Identification of thyrotroph-specific factors and cis-acting sequences of the murine thyrotropin beta subunit gene

Pituitary thyrotroph cells specialize in the synthesis of TSH, and thus represent a model to study cell-specific gene expression. We have used the murine TSH beta (mTSH beta) gene promoter and TSH-producing and nonproducing transplantable tumors derived from murine thyrotroph cells, referred to as TtT-97 and MGH 101A, respectively, to identify nuclear factors which selectively interact with the mTSH beta gene. DNase I protection analyses demonstrate that factors present in TtT-97 nuclear extracts bind with high affinity to five separate sites in the TSH beta promoter region, denoted as distal D1 (-253 to -227) and proximal, P1 (-76 to -68), P2 (-106 to -98), P3 (-126 to -112), and P4 (-142 to -131) footprints. By contrast, non-TSH beta expressing thyrotroph cell nuclear extracts and L-cell nonpituitary cell extracts did not appear to footprint the D1 site; whereas the nonpituitary nuclear extracts revealed minimal DNase I protection in the P1-P4 regions. These data show that the distal D1 site is thyrotroph specific and contains a 6 base pair direct repeat sequence (5'-AGATAT-3'). Factor occupancy of the D1 site is protein dependent, occurs rapidly (less than 15 sec), is destabilized by 170 mM KCl, and results in an associated DNase I hypersensitive region. A double-stranded oligonucleotide spanning the D1 footprint competes only the distal factor binding region. Transfection of plasmid constructs containing progressive 5'-deletions of the mTSH beta promoter linked to the reporter gene luciferase into primary TtT-97 cells demonstrate a marked decrease in activity between the regions -270 and -79, which contains the D1 region.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Insulin is the essential factor maintaining the constitutive expression of hepatic sterol 14-demethylase P450 (CYP51)

The role of serum insulin in regulating the expression level of hepatic sterol 14-demethylase P450 (CYP51) was examined. Administration of streptozotocin, which destroys pancreatic beta-cells, caused reduction of CYP51 mRNA level in rats in parallel with the loss of serum insulin. Streptozotocin treatment also reduced the CYP51 activity. The decreased mRNA level and activity of the streptozotocin-treated rats were restored to the normal level within 24 h by repeated administration of insulin. CYP51 level of normal rats was insensitive to the circadian variation of serum insulin and insulin administration, and no significant difference was observed between the hepatic CYP51 activities of Sprague-Dawley and Wistar lean rats, although the serum insulin concentration of the latter was higher than the former. These facts indicate that the expression of hepatic CYP51 is maintained by serum insulin, and its lowest physiological level is sufficient for supporting the expression of CYP51. The responses of CYP51 expression to streptozotocin and insulin treatments were closely similar to those of the sterol regulatory element binding protein (SREBP)-1c expression [Shimomura et al. (1999) Proc. Nat. Acad. Sci. USA 96, 13656-13661]. Based on this fact, the possible contribution of SREBP-1c to the insulin-dependent expression of hepatic CYP51 gene was also discussed.     

Binding of a pancreatic nuclear protein is correlated with amylase enhancer activity.

The mouse amylase gene Amy-2.2 is expressed at high levels specifically in the acinar cells of the pancreas. The region between -172 and -110 of this gene includes sequence elements common to pancreas-specific genes. Nuclear proteins with specific affinity for this region were partially purified from rat pancreas. The consensus element of another pancreas-specific gene, elastase 1, competes for protein binding to the amylase sequences. Binding was localized by DNase I protection to the sequence -156 to -122. Site-directed mutagenesis of this sequence resulted in concomitant loss of protein binding and enhancer activity. Photo-affinity labelling of pancreatic nuclear extracts identified one predominant binding protein with a molecular weight of approximately 75 kDa. The data indicate that binding of this nuclear protein is essential for the enhancer activity of this pancreas-specific element.     

Gibberellin treatment stimulates nuclear factor binding to the gibberellin response complex in a barley alpha-amylase promoter.

The promoters of a majority of cereal alpha-amylase genes contain three highly conserved sequences (gibberellin response element, box I, and pyrimidine box). Recent studies have demonstrated the functional importance of four regions that either coincide with or are immediately proximal to these three conserved elements as well as an upstream Opaque-2 binding sequence. In this study, we describe the characterization of nuclear protein factors from barley aleurone layers whose binding activity toward gibberellin response complex sequences from the barley low-pl alpha-amylase gene (Amy32b) promoter is stimulated by gibberellin A3 (GA3) treatment. Barley proteins isolated from crude nuclear extracts prepared from aleurone layers incubated with or without GA3 were fractionated by anion exchange fast protein liquid chromatography and studied using band shift assays, sequence-specific competitions, and DNase I footprinting. A GA3-dependent binding activity eluting at 210 mM KCl was shown to bind specifically to the gibberellin response element and the closely associated box I. DNase I footprinting with the proteins in this fraction indicated interactions with sequences in the gibberellin response element and box I. A second DNA binding activity eluting at 310 mM KCl was present constitutively in extracts prepared from tissues incubated both in the absence and in the presence of hormone. Proteins in this fraction were able to bind to many DNA sequences and, in general, were largely nonspecific. DNase I footprinting with the proteins in this fraction indicated a large area of protection with a single unoccupied region located at the 3' end of box I. The possible function of such an activity in hormone regulation of the alpha-amylase genes is discussed.