Subcellular distribution of [3H]-dexamethasone mesylate binding sites in leydig cells using electron microscope radioautography

Abstract

The present view is that glucocorticoid hormones bind to their cytoplasmic receptors before reaching their nuclear target sites, which include specific DNA sequences. Although it is believed that cytoplasmic sequestration of steroid receptors and other transcription factors (such as NFKB) may regulate the overall activity of these factors, there is little information on the exact subcellular sites of steroid receptors or even of any other transcription factors. Tritiated (3H)-dexamethasone 21-mesylate (DM) is an affinity label that binds covalently to the glucocorticoid receptor (GR), thereby allowing morphological localization of the receptor at the light and electron microscope levels as well as for quantitative radioautographic (RAG) analysis. After injection of 3H-DM into the testis, a specific radioautographic signal was observed in Leydig cells, which correlated with a high level of immunocytochemically demonstrable GR in these cells at the light-microscope level. To localize the 3H-DM binding sites at the electron microscope (EM) level, the testes of 5 experimental and 3 control adrenalectomized rats were injected directly with 20 microCi 3H-DM; control rats received simultaneously a 25-fold excess of unlabeled dexamethasone; 15 min later, rats were fixed with glutaraldehyde and the tissue was processed for EM RAG analysis combined with quantitative morphometry. The radioautographs showed that the cytosol, nucleus, smooth endoplasmic reticulum (sER), and mitochondria were labeled. Since the cytosol was always adjacent to tubules of the sER, the term sER-rich cytosol was used to represent label over sER networks, which may also represent cytosol labeling due to the limited resolution of the radioautographic technique. Labeling was highest in sER-rich cytosol and mitochondria, at 53% and 31% of the total, respectively. Cytosol (exclusively of all organelles) and nucleus showed comparatively weak labeling, at 9% and 7%, respectively. This study thus clearly establishes with the electron microscope, the localization of glucocorticoid binding sites using DM. It remains to be determined whether or not these DM binding sites represent bona fide glucocorticoid receptors or nonreceptor proteins that bind DM. Whereas the functional significance of the subcellular distribution of DM is not known, the labeling of the cytosol may represent localization of the steroid and GR in their traditional compartment. The steroid antagonistic properties of DM may have prevented the DM-GR complexes from translocating to the nucleus. However, the significant labeling of the sER-rich cytosol and mitochondria was unexpected and raises intriguing questions that are being addressed in current studies.