Retinoic acid receptor isoform RAR gamma 1: an antagonist of the transactivation of the RAR beta RARE in epithelial cell lines and normal human keratinocytes.

The diversity of isoforms of retinoic acid (RA) receptors (RARs) and of DNA sequences of retinoic acid-responsive elements (RAREs) suggests the existence of selectivities in the RAR/RARE recognition or in the subsequent gene modulation. Such selectivities might be particularly important for RAREs involved in positive feedback, eg. the RAR beta RARE. In the present work we found that in several epithelial cell lines, reporter constructs containing the RAR beta RARE linked to the HSV-tk promoter were transactivated in the presence of RA by endogenous RARs and co-transfected RAR alpha 1 and RAR beta 2 isoforms, but not by RAR gamam 1. On the contrary, this latter isoform behaved towards the RAR beta RARE as an inhibitor of the transactivation produced by endogenous RARs and by cotransfected RAR alpha 1 and RAR beta 2. RAR gamma 1 also behaved as an antagonist of the transactivation produced by cotransfected RXR alpha. The natural RAR beta gene promoter or RAR beta RARE tk constructs were not activated by the endogenous receptors of normal human keratinocytes (NHK), which are known to contain predominantly RAR gamma 1. It was, however, possible to activate to a certain extent RAR beta RARE-reporter constructs in NHK by co-transfecting RAR alpha 1, RAR beta 2 or RXR alpha. The antagonist behavior of RAR gamma 1 towards the RAR beta RARE may explain why in certain cell types such as keratinocytes, RAR beta is neither expressed nor induced by RA.     

Murine RARbeta4 displays reduced transactivation activity, lower affinity for retinoic acid, and no anti-AP1 activity

The 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). Each of the RARs is expressed as four to seven different isoforms. Four isoforms of RAR beta (beta1, beta2, beta3, and beta4), which differ only in their N-terminal sequence (A domain) have been described. These RARbeta isoforms display a specific pattern of expression in developing and adult animals and are highly evolutionarily conserved suggesting that they mediate distinct cellular effects of vitamin A. Experiments were performed to examine directly the RA-binding activity, transactivation activity, and anti-AP1 activity of each of these four RARbeta isoforms. The results demonstrate that RARbeta1, beta2, and beta3 bind RA with a similar K(d) value, have a similar EC(50) value in RA-dependent transactivation assays and inhibit AP1 activity to a similar level. By contrast, RARbeta4 has an elevated K(d) for RA, an increased EC(50) value in RA-dependent transactivation assays and does not display the ability to inhibit AP1 activity. This provides additional evidence that at least one RAR isoform, RARbeta4, may mediate distinct activities within a cell. Furthermore, these data suggest that the presence of an A domain in RARbeta is important for modulating these activities of RARs.     

Modulation by retinoids of mRNA levels for nuclear retinoic acid receptors in murine melanoma cells

Retinoids inhibit the growth and enhance the differentiation of murine S91-C2 melanoma cells. Specific alterations in gene expression are a plausible mechanism for these effects. Since nuclear retinoic acid receptors (RAR) are likely mediators of retinoid-induced changes in gene expression, we used Northern blotting to analyze the expression of RAR alpha, RAR beta, and RAR gamma in S91-C2 cells. mRNA for both RAR alpha and RAR gamma was detected in these cells, but no RAR beta mRNA could be found. Treatment with 10(-7) and 10(-6) M beta-all-trans-retinoic acid (RA) for 24 h caused a 1.5- to 2-fold increase in RAR alpha and RAR gamma mRNA, whereas lower concentrations of RA were ineffective. RAR beta mRNA, which was undetectable in untreated cells, was detected after 24 h of treatment with a RA concentration as low as 10(-9) M, and its level increased with up to 10(-6) M RA. At the latter dose, RAR beta mRNA induction occurred by 4 h and increased progressively, reaching a plateau after 24 h of treatment. RAR beta mRNA induction at 4 h was not inhibited by cycloheximide at a concentration that suppressed protein synthesis by more than 90%. Several retinoids and related synthetic compounds, including 13-cis RA, TTNPB, Ch55, Am80, and the trifluoromethyl nonyloxyphenyl analog of RA, also induced RAR beta mRNA, whereas a 24-h treatment with 10(-6) M retinol, TTNP (a decarboxylated analog of TTNPB), or the phenyl analog of RA failed to induce RAR beta mRNA. With the exception of retinol and the trifluoromethyl nonyloxyphenyl analog of RA, the ability of the retinoids to induce RAR beta mRNA and their growth inhibitory effect were correlated. However, S91-C154, a RA-resistant mutant subclone derived from S91-C2 cells, showed mRNA levels of RAR alpha and RAR gamma and induction of RAR beta by RA similar to those detected in the sensitive S91-C2 cells. Like the S91 melanoma cells, two other mouse melanoma cell lines, K-1735P and B16-F1, constitutively expressed RAR alpha and RAR gamma mRNAs. The level of RAR beta mRNA was increased by RA only in B16-F1 cells, although the growth of both was inhibited by RA. These results demonstrate that RA can, directly and rapidly, induce the expression of mRNA for a high affinity nuclear receptor in some murine melanoma cells and that this induction is not sufficient to inhibit growth.     

