Vitamin D-interacting protein 205 (DRIP205) coactivation of estrogen receptor alpha (ERalpha) involves multiple domains of both proteins

Vitamin D-interacting protein 205 (DRIP205) is a mediator complex protein that anchors the complex to the estrogen receptor (ER) and other nuclear receptors (NRs). In ZR-75 breast cancer cells treated with 17beta-estradiol (E2) and transfected with a construct containing three tandem estrogen responsive elements (pERE(3)), DRIP205 coactivates ERalpha-mediated transactivation. DRIP205Delta587-636 is a DRIP205 mutant in which both NR boxes within amino acids 587-636 have been deleted and, in parallel transfection studies, DRIP205Delta587-636 also coactivates ERalpha. Moreover, both wild-type and variant DRIP205 also colocalize with ERalpha in the nuclei of transfected cells. Extensive deletion analysis of DRIP205 shows that multiple domains of this protein play a role in coactivation of ERalpha and in interactions with ERalpha. Coactivation of ERalpha by DRIP205 does not require NR boxes, and variants with deletion of N-terminal (amino acids 1-639) and C-terminal (amino acids 576-1566) significantly coactivate ERalpha. DRIP205 resembles p160 coactivators that also interact with multiple regions of ERalpha; however, unlike p160 coactivators, DRIP205 coactivation of ERalpha does not require NR boxes.     

Reciprocal recruitment of DRIP/mediator and p160 coactivator complexes in vivo by estrogen receptor

Two functionally distinct classes of coactivators are recruited by liganded estrogen receptor, the DRIP/Mediator complex and p160 proteins, although the relative dynamics of recruitment is unclear. Previously, we have shown a direct, estradiol-dependent interaction between the DRIP205 subunit of the DRIP complex and the estrogen receptor (ER) AF2 domain. Here we demonstrate the in vivo recruitment of other endogenous DRIP subunits to ER in response to estradiol treatment in MCF-7 cells. To explore the relationship between DRIP and p160 coactivators, we examined the kinetics of coactivator recruitment to the ER target promoter, pS2, by chromatin immunoprecipitation. We observed a cyclic association and dissociation of coactivators with the promoter, with recruitment of p160s and DRIPs occurring in opposite phases, suggesting an exchange between these coactivator complexes at the target promoter.     

Cloning and functional characterization of chicken p160 coactivator family members

The factors SRC-1, TIF2 and ACTR were identified as interacting with nuclear receptors in a highly ligand-dependent manner. Because the molecular mass of each of these factors is approximately 160 kDa, they are collectively termed p160 coactivators. So far, p160 coactivators have been cloned from human, mouse and Xenopus. We report here the cloning of the chicken homologues of p160 coactivator members. As in human and mouse, chicken has three p160 coactivators. Each gene encodes an approximately 160 kDa protein which exhibits 70-80% amino acid sequence identity to human and mouse p160 coactivators. Chicken p160 coactivators also have the property of interacting with several liganded nuclear receptors. Moreover, we describe an imperfect LXXLL sequence, termed NR box 4, which is located downstream of NR box 3 and conserved between evolutionarily diverse species. The loss of NR box 4 results in a decrease of interaction with the nuclear receptor, which indicates that NR box 4 is required for efficient interaction.     

Discrete roles for peroxisome proliferator-activated receptor gamma and retinoid X receptor in recruiting nuclear receptor coactivators

Peroxisome proliferator-activated receptor gamma (PPARgamma) plays a major role in adipogenesis. PPARgamma binds to DNA as a heterodimer with retinoid X receptor (RXR), and PPARgamma-RXR can be activated by ligands specific for either receptor; the presence of both ligands can result in a cooperative effect on the transactivation of target genes. How these ligands mediate transactivation, however, remains unclear. PPARgamma is known to interact with both the p160/SRC-1 family of coactivators and the distinct, multisubunit coactivator complex called DRIP. A single DRIP subunit, DRIP205 (TRAP220, PBP), binds directly to PPARgamma. Here we report that PPARgamma and RXR selectively interacted with DRIP205 and p160 proteins in a ligand-dependent manner. At physiological concentrations, RXR-specific ligands only induced p160 binding to RXR, and PPARgamma-specific ligands exclusively recruited DRIP205 but not p160 coactivators to PPARgamma. This selectivity was not observed in interaction assays off DNA, implying that the specificity of coactivator binding in response to ligand is strongly influenced by the allosteric effects of DNA-bound heterodimers. These coactivator-selective effects were also observed in transient-transfection assays in the presence of overexpressed p160 or DRIP coactivators. The results suggest that the cooperative effects of PPARgamma- and RXR-specific ligands may occur at the level of selective coactivator recruitment.