Influence of ACTH secreting tumor (MtTF4) on fetal rat adrenal gland steroidogenesis in vitro in prolonged pregnancy

Pregnant female rats with ACTH secreting tumor (MtTF4) have prolonged pregnancy and cannot deliver. The fetuses of tumor bearing females have in prolonged pregnancy on days 24 and 25 of pregnancy greater body weight and smaller adrenal weight as compared to intact fetuses of the 22nd day of pregnancy. The fetal adrenal glands converted to vitro 4-14C progesterone to radioactive 11-deoxycorticosterone (DOC), corticosterone (B), 18-hydroxy-11-deoxycorticosterone (18-OH-DOC), 18-hydroxy-corticosterone (18-OH-B) and aldosterone. Fetal adrenal glands in prolonged pregnancy synthetized in vitro less amount of radioactive DOC, B and 18-OH-DOC. A negative relationship exists between the maternal corticosterone which passes the placenta to fetuses and corticosteroidogenesis of fetal adrenal glands. These results indicate the possibility that fetal rat adrenal glands with their corticosteroids participate in pregnancy and influence normal delivery.     

An alternative metabolic pathway of 11-deoxycorticosterone in bovine adrenal in vitro: evidence for the presence of a pathway of 11-deoxycorticosterone oxidation at 19-position

Comparative studies of 11 beta-, 18-, and 19-hydroxylation activities of 11-deoxycorticosterone (DOC) by bovine adrenal mitochondria revealed that an appreciable level of hydroxylation rate was observed in 19-hydroxylation (0.32 nmol/min/mg mitochondrial protein), as well as in 11 beta- and 18-hydroxylations (4.7 and 0.27 nmol/min/mg mitochondrial protein, respectively), at saturated substrate concentration in vitro. Also, the rates of the oxidation reactions of 19-hydroxy-11-deoxycorticosterone (19-OH-DOC) and 19-oxo-11-deoxycorticosterone (19-oxo-DOC) at the 19-position were about 5 times higher than the 19-hydroxylation rate of DOC. Although the affinities of 19-OH-DOC and 19-oxo-DOC for the enzyme(s) involved in the C-19 oxidation were about one-fifth those of DOC, these results strongly suggest the presence of the following pathway in bovine adrenal in vitro: DOC----19-OH-DOC----19-oxo-DOC----19-oic-DOC. This was further confirmed by a dynamic study of the formation and subsequent decay of the C-19 oxidized metabolites produced from DOC. At maximum concentrations of 19-OH-DOC and 19-oxo-DOC, the rates of production of, respectively, 19-oxo-DOC and 19-oic-DOC reached maximum. Furthermore, at the beginning of the incubation (1-4 min), an induction period in the formation of 19-oxo-DOC and 19-oic-DOC was observed and the formation of 19-oxo-DOC always preceded the appearance of 19-oic-DOC. These observations strongly support the existence of the pathway of the C-19 oxidation of DOC as mentioned above. It was also established that reduced pyridine nucleotide (NADPH) and molecular oxygen were required for these oxidation reactions. In addition, these three oxidation reactions were uniformly inhibited by the presence of carbon monoxide or metyrapone (0.01-1.0 microM), which is known to bind specifically with cytochrome P-450, while potassium cyanide (0.01-0.1 mM) did not affect them. These results suggest the possibility of the involvement of cytochrome P-450 in the C-19 oxidation reactions of DOC, 19-OH-DOC, and 19-oxo-DOC. We also showed that 19-oic-DOC is not further metabolized to other steroids such as 19-nor-11-deoxycorticosterone in bovine adrenal cortex.     

Serum corticosteroids at the high and low points of the circadian rhythm in rats with regenerating adrenals.

