Steroid levels after intramuscular injection of radioactive estradiol-17beta, estrone, progesterone and testosterone in the bovine

Eight 2 year old Hereford cows from days 8 to 12 of the estrous cycle were injected intramuscularly with 5 ml of corn oil containing 5 mg of estradiol-17beta (two cows), estrone (two cows), progesterone (two cows) or testosterone (two cows). Each cow treated with estradiol received 494 microc of estradiol-17beta-6, 7 H3 and each cow treated with estrone received 492 microc of estrone-6, 7 H3. Each cow treated with progesterone or testosterone received 400 muc of H3 compound labeled in the 7 position. Total urine was collected by urethral catheterization of the cows treated with estrogens. Blood samples for plasma and serum were collected via jugular cannulae. Blood and urine samples from estrogen-treated cows were collected hourly for the first 24 hr, at 2 hr intervals for the next 26 hr, at 4 hr intervals for the next 12 hr and at 12 hr intervals until background was reached. Blood samples were collected hourly from 1 to 8 hr after injection from progesterone or testosterone-treated cows. Plasma and serum levels of radioactive estradiol-17beta, estrone, progesterone and testosterone were similar. Blood levels of radioactivity peaked at 2 hr post-injection in cows receiving estradiol-17beta and at 3 hr in cows receiving estrone. Blood levels of labeled estradiol-17beta and estrone were nondetectable by 54 hr and 83 hr, respectively. Peak urinary excretion of radioactivity was reached at 7 hr for estradiol-17beta and at 14 hr for estrone and nondetectable levels were reached by 95 hr for estradiol-17beta and 14 hr for estrone. At these times, 15.5% of the total dose of radioactive estradiol-17beta and 17.5% of the injected estrone had been excreted in the urine. Peak blood and urinary excretion levels were reached earlier for radioactive estradiol-17beta than for estrone, and excretion of estradiol-17beta was completed more rapidly. No difference was found in plasma and serum levels for any steroid studies; thus, endogenous steroid titers in blood plasma and serum are not different in the cow.     

Radioautographic study of the effect of estradiol-17 , estrone, estriol, progesterone, testosterone and corticosterone on the in vitro uptake of 2,4,6,7- 3 H estradiol-17 by uterine eosinophils of the rat

The in vitro uptake of 2,4,6,7-tritiated estradiol-17beta in uterine eosinophils of the rat was inhibited by the presence of nonradioactive estradiol-17beta, estrone, and estriol, but not by progesterone, testosterone, or corticosterone. This action is attributed to competition between tritiated estradiol and the various estrogenic compounds for the same binding site. Compounds without any estrogenic activity do not compete. The proposal is made that the eosinophil binding system and the 8S-5S binding system are involved in different mechanisms of estrogen action. The parallelism between the doses of estradiol and estriol needed to promote certain estrogenic early effects in the uterus, and the affinity of these steroids for the eosinophil uptake sites, suggests that uterine eosinophils might be responsible for some of these early effects, such as water imbibition, histamine releasing activity, and estrogen priming effect.     

Estrogen interconversions in the induced cycle in female rhesus monkeys

To determine the extractions and interconversions of estrone and estradiol across and within the uterus, [3H]estradiol and [14C]estrone were infused at a constant rate in six ovariectomized female rhesus (Macaca mulatta) monkeys. Studies were done on Days 9, 14, and 23 of artificial menstrual cycles induced by the timed insertion and removal of Silastic capsules of estradiol and progesterone. Measurements of estrogen radioactivity were made from peripheral arterial blood and uterine venous blood as well as from endometrial biopsy samples. A significant increase occurred in the conversion of estradiol to estrone measured within the uterus on Day 23 compared to Days 9 and 14. The conversion of estrone to estradiol, measured within the uterus, fell progressively from Day 9 to Day 23, but this decrease was not significant. The extractions and interconversions across the uterus, and the overall interconversions of estrone and estradiol were not significantly different on Days 9, 14, or 23 of the cycle. Thus, we have been able to confirm in vivo the increase in the activity of the 17 beta-hydroxysteroid dehydrogenase, the enzyme responsible for estradiol to estrone interconversions, shown earlier by studies done in vitro. However, the increase in 17 beta-hydroxysteroid activity in the uterus is not reflected in the overall interconversions of estrone and estradiol as reflected by measurements in peripheral arterial blood.     

