TOR: a new orphan receptor expressed in the thymus that can modulate retinoid and thyroid hormone signals

Vitamin A and other fat-soluble hormones and vitamins have important roles as modulators of essential biological processes such as homeostasis, development, differentiation, and oncogenesis and also as regulators of the immune system. The active form of vitamin A, retinoic acid, as well as vitamin D3 and thyroid hormones exert their actions by binding to specific nuclear receptors that represent one subfamily of the steroid/thyroid hormone receptor superfamily. To identify new members of the retinoid/thyroid hormone receptor subfamily that could play a role in the immune system, a screening of a T cell cDNA library was performed using a retinoid X receptor probe. A clone was isolated encoding a novel nuclear receptor expressed mainly in the thymus and T cell lines. This new receptor, TOR (thymus orphan receptor), is most closely related in both its DNA-binding domain and ligand-binding domain, 90% and 53%, respectively, to ROR alpha/RZR alpha and clusters with these two receptors and RZR beta in a phylogenetic tree, when both the DNA-binding domain and the ligand-binding domain sequences of nuclear receptors are compared. Thus, TOR is part of a subgroup of receptors, one of which has recently been reported to be activated by melatonin. TOR binds specifically to a direct repeat of the half-site sequence 5'-AGGTCA-3' with a four- or five-nucleotide spacer, DNA sequences that also serve as binding sites for thyroid hormone (TR), and retinoic acid receptors (RAR). In transient transfection experiments TOR does not activate a reporter gene carrying these sequences in the absence or the presence of any known nuclear receptor ligands. TOR, however, is able to repress TR and RAR activity on DR-4-TREs or DR-5-RAREs, respectively. Therefore, our data suggest that TOR, similar to COUP-TF, can negatively regulate retinoic acid and thyroid hormone signals. However, the response elements recognized by TOR and COUP-TF differ as do the expression patterns of these receptors. Thus, one important role of TOR could be to modulate retinoid and thyroid hormone signals in the thymus.     

Arg278, but not Lys229 or Lys236, plays an important role in the binding of retinoic acid by retinoic acid receptor gamma

The diverse biological actions of retinoic acid (RA) are mediated by retinoic acid receptors (RARalpha, beta and gamma) and retinoid X receptors (RXR alpha, beta, and gamma). Although the ligand-binding domains of RARs share the same novel folding pattern, many RAR subtype-specific retinoids have been synthesized indicating that the ligand-binding pocket of each RAR subtype has unique features. Previously we have demonstrated the importance for RA binding and RA-dependent transactivation of Arg276 of RARalpha alone and in RARbeta Arg269 in conjunction with Lys220. In this study, we have examined the role of the homologous amino acid residues (Lys229 and Arg278) in RARgamma for these activities. Like RARalpha but dissimilar to RARbeta, Arg278 in RARgamma alone was found to play an important role in RA binding and RA-dependent transactivation. Since Lys236 in RARgamma was suggested from the crystal structure of holo-RARgamma to interact with RA, we also examined its role and that of its homologs in RARalpha and RARbeta. Despite the suggestion from the crystal structure, neither Lys236 nor its homologs in RARalpha and RARbeta play a role in the binding of RA or RA-dependent transactivation. It is likely that Lys236 in RARgamma and its homologs in RARalpha and RARbeta are solvent exposed rather than pointing into the RA-binding pocket.     

Interaction between retinoic acid and vitamin D signaling pathways

The nuclear signaling pathways for retinoids and vitamin D differ in the specificity of the respective receptors for response elements. Two pathways for the action of both retinoic acid receptors (RARs) and vitamin D receptors (VDRs) have been identified, one being retinoid X receptor (RXR)-dependent and the other being RXR-independent. Moreover, RXRs were found to function as homodimers. In several steps we converted the retinoid specific response element of the human retinoic acid receptor beta promoter into the vitamin D/retinoic acid response element of the human osteocalcin promoter. We found that VDR homodimers only bind to the motif RGGTGA. The extended osteocalcin element also contains an imperfect direct repeat based on the motif RGGTGA spaced by three nucleotides, which is bound by RXR homodimers and activated by 9-cis-retinoic acid. The responsiveness of the osteocalcin element to all-trans-retinoic acid is mediated neither by RAR homodimers nor by RAR-RXR heterodimers. However, a VDR-RAR heterodimer binds to the osteocalcin response element and mediates activation by all-trans-retinoic acid. This heterodimer also binds to pure retinoid response elements, but it does not mediate activation by vitamin D alone. In combination with all-trans-retinoic acid, however, vitamin D enhances VDR-RAR heterodimer-mediated gene expression. This finding suggests a direct interaction between nuclear signaling by retinoic acid and vitamin D increasing the combinatorial possibilities for gene regulation by the nuclear receptors involved.     

Regulation of embryonic/fetal globin genes by nuclear hormone receptors: a novel perspective on hemoglobin switching

The CCAAT box is one of the conserved motifs found in globin promoters. It binds the CP1 protein. We noticed that the CCAAT-box region of embryonic/fetal, but not adult, globin promoters also contains one or two direct repeats of a short motif analogous to DR-1 binding sites for non-steroid nuclear hormone receptors. We show that a complex previously named NF-E3 binds to these repeats. In transgenic mice, destruction of the CCAAT motif within the human epsilon-globin promoter leads to substantial reduction in epsilon expression in embryonic erythroid cells, indicating that CP1 activates epsilon expression; in contrast, destruction of the DR-1 elements yields striking epsilon expression in definitive erythropoiesis, indicating that the NF-E3 complex acts as a developmental repressor of the epsilon gene. We also show that NF-E3 is immunologically related to COUP-TF orphan nuclear receptors. One of these, COUP-TF II, is expressed in embryonic/fetal erythroid cell lines, murine yolk sac, intra-embryonic splanchnopleura and fetal liver. In addition, the structure and abundance of NF-E3/COUP-TF complexes vary during fetal liver development. These results elucidate the structure as well as the role of NF-E3 in globin gene expression and provide evidence that nuclear hormone receptors are involved in the control of globin gene switching.