Mark E. Brandt

Cooperativity and Dimerization of Recombinant Human Estrogen Receptor Hormone-binding Domain

The estrogen receptor dimerizes and exhibits cooperative ligand binding as part of its normal functioning. Interaction of the estrogen receptor with its ligands is mediated by a C-terminal hormone-binding domain (HBD), and residues within the HBD are thought to contribute to dimerization. To examine dimer interactions in the isolated HBD, a human estrogen receptor HBD fragment was expressed in high yield as a cleavable fusion protein in Escherichia coli. The isolated HBD peptide exhibited affinity for estradiol, ligand discrimination, and cooperative estradiol binding (Hill coefficient ∼1.6) similar to the full-length protein. Circular dichroism spectroscopy suggests that the HBD contains significant amounts of α-helix (∼60%) and some β-strand (∼7%) and that ligand binding induces little change in secondary structure. HBD dimer dissociation, measured using size exclusion chromatography, exhibited a half-life of ∼1.2 h, which ligand binding increased ∼3-fold (estradiol) to ∼4-fold (4-hydroxytamoxifen). These results suggest that the isolated estrogen receptor HBD dimerizes and undergoes conformational changes associated with cooperative ligand binding in a manner comparable to the full-length protein, and that one effect of ligand binding is to alter the receptor dimer dissociation kinetics.

Expression and characterization of human mitochondrial ferredoxin reductase in Escherichia coli

Ferredoxin reductase (Fd-reductase) supplies reducing equivalents obtained from NADPH to mitochondrial cytochrome P450 enzymes via the small iron-sulfur protein ferredoxin. Two cDNAs (differing by the presence or absence of an 18-bp insert in the coding region) for the human Fd-reductase were subcloned into a newly constructed general purpose expression vector, p delta blue; protein expression under control of the bacteriophage lambda pL promoter was then induced in Escherichia coli. Western blot analysis of subcellular fractions indicated that Fd-reductase protein expressed from both plasmids was present in both inclusion bodies and soluble fractions. However, only the form lacking the insert exhibited Fd-reductase activity. The active material was purified and was found to have electrophoretic, chromatographic, optical, and circular dichroism properties comparable to the bovine homologue. The apparent Km of the expressed protein for NADPH was determined to be 0.7 +/- 0.1 microM and the apparent Km for human ferredoxin was found to be 106 +/- 8 nM. While yields of active enzyme were relatively low (approximately 0.1 mg/liter of culture), the production of Fd-reductase in E. coli will allow structural and mechanistic studies of the enzyme and its interactions with ferredoxin.

Inhibition of aromatase activity and of endocrine-responsive tumor growth by 10-propargylestr-4-ene-3, 17-dione and its 17-propionate derivative

Two androstenedione derivatives, 10-propargylestr-4-ene-3,17-dione and its 17-propionated form, were administered to normal cycling rats, and both compounds led to an inhibition of ovarian aromatase. Under in vitro conditions, only the former compound exhibited high potency as an inhibitor of rat ovarian and human placental microsomal aromatase. At 1 mg/kg/day both compounds were effective in promoting regression of 9,10-dimethyl-1,2-benzanthracene-induced mammary tumors in rats without terminating their estrous cycle. PED also inhibited growth of a human ovarian carcinoma in athymic mice. The results with the 17-propionated compound testify to the necessity of in vivo assays in screening antitumor agents. In summary, PED and its propionated derivative inhibited ovarian aromatase in vivo and inhibited the growth of hormone-responsive tumors.

