Estrogen receptors (ERs) are believed to be ligand-activated transcription factors belonging to the nuclear receptor superfamily, which on ligand binding translocate into the nucleus and activate gene transcription. To date, two ERs have been identified: ER␣ and ER. ER␣ plays major role in the estrogen-mediated genomic actions in both reproductive and nonreproductive tissue, whereas the function of ER is still unclear. In this study, we used immunocytochemistry, immunoblotting, and proteomics to demonstrate that ER localizes to the mitochondria. In immunocytochemistry studies, ER was detected with two ER antibodies and found to colocalize almost exclusively with a mitochondrial marker in rat primary neuron, primary cardiomyocyte, and a murine hippocampal cell line. The colocalization of ER and mitochondrial markers was identified by both fluorescence and confocal microscopy. No translocation of ER into the nucleus on 17-estradiol treatment was seen by using immunocytochemistry. Immunoblotting of purified human heart mitochondria showed an intense signal of ER, whereas no signals for nuclear and other organelle markers were found. Finally, purified human heart mitochondrial proteins were separated by SDS͞PAGE. The 50,000 -65,000 Mr band was digested with trypsin and subjected to matrix-assisted laser desorption͞ionization mass spectrometric analysis, which revealed seven tryptic fragments that matched with those of ER. In summary, this study demonstrated that ER is localized to mitochondria, suggesting a role for mitochondrial ER in estrogen effects on this important organelle.nuclear receptor ͉ mitochondria E strogens play an important role in development, growth, and differentiation of both female and male secondary sex characteristics. Estrogen receptors (ERs) were the first identified nuclear receptor family member (1). The first ER, now called ER␣, was cloned in 1986 (2, 3). A second ER, was identified and cloned a decade later (4, 5). Like other members of the nuclear receptor superfamily, both ERs have a modular structure consisting of distinct functional domains (1). The DNA-binding domain (DBD) enables the receptor to bind its cognate target site consisting of an inverted repeat of two half-sites with the consensus motif AG-GTCA spaced by 3 bp, referred to as an estrogen response element (ERE). The ligand-binding domain enables estrogen binding to the receptors. ERs are highly conserved between ER␣ and ER, with Ͼ95% homology for the DBD and Ϸ50% homology for the ligand-binding domain. Less homology is observed for the transactivational domain between ER␣ and ER (5, 6).Genomic actions of ER␣ are well described (7). On binding to ER␣, estrogens induce a conformational change in the ER␣ proteins, which is accompanied by the dissociation of the accessory protein, heat shock protein 90, thereby exposing the DBD. In the nucleus, the receptor-ligand complex binds to DNA and modulates gene transcription. This transcriptional͞translational activation is comparatively slow and sensitive to cyclohexi...
