What are the physiological estrogens?

Estradiol (E2) is the principal physiological estrogen in mammals. E2 and its active metabolites, estrone and estriol have a characteristic phenolic A ring, unlike progesterone, testosterone, cortisol and aldosterone, which have an A ring containing a C3-ketone, a Δ(4) bond and a C19 methyl group. Crystal structures of E2 in the estrogen receptor (ER) confirm the importance of the A ring in stabilizing E2 in the ER. However, other steroids, including Δ(5)-androstenediol, 5α-androstanediol and 27-hydroxycholesterol, which have a saturated A ring containing a 3ß-hydroxyl and a C19 methyl group, also mediate physiological responses through binding to estrogen receptor-α (ERα) and ERß. Moreover, selective estrogen response modulators (SERMs) with diverse structures also regulate transcription of ERα and ERß. Our understanding of the physiological responses mediated by these "alternative" estrogens is in its infancy. Further studies of the role of these steroids and SERMs in regulating responses mediated by ERα and ERß a variety of tissues, during different stages of development, are likely to uncover additional estrogenic activities.

17α-androstenediol-mediated oncophagy of tumor cells by different mechanisms is determined by the target tumor.

Δ5-androstene-3ß,17α-diol (17α-AED) mediates oncophagy of human myeloid, glioma, and breast tumor cells by apoptotic- and autophagic-programmed cell death pathways, whereas the 17ß-epimer does not. In hematologically derived myeloid tumor cells, 17α-AED induced apoptosis, as determined by TUNEL staining, caspase, PARP activation, and electron microscopy. In contrast, 17α-AED treatment of glioma cells of neuroectodermal lineaged induced autophagy, evident by the presence of acidic vesicular organelles, LC3 processing, and upregulation of beclin-1. Proliferation inhibition studies on primary and established glioma cells demonstrated that the IC-50 of the steroid is ∼15 µM. In the case of breast cancer cells, the bioactivity of 17α-AED is independent of the expression of estrogen or androgen receptors. Collectively, oncophagy is induced by 17α-AED treatment in human tumor cells and proceeds by the induction of either autophagy or apoptosis. The neoplastic cell determines which oncophagic pathway is utilized.

Hydroxylation of DHEA, androstenediol and epiandrosterone by Mortierella isabellina AM212. Evidence indicating that both constitutive and inducible hydroxylases catalyze 7α- as well as 7ß-hydroxylations of 5-ene substrates.

The course of transformation of DHEA, androstenediol and epiandrosterone in Mortierella isabellina AM212 culture was investigated. The mentioned substrates underwent effective hydroxylation; 5-ene substrates--DHEA and androstenediol--were transformed into a mixture of 7α- and 7ß- allyl alcohols, while epiandrosterone was converted into 7α- (mainly), 11α- and 9α- monohydroxy derivatives. Ketoconazole and cycloheximide inhibition studies suggest the presence of constitutive and substrate-induced hydroxylases in M. isabellina. On the basis of time course analysis of the hydroxylation of DHEA and androstenediol, the oxidation of allyl C(7)-H(α) and C(7)-H(ß) bonds by the same enzyme is a reasonable assumption.

C(19)-5-ene steroids in nature.

Dehydroepiandrosterone (DHEA), produced from cholesterol in the adrenals, is the most abundant steroid in our circulation. It is present almost entirely as the sulfate ester, but the free steroid is the form that serves as a precursor of estrogens and androgens, as well as 7- and 16-oxygenated derivatives. Mammalian tissues reduce the 17-keto Group of DHEA to produce androstenediol-a weak estrogen and full-fledged androgen. Its androgen activity is not inhibited by the anti-androgens commonly used to treat prostate cancer. It is probably responsible for the growth of therapy-resistant prostate cancer. DHEA is hydroxylated at the 7 alpha position, and this derivative is oxidized by 11 beta-hydroxysteroid dehydrogenase to form 7-keto DHEA. The latter is reduced by the same dehydrogenase to form 7 beta-hydroxy DHEA. When fed to rats, each of the latter three steroids induce the formation of two thermogenic enzymes in the liver. The late-term human fetus produces relatively large amounts of 16 alphahydroxy DHEA, which serves the mother as a precursor of estriol.

Synthesis of 3-methyl-3-hydroxy-6-oxo-androstane derivatives.

