The effects of adrenal and gonadal steroids and K+-canrenoate on the metabolism of aldosterone by rat liver microsomes

The synthesis of polar aldosterone metabolites by rat liver microsomes at physiological concentrations of aldosterone (21.5 nM), was markedly inhibited by progesterone, testosterone, corticosterone, K+-canrenoate and estradiol-17 beta. In contrast, corticosterone and estradiol-17 beta significantly increased the synthesis of reduced aldosterone metabolites by 8- and 15-fold respectively, the majority of which were 5 alpha-reduced products of aldosterone. In experiments at higher substrate (aldosterone) concentrations (20-200 microM) the synthesis of ring A-reduced aldosterone metabolites by liver microsomes followed Michaelis-Menten kinetics with a Km[app] for aldosterone of 160 microM and Vmax[app] of 12.2 nmoles/mg protein/5 min. In these experiments progesterone, testosterone and K+-canrenoate all competitively inhibited the synthesis of reduced metabolites with inhibition constants (Ki [app]) of 70, 85 and 55 microM respectively; however, corticosterone did not. In contrast, estradiol-17 beta increased the rate of synthesis of reduced products by 40%, lowering the Km[app] to 83 microM.     

The effects of antimineralocorticoids on synthesis of aldosterone metabolites in target tissues

[3H]Aldosterone is transformed into several metabolites by subcellular fractions of rat kidney. 80-90% of the metabolites synthesized by nuclei and plasma membranes are 5 alpha-DHAldo and 3 alpha,5 alpha-THAldo in ratios of 1:2 and 1:1 respectively; small quantities of 3 beta,5 alpha-THAldo are also synthesized. In contrast, kidney cytosol metabolizes Aldo principally to 5 beta-reduced products with co-chromatograph with 5 beta-DHAldo and 3 alpha,5 beta-THAldo. Several polar neutral metabolites, as well as sulfate and acidic metabolites are also synthesized by the cytosol fraction. Similar 5 alpha-reduced metabolites, 5 alpha-DHAldo, 3 alpha,5 alpha-THAldo and 3 beta,5 alpha-THAldo are also synthesized when [3H]aldosterone is incubated in vitro with toad urinary bladder for 1 and 5 h. Significant quantities of 5 beta- and 20 beta-reduced products and sulfate and acidic metabolites are also synthesized. The metabolism of [3H]aldosterone in both target tissues is significantly inhibited by aldosterone antagonists. Several of the reduced metabolites of aldosterone synthesized in kidney and toad bladder possess significant mineralocorticoid activity. 5 alpha-DHAldo and 3 alpha,5 alpha-THAldo possess 1/10 and 1/30 and 3 alpha,5 beta possesses 1/80-1/100 of the antinatriuretic activity of Aldo. It is suggested that the metabolism of Aldo in its target tissues may be linked to regulation or expression of the hormone's actions.     

Enzymatic synthesis of 3H-labeled Ring-A reduced metabolites of aldosterone and their separation by high pressure liquid chromatography

Specific methods are described for the enzymatic synthesis of each of the six possible 3H-labeled Ring-A reduced metabolites of aldosterone (5 alpha- and 5 beta-DHAldo; 3 alpha,5 alpha-THAldo; 3 beta,5 alpha-THAldo; 3 alpha,5 beta-THAldo; and 3 beta,5 beta-THAldo; see footnote 1 for full names). Use of heated jacketed columns (C8-reverse phase) and two HPLC solvent systems, with isocratic aqueous methanol or acetonitrile, respectively, have been developed which resolve all six Ring-A reduced metabolites of aldosterone. The relative retention times and elution order of each reduced metabolite are different with each solvent system and hence help confirm the identities of Ring-A reduced metabolites made in vivo from physiological quantities of [3H]aldosterone. The use of an on-line beta-radioactivity detector (Berthold LB-504) enhanced the sensitivity of detection and markedly improved the resolution of these metabolites, compared with that obtained by off-line scintillation counting. Thus, the use of increased temperature with these two solvent systems, together with an on-line radioactivity detector, provide a useful and efficient analytical tool for the separation and identification of each reduced metabolite of aldosterone.     

