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)     

Novel roles of retinoid X receptor (RXR) and RXR ligand in dynamically modulating the activity of the thyroid hormone receptor/RXR heterodimer

Many members of the type II nuclear receptor subfamily function as heterodimers with the retinoid X receptor (RXR). A permissive heterodimer (e.g. peroxisome proliferator-activated receptor/RXR) allows for ligand binding by both partners of the receptor complex. In contrast, RXR has been thought to be incapable of ligand binding in a nonpermissive heterodimer, such as that of thyroid hormone receptor (TR)/RXR, where it has been referred to as a silent partner. However, we recently presented functional evidence suggesting that RXR in the TR/RXR heterodimer can bind its natural ligand 9-cis-RA in cells. Here we extended our study of the interrelationship of TR and RXR. We examined the potential modulatory effect of RXR and its ligand on the activity of TR, primarily using a Gal4-TR chimera. This study led to several novel and unexpected findings: 1) heterodimerization of apo-RXRalpha (in the absence of 9-cis-RA) with Gal4-TR inhibits T3-mediated transactivation; 2) the inhibition of Gal4-TR activity by RXRalpha is further enhanced by 9-cis-RA; 3) two different RXR subtypes (alpha and beta) differentially modulate the activity of Gal4-TR; 4) the N-terminal A/B domains of RXR alpha and beta are largely responsible for their differential modulation of TR activity; and 5) the RXR ligand 9-cis-RA appears to differentially affect T3-mediated transactivation from the Gal4-TR/RXRalpha (which is inhibited by 9-cis-RA) and TRE-bound TR/RXRalpha (which is further activated by 9-cis-RA) heterodimers. Taken together, these results further support our recent proposal that the RXR component in a TR/RXR heterodimer is not silent and, more importantly, reveal novel aspects of regulation of the activity of the TR/RXR heterodimer by RXR and RXR ligand.     

Photoaffinity labeling of human retinoid X receptor beta (RXRbeta) with 9-cis-retinoic acid: identification of phytanic acid, docosahexaenoic acid, and lithocholic acid as ligands for RXRbeta

We utilized [20-methyl-(3)H]-9-cis-retinoic acid ([(3)H]9-cis-RA) as a direct photoaffinity probe for the characterization of human recombinant retinoid X receptor beta protein (RXRbeta). The photoaffinity labeling was light- and concentration-dependent, saturable, and protected by unlabeled 9-cis-RA in a concentration-dependent manner, indicating that binding occurred in the RXR retinoid binding site. all-trans-Retinoic acid (atRA) did not affect labeling with the 9-cis derivative, confirming that atRA does not compete for the 9-cis-RA binding site. Several retinoid, fatty acid, and bile acid ligands were evaluated for their ability to recognize the 9-cis-RA binding site. Retinol, atRA glucuronide, 13-cis-RA, dolichol, 5,6-epoxy-RA, and vitamin D(3) did not compete for the 9-cis-RA binding site. However, the saturated diterpenoid phytanic acid (PA) and docosahexaenoic acid, which have been recently shown to activate the nuclear receptor, RXR, competed with 9-cis-RA labeling, showing high affinity for the 9-cis-RA binding site. Oleic acid, arachidonic acid, and butyric acid did not interact. However, the bile acid lithocholic acid competed efficiently with 9-cis-RA for the binding site. These data validated the photoaffinity assay as an excellent system for the identification and evaluation of ligands for RXR.