Effects of adrenalectomy and spironolactone on urinary metabolites of aldosterone in rats

The quantities and temporal sequences of appearance of aldosterone metabolites in the urine of adrenalectomized rats, and adrenalectomized rats treated with spironolactone, were compared following subcutaneous administration of a physiological dosage (0.05 microgram) of [1,2,-3H]aldosterone. Large amounts of radiometabolites were rapidly excreted during 0-1 and 1-3 h and only small quantities by 3-4 h in urine of both groups of rats. The majority of the urinary radiometabolites (70-85%) were identified by Sephadex DEAP-LH-20 chromatography as neutral metabolites of aldosterone (NMA), together with lesser quantities of acidic, sulfate, and glucuronide conjugates. Further characterization by high pressure liquid chromatography (HPLC) showed that 90% of the NMA excreted by adrenalectomized rats were polar metabolites which could be separated into at least 15 peaks eluting in regions of increasing polarity (designated A, B, C, and D). Only small quantities of unaltered [3H]aldosterone and no ring-A-reduced metabolites were excreted by the adrenalectomized rats. Spironolactone treatment caused large changes in the excretion of acidic and sulfate derivatives of aldosterone, as well as discrete alterations in the HPLC patterns of the polar NMA (particularly those metabolites in regions A and B). Such discrete changes in these metabolic pathways which occur at the same time as the hormonal actions of aldosterone in the kidney may provide further insight into understanding the biological role of aldosterone metabolism.     

Complex formation by 3 H-aldosterone in rat kidney and liver

Low molecular weight polar complexes were shown to be formed $\text{in vivo}$ from ³H-aldosterone in both kidney and liver subcellular fractions, the majority being present in the cytosol fractions. Significant differences were observed between the quantities of polar complexes present in kidney subcellular fractions from intact and adrenalectomized male rats and also between the quantities of these kidney polar complexes from spironolactone treated male rats. ³H-aldosterone macro-molecule complexes were shown to exist in appreciable quantities only in the kidney cytosol fractions of adrenalectomized male rats. These gel filtration studies also showed the ³H-aldosterone labeled macromolecule complexes to consist of two protein peaks; one of high molecular weight and the other of lower molecular weight (～50,000 mol. wt.). The amount of ³H-aldosterone labeled protein complexes in kidney cytosol was greatly reduced when adrenalectomized rats were pretreated $\text{in vivo}$ with spironolactone.     

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.     

Influence of glucocorticoid on the metabolism of aldosterone in the isolated perfused rat liver and kidney.

The effect of glucocorticoid deficiency and excess on the extraadrenal metabolism of D-[4-14C]aldosterone (at 4 nM) was studied by radioimmunoassay and by high-performance liquid chromatography in the isolated perfused liver and kidney of adult Wistar rats. Bilateral adrenalectomy was performed 3 weeks before experiments. In nonadrenalectomized rats, 0.3 mg/kg/day dexamethasone was continuously infused subcutaneously for 1 week before experiments. Adrenalectomy did not affect hepatic or renal metabolism of aldosterone. Dexamethasone treatment did not change the renal handling of aldosterone. However, the hepatic clearance of aldosterone was 19% lower (P less than 0.05) in livers of dexamethasone treated rats than in livers of normal rats. After 5 minutes, perfusate [4-14C]aldosterone metabolites were lower in livers of dexamethasone-treated than in livers of normal rats (P less than 0.05). Similar perfusate levels were then obtained. Radiometabolite peaks with similar relative retention times were found in the hepatic perfusate of all groups. However, the ratio between circulating polar metabolites of aldosterone and the metabolites less polar than tetrahydroaldosterone, after 5 and 15 minutes, was highest in livers of dexamethasone-treated rats. Biliary elimination of 14C was similar in all groups. Significant amounts of conjugated tetrahydroaldosterone were only excreted in the bile of dexamethasone-treated rats. In conclusion, glucocorticoid excess reduced the hepatic clearance of aldosterone and changed the pattern of the hepatic metabolites of aldosterone both in circulation and in bile.     