Characterization of specific binding sites for corticosterone in mouse liver plasma membrane

The specific binding of [3H]corticosterone to mouse liver purified plasma membrane fractions is a saturable, reversible, and temperature-dependent process. Only one type of independent and equivalent binding sites has been determined in plasma membrane (Kd = 4.1 nM and Bmax = 3368 fmol/mg). As can be deduced from displacement data obtained in plasma membrane, the high-affinity binding site is different from nuclear glucocorticoid, nuclear progesterone, and Na+, K(+)-ATPase digitalis receptors. Probably this corticosterone binding site or receptor is the same one determined previously for [3H]cortisol in mouse liver plasma membrane. Such beta- and alpha-adrenergic antagonists as propranolol and phentolamine did not affect [3H]corticosterone binding to plasma membranes; therefore, this binding site is independent of these receptors. The binding sites in plasma membranes are not exclusive for corticosterone, but other steroids are also bound with very different affinities.     

The role of cytochrome P-450 in the synthesis of polar metabolites of aldosterone by microsomes of male rat liver

Among the tissues of the male rat studied, the largest quantities of the neutral polar metabolites of aldosterone were synthesized by the hepatic microsomal fraction. The polar metabolites of aldosterone were separated by HPLC into six peaks. Three peaks of non-polar (reduced) metabolites were also synthesized. Synthesis of at least four of the neutral polar metabolites was induced by phenobarbital and inhibited by both CO and SKF-525A. The rates of synthesis of these metabolites, which were linear up to 5 minutes, correlated well with the concentration of cytochrome P-450 in the liver microsomes. Addition of aldosterone to the microsomal fraction caused a pronounced type 1 change in the cytochrome P-450 spectrum. The half maximal spectral change (K_s) for aldosterone was calculated to be 8 μM. These experiments indicate that the neutral polar metabolites of aldosterone are produced by cytochrome P-450 dependent hydroxy lations.     

Studies on the Cell-Free Biosynthesis of CNS Membrane Proteins

Abstract: The biosynthesis of CNS membrane proteins was studied in cell-free systems containing membrane-bound polysomes (rough endoplasmic reticulum; RER) or free polysomes from rat forebrain. In previous studies of CNS membrane proteins using two-dimensional gel electrophoretic analysis, five proteins (mol. wt.-pI: 75K 5.4, 68K 5.6, 61K 5.1, 58K 5.1, and 36K 5.6) were found in ceil membrane fractions including preparations enriched in RER, smooth endoplasmic reticulum, and plasma membranes. One of these proteins, 68K 5.6, was also present in cytosol and comigrated with a microtubule-associated protein. In our present study, cell-free systems containing RER were found to synthesize the 75K 5.4, 61K 5.1, and 58K 5.1 proteins. A protein, 34K 5.65, similar (but not identical) to the 36K 5.6 protein was also synthesized. After cell-free synthesis, the 75K 5.4 and 58K 5.1 proteins could be purified by concanavalin A affinity chromatography. Of the five common membrane proteins previously identified, only the 68K 5.6 protein was synthesized by the free polysome population. The free polysomes were also found to synthesize cyclic AMP binding proteins at 48K and 54K, known from previous studies to be present in both cytosol and plasma membrane fractions in mammalian brain tissue. In conclusion, RER synthesized proteins found exclusively in CNS membrane fractions, whereas free polysomes synthesized those proteins found in both soluble and membrane compartments.     

Modulation of aldosterone receptors in rat kidney: effects of steroid treatment and potassium diet

The numbers of type I and type II aldosterone receptors in the kidney cytosol of adrenalectomized rats were estimated after animals were treated with various steroids, or fed with high or low potassium diets. Oestradiol and 5 beta-pregnane-3,20 dione, which exhibited no affinity for aldosterone receptors, did not modify the levels of type I or type II receptors. Cortisol, corticosterone, progesterone and spirolactones, which all competed with aldosterone for both types of receptor, reduced the number of type I sites, as does aldosterone itself. Steroid treatment has no appreciable effect on type II receptors. We conclude that type I receptors are modulated by steroids able to bind to aldosterone receptors and that steroid-receptor interaction is an essential step in the receptor modulation process. The effects of potassium on aldosterone receptor modulation were tested in adrenalectomized rats on hypo- or hyperkalaemic diets. No change in receptor levels was observed in the rats on a low potassium diet, but the number of type I receptors increased in animals on a high potassium diet. However, the effects of potassium on receptor modulation were of lesser magnitude than those of aldosterone agonists and antagonists.     