Serum levels of 11-deoxycorticosterone (DOC), 18-hydroxy-11-deoxycorticosterone (18-OH-DOC) and corticosterone (B) were determined at the high (1800 h) and low (0800 h) points of the circadian rhythm in control rats and in rats with regenerating adrenals. The levels of DOC at 0800 h in quiescent rats with regenerating adrenals were 6.5 times greater than in the control group. The levels of 18-OH-DOC and B, however, were not significantly different between these groups. A circadian rhythm for B, 18-OH-DOC and DOC was evident in control rats with a 12,20 and 3.5 fold increase, respectively, at 1800 h as compared to 0800 h. In animals with regenerating adrenals there was only a minimal change in the levels of B and 18-OH-DOC at 1800 h. There was, however, a 2 fold further increase in the levels of DOC at 1800 h as compared with the elevated levels at 0800 h. These findings show that the decrease in 11β and 18-hydroxylase activity of the regenerating adrenal is most clearly evident at the high point of the circadian rhythm. Furthermore, only by taking into account physiological variations in adrenal activity can an accurate assessment of DOC secretion in the adrenal regeneration model of hypertension be obtained.     

Fetal rat adrenal steroidogenesis and steroid transfer to adrenalectomized mother.

On the 22nd day of gestation in rats, fetuses of acutely adrenalectomized mothers were injected subcutaneously with 0.43 muCi 4-14C-progesterone in 0.05 ml saline. Ten and 20 min after injection to fetuses, samples were taken to determine the 14C-progesterone metabolites in the plasma and adrenal glands. After extraction of the samples taken, the metabolites were separated by two-dimensional thin-layer chromatography and identified by autoradiography. 11-deoxycorticosterone, 18-hydroxy-11-deoxycorticosterone, corticosterone and 11beta-hydroxyprogesterone were identified in the plasma of injected fetuses, and, in far smaller amounts, in the plasma of their mothers. The plasma of noninjected fetuses also contained very small amounts of these corticoids. The fetal adrenal glands contained far smaller amounts of radioactive steroids than the fetal plasma did. The results obtained show that steroids of fetal origin can cross the placenta in and out, constituting evidence that the fetal adrenal glands are the only source of the plasma corticoids of their adrenalectomized mothers.     

Adaptation of aldosterone biosynthesis to sodium and potassium intake in the rat

The steroidogenic response of rat adrenal zona glomerulosa to stimulators is variable and depends on the activity of biosynthetic steps involved in the conversion of deoxycorticosterone (DOC) to aldosterone (Aldo). Corticosterone methyl oxidations (CMO) 1 and 2 are stimulated by sodium restriction and suppressed by potassium restriction. These slow alterations are accompanied by the appearance or disappearance of a specific zona glomerulosa mitochondrial protein with a molecular weight of 49,000. Induction of CMO 1 and 2 activities and the appearance of the 49 K protein can also be elicited in vitro by culture of rat zone glomerulosa cells in a medium with a high potassium concentration. The 49 K protein crossreacts with a monoclonal antibody raised against purified bovine adrenal cytochrome P-450(11 beta). The same antibody stains a protein with a molecular weight of 51,000 in rat zona fasciculata mitochondria and in zone glomerulosa mitochondria of rats in which CMO 1 and 2 activities have been suppressed by potassium restriction and sodium loading. The 51 K crossreactive protein was purified to electrophoretic homogeneity by chromatography on octyl-sepharose. In a reconstituted enzyme system, it converted DOC to corticosterone (B) and to 18-hydroxy-11-deoxycorticosterone (18-OH-DOC) but not to 18-hydroxycorticosterone (18-OH-B) or Aldo. A partially purified 49 K protein preparation from zona glomerulosa mitochondria of rats kept on a low-sodium, high-potassium regimen converted DOC to B, 18-OH-DOC, 18-OH-B and Aldo. According to these results, rat adrenal cytochrome P-450(11 beta) exists in two different forms, with both of them capable of hydroxylating DOC in either the 11 beta- of the 18-position, but with only the 49 K form capable of catalyzing CMO 1 and 2. The adaptation of aldosterone biosynthesis to sodium deficiency or potassium intake in rats is due to the appearance of the 49 K form of the enzyme in zona glomerulosa mitochondria.     

Evidence of adrenal 18-hydroxylase inhibition by metyrapone in man.

