Subnuclear trafficking of estrogen receptor-alpha and steroid receptor coactivator-1.

Abstract

We have analyzed ligand-dependent, subnuclear movements of the estrogen receptor-alpha (ERalpha) in terms of both spatial distribution and solubility partitioning. Using a transcriptionally active green fluorescent protein-ERalpha chimera (GFP-ERalpha), we find that 17beta-estradiol (E2) changes the normally diffuse nucleoplasmic pattern of GFP-ERalpha to a hyperspeckled distribution within 10-20 min. A similar reorganization occurs with the partial antagonist 4-hydroxytamoxifen; only a subtle effect was observed with the pure antagonist ICI 182,780. To examine the influence of ligand upon ERalpha association with nuclear structure, MCF-7 cells were extracted to reveal the nuclear matrix (NM). Addition of E2, 4-hydroxytamoxifen, or ICI 182,780 causes ERalpha to partition with the NM-bound fraction on a similar time course (10-20 min) as the spatial reorganization suggesting that the two events are related. To determine the effects of E2 on the redistribution and solubility of GFP-ERalpha, individual cells were directly examined during both hormone addition and NM extraction and showed that GFP-ERalpha movement and NM association were coincident. Colocalization experiments were performed with antibodies to identify sites of transcription (RNA pol Ilo) and splicing domains (SRm160). Using E2 treated MCF-7 cells, minor overlap was observed with transcription sites and a small amount of the total ERalpha pool. Experiments performed with bioluminescent derivatives of ERalpha and steroid receptor coactivator-1 (SRC-1) demonstrated both proteins colocalize to the same NM-bound foci in response to E2 but not the antagonists tested. Deletion mutagenesis and in situ analyses indicate intranuclear colocalization requires a central SRC-1 domain containing LXXLL motifs. Collectively, our data suggest that ERalpha transcription function is dependent upon dynamic early events including intranuclear rearrangement, NM association, and SRC-1 interactions.