The effects of infusions of ring-A-reduced derivatives of aldosterone on the antinatriuretic and kaliuretic actions of aldosterone

Infusion of Ring-A-reduced metabolites of aldosterone in adrenalectomized male rats for 4 days revealed that 5 alpha-Ring-A-reduced derivatives, 5 alpha-dihydroaldosterone (5 alpha-DHAldo; 2.5-5.0 micrograms/day), 3 alpha,5 alpha-tetrahydroaldosterone (3 alpha,5 alpha-THAldo; 5-25 micrograms/day), and 3 beta,5 alpha-THAldo (50-175 micrograms/day) possessed intrinsic Na+-retaining activity. The same infusions of 5 alpha-DHAldo, 3 alpha,5 alpha-THAldo, and 3 beta,5 alpha-THAldo, also lowered the urinary excretion of potassium. The 5 beta-Ring-A-reduced derivative 3 alpha,5 beta-THAldo did not demonstrate either of these biological properties. In another set of experiments, on the fourth day of infusion, aldosterone (0.1 microgram/rat) was administered acutely subcutaneously; none of the Ring-A-reduced derivatives altered the Na+-retaining activity of aldosterone. However, in a dose-dependent manner, both 3 alpha,5 alpha-THAldo and 3 beta,5 alpha-THAldo blunted the urinary K+-secretory effect of aldosterone; low dosages of 5 alpha-DHAldo and larger dosages of 3 alpha,5 beta-THAldo did not. Thus, the 5 alpha-reduced derivatives of aldosterone not only lowered urinary Na+ and K+ excretion in their own right, but two of them blunted the kaliuretic response of the parent mineralocorticoid, aldosterone. Further experiments will be required to determine whether these aldosterone metabolites are further metabolized or interconverted during the expression of the regulatory properties described here and whether these properties are physiologically relevant.     

Is aldosterone synthesized within the rat brain?

Very small amounts of adrenocorticosteroids are synthesized by brain tissue in vitro. While there is evidence suggesting that the synthesis of aldosterone in the brain may have a role in the hypertension of the Dahl salt-sensitive rat, the de novo synthesis of aldosterone or corticosterone within the brain of a living animal has not been demonstrated. We have used sensitive ELISAs to measure aldosterone and corticosterone in the plasma and whole brains of intact rats receiving a normal-, low-, or high-salt diet to alter adrenal aldosterone production and of adrenalectomized rats provided sodium replacement, some of which received aldosterone, corticosterone, or DOC replacement. The results of several experiments were consistent. In intact rats, the brain concentration of aldosterone and corticosterone reflected that in the plasma. However, whereas aldosterone and corticosterone were undetectable or barely undetectable in the plasma of adrenalectomized animals, as was the corticosterone in their brains, aldosterone was consistently found in the brains of adrenalectomized rats, ranging from a mean of 6.6-41 pg/g, depending on the experiment. Provision of DOC as substrate for the endogenous aldosterone synthase and 11beta-hydroxylase did not significantly increase brain aldosterone or corticosterone content. It is postulated that the small amounts of aldosterone synthesized in the brain could provide a local ligand for autocrine or paracrine activation of the mineralocorticoid receptor.     

Steroid induction of low-affinity glucocorticoid binding sites in rat liver microsomes

Rat liver contains two glucocorticoid binding sites: the high-affinity or glucocorticoid receptor (GR) and the low-affinity glucocorticoid binding sites, or LAGS. The Kd of LAGS predicts that they can be half-saturated by plasma corticosteroids in some physiological circumstances and, therefore, that they can play relevant roles in the rat liver. [3H]dexamethasone was used as a ligand in exchange assays, to study the relative abundance of GR and LAGS in cell fractions of rat liver. GR were found in the cytosol, but not in the purified nuclei, the mitochondria, or the microsomes. LAGS were found in all the particulate fractions, being more abundant in the smooth-surfaced microsomes, but they were not found in the cytosol. The LAGS of microsomes and purified nuclei showed the same Kd and also the same broad range of steroid competition with [3H]dexamethasone (cortisol = progesterone greater than dexamethasone greater than or equal to corticosterone greater than R5020 greater than DHEA greater than testosterone = estradiol). LAGS were found in liver, placenta and kidney, but not in other GR-containing organs. This suggests that the LAGS could be involved in physiological functions related to the metabolism of steroid hormones. The liver microsome LAGS were undetectable at rat birth, and became present in the 25-day-old rat. The level of LAGS then increased progressively, reaching its maximum level in the 2-3-month-old rats (10 pmol/mg protein), and declining afterwards to reach the adulthood level (5 pmol/mg protein) in 6-month-old rats. LAGS are mainly controlled by the corticoadrenal steroids, which is shown by their dramatic decrease after adrenalectomy, and especially after hypophysectomy. Many steroid hormones, like estradiol, testosterone, and corticosterone (but not progesterone) induce LAGS, estradiol being the most effective. A combination of T4 and corticosterone was more effective in inducing LAGS than when the two hormones were injected separately. It is possible to conclude that rat liver LAGS are mainly microsomal proteins, whose concentration is regulated by a multihormone system under pituitary control.     

