dexamethasone also increased Ntcp mRNA in isolated rat hepatocytes, whereas growth hormone decreased Ntcp. These findings demonstrate the essential role that pituitary hormones play in the sexually dimorphic control of Ntcp expression in adult rat liver and in the mediation of estrogen effects.     

Dietary and hormonal regulation of L-type pyruvate kinase gene expression in rat small intestine

L-type pyruvate kinase is an enzyme of the glycolytic pathway whose activity and mRNA levels fluctuate in the small intestine according to dietary status. Both the enzyme activity and mRNA concentration decline during fasting and increase upon refeeding either a glucose-rich or a fructose-rich diet. Using a single-strand M 13 phage complementary to L-type pyruvate kinase mRNA as probe, we determined the level of the mRNA in the small intestine of normal, adrenalectomized, thyroidectomized, diabetic and glucagon-treated or cAMP-treated animals refed either a glucose-rich or a fructose-rich diet. The specific mRNA is present in the small intestine of normal fasted rats and increases twofold and threefold on refeeding glucose and fructose respectively. However, the hormonal control of the gene expression differs according to the dietary carbohydrate. The L-type pyruvate kinase mRNA increase, induced by glucose feeding, is hormone-dependent and requires the presence of thyroid hormones and insulin. In fructose-fed rats a certain level of mRNA increase occurs regardless of the hormonal status of the animals, but the full induction of the mRNA by fructose requires the presence of glucocorticoids, thyroid hormones and insulin. Thus, the hormonal regulation of L-type pyruvate kinase gene expression in the small intestine is largely similar to that described in normal rat liver but the basal mRNA level and the stimulation of the mRNA increase by fructose are higher in the small intestine.     

Regulation of hepatic beta-hydroxy-beta-methylglutaryl coenzyme A reductase by the interplay of hormones

We have previously established that insulin causes a marked and rapid stimulation of hepatic β-hydroxy-β-methylglutaryl coenzyme A reductase activity in normal and diabetic rats [Biochem. Biophys. Res. Commun.50, 504 (1973)], whereas l-triiodothyronine stimulates the reductase activity to supranormal levels in hypophysectomized rats two days after administration [Proc. Nat. Acad. Sci. (1974) In press]. In the present investigation it is demonstrated that the stimulation of the reductase activity in hypophysectomized-diabetic rats requires the mediation of both insulin and l-triiodothyronine. Neither hormone alone is effective. The rapid stimulation of reductase activity by insulin and the delayed stimulation elicited by l-triiodothyronine are both inhibited by either glucagon or hydrocortisone. Thus, an interplay of hormones regulates reductase activity and consequently cholesterol biosynthesis.     

Quantitative modulation of thyroid iodide peroxidase by thyroid stimulating hormone

The activity of rat thyroid iodide peroxidase fell to 8% of the normal value 48 hours after hypophysectomy. Rats given injections of thyroid stimulating hormone manifested an enzyme activity indistinguishable from that of the sham-operated animals. Cycloheximide prevented the thyroid stimulating hormone-induced restoration of the enzyme activity. The incorporation of ¹⁴C-leucine into the thyroid gland decreased gradually and reached two thirds of the sham-operated group by 48 hours after hypophysectomy. Thyroid stimulating hormone administration prevented this decrease, as observed for iodide peroxidase activity. Thyroidal RNA contents decreased also in hypophysectomized rats, thyroid stimulating hormone treatment prevented the reduction of RNA contents and no significant change was observed in thyroidal DNA contents. These data are consistent with the idea that protein biosynthesis is involved in thyroid stimulating hormone regulation of thyroidal iodide peroxidase and that the life span of the peroxidase is less than 48 hours.     

Sexual dimorphic expression of ADH in rat liver: importance of the hypothalamic-pituitary-liver axis

Hepatic alcohol dehydrogenase (ADH) activity is higher in female than in male rats. Although sex steroids, thyroid, and growth hormone (GH) have been shown to regulate hepatic ADH, the mechanism(s) for sexual dimorphic expression is unclear. We tested the possibility that the GH secretory pattern determined differential expression of ADH. Gonadectomized and hypophysectomized male and female rats were examined. Hepatic ADH activity was 2.1-fold greater in females. Because protein and mRNA content were also 1.7- and 2.4-fold greater, results indicated that activity differences were due to pretranslational mechanisms. Estradiol increased ADH selectively in males, and testosterone selectively decreased activity and mRNA levels in females. Effect of sex steroids on ADH was lost after hypophysectomy; infusion of GH in males increased ADH to basal female levels, supporting a role of the pituitary-liver axis. However, GH and L-thyroxine (T4) replacements alone in hypophysectomized rats did not restore dimorphic differences for either ADH activity or mRNA levels. On the other hand, T4 in combination with intermittent administration of GH reduced ADH activity and mRNA to basal male values, whereas T4 plus GH infusion replicated female levels. These results indicate that the intermittent male pattern of GH secretion combined with T4 is the principal determinant of low ADH activity in male liver.     

