Studies of the pharmacology of 17α-ethynyl-androst-5-ene-3ß,7ß,17ß-triol, a synthetic anti-inflammatory androstene.

17α-Ethynyl-androst-5ene-3ß, 7ß, 17ß-triol (HE3286) is an orally bioavailable analogue of androst-5-ene-3ß,7ß,17ß-triol, a non-glucocorticoid anti-inflammatory metabolite of the adrenal steroid, dehydroepiandrosterone. The pharmacology of HE3286 was characterized in preparation for clinical trials in type 2 diabetes mellitus and other diseases of inflammation. Interactions with nuclear hormone receptors and P450 enzymes were measured in vitro. Drug metabolism was studied preclinically in mice, rats, dogs, and monkeys. Neurological and cardiopulmonary safety and dose-ranging and chronic toxicity studies were conducted in rats and dogs in accordance with FDA guidelines. Pharmacokinetics and metabolites were measured in Phase I clinical trials. HE3286 was differentially metabolized between species. HE3286 and metabolites did not bind or transactivate steroid binding nuclear hormone receptors or inhibit P450 enzymes. There were no adverse effects in safety pharmacology and canine toxicology studies. Although HE3286 did not elicit systemic toxicity in rats, mild estrogenic effects were observed, but without apparent association to hormonal changes. Safety margins were greater than 20-fold in rats and dogs with respect to the most commonly used clinical dose of 10 mg/day. The terminal half-life in humans was 8 hours in males and 5.5 hours in females. HE3286 is the first derivative of the DHEA metabolome to undergo a comprehensive pharmacological and safety evaluation. The results of these investigations have shown that HE3286 has a low potential for toxicity and possesses pharmacological properties generally suitable for use in human medicine. The favorable profile of HE3286 warrants further exploration of this new class of anti-inflammatory agents.

Pharmacology and immune modulating properties of 5-androstene-3ß,7ß,17ß-triol, a DHEA metabolite in the human metabolome.

Androst-5-ene-3ß,7ß,17ß-triol (ßAET) is an anti-inflammatory metabolite of DHEA that is found naturally in humans, but in rodents only after exogenous DHEA administration. Unlike DHEA, C-7-oxidized DHEA metabolites cannot be metabolized into potent androgens or estrogens, and are not peroxisome proliferators in rodents. The objective of our current studies was to characterize the pharmacology of ßAET to enable clinical trials in humans. The pharmacology of ßAET was characterized by pharmacokinetics, drug metabolism, nuclear hormone receptor interactions, androgenicity, estrogenicity, and systemic toxicity studies. ßAET's acute anti-inflammatory activity and immune modulating characteristics were measured in vitro in RAW264.7 cells and in vivo in murine models with parenteral administration. ßAET was rapidly metabolized and cleared from circulation in mice and monkeys. ßAET was weakly androgenic and estrogenic in immature rodents, but not bound by androgen, estrogen, progesterone, or glucocorticoid nuclear hormone receptors. ßAET did not induce peroxisome proliferation, nor was it systemically toxic or trophic for sex hormone responsive tissues in mature rats and monkeys. ßAET significantly attenuated acute inflammation both in vitro and in vivo, augmented immune responses in adult mice, and reversed immune senescence in aged mice. ßAET may contribute to the anti-inflammatory activity in rodents attributed to DHEA. Unlike DHEA, ßAET's anti-inflammatory activity cannot be ascribed to activation of PPARs, androgen, or estrogen nuclear hormone receptors. Exogenous ßAET is unlikely to produce untoward toxicity or hormonal perturbations in humans.

Differential metabolism of androst-5-ene-3ß,17ß-diol between rats, canines, monkeys and humans.

The potent anti-inflammatory activity of exogenous dehydroepiandrosterone (DHEA) in rodents has not translated to humans. This disparity in pharmacological effects has been attributed to factors such as differences in expression and function of molecular targets and differential metabolism. Hepatocytes from rats, dogs, monkeys, and humans were used to measure species-specific metabolism of a related compound, androst-5-ene-3ß,17ß-diol (5-AED) using reversed-phase radio-HPLC, to explore the metabolic contribution to this interspecies disparity. We found that rat hepatocytes transformed 5-AED predominantly into an array of highly oxidized metabolites. Canine metabolites overlapped with rat, but contained a greater abundance of less hydrophilic species. Monkey and human metabolites were strikingly less hydrophilic, dominated by 5-AED and DHEA conjugates. From the accumulating evidence indicating that the DHEA anti-inflammatory activity may actually reside in its more highly oxidized metabolites, we advance a hypothesis that the virtual absence of these metabolites in humans is central to the failure of exogenous DHEA to produce a potent pharmacological effect in clinical investigations. Accordingly, emulation of its anti-inflammatory activity in humans will require administration of an active native metabolite or a synthetic pharmaceutical derivative.

A potential role for 5-androstene-3ß,7ß,17ß-triol in obesity and metabolic syndrome.

Metabolic syndrome is marked by perturbed glucocorticoid (GC) signaling, systemic inflammation, and altered immune status. Dehydroepiandrosterone (DHEA), a major circulating adrenal steroid and dietary supplement, demonstrates antiobesity, anti-inflammatory, GC-opposing and immune-modulating activity when administered to rodents. However, plasma DHEA levels failed to correlate with metabolic syndrome and oral replacement therapy provided only mild benefits to patients. Androstene-3ß,7ß,17ß-triol (ß-AET) an anti-inflammatory metabolite of DHEA, also exhibits GC-opposing and immune-modulating activity when administered to rodents. We hypothesized a role for ß-AET in obesity. We now report that plasma levels of ß-AET positively correlate with BMI in healthy men and women. Together with previous studies, the observations reported here may suggest a compensatory role for ß-AET in preventing the development of metabolic syndrome. The ß-AET structural core may provide the basis for novel pharmaceuticals to treat this disease.

Novel components of the human metabolome: the identification, characterization and anti-inflammatory activity of two 5-androstene tetrols.

Two natural 5-androstene steroid tetrols, androst-5-ene-3ß,7ß,16α,17ß-tetrol (HE3177) and androst-5-ene-3α,7ß,16α,17ß-tetrol (HE3413), were discovered in human plasma and urine. These compounds had significant aqueous solubility, did not bind or transactivate steroid-binding nuclear hormone receptors, and were not immunosuppressive in murine mixed-lymphocyte studies. Both compounds appear to be metabolic end products, as they were resistant to primary and secondary metabolism. Both were orally bioavailable, and were very well tolerated in a two-week dose-intensive toxicity study in mice. Anti-inflammatory properties were found with exogenous administration of these compounds in rodent disease models of multiple sclerosis, lung injury, chronic prostatitis, and colitis.