Steroidal 21-diazo ketones: photogenerated corticosteroid receptor labels.

The 21-diazo derivatives of 9 alpha-fluoro- and 9 alpha-bromo-21 deoxycorticosterone, 21-deoxycorticosterone, and progesterone were synthesized for use as photoaffinity labels for corticosteroid receptors. In the isolated toad bladder system, 9 alpha-bromo-21-diazo-21-deoxycorticosterone was as active as d-aldosterone and more active than 9 alpha-fluoro-cortisol in augmenting active Na+ transport. The activities of 21-diazoprogesterone and progesterone were equal; both were much less potent than d-aldosterone, however. These results indicate that the 21-diazo derivatives had significant functional activity in the toad bladder system. The rat kidney slice system was used to estimate the relative affinities of the diazo steroids for aldosterone receptor sites by competition experiments. At 100-fold excess of competitor to [3-H]aldosterone, the order of affinities was 9 alpha-fluoro-21-diazo-21-deoxycorticosterone greater than 9 alpha-bromo-21-diazo-21-deoxycorticosterone greater than 21-diazoprogesterone. Moreover, 9 alpha-bromo-21-diazo-21-deoxycorticosterone reduced binding of [3-H]aldosterone to cytoplasmic and nuclear forms of the receptor proportionately. On the basis of competition for [3-H]corticosterone binding, presumably to corticosteroid-binding globulin (CBG), the order of affinities was 21-diazo-21-deoxycorticosterone greater than 21-diazoprogesterone greater than 9 alpha-bromo-21-diazo-21-deoxycorticosterone. These findings indicate that 21-diazo steroids may be suitable as photogenerated affinity labels for mineralocorticoid receptors. The tritiated derivative, [1,2-3-H]-9 alpha-bromo-21-diazo-21-deoxycorticosterone (specific activity 25 Ci/mol) was synthesized and used in model experiments on photogenerated covalent binding to rat plasma proteins. Irradiation with uv light resulted in binding of [1,2-3-H]-9 alpha-bromo-21-diazo-21-deoxycorticosterone to plasma proteins, that was resistant to extraction with methylene dichloride and did not exchange with unlabeled corticosterone. The diazocorticosteroids, therefore, may have the requisite functional and selectivity properties for photoaffinity labeling of corticosteroid-binding proteins. Further studies are needed, however, to assure that photogenerated labeling with these steroids was site specific.     

Effects of short-term changes in electrolyte intake on the adrenal steroidogenic responses of juvenile mallard ducks (Anas platyrhynchos)

1. Adjusting the Na+ and K+ intake of juvenile mallard ducks caused the plasma concentrations of corticosterone (B) and aldosterone (Aldo) to increase independently of one another, but none of these changes in electrolyte intake had a significant effect on the deoxycorticosterone (DOC) concentration. 2. With the exception of DOC in birds consuming the control diet, the plasma concentration of each hormone, regardless of diet, increased significantly following exposure to stress. 3. Stress-induced increases in Aldo concentration were greatest in birds given diets containing low concentrations of Na+. 4. Unlike the mammal and some other species of birds, Na+ may be the primary secretagogue responsible for the regulation of both corticosterone and aldosterone synthesis in the mallard duck.     

