Comparison of the mineralocorticoid activity of 19-oxygenated and 19-nor derivatives of deoxycorticosterone.

19-Nordeoxycorticosterone (19-nor-DOC) is a mineralocorticoid with several unresolved physiologic questions. First, is 19-nor-DOC synthesized in the kidney from a circulating adrenocortical precursor (19-oicdeoxycorticosterone [19-oic-DOC] or 19-oxodeoxycorticosterone [19-oxo-DOC])? Second, does 19-nor-DOC, synthesized in the kidney, have mineralocorticoid activity or is it excreted in the urine without biologic activity? To answer this question, we administered two of the putative 19-nor-DOC precursors (19-oxo-DOC and 19-oic-DOC) to adrenalectomized rats and measured the formation of 19-nor-DOC and bioactivity as the urinary Na+ to K+ ratio. Each of the 10-microgram steroid treatments produced an elevation of urinary-free 19-nor-DOC (0 to 2 hours), whereas at the 1-micrograms dose only 19-oic-DOCA produced an increased UF 19-nor-DOC. None of the treatments led to an increase of conjugated 19-nor-DOC except 10 microgram 19-oic-DOCA. Increased mineralocorticoid activity (decreased urinary Na+ to K+ ratio) was produced by aldosterone, 1 and 10 micrograms 19-nor-DOC, and 10 micrograms 19-oic-DOCA over the same time period. An anti-mineralocorticoid effect (increased urinary Na+ to K+ ratio) was produced by 1 microgram 19-oxo-DOC. Urinary-free 19-nor-DOC, but not conjugated 19-nor-DOC, correlated with the urinary mineralocorticoid effect (decreased Na+ to K+ ratio). These data support the contention that 19-oic-DOC is the circulating 19-nor-DOC precursor and that, at least at the higher dose, it has a mineralocorticoid action on the kidney.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism of 11-deoxycorticosterone by hamster adrenal mitochondria.

Metabolism of 11-deoxycorticosterone (DOC) by hamster adrenal mitochondria gives 19-hydroxy-DOC and corticosterone (via 11-hydroxylation) in approximately equal yields. The ratio of 19- to 11-hydroxylation was invariant with changes in concentration of substrate or a competitive inhibitor. It is most likely, therefore, that a single 11,19-hydroxylase catalyzes both oxidations. Both primary products are further oxidized to the corresponding carbonyl analogs, 19-oxo-DOC and 11-dehydrocorticosterone, at rates that are approx. 20% of their rates of formation. The oxidation of 11-dehydrocorticosterone is catalyzed by a dehydrogenase utilizing either NAD or NADP while the oxidation of 19-hydroxy-DOC is catalyzed by an oxidase requiring NADPH. The 11-dehydrocorticosterone is stable in this enzyme preparation while 19-oxo-DOC is metabolized to two additional products, which are tentatively identified as 19-oic-DOC and 19-norcorticosterone. 19-nor-DOC was found to be hydroxylated at a rate that is 20% faster than the rate for DOC under the same conditions. It is therefore possible that 19-norcorticosterone can arise from 19-oic-DOC via decarboxylation to 19-nor-DOC and subsequent 11-hydroxylation, but the kinetics of its formation suggest that it may actually be formed directly from 19-oxo-DOC without free intermediates. 4-Androstene-3,17-dione and 17-hydroxy-DOC were also substrates for this 11,19-hydroxylase, but 18-hydroxy-DOC was not. Maintenance of hamsters on a low sodium diet had no effect on the metabolism of DOC by the isolated adrenal mitochondria.     