Sex-dependence of the metabolism of aldosterone in adrenalectomized and intact rats

The metabolism of aldosterone at physiological levels was shown to be significantly different in male and female rats: more aldosterone was metabolized in the male rats leading to significantly higher quantities of non-extractable polar derivatives of aldosterone in all subcellular fractions of kidney, particularly in the cytosol fractions. These results may be correlated with our findings in which it was shown that the physiological responses to aldosterone in both adrenalectomized and intact rats were significantly greater in the males than the females. These sex differences support the concept that the metabolism of aidosterone may be essential for the components of the physiological response to aldosterone to occur. Furthermore, the sex-dependence of the metabolism of aldosterone appears to be independent of the presence of the previously identified protein receptor-hormone complexes. At all dosages within the physiological range, no significant differences were observed between the extent of the ³H-aldosterone labeling of these binding proteins in the kidney cytosol fractions of male and female adrenalectomized rats, even at dosages where no physiological response was demonstrable in the females.     

Aldosterone Induces Renal Fibrosis and Inflammatory M1-Macrophage Subtype via Mineralocorticoid Receptor in Rats

We aimed to evaluate macrophages heterogeneity and structural, functional and inflammatory alterations in rat kidney by aldosterone + salt administration. The effects of treatment with spironolactone on above parameters were also analyzed. Male Wistar rats received aldosterone (1 mgkg^-1d^-1) + 1% NaCl for 3 weeks. Half of the animals were treated with spironolactone (200 mg kg^-1d^-1). Systolic and diastolic blood pressures were elevated (p<0.05) in aldosterone + salt–treated rats. Relative kidney weight, collagen content, fibronectin, macrophage infiltrate, CTGF, Col I, MMP2, TNF-α, CD68, Arg2, and SGK-1 were increased (p<0.05) in aldosterone + salt–treated rats, being reduced by spironolactone (p<0.05). Increased iNOS and IFN-γ mRNA gene expression (M1 macrophage markers) was observed in aldosterone + salt rats, whereas no significant differences were observed in IL-10 and gene ArgI mRNA expression or ED2 protein content (M2 macrophage markers). All the observed changes were blocked with spironolactone treatment. Macrophage depletion with liposomal clodronate reduced macrophage influx and inflammatory M1 markers (INF-γ or iNOS), whereas interstitial fibrosis was only partially reduced after this intervention, in aldosterone plus salt-treated rats. In conclusion, aldosterone + salt administration mediates inflammatory M1 macrophage phenotype and increased fibrosis throughout mineralocorticoid receptors activation.     

The synthesis of reduced metabolites of aldosterone by subcellular fractions of rat kidney: effects of antimineralocorticoids

Subcellular fractionation of male rat kidney revealed that the nuclear and plasma membrane fractions isolated from the 1,000 g pellet retained a significant proportion of the aldosterone ring-A reducing activity. Improved HPLC solvent systems separated all six possible ring-A reduced metabolites of aldosterone and revealed that 80-90% of the reduced metabolites synthesized by purified nuclei and plasma membranes were 5 alpha-reduced compounds consisting of 5 alpha-DHA and 3 alpha,5 alpha-THA in ratios of 1:2 (nuclei) and 1:1 (membranes). The 105,000 g cytosol also synthesized significant quantities of reduced, hydroxylated, and conjugated metabolites of aldosterone. In contrast, the majority of the reduced metabolites of aldosterone synthesized by kidney cytosol were 5 beta-products, consisting principally of 5 beta-DHA and smaller quantities of 3 alpha,5 beta-THA and 3 beta,5 beta-THA. The synthesis of reduced aldosterone metabolites in the cytosol, nuclear, and plasma membrane fraction was inhibited by both 5 and 50 microM concentrations of the antimineralocorticoids, progesterone, K+-canrenoate, and corticosterone. Progesterone was the strongest inhibitor of the synthesis of 5 alpha-DHA and 3 alpha,5 alpha-THA in both nuclei and plasma membranes. The overall order of inhibition of the synthesis of ring-A reduced metabolites in the kidney subcellular fractions was progesterone greater than K+-canrenoate greater than corticosterone; both progesterone and K+-canrenoate inhibited 5 alpha-reduction more than 5 beta-reduction.     

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.     

Sex dependence of clearance rates of aldosterone and its metabolites from plasma of intact rats.