The influence of metyrapone (M) on the adrenal 18-hydroxylation was studied in two groups of healthy young men. In group I, serum concentrations of 18-OH-11-deoxycorticosterone (18-OH-DOC) fell significantly after a single oral dose of 40 mg/kg of M at 8.00 h, while those of 11-deoxycorticosterone (DOC) increased by a factor of about 500 within 4 hours after drug administration. Serum concentrations of 18-OH-DOC remained suppressed up to 14,00 h and tended to increase up to 16.00 h with a concomitant increase of plasma ACTH. In group II, serum concentrations of 18-OH-DOC and corticosterone (B) were slightly lowered eight hours after oral administration of 30 mg/kg of M at midnight in comparison with measurement of the previous day. Serum concentrations of 11-deoxycortisol (S) and DOC were markedly increased after drug administration. These findings indicate an inhibitory effect of M on adrenal 18-hydroxylation in addition to 11-hydroxylation under in vivo conditions. The slight increase of 18-OH-DOC at 16.00 h in group I and the only slight decrease of this steroid 8 hrs after drug administration in group II may be explained by declining enzyme blockade and a superimposed ACTH stimulation of the adrenal cortex at this time.     

ACTH and growth hormone relationship in fetal rat adrenal steroidogenesis in vitro.

The effects of growth hormone and ACTH, alone or in combination, on fetal rat adrenal steroidogenesis in vitro were examined on the last day of intrauterine development. ACTH increased, while growth hormone did not affect fetal adrenal weight. ACTH increased fetal rat adrenal steroidogenesis, hydroxylation of 4-14C-progesterone to corticosterone, 18-hydroxy-11-deoxycorticosterone, 11-hydroxycorticosterone and aldosterone. Growth hormone alone had no effect on fetal adrenal steroidogenesis. ACTH and growth hormone administered together increased the conversion of progesterone to the above mentioned steroids to a greater extent than ACTH alone. The results indicate that growth hormone may participate in the fetal rat adrenal steroidogenesis potentiating the effects of fetal pituitary ACTH.     

In vivo and in vitro studies on steroid metabolism in a case of primary aldosteronism with multiple lesions of adenoma and nodular hyperplasia

In order to systematically analyze the regulation and metabolism of steroid hormones in a case of primary aldosteronism with multiple lesions, including adenoma and nodular hyperplasia of the left adrenal gland, the amounts of 9 steroids (progesterone (P), 11-deoxycorticosterone (DOC), corticosterone (B), 18-hydroxycorticosterone (18-OH-B), aldosterone (Aldo), 17 alpha-hydroxyprogesterone (17-OH-P), 11-deoxycortisol (S), cortisol (F) and dehydroepiandrosterone sulfate (DHEAS)) contained in the plasma and in the adrenal tissues were measured. The patient (a 39-year-old female) was admitted to our hospital because of hypokalemia and hypertension. A diagnosis of primary aldosteronism was made on the basis of a complete evaluation, and an adenoma (1.8 x 1.2 cm), a nodular hyperplasia (0.5 x 0.5 cm), a microadenoma and a cortical nodule were found on the left adrenal gland. In vivo studies revealed that the plasma level of Aldo was high, but those of the other steroid hormones were within the normal range. After ACTH infusion, the plasma levels of the 9 steroid hormones increased by 2 to 17 times the base levels. In particular, the responses of DOC and B were markedly high. In vitro studies on P, DOC, B, Aldo and F content in the adenoma (A), the nodular hyperplasia (A'), the adjacent adrenal tissue (C) and the right normal adrenal tissue (D) revealed that, except for F, they were highest in A, followed by A', D and C in that order. In incubation studies with ACTH using A and C, it was found that the levels of 8 steroid hormones with the exception of DHEAS were high in A than in C. In particular, the response of B in A was markedly increased. These findings suggest that aldosteronoma produces 8 steroid hormones under conditions of excess ACTH, while at physiological levels of ACTH, it produces only Aldo in excess.     