The uptake of radioactivity by the uterus of the rabbit following the sytemic administration of (3H) estradiol-17beta and (3H) estrone and the identification and subcellular localization of radiometabolites in the uterus

In an effort to determine the relevance of the uterine oxido-reduction of estrogens to their action in the rabbit uterus, the uterine uptake of radioactivity administered subcutaneously as [³h] estradiol-17β or [³H]estrone and the subcellular distribution of radio-metabolites in the uterine tissue were studied. The animals were killed 20 min, 1, 3 and 9 hr after the administration of 0.1 μg tritiated steroid and the relative proportions of radioactive estradiol-17β and estrone in plasma and in ‘cytosol’, ‘mitochondrial/microsomal’ and ‘nuclear’ fractions of the uterine homogenates were studied. Despite the presence of a high proportion of estrone in chloroform extract of plasma, very little was found in the fractions from uterine tissue irrespective of the steroid administered. Highest levels of uterine estrone were found in the ‘mitochondrial/microsomal’ preparation. There was no apparent difference in the pattern of uptake of radioactivity administered as [³H] estradiol-17β or [³H] estrone. The presence of high levels of 17β-hydroxysteroid dehydrogenase activity in the rabbit uterus may be responsible for the apparent difference between these results and those of similar experiments using the rat.     

Plasma estradiol concentrations and effect of HCG on plasma estradiol and testosterone in normal subjects and patients with endocrine disorders.

Plasma estradiol concentrations were determined by radioimmunoassay in various endocrine disorders using antiserum to estradiol-17beta succinyl bovine serum albumin. Clinical significance and diagnostic value of plasma estradiol were assessed in hypothalamic-pituitary, adrenal and gonadal disorders. In general, estradiol concentration was correlated well with the degree of sexual maturity and was of great diagnostic use. Plasma estradiol in females mainly originated from the ovary, while the testis is the principal source of estradiol in males. The adrenal gland seemed to play a minor role as a source of estradiol at least in normal males and females. The role of estradiol in gynecomastia and in liver disease was also investigated. More than a half of the cases with gynecomastia had elevated concentrations of plasma estradiol, which probably explains the pathogenesis of this manifestation. Cirrhotic patients showed frequently hyperestrogenemia probably due to delayed disappearance of estradiol. In the study of stimulation with human chorionic gonadotropin (HCG), 3,000 IU daily for three days in ten normal men, the peripheral concentrations of esradiol showed maximum and fourfold increases 24 hours after the 1st injection of HCG. The testosterone levels, on the other hand, increased stepwise and reached a maximum of about two times preinjection levels 24 hours after the 3rd injection. In gonadal disorders, HCG produced various patterns of plasma estradiol and testosterone in accordance with the gonadal conditions and dissociated response patterns of both sex hormones were frequently found. The determination of plasma estradiol was useful in the study of the function of not only the ovary, but also the testis and the simultaneous measurement of plasma estradiol and testosterone after HCG administration presented interesting informations about pathophysiology of gonadal disorders.     

Steroidal control of rat uterine 17β-hydroxysteroid dehydrogenase activity

The interconversion of estradiol-17β and estrone in the rat uterus is due to the action of 17β-hydroxysteroid dehydrogenase. Whole uteri or 800 × g supernatant fractions of the uteri were incubated in the presence of [³H] estradiol-17β and NAD at 37°C for 3 h or 1 h, respectively. In the mature rat uterus the oxidation of estradiol-17β and estrone was dependent on the stage of the estrous cycle, suggesting hormonal control. The 17β-hydroxysteroid dehydrogenase activity was highest at estrus (200 fmol estrone) and lowest at diestrus (80 fmol estrone). An enhancement of activity occurred when adult rats at each stage of the estrous cycle were administered estradiol-17β, while progesterone administration at each stage resulted in decreased enzyme activity. The uterine 17β-hydroxysteroid dehydrogenase activity of estradiol-17β treated ovariectomized rats was time and dose dependent but decreased when progesterone was administered with or without estradiol-17β administration. These results suggest that estradiol-17β caused an increase in enzyme activity that was inhibitable by progesterone in the rat uterus. The increased 17β -hydroxysteroid dehydrogenase activity may reflect a specific response of the rat uterus to estradiol-17β.     