Retinoic acid receptor beta mediates the growth-inhibitory effect of retinoic acid by promoting apoptosis in human breast cancer cells.

Retinoids are known to inhibit the growth of hormone-dependent but not that of hormone-independent breast cancer cells. We investigated the involvement of retinoic acid (RA) receptors (RARs) in the differential growth-inhibitory effects of retinoids and the underlying mechanism. Our data demonstrate that induction of RAR beta by RA correlates with the growth-inhibitory effect of retinoids. The hormone-independent cells acquired RA sensitivity when the RAR beta expression vector was introduced and expressed in the cells. In addition, RA sensitivity of hormone-dependent cells was inhibited by a RAR beta-selective antagonist and the expression of RAR beta antisense RNA. Introduction of RAR alpha also restored RA sensitivity in hormone-independent cells, but this restoration was accomplished by the induction of endogenous RAR beta expression. Furthermore, we show that induction of apoptosis contributes to the growth-inhibitory effect of RAR beta. Thus, RAR beta can mediate retinoid action in breast cancer cells by promoting apoptosis. Loss of RAR beta, therefore, may contribute to the tumorigenicity of human mammary epithelial cells.     

Cyclic AMP analogs and retinoic acid influence the expression of retinoic acid receptor alpha, beta, and gamma mRNAs in F9 teratocarcinoma cells.

Retinoic acid (RA) receptor alpha (RAR alpha) and RAR gamma steady-state mRNA levels remained relatively constant over time after the addition of RA to F9 teratocarcinoma stem cells. In contrast, the steady-state RAR beta mRNA level started to increase within 12 h after the addition of RA and reached a 20-fold-higher level by 48 h. This RA-associated RAR beta mRNA increase was not prevented by protein synthesis inhibitors but was prevented by the addition of cyclic AMP analogs. In the presence of RA, cyclic AMP analogs also greatly reduced the RAR alpha and RAR gamma mRNA levels, even though cyclic AMP analogs alone did not alter these mRNA levels. The addition of either RA or RA plus cyclic AMP analogs did not result in changes in the three RAR mRNA half-lives. These results suggest that agents which elevate the internal cyclic AMP concentration may also affect the cellular response to RA by altering the expression of the RARs.     

Inhibition of trans-retinoic acid-resistant human breast cancer cell growth by retinoid X receptor-selective retinoids.