Following I.V. injection of 3H-aldosterone, the rates of clearance of plasma 3H-radioactivity was demonstrated to be sex-dependent in intact rats. Even though the percentages of CH2Cl2-extractable plasma radioactivity are greater in female than in male rats, the quantities of CH2Cl2-extractable label are similar until 60 min post-injection. However, the quantities of non-extractable, polar metabolites of aldosterone (NEPD) are markedly greater in the plasma of males and rapidly reach peak levels 10 min post-injection of aldosterone. In females, these polar metabolites (NEPD) are rapidly cleared from the blood. After bile-duct cannulation, the rate of excretion of aldosterone radiometabolites was demonstrated to be rapid and sex-dependent. Within 1 hr., female rats excreted via the bile 82% of the injected dose of 3H-aldosterone, compared to 49% in male rats. In both sexes, greater than 95% of the total radioactivity excreted in the bile are non-extractable polar metabolites of aldosterone (NEPD). The sex hormones appear to influence not only the nature of metabolism of aldosterone in the liver, but also the rates of clearance of aldosterone and its metabolites from the plasma into the bile.     

Metabolism of aldosterone in the colostomized duck (Anas platyrhynchos): partial characterization of urinary metabolites

1. Chronically colostomized ducks were injected with [4-14C]-aldosterone to study the metabolism of aldosterone and the pattern of metabolite excretion via the kidney. 2. Nearly half of the injected dose was excreted as radiometabolites during the first 24 hr; the largest amounts being excreted during the first 3 hr after injection. 3. Ion-exchange chromatography showed that monosulfate, disulfate, glucuronide, acidic, and neutral metabolites were excreted during each collection period, and that their relative proportions changed with time after injection of [4-14C]-aldosterone. 4. HPLC analysis of the neutral radiometabolites revealed 15 major peaks with retention times corresponding to both polar and reduced derivatives of aldosterone. 5. Only small quantities of unaltered labelled aldosterone were excreted. 6. Treatment of the birds with SKF 525-A caused a decrease in the total quantity of radiometabolite excreted and a change in the proportions of neutral and acidic metabolites in the cloacal fluid. 7. The decreases that occurred in the absolute amounts of some of the polar metabolites excreted by the birds treated with SKF-525A suggests that they may be hydroxylated and at least part of the aldosterone metabolizing system in the duck is cytochrome P450 dependent.     

Identification of Monohydroxy metabolites of 15,16-dihydrocyclopenta(a)phenanthren-17-one and its carcinogenic 11-methyl homolog produced by rat liver preparations in vitro.

Incubation of 15,16-dihydrocyclopenta[a]phenanthren-17-one and its carcinogenic 11-methyl homolog with rat liver microsomes led to similar patterns of metabolites. The carcinogen was the more slowly metabolized, but both ketones gave the corresponding 15-hydroxy derivatives, together with small quantities of the isomeric 16-ols. The 11-hydroxymethyl-17-ketone also occurred as a minor carcinogen metabolite. Incubation of the carcinogen with rat liver homogenates caused more extensive metabolism. The ratio of mono-ols to more polar metabolites was similar with homogenates from untreated and methylcholanthrene-induced rats, but increased metabolism to polar derivatives was observed after phenobarbitone induction.     

Metabolism of 3 H-digitoxigenin by rat liver, adrenal, and ovary homogenates

The metabolism of ³H-digitoxigenin was studied in rat liver, adrenal, and ovary homogenates under identical conditions. The major metabolite formed by liver and ovarian preparations was 3-epidigitoxigenin. Male liver homogenates showed higher epimerizing activity than female liver or ovary homogenates. In the adrenal preparations, the major metabolite formed was 3-digitoxigenone, and no sex difference was observed in its rate of formation. Adrenal and liver homogenates produced small amounts of digitoxigenin polar metabolites. The polar metabolites formed by the adrenal preparations were tentatively identified as 5-hydroxydigitoxigenin and 16β-hydroxydigitoxigenin.     