The metabolism of estradiol-17β by the pregnant guinea pig uterus in vitro

The in vitro metabolism of [³H estradiol-17β-by the uterus was studied in non-pregnant, prenant (day 30-term) and post-parturant guinea pigs. Following incubation of tissue sections for one hour is Krebs-Ringer phosphate buffer, five major metabolites could be extracted from the medium or tissue depending upon age of gestation: estrone-3-glucuronide, estrone-3-sulfate, estradiol-3-glucuronide and estradiol-3-sulfate. Both sulfated estrogens were detected at each age of gestation studied, whereas the glucuronides, mainly of estrone, were not detected until approximately day 50. Thereafter, as term (day 65–70) was approached, their percentage contribution to total radioactivity increased at the expense of estradiol and the sulfates. Following parturition, total metabolites of estradiol rapidly decreased, particularly the glucuronides. No conjugates were detected in uteri from nonpregnant guinea pigs. In addition, no conjugates were found in the pre-partum mouse, rat and hamster or in human endometrium obtained immediately after birth. The data suggest that, in the guinea pig, a biochemical factor in the termination of normal pregnancy is the control of tissue levels of active estrogen (estradiol) by conjugation with glucuronic acid.     

The effects of steroid hormones and gonadotropins on in vitro placental conversion of pregnenolone to progesterone

Using human term placental mitochondrial preparations, optimal conversion of [3H]pregnenolone to [3H]progesterone was obtained at 30 min incubation and with a mitochondrial protein content of 2.5-3.5 mg/ml. Estradiol, estrone, progesterone and testosterone in a dose range of 0.03-8.66 mumol inhibited the in vitro conversion of [3H]pregnenolone to [3H]progesterone by placental homogenates. All four steroids inhibited the pregnenolone to progesterone conversion in a dose-dependent manner. The ID50 (dose required to inhibit conversion of pregnenolone to progesterone by 50%) was 0.04 mumol for estradiol, 0.13 mumol for testosterone, 0.3 mumol for progesterone and 1.0 mumol for estriol. Neither gonadotropin releasing hormone (50-1000 ng) nor human chorionic gonadotropin (5-500 IU) affected the placental basal conversion rate of pregnenolone to progesterone in vitro. Our findings indicate that steroid hormones such as estradiol, estrone, testosterone and progesterone can inhibit local placental progesterone biosynthesis through inhibition of the enzyme complex 5-ene-3 beta-hydroxysteroid dehydrogenase.     

Importance of estrogen sulfates in breast cancer

Estrogen sulfates are quantitatively the most important form of circulating estrogens during the menstrual cycle and in the post-menopausal period. Huge quantities of estrone sulfate and estradiol sulfate are found in the breast tissues of patients with mammary carcinoma. It has been demonstrated that different estrogen-3-sulfates (estrone-3-sulfate, estradiol-3-sulfate, estriol-3-sulfate) can provoke important biological responses in different mammary cancer cell lines: there is a significant increase in progesterone receptor. On the other hand, no significant effect was observed with estrogen-17-sulfates. The reason for the biological response of estrogen-3-sulfates is that these sulfates are hydrolyzed, and no sulfatase activity for C17-sulfates is present in these cell lines. [3H]Estrone sulfate is converted in a very high percentage to estradiol (E2) in different hormone-dependent mammary cancer cell lines (MCF-7, R-27, T-47D), but very little or no conversion was found in the hormone-independent mammary cancer cell lines (MDA-MB-231, MDA-MB-436). Different anti-estrogens (tamoxifen and derivatives) and another potent anti-estrogen: ICI 164,384, decrease the concentration of estradiol very significantly after incubation of estrone sulfate with the different hormone-dependent mammary cancer cell lines. No significant effect was observed for the uptake and conversion of estrone sulfate in the hormone-independent mammary cancer cell lines. Progesterone provokes an important decrease in the uptake and in estradiol levels after incubation of [3H]estrone sulfate with the MCF-7 cells. It is concluded that in breast cancer: (1) Estrogen sulfates can play an important role in the biological response of estrogens; (2) Anti-estrogens and progesterone significantly decrease the uptake and estradiol levels in hormone-dependent mammary cancer cell lines; (3) The control of the sulfatase and 17 beta-hydroxysteroid dehydrogenase activities, which are key steps in the formation of estradiol in the breast, can open new possibilities in the treatment of hormone-dependent mammary cancer.     

