Triiodothyronine regulation of multiple rat hepatic genes: requirement for ongoing protein synthesis

We have examined the role of rapidly turning over proteins in the T3 regulation of multiple rat hepatic genes. T3 induction of the rapidly responsive mRNA-S14 was markedly inhibited by cycloheximide (1 mg/100 g BW) or emetine (3 mg/100 g) injected ip 30 min before T3 (mRNA-S14 concentration was only 35% of that in T3-treated controls 8.5 h after administration of either protein synthesis inhibitor, P less than 0.01). Cycloheximide exhibited a similar effect on each of five other more slowly responsive T3 regulated genes. When cycloheximide was given 10 h after T3, the expected T3-induced rise of mRNA-S7 activity was completely prevented, and for mRNA-S4 activity the anticipated rise was blunted to 40% of T3-treated control (P less than 0.05). Cycloheximide caused sharp declines in the activity of two other mRNAs, S6 and S8, which because of shorter lag times of response to T3, had already risen when the drug was given. Values for both these mRNAs returned to the baseline hypothyroid level within 6 h of injection of the drug and remained low for a further 8 h (P less than 0.05). The expected deinduction of mRNA-S10 by T3 was also markedly modified. T3 lowered this mRNA to 11% of the hypothyroid control after 8 h, whereas cycloheximide given 30 min before the hormone blunted this fall to only 72% of control (P less than 0.01). Thus there appeared to be a 70% reduction in the rate of T3 induced fall of mRNA-S10. We did not find that cycloheximide caused a generalized decrease in poly (A)+ RNA mass.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of rat S14 protein and comparison of its regulation with that of mRNA S14 employing synthetic peptide antisera

The rat S14 gene encodes a protein of unknown function and has an amino acid sequence unrelated to any published sequences. Expression of mRNA S14 and lipogenesis in liver, fat, and mammary gland are regulated coordinately by dietary and hormonal stimuli, suggesting that the S14 protein may be associated with lipogenesis. Antisera to synthetic peptides corresponding to portions of the deduced amino acid sequence of the protein were used to identify the protein and to compare its regulation with that of mRNA S14. Antisera specifically recognized the in vitro translation product of mRNA S14 as defined by its migration on two-dimensional gel electrophoresis. A product of identical Mr was identified on Western blots of liver homogenates from hyperthyroid, carbohydrate-fed rats. Subcellular fractionation showed that S14 protein is primarily cytosolic. The protein was detectable in tissues with abundant S14 gene expression, including hyperthyroid liver and epididymal fat and hypothyroid brown adipose tissue, whereas it was undetectable in hypothyroid liver and euthyroid kidney, testis, and spleen. Diurnal variation in hepatic mRNA S14 correlated with comparable changes in levels of the protein. Surprisingly, no S14 protein was observed in the livers of chronically (3 week) hypothyroid rats treated with triiodothyronine (T3) until 12 h had elapsed, despite attainment of maximal levels of mRNA S14 within 4 h. Rapid appearance of protein after T3 treatment was observed in both euthyroid and short term (4 day) hypothyroid rats, suggesting that long-term hypothyroidism is associated with a defect in the translational efficiency of mRNA S14.     

Interaction of dietary carbohydrate and glucagon in regulation of rat hepatic messenger ribonucleic acid S14 expression: role of circadian factors and 3',5'-cyclic adenosine monophosphate

The mRNA of the rat hepatic S14 gene accumulates rapidly after administration of T3 and carbohydrate, making it an excellent model for studies of the effects of dietary and hormonal stimuli at the hepatocellular level. We undertook studies to assess circadian changes in responsivity of this sequence to intragastric sucrose administration combined with insulin injection, and evaluated the capacity of glucagon to reverse these effects. As in the case of T3, the response of mRNA-S14 to carbohydrate in the morning was brisk whereas there was no significant increment when the stimulus was applied in the evening. In confirmation of previous studies, glucagon markedly lowered levels of mRNA-S14 in the evening but exerted no effect in the morning. These results support the concept that the rate of hepatic production of mRNA-S14 in unmanipulated rats is maximal in the evening, thus allowing no further induction by carbohydrate or T3 but permitting reduction by glucagon. Conversely, the rate of production is minimal in the morning, permitting induction by carbohydrate or T3 but allowing no further reduction by glucagon. A major difference between the effects of carbohydrate and those of T3 was the observed failure of carbohydrate to reverse the effect of glucagon in the evening. The effect of glucagon was stimulated by (Bu)2cAMP, and this was reversed by T3. However, T3 did not modify the glucagon-induced increase in hepatic cAMP levels. We therefore conclude that the capacity of T3 to abolish the glucagon effect is mediated at a step distal to the generation of cAMP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hormonal changes during the early development of ovarian cysts in the rat