Inhibition of aldosterone production in rat adrenal mitochondria by 18-ethynyl-11-deoxycorticosterone: a simple model for kinetic interpretation of mechanism-based inhibitors

A simple mathematical model for studying mechanism-based inhibitors (MBIs) is presented. The mathematical equations are deduced for an experimental protocol consisting of a first incubation of the enzyme in the presence of MBI followed by a washing protocol to eliminate free MBI. Finally enzyme activity (initial velocity) is measured with specific substrate. The representation of the final equation obtained is a straight line, and the MBI-specific association constant of velocity (k) can be calculated from its slope. The mathematical model was then challenged with the effect of 18-ethynyl-11-deoxycorticosterone (18-EtDOC) as an MBI on aldosterone biosynthesis from 11-deoxycorticosterone (DOC) in rat adrenal mitochondria. The last step of the mitochondrial biosynthesis of aldosterone consists of the conversion of DOC into corticosterone (B) or 18-hydroxy-11-deoxycorticosterone (18-OHDOC), and both steroids can then be transformed into aldosterone. The k (mM(-1) x min(-1)) values obtained for 18-EtDOC were: 451 +/- 36 for DOC to aldosterone; 177 +/- 16 for B to aldosterone; 175 +/- 15 for 18-OHDOC to aldosterone; and 2.7 +/- 0.2 for DOC to B. These results show that this MBI practically does not affect the metabolism of DOC to B in our enzyme preparation and that conversions of B and 18-OHDOC into aldosterone are catalyzed by the same enzyme.     

4-14C-progesterone conversion by the fetal rat adrenal gland in vitro.

The adrenal glands of rat fetuses with activated or inhibited pituitary adrenocorticotropic activity between the 15th and 22nd day of intrauterine development were incubated with 4-14C-progesterone for 3hr. Fetuses of intact mothers were used as controls. Conversion of progesterone into adrenal steroids was found increased on the 18th day of intrauterine development, i.e., at the time when fetal adrenocorticotropic activity begins. In comparison to controls, conversion of progesterone into fetal adrenal corticosteroids was the smallest in the fetuses of mothers with inhibited pituitary ACTH and the greatest in the adrenals of fetuses of mothers with activated pituitary adrenocorticotropic activity.     

The development and application of a radioimmunoassay for 18-hydroxy-corticosterone.

A sensitive and specific radioimmunoassay has been developed for 18-hydroxy-corticosterone (18-OH-B) and applied to the measurement of this steroid in peripheral plasma. High specific activity label (3H-18-OH-B) was prepared using the incubation of 3H-corticosterone with duck adrenal mitochondria. Antisera were produced by immunisation with 18-OH-B gamma-lactone 3-oxime conjugated to bovine serum albumin. The antibodies examined showed 100% cross-reactivity with 18-hydroxy-deoxycorticosterone gamma-lactone (18-OH-DOC gamma-lactone), but minimal cross-reactivity with other steroids. Paper chromatography was used to separate 18-OH-DOC gamma-lactone from 18-OH-B gamma-lactone. The interassay precision was 7.6% and the intra-assay precision 11.0%. The accuracy of the method was confirmed by showing a linear relationship between amounts of 18-OH-B added and amounts of 18-OH-B gamma-lactone measured (y = 0.854 X +15.1, r = 0.9. p less than 0.001). The mean plasma level in normal subjects on an ad libitum sodium intake was 225 +/- 92.7 (SD) pg/ml (n = 17) when standing, and 99 +/- 38.3 (SD) pg/ml (n = 6) after lying down for 30 minutes.     

Stable expression of rat cytochrome P450 11β-Hydroxylase (CYP11B1) and aldosterone synthase (CYP11B2) in MA-10 cells