Sulfation by guinea pig chorion and uterus: Differential action towards estrone and estradiol

The activities of estrogen sulfotransferase, estrogen sulfatase and estradiol 17β-dehydrogenase change considerably in the guinea pig uterine compartment during gestation. This study was undertaken to enquire if the chorion membrane could influence the pattern of estrogen resulting when substrates were applied to the fetal surface of the chorion while it was attached, late in gestation, to the uterine wall. This tissue system resulted in a differential handling of estrone and estradiol. Estrone was largely excluded from the tissue, remaining mainly in free steroidal form. Estradiol was considerably converted to its 3-sulfate which was mainly retained by the chorion. Parallel experiments with chorion and uterus separately failed to discriminate between the two substrates. Hydrolysis of estrone sulfate and estradiol 3-sulfate was similar in all three tissue systems. It appears that the interaction of chorion with uterus late in gestation causes a difference in tissue action towards the two steroid substrates of closely related structure. The results suggest a limitation in tissue uptake of estrone compared with estradiol, or a much greater sulfotransferase activity towards estradiol. Whole cytosols of late gestational chorion catalyzed sulfation of estradiol at about double the velocity of estrone. This may only partly account for the difference in the intact chorion-uterine tissue system.     

In vitro synthesis of estrogen glucuronides and sulfates by human renal tissue.

17beta-[6,7-3H]Estradiol (E2) was incubated with slices and homogenates of adult human renal tissue. The metabolites formed were identified by chromatography on DEAE-Sephadex, thin layer chromatography and crystallization with carrier steroids or steroid derivatives. The major metabolites formed by slices were estradiol-17-glucuronide (E217G), estrone sulfate and estradiol-3-sulfate. This is the first report of in vitro synthesis of estrogen sulfates by adult renal tissue. Minor quantities of the 3-glucuronides of estrone and estradiol were also found. An oxygen atmosphere appeared to stimulate the production of E217G. A time study with tissue slices showed similarities between the in vitro pattern of glucuronide synthesis and the excretion pattern of these compounds seen in earlier in vivo studies. Homogenates fortified with uridine diphosphoglucuronic acid formed the same pattern of glucuronide products but in lesser amounts. No sulfates were formed under these conditions. Testosterone did not act as a substrate in the experimental conditions used.     

Sex differences in adrenocortical structure and function. XXVIII. ACTH and corticosterone in intact, gonadectomised and gonadal hormone replaced rats

Plasma ACTH and corticosterone (B) concentration, ACTH content in the anterior pituitary gland and B content in the adrenals were measured in intact, gonadectomised and testosterone or estradiol replaced rats. Plasma ACTH and B levels and adrenal B content were higher in female than male rats. Neither orchiectomy nor testosterone replacement had an effect on plasma ACTH and B concentration. Orchiectomy did not affect adrenal B content and decreased pituitary ACTH while testosterone significantly lowered ACTH and B content in studied glands. On the other hand ovariectomy did not change pituitary ACTH and adrenal B content and notably lowered concentrations of these hormones in the blood. Estradiol replacement resulted in an increase in plasma ACTH and B concentrations, an effect accompanied by a marked drop in pituitary ACTH and an increase in adrenal B. These findings indicate the distinct sex differences in basal plasma ACTH and B concentrations with higher values in female rats, an effect dependent on the stimulatory action of estradiol on pituitary-adrenocortical axis.     