19-Nordeoxycorticosterone synthesis by rat kidney inner medullary collecting duct cells

19-Nordeoxycorticosterone (19-nor-Doc), a potent mineralocorticoid, was found to be synthesized by the isolated rat kidney perfused by an adrenal precursor (19-oxo-Doc). To determine if this bioconversion is a function of renal tubular cells, various adrenal precursors of 19-nor-Doc were added separately to rat kidney inner medullary collecting duct cells culture media at a concentration of 10 nM. While 4.6% +/- 1.0% of 19-oxo-Doc (n = 3) and 14.4% +/- 1.4% of 19-oic-Doc (n = 3) were converted to 19-nor-Doc after 24 hours of incubation, Doc, and 19-OH-Doc were not converted. This represents further evidence that Doc has to be metabolized to 19-oxo-Doc or 19-oic-Doc (19-carboxy-Doc) before it can be converted by the kidney inner medullary collecting duct cells to 19-nor-Doc.     

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.     

Renal 21-hydroxylation of 19-hydroxy-progesterone to 19-hydroxy-deoxycorticosterone

19-Nor-deoxycorticosterone (19-nor-DOC) is a mineralocorticoid present in both rat and human urine, and it is elevated in some forms of experimental and human hypertension. Although the exact steps in the biosynthesis of 19-nor-DOC are uncertain, it is probably produced from a 19-oxygenated derivative of DOC, which undergoes 19-desmolation in the kidney. Since DOC biosynthesis is partly due to renal 21-hydroxylation of progesterone (Prog), we sought to determine whether a parallel pathway could exist for the biosynthesis of 19-hydroxy-DOC, a precursor to 19-nor-DOC. In order to test this hypothesis, authentic 19-hydroxy-progesterone was incubated with homogenized renal tissues from either rat or human sources. Formation of 19-hydroxy-DOC was found to be the major metabolite in both rat and human incubations, as demonstrated by an HPLC retention time identical to authentic 19-hydroxy-DOC. 19-Hydroxy-DOC formation was further verified by GC/MS analysis with highly sensitive selected ion recording. Since it has been demonstrated that the placenta can convert progesterone to 19-hydroxy-progesterone, the renal 21-hydroxylation of 19-hydroxy-progesterone to 19-hydroxy-DOC could be an alternate pathway of 19-nor-DOC production especially during pregnancy.     

Decreased serum 19-nor-deoxycorticosterone (21-hydroxy-19-nor-4-pregnene-3, 20-dione) level in adrenal regeneration hypertensive rats

An enzyme immunoassay of 19-nor-deoxycorticosterone in rat serum was established. The normal value of 19-nor-DOC in rat serum obtained from 9:00 am to 10:00 am was 148 +/- 30 ng/dl (mean +/- SE,n = 10). Serum levels of this steroid decreased in rats with adrenal regeneration hypertension during the course of the experiment up to 8 weeks, while systolic blood pressure rose progressively. We concluded that this mineralocorticoid is not involved at least as a circulating hormone in the pathogenesis of adrenal regeneration hypertension in rats.     

Characterization of a mitochondrial matrix protease catalyzing the processing of adrenodoxin precursor

Adrenodoxin (Ad) is synthesized as a larger precursor (preAd) by cytoplasmic polysomes and then transported into mitochondria concomitant with its proteolytic processing to the mature form. The protease in bovine adrenal cortex mitochondria, which converts preAd to the mature form, is a metalloprotease in the matrix (Sagara, Y., Ito, A. & Omura, T. (1984) J. Biochem. 96, 1743-1752). In this study, the protease was purified about 100-fold from the matrix fraction of bovine adrenal cortex mitochondria. The partially purified protease converted not only preAd, but also the precursors of malate dehydrogenase (MDH) and 27 kDa protein (P-27) to the corresponding mature forms. However, it was inactive toward the precursors of P-450(SCC) and of P-450(11 beta). Since isolated rat liver mitochondria can import and process preAd as efficiently as bovine adrenal cortex mitochondria, we partially purified a preAd-processing protease from rat liver mitochondria and compared its properties with those of the bovine adrenal cortex enzyme. The properties of the rat liver protease were indistinguishable from those of the bovine adrenal cortex enzyme in molecular weight determined from Sephadex G-150 gel filtration, metal requirement and ability to process preMDH and preP-27. The rat liver enzyme was also inactive toward the precursors of P-450(SCC) and P-450(11 beta). These results indicate the presence in both adrenal cortex and liver mitochondria of the same type of processing protease, which processes preAd and also the precursors of some other mitochondrial proteins.     

