Retinoic acid receptor/retinoid X receptor heterodimers can be activated through both subunits providing a basis for synergistic transactivation and cellular differentiation

The receptor for 9-cis-retinoic acid, retinoid X receptor (RXR), forms heterodimers with several nuclear receptors, including the receptor for all-trans-retinoic acid, RAR. Previous studies have shown that retinoic acid receptor can be activated in RAR/RXR heterodimers, whereas RXR is believed to be a silent co-factor. In this report we show that efficient growth arrest and differentiation of the human monocytic cell line U-937 require activation of both RAR and RXR. Also, we demonstrate that the allosteric inhibition of RXR is not obligatory and that RXR can be activated in the RAR/RXR heterodimer in the presence of RAR ligands. Remarkably, RXR inhibition by RAR can also be relieved by an RAR antagonist. Moreover, the dose response of RXR agonists differ between RXR homodimers and RAR/RXR heterodimers, indicating that these complexes are pharmacologically distinct. Finally, the AF2 activation domain of both subunits contribute to activation even if only one of the receptors is associated with ligand. Our data emphasize the importance of signaling through both subunits of a heterodimer in the physiological response to retinoids and show that the activity of RXR is dependent on both the identity and the ligand binding state of its partner.     

Metabolism to a response pathway selective retinoid ligand during axial pattern formation

We report identification of 9-cis-4-oxo-retinoic acid (9-cis-4-oxo-RA) as an in vivo retinoid metabolite in Xenopus embryos. 9-Cis-4-oxo-RA bound receptors (RARs) alpha, beta, and gamma as well as retinoid X receptors (RXRs) alpha, beta, and gamma in vitro. However, this retinoid displayed differential RXR activation depending on the response pathway used. Although it failed to activate RXRs in RXR homodimers, it activated RXRs and RARs synergistically in RAR-RXR heterodimers. 9-Cis-4-oxo-RA thus acted as a dimer-specific agonist. Considering that RAR-RXR heterodimers are major functional units involved in transducing retinoid signals during embryogenesis and that 9-cis-4-oxo-RA displayed high potency for modulating axial pattern formation in Xenopus, metabolism to 9-cis-4-oxo-RA may provide a mechanism to target retinoid action to this and other RAR-RXR heterodimer-mediated processes.     

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.     

Genetic control of the development by retinoic acid

Two families of nuclear receptors for retinoic acid (RA) have been characterized. Members of the RAR family (types alpha, beta and gamma and their isoforms alpha 1, alpha 2, beta 1 to beta 4, and gamma 1 and gamma 2) are activated by most physiologically occurring retinoids (all-trans RA, 9-cis RA, 4oxo RA and 3,4 dihyroRA). In contrast, members of the RXR family (types alpha, beta and gamma and their isoforms) are activated by 9cis-RA only. In addition to the multiplicity of receptors, the complexity of retinoid signalling is further increased by the fact that, at least in vitro, RARs bind to their cognate response elements as heterodimers with RXRs. Moreover, RXRs can also bind, in vitro, to some DNA elements as homodimers, and are heterodimeric partners for other nuclear receptors, including TRs, VDR, PPARs and a number of orphan nuclear receptors. To evaluate the functions of the different RARs and RXRs types and isoforms, we have generated null mutant mice by targeted gene disruption in ES cells. As to the functions of RARs, we found that RAR alpha 1 and RAR gamma 2 null mutant mice are apparently normal. Mice deficient in RAR alpha or RAR gamma (i.e., all alpha or gamma isoforms disrupted) show aspects of the post-natal vitamin A deficiency (VAD) syndrome which can be cured or prevented by RA, including post-natal lethality, poor weight gain and male sterility. RAR beta 2 (and RAR beta) null mutants display a retrolenticular membrane which represents the most frequent defect of the fetal VAD syndrome. That these abnormalities were restricted to a small subset of the tissues normally expressing these receptors suggested that some degree of functional redundancy should exist in the RAR family. To test this hypothesis we then generated RAR double null mutants. RAR alpha beta, RAR alpha gamma and RAR beta gamma compound mutants exhibit all the malformations of the fetal VAD syndrome, thus demonstrating that RA is the vitamin A derivative which plays a crucial role at many different stages and in different structures during organogenesis. Interestingly, almost all the structures derived from mesenchymal neural crests cells (NCC) are affected in RAR compound mutants. As to the functions of RXRs, RXR gamma null mutants are viable, fertile and morphologically normal. In contrast, RXR alpha null fetuses display a thin ventricular wall and die in utero from cardiac failure. A myocardial hypoplasia has also been observed in some RAR compound mutants as well as in VAD fetuses. Thus, RXR alpha seems to act as an inhibitor of ventricular cardiocyte differentiation and/or as a positive regulator of their proliferation, and these functions might involve heterodimerization with RARs and activation by RA. RXR beta null mutants are viable but the males are sterile, most probably because of an abnormal lipid metabolism in the Sertoli cells. New abnormalities, absent in RXR alpha mutants, are generated in RXR alpha/RAR (alpha, beta or gamma) compound mutants. All these abnormalities are also seen in RAR double mutants as well as in VAD fetuses. In contrast, such manifestations of synergism are not observed between the RXR beta or RXR gamma and the RAR (alpha, beta or gamma) null mutations. These data strongly support the conclusion that RXR alpha/RAR heterodimers represent the main functional units of the RA signalling pathway during embryonic development. Moreover, since RXR gamma-/-/RXR beta-/-/RXR alpha +/-mutants are viable, a single allele of RXR alpha can perform most of the developmental RXR functions.     