In vitro ecdysteroid conjugation by enzymes of Manduca sexta midgut cytosol

In incubations with 80,000g supernatant of Manduca sexta midgut homogenates, [³H]ecdysone was converted to 3-[³H]epiecdysone and tritiumlabeled highly polar metabolites. C₁₈ SEP-PAK cartridges were found suitable for the separation and purification of the free ecdysteroids and of the highly polar metabolites. Eighty to ninety percent of the metabolites were hydrolyzed by enzyme mixtures (mainly β-glucuronidase, sulphatase, and acid phosphatase) from molluscs, even when β-glucuronidase activity was completely inhibited by D-saccharic acid 1,4-lactone, or various human acid phosphatases (free of sulphatase activity). In each experiment, the hydrolysate contained a much higher proportion of 3-epiecydsone than the free (unconjugated) ecdysteroid fraction. [³H]ecdysone was not metabolized in anaerobic incubations of midgut supernatant that had been filtered through Sephadex G-25. Addition of 5 mM ATP and 5 mM Mg²⁺ restored the conjugate formation in incubations of Sephadex-filtered supernatant. Four ecdysone conjugates and two 3-epiecdysone conjugates were resolved by reversedphase ion-pair high-performance liquid chromatography. It is concluded that the midgut cytosol contains several ATP:ecdysteriod phosphotransferases. This is the first demonstration of the formation of ecdysteroid phosphoconjugates in a cell-free system.     

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.     

Endothelial Cell Swelling by Aldosterone

There is accumulating evidence that mineralocorticoids not only act on kidney but also on the cardiovascular system. We investigated the response of human umbilical venous endothelial cells (HUVECs) to aldosterone at a time scale of 20 minutes in absence and presence of the aldosterone antagonist spironolactone or other transport inhibitors. We applied atomic force microscopy (AFM), which measures cell volume and volume shifts between cytosol and cell nucleus. We observed an immediate cell volume increase (about 10%) approximately 1 min after addition of aldosterone (0.1 µmol/l), approaching a maximum (about 18%) 10 min after aldosterone treatment. Cell volume returned to normal 20 min after hormone exposure. Spironolactone (1 µmol/l) or amiloride (1 µmol/l) prevented the late aldosterone-induced volume changes but not the immediate change observed 1 min after hormone exposure. AFM revealed nuclear swelling 5 min after aldosterone addition, followed by nuclear shrinkage 15 min later. The Na⁺/H⁺ exchange blocker cariporide (10 µmol/l) was ineffective. We conclude: (i) Aldosterone induces immediate (1 min) swelling independently of plasma membrane Na⁺ channels and intracellular mineralocorticoid receptors followed by late mineralocorticoid receptor- and Na⁺-channel-dependent swelling. (ii) Intracellular macromolecule shifts cause the changes in cell volume. (iii) Both amiloride and spironolactone may be useful for medical applications to prevent aldosterone-induced vasculopathies.     

Biliary metabolites of estriol in the rat

Following the subcutaneous administration of estriol-6,7-³H to rats, biliary metabolites were identified and quantitated. Approximately 70% of the metabolites were excreted in the form of “glucosiduronate” conjugates. 3, 17β-Dihydroxy-2-methoxy-1,3,5(10)-estratrien-16-one was the major metabolite in this conjugate fraction. Significant amounts of 3,17β-dihydroxy-1,3,5(10)-estratrien-16-one and 2,3,17β-trihydroxy-1,3,5(10)-estratrien-16-one, as well as smaller quantities of 1,3,5(10)-estratriene-2,3,16α,17β-tetrol and 2-methoxy-1,3,5(10)-estratriene-3,16α, 17β-triol, were also found. In 17α-ethinylestradiol - treated animals, the rate of excretion of radioactivity and the proportion of 16-oxo-17β-ol metabolites found in the “glucosiduronate” fraction were reduced.     