Glucocorticoids and mineralocorticoids are synthesized in the adrenal cortex through the action of two different cytochrome 11β-hydroxylases, CYP11B1 (11β-hydroxylase) and CYP11B2 (aldosterone synthase) which are distributed in the zona fasciculata and glomerulosa, respectively. We have created stably transfected cell lines using the Leydig tumor cell line MA-10 with CYP11B1 and CYP11B2 cDNA-containing plasmids which have a selectable gene to confer resistance to geneticin. The expression of the transfected cDNA in the cells was characterized by Northern-blot and measurement of enzymatic activity. The cell lines express the enzymes stably for many generations. CYP11B1 transfected cells converted DOC into corticosterone, 18-OH-DOC and small amounts of 18-OH-corticosterone, in a time and concentration dependent manner. Incubation of the cells with corticosterone generated 18-OH-corticosterone especially at concentrations of 30 and 100 μM. The production of 18-OH-corticosterone from corticosterone at these doses was significantly higher than incubations with similar concentrations of DOC. CYP11B2 transfected cells converted DOC into corticosterone, 18-OH-corticosterone, aldosterone and small amounts of 18-OH-DOC in a time and concentration dependent manner. They converted corticosterone into 18-OH-corticosterone and aldosterone in a time and concentration dependent manner. The absolute and relative production of aldosterone from DOC was significantly higher than when cells were incubated with corticosterone, and the ratio of aldosterone to 18-OH-corticosterone was higher at all concentrations of DOC compared to corticosterone. CYP11B2 transfected cells (but not the CYP11B1 transfected cells) transform 18-OH-DOC into 18-OH-corticosterone, but can not convert 18-OH-DOC into aldosterone. In conclusion, stably transfected MA-10 cells with the cDNAs for the CYP11B1 and CYP11B2 enzymes were prepared and their enzymatic activity studied. These cells are useful in the study of inhibitors of the specific enzymes, as well as determining the roles that each enzyme plays in zone-specific steroidogenesis in the adrenal cortex.     

19-Hydroxylation of 18-hydroxy-11-deoxycorticosterone by adrenal mitochondria prepared from various animal species

We have recently reported that bovine adrenocortical cytochrome P-45011 beta catalyzes 19-hydroxylation of 18-hydroxy-11-deoxycorticosterone (18(OH)DOC) in addition to 11 beta-hydroxylation of the steroid. In this report, we examine the presence of these two activities in 18(OH)DOC and 11 beta- and 18-hydroxylation activities on deoxycorticosterone (DOC) among the adrenal mitochondria prepared from man, ox, pig, rabbit, guinea-pig and rat. The results indicate that these animals could be classified into three groups with respect of these hydroxylation activities. Mitochondria of the first group comprising ox and pig showed rather high 19- and 11 beta-hydroxylation activities on 18(OH)DOC compared to the hydroxylation activities on DOC. Mitochondria prepared from the second group which comprised rabbit, guinea-pig and man showed low 19-hydroxylation activity on 18(OH)DOC, whereas the 11 beta-hydroxylation of 18(OH)DOC well occurred in these species. The last group comprising rat had very low activity both of 11 beta- and 19-hydroxylations when 18(OH)DOC was used as the substrate, whereas both 11 beta- and 18-hydroxylations of DOC were high in rat adrenal mitochondria. No significant difference of these activities could be found between zona glomerulosa cells and zonae fasciculata-reticularis cells of bovine adrenal cortex, and between adrenal mitochondria from spontaneously hypertensive rat and those from WKY normotensive rat.     

18,19-Dihydroxydeoxycorticosterone; A novel product of cytochrome P-45011β-catalyzed reaction

After incubating 18-hydroxydeoxycorticosterone (18-OH-DOC) with cytochrome P-450_11β in the reconstituted system, the products were analyzed with HPLC. There appeared two product-peaks on the chromatogram, one of which was identified as a peak of 18-hydroxycorticosterone (18-OH-B), an expected product of the 11β-hydroxylation. Another peak did not coincide with those of any known corticoids. This unidentified product was further purified, and the purified material was analyzed by gas chromatography-mass spectrometry ($\text{GC}\text{MS}$). The mass spectrum showed that the unidentified product is one of the structural isomers of 18-OH-B. A further analysis with ¹H-NMR spectrometry indicated that a proton resonance peak of 19-CH₃ in 18-OH-DOC disappeared in the product and the methyl group of the substrate seemed to be converted to -CH₂OH. These results suggested that the unidentified product generated from 18-OH-DOC by P-450_11β-linked hydroxylase system may be 18,19-dihydroxydeoxycorticosterone (18,19,21-trihydroxypregn-4-ene-3,20-dione; 18,19-diOH-DOC), a hitherto unreported corticoid.     