Dimerization of the head-rod junction of scallop myosin

Retinoic acid (RA) is an important mediator of cell differentiation. It stimulates hCG secretion by JEG-3 choriocarcinoma cells in vitro after a time lag. The first aim of this study was to characterize which types of retinoid receptors (RARs and RXRs) are present in JEG-3 cells. Using Western blot analysis and immunocytochemistry with specific antibodies as well as Northern blot analysis, we found that JEG-3 cells expressed RAR alpha and RXR alpha, the latter being the predominant receptor. We then analyzed the action on cell proliferation and hCG secretion of the physiological retinoids all-trans RA (RA) and 9 cis RA as well as synthetic retinoids with specific affinity for RAR alpha and RXR alpha. All these retinoids were potent inhibitors of cell growth, maximal inhibition (72 +/- 2%) being observed after 4 days of treatment with Ro 25, a RXR alpha specific ligand. Within 24 h, 9 cis RA and Ro 25 stimulated hCG secretion, and maximal stimulation (1,472 +/- 10%) occurred at 48 h with the RXR alpha-specific ligand. The RAR alpha-specific ligand also stimulated hCG secretion but to a lower extend and after a delay of 48 h. These results suggest a predominant role of RXR alpha in mediating the biological effects of retinoids on JEG-3 cells and the possible induction by RA itself of the metabolic pathway leading to 9 cis RA.     

Noradrenergic regulation of synaptic plasticity in the hippocampal CA1 region

The F9 murine embryonal carcinoma cell line represents a well-established system for the study of retinoid signaling in vivo. We have investigated the functional specificity of different retinoid X receptor (RXR)-retinoic acid (RA) receptor (RAR) isotype pairs for the control of expression of endogenous RA-responsive genes, by using wild-type (WT), RXR alpha(-/-), RAR alpha(-/-), RAR gamma(-/-), RXR alpha(-/-)-RAR alpha(-/-), and RXR alpha(-/-)-RAR gamma(-/-) F9 cells, as well as panRXR and RAR isotype (alpha, beta, and gamma)-selective retinoids. We show that in these cells the control of expression of different sets of RA-responsive genes is preferentially mediated by distinct RXR-RAR isotype combinations. Our data support the conclusion that RXR-RAR heterodimers are the functional units transducing the retinoid signal and indicate in addition that these heterodimers exert both specific and redundant functions on the expression of particular sets of RA-responsive genes. We also show that the presence of a given receptor isotype can hinder the activity of another isotype and therefore that functional redundancy between retinoid receptor isotypes can be artifactually generated by gene knockouts.     

Retinoid-X receptor signalling in the developing spinal cord

Retinoids regulate gene expression through the action of retinoic acid receptors (RARs) and retinoid-X receptors (RXRs), which both belong to the family of nuclear hormone receptors. Retinoids are of fundamental importance during development, but it has been difficult to assess the distribution of ligand-activated receptors in vivo. This is particularly the case for RXR, which is a critical unliganded auxiliary protein for several nuclear receptors, including RAR, but its ligand-activated role in vivo remains uncertain. Here we describe an assay in transgenic mice, based on the expression of an effector fusion protein linking the ligand-binding domain of either RXR or RAR to the yeast Gal4 DNA-binding domain, and the in situ detection of ligand-activated effector proteins by using an inducible transgenic lacZ reporter gene. We detect receptor activation in the spinal cord in a pattern that indicates that the receptor functions in the maturation of limb-innervating motor neurons. Our results reveal a specific activation pattern of Gal4-RXR which indicates that RXR is a critical bona fide receptor in the developing spinal cord.