Steroid metabolism in human teratocarcinoma cell line PA 1

Human ovarian teratocarcinoma cells of line PA 1, (Zeuthen et al., 1979[1]) used as model for early embryonic cells, were analyzed for their in vitro capacity to convert steroids. The cells were incubated for 20 h with radioactive pregnenolone, progesterone, dehydroepiandrosterone, androstenedione, testosterone or estradiol-17 beta, or with non-radioactive progesterone, 6 alpha- or 6 beta-hydroxyprogesterone, 3 beta-hydroxy-5 alpha-pregnan-20-one, dehydroepiandrosterone or estradiol-17 beta. The metabolites were analyzed by thin layer chromatography or studied by gas chromatography-mass spectrometry. The results indicate that PA 1 cells are able to metabolize, although to a restricted amount, a variety of steroids, most markedly progesterone. The metabolites were almost exclusively found in the medium. The main metabolite of progesterone was 3 beta, 6 alpha-dihydroxy-5 alpha-pregnan-20-one. Minor formation of progesterone from pregnenolone could be detected. Human chorionic gonadotropin did not have any effect on pregnenolone metabolism. No formation of estradiol-17 beta or estrone from dehydroepiandrosterone, androstenedione or testosterone could be detected. However, estradiol-17 beta was shown to be converted mainly to estrone. These findings indicate that undifferentiated PA 1 teratocarcinoma cells like certain mouse teratocarcinoma cells, seem not to be steroidogenic but are capable of metabolizing naturally occurring steroid hormones and their precursors.     

Anabolic utilization of steroid hormones in Helicobacter pylori

In this study, we have demonstrated that Helicobacter pylori absorbs a steroid prehormone (pregnenolone) and two androgens (dehydroepiandrosterone and epiandrosterone), glucosylates these steroids, and utilizes glucosyl-steroid hormone compounds as the membrane lipid components. The only common structure among the steroid prehormone and the two androgens is a 3β-OH in the steroid framework. Our results indicate that the 3β-OH in the steroid hormones is a crucial conformation required for steroid glucosylation by H. pylori . In addition, we found that H. pylori absorbs and holds estrogens possessing 3-OH (estrone and estradiol) into the membrane. The effective absorption of estrogen into the membrane appeared to be controlled by the number of hydroxyl groups modifying the steroid framework. In contrast, H. pylori induced neither membrane absorption nor glucosylation of the other steroid hormones possessing 3=O (progesterone, androstenedione and testosterone) or 3α-OH (androsterone). These results indicate that H. pylori selectively absorbs 3β-OH and 3-OH steroid hormones, and utilizes only 3β-OH steroid hormones as the materials for glucosylation.     

Effect of 3-(3,4-dihydro-6-methoxy-2-naphthyl)2,2-dimethyl pentanoic acid--an antifertility agent--on in vitro uptake of estradiol 17beta-6, 7(3)-H in rat uterus.

The effect of 3-(3,4-dihydro-6-methoxy-2-naphthyl)-2,2-dimethyl-pentanoic acid, a potent nonsteroidal antifertility compound, on the uptake of estradiol-17beta-6, 7-tritiated in vitro in the rat uterus was studied. The estradiol uptake of estrogen-primed and compound-treated groups were the same. When estradiol and the compound were present in medium at the same time, estradiol uptake was significantly (p less than .01) increased. The results indicate that the compound synergizes the effect of estradiol.     