Plasma levels of 18-hydroxy-11-deoxycorticosterone in essential hypertension.

In order to investigate the role of 18-hydroxy-11-deoxycorticosterone (18-OH-DOC) in essential hypertension (EH), the responses of plasma 17-OH-DOC to 7 stimulation tests (furosemide test, adrenal suppression test, angiotensin II infusion test, adrenal stimulation test, metopirone test, saline infusion test and potassium chloride infusion test) and the circadian rhythm were investigated in 18 patients with essential hypertension (low renin group: 8, and normal renin group: 10). From the present study, it micht be thought that plasma 18-OH-DOC does not play an important role in the suppression of PRA in patients with low PRA.     

18-Hydroxy-11-deoxycorticosterone in hypertensive uremic patients during hemodialysis.

The present study was carried out in 25 hypertensive uremic patients on regular 4 h dialysis, 3 times a week. Plasma 18-hydroxy-11-deoxycorticosterone (18-OH-DOC), aldosterone (PA) and corticosteroids were determined by radioimmunoassay and competitive protein binding technique before and at the end of the 1st, 2nd and 3rd hour of hemodialysis. Plasma 18-HD-DOC was normal before dialysis and did not change significantly during hemodialysis, whereas body fluids and electolytes decreased progressively. No correlation was observed between blood pressure and 18-OH-DOC during dialysis. 18-OH-DOC did not correlate with PA which decreases progressively during hemodialysis and was correlated to plasma corticosteroids only at the 3rd hour of dialysis, probably on account of the enhanced influence of ACTH on the adrenal cortex.     

Norbormide enhances late steps of steroid-hormone synthesis in rat and mouse adrenal cortex

Norbormide (N) is a vasoconstrictor agent, which acts selectively on the peripheral arteries of the rat, through the activation of the phospholipase C (PLC) cascade and the stimulation of Ca(2+) entrance in the vascular myocytes. Several endogenous vasoconstrictor agent (e.g. angiotensin-II (ANG-II) and endothelin-1 (ET-1)), that stimulate PLC pathway, are also able to enhance aldosterone secretion by the adrenal gland. Hence, we examined the effects of norbormide ((0.5, 1.0 or 5) x 10(-5)M) on corticosteroid-hormone secretion from adrenal slices of rats and mice. Quantitative HPLC assay showed that under basal conditions rat and mouse adrenal quarters secreted progesterone (PROG), 11-deoxycorticosterone (DOC), 18-hydroxy-DOC (18OH-DOC), corticosterone (CORT), 18-hydroxy-corticosterone (18OH-CORT) and aldosterone (ALDO), as well as large amounts of pregnenolone (PREG) when its metabolism was blocked by 10(-5)M cyanoketone. Norbormide concentration-dependently raised the secretion of all post-DOC steroids assayed, decreased progesterone and DOC production, and did not affect pregnenolone release. In conclusion, norbormide is able to enhance late steps of steroid synthesis, i.e. those leading to the transformation of DOC to corticosterone and aldosterone, without affecting early steps. This is an interesting finding because the other main endogenous adrenal secretagogues are known to stimulate both early and late steps of steroid synthesis. The mechanism underlying the selective activating action of norbormide on 11beta- and 18-hydroxylation remains to be investigated.     

Adrenal cortex, tumor, and peripheral production of deoxycorticosterone.

A method is reported for the measurement of the urine excretion rates of tetrahydro-11-deoxycorticosterone (3 alpha,5 beta-THDOC), an important metabolite of 11-deoxycorticosterone (DOC). Quantification using gas chromatography/mass spectrometry (GC/MS) was achieved by comparing the ion fragment response for the molecular ion (m/z 507) of the analyte (as methyloxime trimethylsilyl ether derivative) to that of a fixed amount of an isomer of THDOC added to urine as internal standard. To improve the specificity of measuring THDOC in clinical samples, an additional Sephadex LH-20 chromatography step was introduced to separate 11-deoxycortisol and some progesterone metabolites. In the luteal phase of the menstrual cycle, THDOC excretion was higher than in the follicular phase; it was also higher than in women taking oral contraceptives. The correlation of THDOC with progesterone production, independent of a constant cortisol output, supports an ovarian or peripheral conversion of progesterone to DOC. The assay proved useful (1) in monitoring for the recurrence of a mineralocorticoid-secreting tumor and (2) when adrenal production of DOC was not fully suppressed in congenital adrenal hyperplasia due to 11 beta-hydroxylase deficiency. Under the latter circumstances, the renin-angiotensin system seemed to be an important regulator of DOC production.     