3alpha,17beta-Dihydroxy-3beta-methyl-5alpha-androstan-6-one (1) and 3beta,17beta-dihydroxy-3alpha-methyl-5alpha-androstan-6-one (13) were prepared by the reaction of methylmagnesium bromide with the 3-ketosteroids. Structures and configurations in position 3 were determined by NMR spectra. Substitution in the position 6 influences the ratio of the products.

Sterol structure and sphingomyelin acyl chain length modulate lateral packing elasticity and detergent solubility in model membranes.

Membrane microdomains, such as caveolae and rafts, are enriched in cholesterol and sphingomyelin, display liquid-ordered phase properties, and putatively function as protein organizing platforms. The goal of this investigation was to identify sterol and sphingomyelin structural features that modulate surface compression and solubilization by detergent because liquid-ordered phase displays low lateral elasticity and resists solubilization by Triton X-100. Compared to cholesterol, sterol structural changes involved either altering the polar headgroup (e.g., 6-ketocholestanol) or eliminating the isooctyl hydrocarbon tail (e.g., 5-androsten-3beta-ol). Synthetic changes to sphingomyelin resulted in homogeneous acyl chains of differing length but of biological relevance. Using a Langmuir surface balance, surface compressional moduli were assessed at various surface pressures including those (pi > or =30 mN/m) that mimic biomembrane conditions. Sphingomyelin-sterol mixtures generally were less elastic in a lateral sense than chain-matched phosphatidylcholine-sterol mixtures at equivalent high sterol mole fractions. Increasing content of 6-ketocholestanol or 5-androsten-3beta-ol in sphingomyelin decreased lateral elasticity but much less effectively than cholesterol. Our results indicate that cholesterol is ideally structured for maximally reducing the lateral elasticity of membrane sphingolipids, for enabling resistance to Triton X-100 solubilization, and for interacting with sphingomyelins that contain saturated acyl chains similar in length to their sphingoid bases.

Identification of 5alpha-androst-1-ene-3beta,17beta-diol in the fat of Sus scrofa L.: a "nutritional supplement" not found previously in the food supply.

5alpha-Androst-1-ene-3beta,17beta-diol (1) was detected in extracts from fat of Sus scrofa L. (pig) by comparison with the commercially available synthetic compound, using gas chromatography-mass spectrometry. This observation is unprecedented because 1 is currently sold as a nutritional supplement, yet has not been previously reported as naturally occurring in the food supply.

Contrasting effects of alpha- and beta-androstenediol on oncogenic myeloid cell lines in vitro.

The in vitro effects of 17 alpha AED, the isomer of 5-androstene-3 beta,17 beta diol (17 beta AED) on the basal growth of murine RAW 264.7, P388D1, and human HL-60 cells were investigated. 17 alpha AED treatment of RAW cells for 48 h reduced total cell number without increasing cell death as detected by trypan blue exclusion. At these doses, DNA synthesis as measured by [3H]thymidine incorporation was suppressed by as much as 65%, P < 0.05. This effect was time- and dose-dependent and reversible on removal of the steroid. Similar results were obtained with P388D1 and human HL-60 cell lines. At 50 nM or above, 17 alpha AED induced apoptosis in RAW cells and HL-60 as detected by transmission electron microscopy and TUNEL assays. By contrast, treating cells with the isomer 17 beta AED had no such effect. These data suggest that the balance between the anti-proliferative effect of 17 alpha AED and the proliferative effects of 17 beta AED may determine the overall level of myelopoiesis.

Kinetic competence of an externally generated dienol intermediate with steroid isomerase.

The putative intermediate dienol (2) in the steroid isomerase (KSI) catalyzed conversion of 5-androstene-3,17-dione (1) to 4-androstene-3,17-dione (3) has been independently generated and tested as a substrate for KSI. At pH 7, dienol 2 is converted by KSI to a mixture of 1 (46%) and 3 (54%). The apparent second-order rate constant for reaction of 2 with KSI to produce 3 (kappa cat/Km = 2.3 x 10(8) M-1 s-1) is similar to that for reaction of 1 with KSI (kappa cat/Km = 2.1 x 10(8) M-1 s-1), demonstrating that 2 is kinetically competent. Isomerization of 1 by KSI in D2O gives only 5% of solvent deuterium incorporated into the product 3. When 2 reacts with KSI in D2O, and the product 3 is isolated (from direct reaction of 2 and from subsequent conversion of the 1 initially formed), ca. 80 atom % deuterium is located at C-6 beta, confirming that protonation of the dienol by KSI occurs at the same face as the proton transfer in the KSI catalyzed reaction of 1 to 3.