Glucocorticoid metabolism and Na+ transport in chicken intestine

The role of aldosterone in regulation of electrogenic Na+ transport is well established, though mineralocorticoid receptors bind glucocorticoids with similar binding affinity as aldosterone and plasma concentration of aldosterone is much lower than glucocorticoids. In mammals, the aldosterone specificity is conferred on the low-selective mineralocorticoid receptors by glucocorticoid inactivating enzyme 11beta-hydroxysteroid dehydrogenase (11HSD) that converts cortisol or corticosterone into metabolites (cortisone, 11-dehydrocorticosterone) with lower affinity for these receptors. The present study examined the chicken intestine, whether changes in 11HSD activity are able to modulate the effect of corticosterone on Na+ transport, and how the metabolism of this hormone is distributed within the intestinal wall. This study shows that not only aldosterone, but also corticosterone (B), was able to increase the electrogenic Na+ transport in chicken caecum in vitro. The effect of corticosterone was higher in the presence of carbenoxolone, an inhibitor of steroid dehydrogenases, and was comparable to the effect of aldosterone. The metabolism of B in the intestine was studied; results showed oxidation of this steroid to 11-dehydrocorticosterone (A) and reduction to 11-dehydro-20beta-dihydrocorticosterone (20diA) as the main metabolic products at low nanomolar concentration of the substrate. In contrast, 20beta-dihydrocorticosterone and 20diA were the major products at micromolar concentration of B. Progesterone was converted to 20beta-dihydroprogesterone. The metabolism of corticosterone was localized predominantly in the intestinal mucosa (enterocytes). In conclusion, the oxidation at position C11 and reduction at position C20 suggest that both 11HSD and 20beta-hydroxysteroid dehydrogenase (20HSD) operate in the chicken intestine and that the mucosa of avian intestine possesses a partly different system of modulation of corticosteroid signals than mammals. This system seems to protect the aldosterone target tissue against excessive concentration of corticosterone and progesterone.     

Binding of progesterone receptor by nuclear preparations of rabbit and guinea pig uterus.

Guinea pig and rabbit uterine nuclei bound [3H] progesterone in vitro only in the presence of cytosol from estrogen-stimulated uteri. Nuclei from unstimulated and estrogen-stimulated uteri bound progesterone equally well. Nuclei of nontarget tissues also bound progesterone, but to a lesser extent. The rate of nuclear bindins increased with temperature from 0-30 degrees. At 25 degrees nuclear binding remained stable for at least 3 h, but at temperatures of 30 degrees and greater, nuclear binding decreased rapidly after 15 min. Activation of the progesterone-cytoplasmic receptor complex (the change in the complex that enables it to bind quickly to nuclei at 0 degrees) took place slowly at temperatures from 0-5 degrees and rapidly at 10-25 degrees. Activation was facilitated by dilution of the cytosol. Some activation occurred in diluted cytosol in the absence of added progesterone. The cytoplasmic progesterone receptor had a sedimentation coefficient of 7 S when concentrated cytosol (20 mg of protein/ml) was incubated with progesterone at 0 degrees in 5 mM phosphate buffer. Diluting the cytosol and increasing the temperature to 20 degrees caused the sedimentation coefficient to decrease to 5.5 S. Gel filtration of guinea pig uterine cytosol on Sephadex G-100, in the absence of progesterone, yielded a progesterone-binding fraction in the void volume, with a sedimentation coefficient of 5.5 S. The complex of progesterone with the material in the void volume was taken up by nuclei at 0 degrees more rapidly than the complex of progesterone and crude cytosol. The nuclear uptake of progesterone was decreased in phosphate buffer of concentrations greater than 80 mM. Under conditions that favor the nuclear binding of progesterone, the sedimentation coefficient of the cytoplasmic progesterone receptor was 5.5 S. This may be the form of the preceptor which is taken up by nuclei. In decreasing order of effectiveness, unlabeled progesterone, 5 alpha-pregnane-3,20-dione, corticosterone 20 alpha-hydroxy-4-pregnen-3-one, testosterone, estradiol-17 beta, and cortisol competed with [3H] progesterone for binding to nuclei.     

Reversal of progesterone-induced sequential inhibition by progesterone metabolites

Previous reports have shown that intrabrain administration of progesterone (P) ring A-reduced metabolites into the medial preoptic area (MPOA) and ventromedial hypothalamus (VMH) induces facilitation of female sexual behaviour in ovariectomized (ovx) rats pretreated with estrogen. Present studies were designed to explore the possibility that ring-A reduced progesterone metabolites might play a role in controlling the duration of estrous behavior. To this aim ovariectomized (ovx) Sprague Dawley rats implanted with guide cannulae directed towards the VMH or the MPOA were submitted to a systemic hormonal treatment to provoke P-induced sequential inhibition (estradiol benzoate (EB) at time 0 + P at 44 h + P at 68 h). The second dose of P was administered simultaneously with the ic implantation of one of the following P metabolites: 3β-hydroxy-5β-pregnan-20-one (5β,3α P), 3α-hydroxy-5β-pregnan-20-one (5β,3α P) or 3β-hydroxy-5βpregnan-20-one (5α,3β P) into the MPOA or VHM. Lordosis behavior was evaluated by the lordosis quotient (LQ = number of lordosis/10 male mount × 100) and by the percentage of responding subjects. Results show that 5β,3βP implanted into the VMH or MPOA counteracted the sequential inhibitory effect induced by systemic administration of P. 5α,3β P was also able to counteract sequential inhibition, but with less potency and only in the VMFI. Results show that P-induced sequential inhibition can be counteracted by intrabrain administration of ring-A reduced progestins in both the VMH and MPOA. Data are discussed in terms of a putative physiological role of naturally occurring P metabolites in P-mediated female sexual behavior expression.     