Conversion of progesterone to corticosteroids by the midterm fetal adrenal and kidney

Midterm fetal adrenal and kidney tissue homogenates were incubated with 3H-progesterone (1 microM) and its conversion to te 3H-corticosteroids metabolites studied. Cortisol (36.3%) and corticosterone (4.7%) were isolated from the adrenal, and 11-deoxycortisol (32.5%) and deoxycorticosterone (21.1%) from the kidney. The results of these incubations confirmed the presence of 17- and 21-hydroxylase activities in both fetal tissues, and that of 11 beta-hydroxylase activity only in fetal adrenal tissue. We conclude that during pregnancy when progesterone levels are high, biosynthesis by the fetal kidney of 11-deoxycortisol, the most abundant corticosteroid formed by this tissue in this investigation, might provide to the fetal adrenal an important precursor for cortisol biosynthesis within the fetal compartment.     

19-Nor-deoxycorticosterone in the neutral fraction of human urine

19-Nor-deoxycorticosterone (19-nor-DOC), in the neutral fraction of human urine, was isolated and quantitated as the acetate derivative using ultraviolet absorption of the peak emerging from a high-pressure liquid chromatographic column. Identification of 19-nor-DOC in a pooled collection of urine after ACTH administration included identical chromatographic mobilities as the parent compound and acetate derivative compared to authentic 19-nor-DOC and mass spectral analysis of the acetate derivative. Values obtained for control and post-ACTH urines were 528 +/- 100 (SE) ng/24 hours and 8851 +/- 824 ng/24 hours, respectively. One patient with primary aldosteronism excreted 1894 ng/24 hours.     

Characterization of a processing protease that converts the precursor form of gamma-glutamyltranspeptidase to its subunits

Previously it was found that the proteolytic processing of precursors of gamma-glutamyltranspeptidase takes place on the brush border membrane of the kidney. The activity of the processing protease in purified brush border membranes was examined using endogenous substrates labeled with [3H]fucose and [35S]methionine. On incubation with brush border membranes in vitro, the precursors were converted stoichiometrically to two subunits, and the reaction followed first order kinetics with a rate constant k of -0.048 min-1. The enzyme responsible for this conversion was membrane-bound, had a weakly basic optimum pH and was inhibited by serine protease inhibitors. These results suggest that the precursor of gamma-glutamyltranspeptidase is processed to the mature form by a serine protease bound to the brush border membrane of kidney.     

Kinetic pulse-labeling study of Fusarium culmorum. Biosynthetic intermediates and dead-end metabolites

A kinetic pulse-labeling method was utilized in Fusarium culmorum to detect plausible biosynthetic intermediates and differentiate them from dead-end metabolites. The ultimate test to demonstrate a precursor relies on feeding experiments. We now report the detection of four new metabolites, one of them (compound 1) behaves as a dead-end metabolite, whereas compounds 2, 3, and 4 seem to be putative intermediates: they metabolize with time just when 3-acetyldeoxynivalenol (3-ADN) and/or sambucinol (SOL) start to be produced. Feeding experiments confirmed these results: compound 1 is not converted to 3-ADN or SOL, and compounds 2-4 are precursors to 3-ADN. In addition 3 is a precursor to SOL.     