Conversion,in vitro,of (7n-3H) testosterone to estrone and estradiol-17β and their 3-sulfäte conjugate by the guinea-pig placenta

Different cellular fractions of guinea-pig placenta were incubated in the presence of (7n-³H) testosterone. Microsomal aromatization of ³H-testosterone into estrone and estradiol-17β was demonstrated in the presence of NADPH. The predominance of estrone after incubation with 17β-hydroxylated precursors, (7n-³H) testosterone and (6,7-³H) estradiol-17β, indicate that there is a microsomal 17β-hydroxysterold dehydrogenase activity. In this report, cytosolic sulfurylation of estrogens is demonstrated. This latter activity represents a quite original characteristic of the placental metabolism of estrogens in guinea-pigs. In contrast with the human placenta where there is considerable sulfatase activity, the guinea-pig placenta can sulfurylate estrogens.     

In vitro metabolism of estrone 2,4,6,7-3H and 4-androstene-3,17-dione-1,2-3H in submandibular gland and submandibular gland cancer tumor

Tritiated estrone and 4-androstene-3, 17-dione were incubated with slices of human submandibular gland and submandibular gland cancer tumor. Metabolites were separated by paper and thin layer chromatography. Estradiol-17β and testosterone were identified as metabolites. The metabolites were identified by reverse isotope dilution and the preparation of derivatives (formation of acetates). The amounts of estradiol-17β and testosterone formed in the tumor were significantly higher than that formed in the submandibular gland.     

Steroid sulfatase and 17 beta-hydroxysteroid oxidoreductase activities in mouse tissues

The metabolism of estrone sulfate and dehydroisoandrosterone sulfate to the free, unconjugated steroids, estrone and dehydroisoandrosterone, was demonstrated in more than thirty different tissues from male and female BALB/c mice. The activity of steroid sulfatase, when expressed per mg tissue, was greatest in both the pituitary gland and the adrenal glands. The pituitary gland, however, had the lowest capacity for hydrolysis of steroid sulfates while the liver had the greatest capacity. 17 beta-Hydroxysteroid oxidoreductase activity also was demonstrated in all mouse tissues by the formation of estradiol-17 beta when using estrone sulfate as the substrate. The highest apparent activity for 17 beta-hydroxysteroid oxidoreductase was found in lung tissue, and the greatest capacity to form estradiol-17 beta from estrone sulfate was found in liver, lungs, kidneys and testes. This study demonstrates that the majority of mouse tissues have steroid sulfatase and 17 beta-hydroxysteroid oxidoreductase activities.     

Luteinizing hormone concentrations in anestrous ewes administered various estrogens

Twenty four anestrous ewes were evenly assigned to one of six groups and administered either sesame oil, estradiol-17β, estradiol-17α, estrone, estradiol benzoate or estradiol valerate. All estrogen treated ewes received 50 μg of the respective estrogen. Blood plasma was collected for 28 hours post-treatment and quantified for luteinizing hormone (LH) by radioimmunoassay. An estrogen induced LH surge was detected in at least three of the four ewes administered either estradiol-17β, estrone, estradiol benzoate or estradiol valerate whereas only one of the four estradiol-17α treated ewes and none of the ewes administered sesame oil had an LH surge. The interval from treatment to peak LH was similar for estradiol-17β (17.3±2.7 hours), estrone (18.5±1.0 hours) and estradiol benzoate (19.0±0.6 hours) treated ewes but delayed 7 to 9 hours for ewes administered estradiol valerate (26.0±1.2 hours).     

Metabolites of estradiol-17β in guinea pig uterus late in pregnancy

The metabolism of estradiol-17β by the guinea pig uterus late in pregnancy was studied $\text{in vivo}$ and $\text{in vitro}$.Whole uteri were examined for estrogen metabolites one hour following an intravenous injection of [³H]-estradiol-17β or uterine sections were examined after incubation for one hour at 37°C in medium containing [³H]-estradiol-17β.In both instances uterine tissue metabolized estradiol-17g to five products: estrone, estrone-3-sulfate, 17β-estradiol-3-sulfate, estrone-3-glucuronide and 17β-estradiol-3-glucuronide. Of the total radioactive products 11 – 43% were glucuronides, 17 – 26% were sulfates and 4 – 17% was estrone. These results indicate that the guinea pig uterus actively transforms estradiol-17β into glucuronides and sulfates late in pregnancy.