Characterization of pregnant mare's serum gonadotropin-stimulated rat ovarian aromatase and its inhibition by 10-propargylestr-4-ene-3,17-dione

Aromatase, the important regulatory enzyme that converts androgens to estrogens, is found in relatively high levels in the human placenta. However, since the ovary is the major source of the estrogens in females, we undertook studies to compare the rodent ovarian enzyme with that from human placenta. Pregnant mares serum gonadotropin (PMSG) markedly increases aromatase activity in the ovaries of immature rats, and this model was used in order to reproducibly obtain high enzyme levels. An injection of PMSG resulted in a specific stimulation of aromatase activity 12 times the increase in ovarian weight in 48 h. Kinetic studies demonstrated that, although the PMSG-stimulated ovarian microsomes had one-tenth the specific activity of the human placenta, the Km values were similar (about 33 and 44 nM, respectively). The potent inhibitor of placenta aromatase, 10-propargylestr-4-ene-3,17-dione, was used to further characterize the enzyme. It inhibited the rat aromatase with an I50 of 36 nM and exhibited time-dependent inhibition with a half-life of inactivation of 16 min and a Ki of 15 nM. These values are similar to those we obtained with the human enzyme (10 nM, 12 min, and 5 nM, respectively). The enzyme parameters in the presence and absence of the inhibitor suggest that the enzymes from the two sources are kinetically quite similar.

Inhibition of growth and appearance of estrogen-dependent rat mammary tumors by 10-propargylestr-4-ene-3,17-dione, an aromatase inhibitor

SummaryThe aromatase inhibitor 10-propargylestr-4-ene-3,17-dione (PED) has been evaluatedin vivo as an anticancer agent. Prolonged administration of PED to rats bearing dimethylbenzanthracene-induced mammary tumors resulted in significant regression of hormone-responsive tumors within several days. Greater than 50% regression was generally observed after 14 days of treatment, irrespective of dose (1, 5, or 50mg/kg body weight/day). In addition to tumor regression, a significantly increased incidence in tumor stasis was observed over the course of PED treatment. While all doses of PED examined were equipotent for both tumor regression and stasis, a dose-dependent inhibition of new tumor formation was observed in PED-treated rats. In control animals an average of 1.2 new tumors was observed during the experimental period; in contrast, averages of 0.5 tumors appeared in animals receiving 1mg PED/kg body weight/day, 0.1 tumors at 5 mg/kg, and at 50mg of PED/kg body weight/day, no new tumors occurred during the time PED was administered. The effects of PED on both regression of existing tumors and appearance of new tumors were reversed by co-administration of estradiol. Thus, PED impairs estrogen-dependent mammary tumor growth, resulting in cessation of new growth and regression of responsive tumors.

The effects of in vivo administration of 10-propargylestr-4-ene-3,17-dione on rat ovarian aromatase and estrogen levels

We have previously demonstrated that 10-propargylestr-4-ene-3,17-dione (PED) functioned as an irreversible inhibitor of rat ovarian aromatase in vitro. These studies were undertaken to examine the in vivo effects of PED on rat ovarian aromatase activity and estrogen production. In the current experiments, a single injection of PED (0.5 or 2.5 mg/kg) was found to maximally inhibit aromatase at 3 h regardless of dose. Significant inhibition of enzyme activity by PED was observed beyond 18 h, although some recovery was noted at the lower dose (0.5 mg/kg). Concomitantly, ovarian estrogen levels were also maximally reduced at 3 h, however ovarian estrogen levels returned toward control values prior to the recovery in enzyme activity. Even though significant inhibition of enzyme activity was observed at 12 h following a single injection of PED, the effect of double injections of the inhibitor at 12 h intervals was surprisingly not cumulative. Similarly, continued multiple injections of PED revealed significant inhibition of enzyme activity and estrogen production several hours after the injection, but variations in effectiveness were observed by 12 h which changed in accordance with a circannual cycle in aromatase. Apparently other factors are involved with maintaining aromatase levels and compensating for reduced enzyme activity. These mechanisms are evidenced by a continuation of the rat reproductive cycle with prolonged PED administration and a reduced influence of PED in regard to enzyme inhibition at certain times of the year. Despite these variations in the duration of action of PED, no comparable changes were observed in effectiveness as an anti-tumor agent. These results suggest that complex mechanisms exist which regulate the activity of aromatase in order to maintain estrogen production. Further research using compounds such as PED may assist in elucidating the factors that modulate ovarian estrogen production.