The daily administration of human chorionic gonadotropin (hCG) to rats with thiouracil-induced hypothyroidism results in the development of cystic ovaries. This study was undertaken to delineate hormonal changes during the first 48 h of hCG treatment. Groups of euthyroid and hypothyroid rats were injected daily with hCG or saline for up to two days and killed at 0, 12, 24, or 48 h after the initial hCG injection. Sera were analyzed for progesterone (P), testosterone (T), 17 beta-estradiol (E2), and prolactin (Prl) by specific radioimmunoassay (RIA). Serum levels of these hormones were not significantly different in the euthyroid and hypothyroid rats. However, P was significantly elevated at 12, 24, and 48 h in the hypothyroid/hCG rats. T and Prl were significantly elevated at 12 and 48 h in the hypothyroid/hCG rats. T levels were also elevated at 12 and 48 h in the euthyroid rats receiving hCG. In contrast, hCG had no effect on P and Prl levels in the euthyroid rats. E2 levels were undetectable in the euthyroid and hypothyroid rats. The administration of hCG increased E2 in both the euthyroid and hypothyroid rats at 48 h with significantly more E2 detected in the hypothyroid rats. These results show that ovarian steroids and Prl levels increase during the early stages of cyst induction and suggest they may be important in triggering ovarian cyst formation.     

Thyroid hormone-, carbohydrate, and age-dependent regulation of a methylation site in the hepatic S14 gene

The rat hepatic S14 gene has served as a model of thyroid hormone regulation of gene expression. Earlier studies of the S14-containing chromatin region demonstrated that a cytosine residue at position 625 (C-625) in the 3' untranslated exon was hypermethylated in hepatic DNA derived from hypothyroid animals. This observation was consistent with the markedly reduced level of expression of the S14 gene in these rats. The current studies have extended these observations to groups of rats in various thyroidal states. By using the restriction enzyme Hhal, the percent demethylation of this site was quantitated (hypothyroid, 9.3%; euthyroid, 19.2%; hyperthyroid, 66.6%). Moreover, the level of methylation was shown to be reversible as the thyroidal state was altered. Our data also indicate that these changes are probably independent of de novo DNA synthesis. Kinetic studies of the demethylation of this cytosine residue after T3 administration showed no change for at least 1 day and maximal change after about 4 days. This contrasts with the significant rise in S14 mRNA evident within 30 min and suggests that demethylation plays no role in the acute induction of this gene by T3. Carbohydrate feeding, another stimulus of S14 expression, similarly caused the demethylation of this cytosine residue. Earlier studies had demonstrated that mRNA S14 expression was not detectable in rat pups before about 20 days of age and continued to rise through the first year of life. Consistent with those findings, S-14 C-625 was fully methylated up to 15 days of age. Progressive demethylation then occurred up to 12 months of age. These results indicate that increased demethylation of a specific site in the 3' untranslated region of the S14 gene, possibly resulting from augmented excision repair processes, is correlated with increased expression of the gene.     

Thyroid hormone and circadian regulation of the binding activity of a liver-specific protein associated with the 5'-flanking region of the S14 gene

Recent studies have described a DNase I hypersensitive site in the 5'-flanking region of the rat hepatic S14 gene that is closely associated with its expression. A 111-base pair subfragment (-389 to -279) of this region interacts specifically in a gel shift assay with a protein present in hepatic nuclear protein extracts. This protein, designated P1, was not present in extracts of other tissues, even those in which the gene is expressed and hormonally regulated. The binding activity of P1 is exceedingly low in extracts from hypothyroid rats and is markedly increased by administration of thyroid hormone. However, the slow accumulation of P1 after thyroid hormone administration indicates that increased levels of P1 are not necessary for the acute hormonal induction of S14 gene expression. The level of P1 binding activity increases in the evening, synchronous with circadian variation of hepatic mRNA S14. Since neither P1 binding activity nor circadian variation in mRNA-S14 levels are observed in the other tissues expressing the S14 gene, P1 may function to modulate the circadian rhythm observed in hepatic S14 gene expression. DNase I footprinting analysis revealed that P1 binds to a defined nucleotide sequence, 5'-AAAAGAGCTATTGATTGCCTGCA-3', located between -310 and -288 in the S14 gene.