All-trans-retinoic acid (trans-RA) and other retinoids exert anticancer effects through two types of retinoid receptors, the RA receptors (RARs) and retinoid X receptors (RXRs). Previous studies demonstrated that the growth-inhibitory effects of trans-RA and related retinoids are impaired in certain estrogen-independent breast cancer cell lines due to their lower levels of RAR alpha and RARbeta. In this study, we evaluated several synthetic retinoids for their ability to induce growth inhibition and apoptosis in both trans-RA-sensitive and trans-RA-resistant breast cancer cell lines. Our results demonstrate that RXR-selective retinoids, particularly in combination with RAR-selective retinoids, could significantly induce RARbeta and inhibit the growth and induce the apoptosis of trans-RA-resistant, RAR alpha-deficient MDA-MB-231 cells but had low activity against trans-RA-sensitive ZR-75-1 cells that express high levels of RAR alpha. Using gel retardation and transient transfection assays, we found that the effects of RXR-selective retinoids on MDA-MB-231 cells were most likely mediated by RXR-nur77 heterodimers that bound to the RA response element in the RARbeta promoter and activated the RARbeta promoter in response to RXR-selective retinoids. In contrast, growth inhibition by RAR-selective retinoids in trans-RA-sensitive, RAR alpha-expressing cells most probably occurred through RXR-RAR alpha heterodimers that also bound to and activated the RARbeta promoter. In MDA-MB-231 clones stably expressing RAR alpha, both RARbeta induction and growth inhibition by RXR-selective retinoids were suppressed, while the effects of RAR-selective retinoids were enhanced. Together, our results demonstrate that activation of RXR can inhibit the growth of trans-RA-resistant MDA-MB-231 breast cancer cells and suggest that low cellular RAR alpha may regulate the signaling switch from RAR-mediated to RXR-mediated growth inhibition in breast cancer cells.     

Analysis of the ligand-binding domain of human retinoic acid receptor alpha by site-directed mutagenesis.

Three subtypes of retinoic acid receptors (RAR), termed RAR alpha, RAR beta, and RAR gamma, have been described. They are composed of different structural domains, including distinct domains for DNA and ligand binding. RARs specifically bind all-trans-retinoic acid (RA), 9-cis-RA, and retinoid analogs. In this study, we examined the functional role of cysteine and arginine residues in the ligand-binding domain of hRAR alpha (hRAR alpha-LBD, amino acids 154 to 462). All conserved cysteine and arginine residues in this domain were mutated by site-directed mutagenesis, and the mutant proteins were characterized by blocking reactions, ligand-binding experiments, transactivation assays, and protease mapping. Changes of any cysteine residue of the hRAR alpha-LBD had no significant influence on the binding of all-trans RA or 9-cis RA. Interestingly, residue C-235 is specifically important in antagonist binding. With respect to arginine residues, only the two single mutations of R-276 and R-394 to alanine showed a dramatic decrease of agonist and antagonist binding whereas the R272A mutation showed only a slight effect. For all other arginine mutations, no differences in affinity were detectable. The two mutations R217A and R294A caused an increased binding efficiency for antagonists but no change in agonist binding. From these results, we can conclude that electrostatic interactions of retinoids with the RAR alpha-LBD play a significant role in ligand binding. In addition, antagonists show distinctly different requirements for efficient binding, which may contribute to their interference in the ligand-inducible transactivation function of RAR alpha.     

Retinoid receptors involved in the effects of retinoic acid on rat testis development

We have previously shown that retinoic acid (RA) is able to act on the development of Leydig, Sertoli, and germ cells in the testis in culture (Livera et al., Biol Reprod 2000; 62:1303-1314). To identify which receptors mediate these effects, we have now added selective agonists and antagonists of retinoic acid receptors (RARs) or retinoid X receptors (RXRs) in the same organotypic culture system. The RAR alpha agonist mimicked most of the effects of RA on the cultured fetal or neonatal testis, whereas the RAR beta, gamma, and pan RXR agonists did not. The RAR alpha agonist decreased the testosterone production, the number of gonocytes, and the cAMP response to FSH of fetal testis explanted at 14.5 days postconception (dpc). The RAR alpha agonist disorganized the cords of the 14.5-dpc cultured testis and increased the cord diameter in cultured 3-days-postpartum (dpp) testis in the same way as RA. All these RA effects could be reversed by an RAR alpha antagonist and were unchanged by an RAR beta/gamma antagonist. The RAR beta agonist, however, increased Sertoli cell proliferation in the 3-dpp testis in the same way as RA, and this effect was blocked by an RAR beta antagonist. The RAR gamma and the pan RXR agonists had no selective effect. These results suggest that all the effects of RA on development of the fetal and neonatal testis are mediated via RAR alpha, except for its effect on Sertoli cell proliferation, which involves RAR beta.