DNA recognition by the aberrant retinoic acid receptors implicated in human acute promyelocytic leukemia.

Human acute promyelocytic leukemias (APLs) are associated with chromosomal translocations that replace the NH2 terminus of wild-type retinoic acid receptor (RAR) alpha with portions of the promyelocytic leukemia protein (PML) or promyelocytic leukemia zinc-finger protein (PLZF). The wild-type RARalpha readily forms heterodimers with the retinoid X receptors (RXRs), and these RAR/RXR heterodimers appear to be the principal mediators of retinoid signaling in normal cells. In contrast, PML-RARalpha and PLZF-RARa display an enhanced ability to form homodimers, and this enhanced homodimer formation is believed to contribute to the neoplastic properties of these chimeric oncoproteins. We report here that the DNA recognition specificity of the RXRalpha/RARa heterodimer, which is presumed to be the dominant receptor species in normal cells, differs from that of the PML-RARalpha and PLZF-RARalpha homodimers, which are thought to prevail in the oncogenic cell. We suggest that differences in target gene recognition by the normal and oncogenic RARalpha proteins may contribute to the leukemogenic phenotype.     

Unliganded T3R, but not its oncogenic variant, v-erbA, suppresses RAR-dependent transactivation by titrating out RXR.

V-erbA is thought to be an antagonist of thyroid hormone receptor (T3R) function. Here we show that unliganded T3R, but not v-erbA, suppresses retinoic acid (RA)-dependent induction of the RAR-beta 2 promoter by competing for the common dimerization partner, the retinoid X receptor (RXR). Firstly, T3R suppression can be alleviated by co-transfection of RXR. Secondly, T3R, but not v-erbA, competes with RAR for RXR and causes the dissociation of a preformed RAR/RXR-RARE ternary complex in vitro. A single point mutation located in the dimerization interface of v-erbA (Pro349 to Ser) abolishes the transdominant phenotype when introduced at the respective position in T3R. The hypertransforming v-erbA variant r12, in which this mutation is reversed (Ser349 to Pro) suppresses RA-induced differentiation in chicken erythroid progenitors, while v-erbA does not. Our data thus suggest that unliganded T3R and v-erbA act as dominant suppressors through mechanistically distinct pathways.     

The patterns of binding of RAR, RXR and TR homo- and heterodimers to direct repeats are dictated by the binding specificites of the DNA binding domains.

We show here that, in addition to generating an increase in DNA binding efficiency, heterodimerization of retinoid X receptor (RXR) with either retinoic acid receptor (RAR) or thyroid hormone receptor (TR) alters the binding site repertoires of RAR, RXR and TR homodimers. The binding site specificities of both homo- and heterodimers appear to be largely determined by their DNA binding domains (DBDs), and are dictated by (i) homocooperative DNA binding of the RXR DBD, (ii) heterocooperative DNA binding of RXR/RAR and RXR/TR DBDs, and (iii) steric hindrance. No homodimerization domain exists in the DBDs of TR and RAR. The dimerization function which is located in the ligand binding domain further stabilizes, but in general does not change, the repertoire dictated by the corresponding DBD(s). The binding repertoire can be further modified by the actual sequence of the binding site. We also provide evidence supporting the view that the cooperative binding of the RXR/RAR and RXR/TR DBDs to directly repeated elements is anisotropic, with interactions between the dimerization interfaces occurring only with RXR bound to the 5' located motif. This polarity, which appears to be maintained in the full-length receptor heterodimers, may constitute a novel parameter in promoter-specific transactivation.     

Purification, cloning, and RXR identity of the HeLa cell factor with which RAR or TR heterodimerizes to bind target sequences efficiently.

We have purified and cloned a HeLa cell nuclear protein that strongly stimulates binding of retinoic acid and thyroid hormone receptors (RARs and TRs) to response elements. The purified protein is a human retinoid X receptor beta (hRXR beta). Three murine members of the RXR family (mRXR alpha, beta, and gamma) have also been cloned, and their interactions with RARs and TRs have been investigated. Under conditions where RAR, RXR, and TR bound poorly as homodimers to various response elements, strongly cooperative RAR-RXR and TR-RXR binding was observed. The binding efficiency was dependent on the sequence, relative orientation, and spacing of the repeated motifs of response elements. We show also that unstable RAR-RXR heterodimers were formed in solution, and that C-terminal sequences and the DNA-binding domains of both receptors were required for efficient formation of stable heterodimers on response elements. These findings suggest a convergence of the signaling pathways of some members of the nuclear receptor superfamily.