Evaluation of adrenal function in rats by the measurement of urinary free corticosterone, free aldosterone and free 11-deoxycorticosterone.

Methods für the determination of urinary free corticosterone, free aldosterone and free 11-deoxycorticosterone (DOC) in rats are described. The free corticosteroids were measured in urine samples of 0.1–0.5 (2.0) ml by radioimmunoassay after purification by column chromatography. The validity of the methods is demonstrated by the data of the free urinary corticoids under basal conditions and after adrenal suppression and various forms of adrenal stimulation. The basal excretion of free corticosterone, free aldosterone and free DOC was 123.71 ± 15.31 (x? ± SD), 3.87 ± 1.29 and 10.61 ± 2.24 ng/day, respectively, exhibiting a decrease to 26.20 ± 5.21, 1.05 ± 0.47 and 1.35 ± 1.20 ng/day after adrenal suppression by dexamethasone. Irrespective of the mode of adrenal stimulation i.e., synthetic ACTH and systemic (cold, hunger) or neurotrophic (ether, reserpine) stress stimuli free corticosterone increased to about 450 ng/day, while free aldosterone excretion decreased during hunger and cold and was strongly enhanced after the application of reserpine. Furthermore, determination of urinary free DOC, which increased by a factor of 4, may be applied in the metyrapone test. There was a good correlation between the excretion of free corticosterone and that of free aldosterone and free DOC under basal conditions and after ACTH application, demonstrating that ACTH is responsible for the secretion of all the 3 corticoids measured. It is concluded, that the measurement of the urinary excretion of corticosterone, aldosterone and DOC is a valuable parameter of adrenal function in rats. Furthermore, in small laboratory animals like rats steroid measurements in urine are often more advantageous than Measurements in plasma.     

Basal and HCG-stimulated testosterone production by interstitial cells of the Mongolian gerbil (Meriones unguiculatus)--II. Influence of glucocorticosteroids and steroidal precursors

Compared to testosterone production by Mongolian gerbil interstitial cells in the absence of HCG or precursors, testosterone formation was significantly elevated by the addition of 100 ng pregnenolone, progesterone, 17-hydroxyprogesterone or DHEA. Production increased linearly with the amounts of precursors added (pregnenolone: r = 0.99; progesterone: r = 0.98; 17-OH-progesterone: r = 0.96; DHEA: r = 0.92, N = 40, all P less than 0.001). Approximately 50% of DHEA were converted to testosterone during the 6-hr incubation period. Neither the addition of 100 ng 11-deoxycortisol, 11-deoxycorticosterone, cortisol, corticosterone, cortisone, 18-OH-corticosterone, 21-deoxycortisone or 11-dehydrocorticosterone, nor of 100 ng estradiol had a significant effect on testosterone production by isolated interstitial cells incubated without or with 1 mIU HCG. Testosterone production by isolated interstitial cells was significantly increased within 2 min after the addition of 100 ng DHEA; production then linearly increased with the length of incubation (r = 0.98, N = 40, P less than 0.001). After addition of as little as 2 ng DHEA, testosterone formation was higher than by cells incubated without DHEA. While testosterone production could not be stimulated by the addition of 1-500 microIU HCG during a 30-min incubation period, it was drastically elevated by the addition of 10, 20 or 100 ng DHEA. Steroidal precursor concentrations secreted by the Mongolian gerbil adrenal gland incubated in vitro for 120 min were too low to stimulate testosterone production by interstitial cells. On the other hand, testosterone synthesis could be increased by the addition of 10-100-microliter aliquots of adrenal extracts.