Spironolactone reduces cerebral infarct size and EGF-receptor mRNA in stroke-prone rats

Remodeling of the cerebral vasculature contributes to the pathogenesis of cerebral ischemia. Remodeling is caused by increased smooth muscle proliferation and may be due to an increase in the responsiveness of vascular cells to epidermal growth factor (EGF). Aldosterone is a risk factor for stroke, and the literature suggests it may play a role in increasing the expression of the receptor for EGF (EGFR). We hypothesized that mRNA for the EGF-stimulated pathway would be elevated in the vasculature of stroke-prone spontaneously hypertensive rats (SHRSP) and that this and experimental ischemic cerebral infract size would be reduced by aldosterone inhibition with spironolactone. We found that spironolactone treatment reduced the size of cerebral infarcts after middle cerebral artery occlusion in SHRSP (51.69 +/- 3.60 vs. 22.00 +/- 6.69% of hemisphere-infarcted SHRSP vs. SHRSP + spironolactone P < 0.05). Expression of EGF and EGFR mRNA was higher in cerebral vessels and aorta from adult SHRSP compared with Wistar-Kyoto rats. Only the expression of EGFR mRNA was elevated in the young SHRSP. Spironolactone reduced the EGFR mRNA expression in the aorta (1.09 +/- 0.25 vs. 0.56 +/- 0.11 phosphorimage units SHRSP vs. SHRSP + spironolactone P < 0.05) but had no effect on EGF mRNA. In vitro incubation of aorta with aldosterone +/- spironolactone produced similar results, suggesting a direct effect of aldosterone. Thus spironolactone may reduce the size of cerebral infarcts via a reduction in the expression of the EGFR mRNA, leading to reduced remodeling.     

应激大鼠肾胞液[^3H]醛固酮结合活性的变化及调节机制的初步研究

为探讨烫伤引起病理性应激时大鼠肾胞液醛固酮结合活性的变化及可能的调节机制,以[～3H]-醛固酮为配体,用放射性配基-受体结合分析法测定了正常对照组、轻度烫伤组和重度烫伤组大鼠肾胞液醛固酮结合活性的结合容量(Rt)和表观解离常数(Kd);采用体内注射TNF-α、IL-1β中和抗体和α-促黑色素细胞刺激激素(α-melanocyte-stimulatinghormone,α-MSH)和合成肽KPV(Ac-D-Lys-L-Pro-D-Val)等措施调节其改变.结果发现,肾胞液存在两种不同结合容量、不同亲和力的醛固酮结合活性受体.与正常对照组的Rt(Rt141.6±7.2fmol/mgpro;Rt2317.6±70.0fmol/mgpro)相比,轻烫组的Rt(Rt141.4±5.0fmol/mgpro;Rt2314.8±45.7fmol/mgpro)无显著差异(P>0.05;P>0.05);重烫组的Rt(Rt122.4±5.4fmol/mgpro;Rt2196.3±32.5fmol/mgpro)则显著下降(P<0.01;P<0.01).体内注射TNF-α与IL-1β中和抗体、α-MSH及KPV均能明显提高重烫组Rt值.结果提示,重度烫伤大鼠肾胞浆醛固酮结合活性降低,TNF-α、IL-1β中和抗体、α-MSH及KPV均可防止重度烫伤引起病理性应激时醛固酮结合活性降低.     

Mineralocorticoids modify rat liver delta 6 desaturase activity and other parameters of lipid metabolism

The changes in linoleyl-CoA desaturase activity of rat liver microsomes were studied after a single intraperitoneal injection of 11-deoxycorticosterone or aldosterone at physiological doses. Fatty acid of plasma and different liver fractions, and physical properties of microsomal membranes were also investigated. It was found that the specific activity of delta 6 desaturase decreased 4-fold 24 hr after the injection of aldosterone or deoxycorticosterone. Pretreatment of the rats with aldosterone led to a significant decrease in the percent distribution of palmitic, arachidonic, docosapentaenoic and docosahexenoic acids, with a concomitant increase in palmitoleic, oleic and linoleic acids in plasma and liver homogenates, microsomes and cytosol fractions. A similar pattern was observed after deoxycorticosterone administration. The changes resulted in a decreased unsaturation index of all fractions studied and were well-correlated with the increase observed in fluorescence depolarization of the hydrophobic probe 1,6-diphenylhexatriene in liver microsomal membranes. The interlipid and lipid/protein ratios in microsomes remained constant after hormonal treatment. These results are consistent with the idea that the inhibition of delta 6 desaturase activity and the alterations in fatty acid composition induced by mineralocorticoids, are solely responsible for the measured decrease in liver microsomal membrane fluidity.