Upregulation of macrophage plasma membrane and nuclear phospholipase D activity on ligation of the alpha2-macroglobulin signaling receptor: involvement of heterotrimeric and monomeric G proteins

The effect of ligating the alpha2-macroglobulin signaling receptor (alpha2MSR) with receptor-recognized forms of alpha2M (alpha2M*) was studied with respect to phospholipase D (PLD) activity in murine macrophages, their plasma membranes, and nuclei. PLD activity in plasma membranes and nuclei increased linearly up to a ligand concentration of about 100 pM of either alpha2M* or a cloned and expressed receptor binding fragment (RBF). The RBF binding site mutant K1370A, which binds with high affinity to alpha2MSR, also increased nuclear PLD activity comparable to RBF and alpha2M*. Phorbol dibutyrate caused a two- to threefold stimulation of membrane and nuclear PLD activity, whereas PLD activity was nearly abolished by downregulation of protein kinase C; prior treatment with staurosporin, genestein, cyclosporin A, actinomycin D; or chelation of intracellular Ca2+. In permeabilized macrophages, isolated plasma membranes, and nuclei, GTP-gamma-S increased alpha2M*-stimulated PLD activity via a pertussis toxin-insensitive G protein and this effect was abolished on preincubation with GDP-beta-S. Incubation of plasma membranes with polyclonal antibody against sARFII, or the addition of cytosol which was immunoprecipitated with antibody against sARFII, greatly reduced alpha2M*-stimulated PLD activity in the presence of GTP-gamma-S. Preincubation of plasma membranes with GDP-beta-S prior to the addition of GTP-gamma-S and recombinant ARF1 significantly inhibited alpha2M*-stimulation of PLD activity. Nuclear PLD activity was maximally stimulated in the presence of both GTP-gamma-S and rARF1, whereas plasma membrane PLD activity was maximally stimulated in the presence of rARF1, GTP-gamma-S, RhoA, and ATP. In contrast, nuclear PLD activity was not affected by RhoA either alone or in combination with GTP-gamma-S or ATP.     

Corticosteroid receptors in the avian kidney

The binding $\text{in vitro}$ of tritiated aldosterone to domestic duck ($\text{Anas platyrhynchos}$) kidney tissue has been investigated. Using tissue from animals on a normal diet, tritiated aldosterone was specifically bound to kidney cytosol with an apparent equilibrium dissociation constant of about 9 nM and number of binding sites in the 20 fmol/mg protein range. These values did not show statistically significant changes when the cytosol originated from animals with salt activated nasal glands. Kidney cytosols labeled with tritiated aldosterone sedimented with a single peak at 8S in a linear sucrose gradient (10–30%) and this peak was quenched by excess, radioinert aldosterone. Following incubation of labeled cytosols with crude nuclei, the cytosols became depleted of the label and aldosterone was translocated to the Tris-soluble and Tris-insoluble, 0,4 M KCl soluble nuclear fractions. Kidney cytosols metabolized aldosterone extensively to a compound presumed to be 3α,5β-tetrahydroaldosterone. However, only unchanged aldosterone became receptor-bound. It was concluded that the duck kidney possesses aldosterone receptors, though competition studies indicated that the specificity of these receptors might be different from those described in the mammalian kidney.     