Expression of adrenomedullin mRNA in adrenocortical tumors and secretion of adrenomedullin by cultured adrenocortical carcinoma cells

Immunoreactive-adrenomedullin concentrations and the expression of adrenomedullin mRNA were studied in the tumor tissues of adrenocortical tumors. Northern blot analysis showed the expression of adrenomedullin mRNA in tumor tissues of adrenocortical tumors, including aldosterone-producing adenomas, cortisol-producing adenomas, a non-functioning adenoma and adrenocortical carcinomas, as well as normal parts of adrenal glands and pheochromocytomas. On the other hand, immunoreactive-adrenomedullin was not detected in about 90% cases of adrenocortical tumors (<0.12 pmol/g wet weight (ww)). Immunoreactive-adrenomedullin concentrations ranged from 0.44 to 198.2 pmol/g ww in tumor tissues of pheochromocytomas and were 9.2 ± 1.2 pmol/g ww (mean ± SD, n = 4) in normal parts of adrenal glands. Adrenomedullin mRNA was expressed in an adrenocortical adenocarcinoma cell line, SW-13 and immunoreactive-adrenomedullin was detected in the culture medium of SW-13 (48.9 ± 1.8 fmol/10⁵ cells/24h, mean ± SEM, n = 4). On the other hand, immunoreactive-adrenomedullin was not detectable in the extract of SW-13 cells (<0.09 fmol/10⁵ cells), suggesting that adrenomedullin was actively secreted from SW-13 cells without long-term storage. These findings indicate that adrenomedullin is produced and secreted, not only by pheochromocytomas, but also by adrenocortical tumors. Undetectable or low levels of immunoreactive-adrenomedullin in the tumor tissues of adrenocortical tumors may be due to very rapid secretion of this peptide soon after the translation from these tumors.     

Differences between adrenal adenoma causing primary aldosteronism and other adrenal tissues in the incorporation of labeled steroid precursors into their products

The incorporation and conversion of several labeled steroid precursors into their products were examined in slices of adrenal tissue from two patients with primary aldosteronism and compared with that in “normal” adrenal tissue and adrenal tissues from a patient with Gushing's syndrome. The products of the incorporation were separated by Sephadex LH-20 column chromatography. The major products of conversion in the adenomatous tissue of primary aldosteronism were 18-hydroxycorticosterone and lesser amounts of aldosterone. Smaller amounts of 18-hydroxycorticosterone were isolated from all other adrenal tissues studied. No aldosterone could be recovered after incubating any of the adrenal tissue studied with labeled 18-hydroxy-11-deoxycorticosterone or 18-hydroxycorticosterone as precursor steroid. These $\text{in vitro}$ results seem to suggest that there is increased 18-hydroxylation in the adenoma of primary aldosteronism compared with other tissues and that relatively more 18-hydroxycorticosterone is produced in such tissue than aldosterone.     

Odd-skipped related 1 is required for development of the metanephric kidney and regulates formation and differentiation of kidney precursor cells

Formation of kidney tissue requires the generation of kidney precursor cells and their subsequent differentiation into nephrons, the functional filtration unit of the kidney. Here we report that the gene odd-skipped related 1 (Odd1) plays an important role in both these processes. Odd1 is the earliest known marker of the intermediate mesoderm, the precursor to all kidney tissue. It is localized to mesenchymal precursors within the mesonephric and metanephric kidney and is subsequently downregulated upon tubule differentiation. Mice lacking Odd1 do not form metanephric mesenchyme, and do not express several other factors required for metanephric kidney formation, including Eya1, Six2, Pax2, Sall1 and Gdnf. In transient ectopic expression experiments in the chick embryo, Odd1 can promote expression of the mesonephric precursor markers Pax2 and Lim1. Finally, persistent expression of Odd1 in chick mesonephric precursor cells inhibits differentiation of these precursors into kidney tubules. These data indicate that Odd1 plays an important role in establishing kidney precursor cells, and in regulating their differentiation into kidney tubular tissue.     

Distribution and localization of neurokinin A-like immunoreactivity and neurokinin B-like immunoreactivity in rat peripheral tissue

Using specific radioimmunoassays and immunocytochemistry for neurokinin A (NKA) and neurokinin B (NKB), distribution and localization of these peptides in rat peripheral tissues were studied. NKA-like immunoreactivity (NKA-LI) was present in highest levels of 15.7–23.9 pmol/g wet wt. and NKB-like immunoreactivity (NKB-LI) was in levels of 0.33–0.67 pmol/g wet wt., throughout the gastrointestinal tract involving stomach, duodenum, jejunum, ileum and colon. Immunocytochemical analysis of gastrointestinal tract revealed that NKA-LI and NKB-LI localized in ganglia of both the submucosal and myenteric plexuses as well as varicose neurons in the mucosa and the muscle layer of the small and large intestine. On the other hand, high levels of NKB-LI were observed in oesophagus (0.83 ± 0.08 pmol/g wet wt.), adrenal (1.02 ± 0.21), head of pancreas (0.73 ± 0.06) and kidney (0.98 ± 0.05).