Regulation of hepatic lanosterol 14 alpha-demethylase gene expression by dietary cholesterol and cholesterol-lowering agents.

Binding of sterol response element binding protein 1a to sterol response element-1 (SRE-1) in the promoter region of lanosterol 14 alpha-demethylase (14DM) has been demonstrated previously. Decreased 14DM activity has been shown to result in accumulation of the intermediate, 3 beta-hydroxy-lanost-8-en-32-al, a known translational downregulator of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase. Since it has also been demonstrated that feedback regulation of hepatic HMG-CoA reductase occurs primarily at the level of translation, the effects of dietary cholesterol and cholesterol lowering agents on levels of hepatic 14DM mRNA and immunoreactive protein were investigated. Addition of 1% cholesterol to a chow diet markedly decreased hepatic 14DM mRNA and protein levels in Sprague-Dawley rats. The extent and time course of this decrease in 14DM immunoreactive protein closely paralleled that of HMG-CoA reductase. Supplementation of the diet with the HMG-CoA reductase inhibitor, Lovastatin, to a level of 0.02%, raised 14DM mRNA and protein levels 2- to 3-fold. Addition of 2% Colestipol, a bile acid binding resin, to the chow diet caused smaller increases. The highest level of 14DM protein expression was observed in liver, the major site of feedback regulation of HMG-CoA reductase by cholesterol. Taken together, these observations suggest a critical role for 14DM in the feedback regulation of hepatic HMG-CoA reductase.     

Hepatic triiodothyronine sulfation and its regulation by growth hormone and triiodothyronine in rats.

The regulatory mechanism of cytosolic sulfation of T3 has been studied in rat liver. Sulfation of T3 is sexually differentiated in adult rats of Sprague-Dawley (SD), Fisher 344, and ACI strains. In SD strain, the male animals showed 4 times higher sulfating activity than did the females. The specific activity was decreased by hypophysectomy of male adult rats, but was not affected in the females. Thus, the sex-difference was abolished in the hypophysectomized condition. Supplement of human GH intermittently twice daily for 7 days, to mimic the male secretory pattern, increased T3 sulfating activity in both sexes of hypophysectomized rats, whereas continuous infusion to mimic a female secretory pattern had no appreciable effect. Cytosolic sulfation of T3 was decreased by 25 to 30% by thyroidectomy or propylthiouracil treatment of male adult rats, and was restored by the supplementation of T3 (50 micrograms/kg daily for 7 days) to thyroidectomized rats. Administration of T3 in hypophysectomized rats almost completely restored the sulfating activity in the males and increased the activity in the females. Cytosolic T3 sulfation was inhibited by the addition of known inhibitors of phenol sulfotransferase, pentachlorophenol or 2,6-dichloro-4-nitrophenol. These results indicate a role of pituitary GH in hepatic sulfation of thyroid hormones in rats. The data obtained also raise the possibility that GH may modify the effect of thyroid hormones on the pituitary by a feed-back mechanism through changing the level of a sex-dominant phenol sulfotransferase(s) in rat livers. T3 was also sulfated in hepatic cytosols of mouse, hamster, rabbit, dog, monkey, and human.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of rat liver beta-hydroxy-beta-methylglutaryl coenzyme. A reductase activity and cholesterol levels of serum and liver in various dietary and hormonal states.

The effects of hormones and dietary factors on rat liver β-hydroxy-β-methylglutaryl coenzyme A reductase activity and serum and liver cholesterol levels were tested. Cholestyramine feeding markedly stimulated reductase activity in the livers of rats depleted of insulin or l-triiodothyronine. Therefore, these hormones are not absolute requirements for the stimulation of reductase activity.In hypophysectomized rats, l-triiodothyronine markedly stimulated reductase activity, even when the animals were cholesterol fed or fasted. However, this stimulation was accompanied by a reduction of serum and liver cholesterol levels. In diabetic rats, insulin failed to either stimulate reductase activity after cholesterol feeding, or to depress the level of liver cholesterol. These results are consistent with a model in which cholesterol functions as a feedback repressor of reductase activity.In contrast, a number of dietary and hormonal states produced little or no change in the level of serum and liver cholesterol while producing widely different reductase activities. These results suggest that the cholesterol level does not regulate reductase activity and cholesterol synthesis and that the factors that affect the formation of cholesterol also have a similar effect on its degradation. However, the possibility of a small subcellular pool of cholesterol regulating reductase activity and thus showing a positive correlation cannot be ruled out.The results reported in this paper suggest that the repressor, in a feedback repression model of regulation, should have similar effects on the rate-limiting enzymes of cholesterol synthesis and degradation. In this way a factor that operates through the repressor affects the rates of synthesis and degradation, but not the level of liver and serum cholesterol.