Levels and subcellular distribution of endogenous corticosterone in rat liver during development

The concentration of corticosterone in liver homogenates, liver cytosol and purified nuclear fractions, and in plasma of fetal, newborn, immature and adult rats has been measured by radioimmunoassay.Highest plasma corticosterone levels were found in fetal rats, decreasing close to the levels observed in the adrenalectomized rat by the 6th day of postnatal life followed by a rise in the adult rat. The concentration of corticosterone in liver during development paralleled the plasma levels, the liver to plasma corticosterone ratio ranging between 0.09 and 0.17 suggesting that the corticosterone retained by the tissue is related to the unbound fraction of the hormone in plasma.Both plasma and tissue corticosterone levels declined after adrenalectomy and they were elevated after ether stress.Fractionation of liver homogenates showed that the major fraction of liver corticosterone is localized in the cytosol. Purified liver nuclei contained between 9 and 16% of the total liver corticosterone. The amount of corticosterone in the nuclei seems to be related to the plasma and tissue hormone levels rather than the concentration of cytoplasmic glucocorticoid receptors. Since most of the nuclear corticosterone appears to be bound to receptors, it has been calculated that close to 60% of the cellular receptors in fetal liver are localized in the nucleus. In adult rat liver, only about 10% of the cellular receptors appear to be associated with nuclei. Changes in the concentration of glucocorticoid receptors in liver during development and after adrenalectomy are inversely related to changes in plasma corticosterone levels. It is suggested that corticosterone may regulate the levels of its own receptors in liver.     

Preparation of renal cortex basal-lateral and bursh border membranes. Localization of adenylate cyclase and guanylate cyclase activities.

Luminal brush border and contraluminal basal-lateral segments of the plasma membrane from the same kidney cortex were prepared. The brush border membrane preparation was enriched in trehalase and gamma-glutamyltranspeptidase, whereas the basal-lateral membrane preparation was enriched in (Na+ + K+1)-ATPase. However, the specific activity of (Na+ + K+)-ATPase in brush border membranes also increased relative to that in the crude plasma membrane fraction, suggesting that (Na+ + K+)-ATPase may be an intrinsic constituent of the renal brush border membrane in addition to being prevalent in the basal-lateral membrane. Adenylate cyclase had the same distribution pattern as (Na+ + K+)-ATPase, i.e. higher specific activity in basal-lateral membranes and present in brush border membranes. Adenylate cyclase in both membrane preparations was stimulated by parathyroid hormone, calcitonin, epinephrine, prostaglandins and 5'-guanylylimidodiphosphate. When the agonists were used in combination enhancements were additive. In contrast to the distribution of adenylate cyclase, guanylate cyclase was found in the cytosol and in basal-lateral membranes with a maximal specific activity (NaN3 plus Triton X-100) 10-fold that in brush border membranes. ATP enhanced guanylate cyclase activity only in basal-lateral membranes. It is proposed that guanylate cyclase, in addition to (Na+ + K+)-ATPase, be used as an enzyme "marker" for the renal basal-lateral membrane.     

Extraction of corticosterone from cell homogenates and subcellular fractions of the rat adrenal cortex. III. ACTH-induced temporal subcellular redistributions of steroid precursors to corticosterone

Cholesterol, pregnenolone, progesterone, 11-deoxycorticosterone (11-DOC) and corticosterone were quantitated in subcellular fractions isolated from in vivo adrenocorticotropin (ACTH)-stimulated rat adrenal zona fasciculata/reticularis. Six adrenal subcellular fractions separated by discontinuous sucrose gradient centrifugation (lipid, 0.125 M sucrose, cytosolic, microsomal, mitochondrial and nuclear) were extracted with alkaline ether/ethanol and assayed by high pressure liquid chromatography (HPLC). Lipid fractions contained the major cholesterol stores, while most pregnenolone and progesterone was found in lipid, microsomal and mitochondrial fractions. The 0.125 M sucrose and cytosol fractions together contained approximately 75% of the total 11-DOC and corticosterone. The five steroids were only present in small amounts in organelle fractions containing steroidogenic enzymes. Homogenate and lipid fraction cholesterol decreased between 10 and 15 min and again 30 min after ACTH injection. In the homogenate, lipid, microsomal and mitochondrial fractions, pregnenolone and progesterone were increased after ACTH injection; peak pregnenolone and progesterone concentrations were often measured in adrenal gland sucrose, cytosolic, microsomal and mitochondrial fractions 15 to 20 min after rats were injected with ACTH. Although ACTH increased 11-DOC and corticosterone in all but the mitochondrial and nuclear fractions, the sucrose, cytosolic and microsomal 11-DOC, and cytosolic corticosterone increased most dramatically. In many fractions, peak 11-DOC and corticosterone concentrations were most often observed between the 10 and 15 min periods and again at 30 min.