The present study shows the difference of localization of NKA-LI and NKB-LI in peripheral tissues and suggests that NKB may have some physiological role differing from that of NKA in peripheral tissues.     

The hypertensinogenic activity of 19-nor-deoxycorticosterone in the adrenalectomized spontaneously hypertensive rat

Infusions of 10 or 25 micrograms/day 19-nor-DOC for 2 weeks in adrenalectomized spontaneously hypertensive rats led to significant increases in blood pressure, 55 and 70 mmHg respectively. This study provides further evidence that 19-nor-DOC is a potent hypertensinogenic steroid and that the ADX SHR model is a useful, sensitive bioassay system to test for hypertensinogenic activity.     

Influence of temperature and high acetate concentrations on methanogenesis in lake sediment slurries

Methanogenesis from main methane precursors H(2)/CO(2) and acetate was investigated in a temperature range of 2-70 degrees C using sediments from Lake Baldegg, Switzerland. Psychrophilic, psychrotrophic, mesophilic, and thermophilic methanogenic microbial communities were enriched by incubations for 1-3 months of nonamended sediment slurries at 5, 15, 30, and 50 degrees C. Isotope experiments with slurries amended with (14)C-labeled bicarbonate and (14)C-2-acetate showed that in the psychrophilic community (enriched at 5 degrees C), about 95% of methane originated from acetate, in contrast to the thermophilic community (50 degrees C) where up to 98% of methane was formed from bicarbonate. In the mesophilic community (30 degrees C), acetate was the precursor of about 80% of the methane produced. When the hydrogen-carbon dioxide mixture (H(2)/CO(2)) was used as a substrate, it was directly converted to methane under thermophilic conditions (70 and 50 degrees C). Under mesophilic conditions (30 degrees C), both pathways, hydrogenotrophic and acetoclastic, were observed. At low temperatures (5 and 15 degrees C), H(2)/CO(2) was converted into methane by a two-step process; first acetate was formed, followed by methane production from acetate. When slurries were incubated at high partial pressures of H(2)/CO(2), the high concentrations of acetate produced of more than 20 mM inhibited acetoclastic methanogenesis at a temperature below 15 degrees C. However, slow adaptation of the psychrophilic microbial community to high acetate concentrations was observed.     

Steroid glucuronides: Human circulatory levels and formation by LNCaP cells

We studied the relationship between circulating androsterone glucuronide, androstane-3,17β-diol glucuronide and androstane-3β,17β-diol glucuronide concentrations and adrenal as well as testicular C-19 steroids in men. Among the three 5-reduced steroid glucuronides, androsterone glucuronide is the predominant C-19 steroid measured in plasma and its levels are markedly elevated compared to those of the non-conjugated steroid. The marked rise in testosterone during puberty was strongly correlated with the increase in both androsterone glucuronide and androstane-3,17β-diol glucuronide, thus suggesting that testicular C-19 steroids are the main precursors of the steroid glucuronides. We also found that the presence of testicular androgen in plasma contributes to approx. 70% of plasma androsterone glucuronide and androstane-3,17β-diol glucuronide. Our data suggest that the adrenal C-19 steroids remaining in circulation after castration in men are converted into potent androgen which are then glucuronidated by UDP-glucuronyltransferase. We also demonstrated that the human prostate cell line LNCaP is capable of converting to a large extent androstenedione into androsterone glucuronide. Our data further confirm that glucuronidation is a major pathway of steroid metabolism in steroid target tissues.