Mario Palermo

CA-Repeat Polymorphism in Intron 1 of HSD11B2: Effects on Gene Expression and Salt Sensitivity

Mutations in the HSD11B2 gene encoding the kidney (11-HSD2) isozyme of 11beta-hydroxysteroid dehydrogenase cause apparent mineralocorticoid excess, a form of familial hypertension. Because the hypertension associated with AME is of the salt-sensitive type, it seemed possible that decreases in 11-HSD2 activity might be associated with salt sensitivity. To examine this, Italians with mild hypertension underwent a protocol consisting of a rapid intravenous saline infusion and subsequent furosemide diuresis. To determine whether there were genetic associations between HSD11B2 and salt sensitivity, 198 Italians were genotyped for a CA repeat polymorphism (11 alleles) in the first intron. Increased differences in mean arterial pressure between the sodium loaded and depleted states were correlated with shorter CA repeat length (R=0.214, P=0. 0025). The effect behaved as a recessive trait. This suggested that decreased HSD11B2 expression was associated with shorter CA repeat length. Furthermore, activity of renal 11-HSD2 as measured by an increase in the ratio of urinary-free cortisol/urinary-free cortisone was lower in 33 salt-sensitive subjects (urinary-free cortisol/urinary-free cortisone 0.89+/-0.04 [mean+/-SE]) compared with 34 salt-resistant subjects (0.71+/-0.04, P<0.001). However, when minigenes containing either 14 or 23 CA repeats were transfected into rabbit or human kidney cortical collecting duct cells, the construct with 14 repeats was instead expressed at levels 50% higher than those of the construct with 23 repeats, as determined by reverse transcription-polymerase chain reaction. We conclude that polymorphisms in HSD11B2 and decreased 11-HSD2 activity are associated with sensitivity to sodium loading, but a functional explanation for these associations remains to be elucidated.

Quantitation of cortisol and related 3-oxo-4-ene steroids in urine using gas chromatography/mass spectrometry with stable isotope-labeled internal standards

A method for the profiling of several important 3-oxo-4-ene urinary steroids is reported. The methodology is combined gas chromatography/mass spectrometry (GC/MS) utilizing stable isotope-labeled internal standards. The following standards were obtained or easily synthesized: [9, 11, 12, 12-2H4]cortisol, [1,2-2H2] and [9, 12, 12-2H2]cortisone, [1,2-2H2]6 beta-hydroxycortisol, and [1,2-2H2]18-hydroxycortisol. We found the following excretions of free steroids for normal adult males and females: cortisol (males mean +/- SD, 35 +/- 13; females mean +/- SD, 23 +/- 13), cortisone (males mean +/- SD, 58 +/- 23; females mean +/- SD, 50 +/- 22), 6 beta-hydroxycortisol (males mean +/- SD, 164 +/- 59; females mean +/- SD, 108 +/- 55), and 18-hydroxycortisol (males mean +/- SD, 148 +/- 55; females mean +/- SD, 71 +/- 30). For 18-hydroxycortisol in particular, the excretions were much higher for males than for females. We found that the larger part of urinary cortisol and cortisone is not free but is released from conjugation by enzymes present in snail digestive juice. Using a pooled urine sample from an equal number of male and female subjects, we found that for cortisol 29% was excreted free, 28% as glucuronide and 43% as other conjugates (probably sulfates). For cortisone 41% was free, 45% beta-glucuronide and 14% as other conjugates. Relatively little (3-8%) of the hydroxylated cortisols were excreted conjugated.

Apparent mineralocorticoid excess syndrome: an overview

Apparent mineralocorticoid excess (AME) syndrome results from defective 11beta-hydroxysteroid dehydrogenase type 2 (11beta-HSD2). This enzyme is co-expressed with the mineralocorticoid receptor (MR) in the kidney and converts cortisol (F) to its inactive metabolite cortisone (E). Its deficiency allows the unmetabolized cortisol to bind to the MR inducing sodium retention, hypokalemia, suppression of PRA and hypertension. Mutations in the gene encoding 11beta-HSD2 account for the inherited form, but a similar clinical picture to AME occurs following the ingestion of bioflavonoids, licorice and carbenoxolone, which are competitive inhibitors of 11beta-HSD2. Reduced 11beta-HSD2 activity may explain the increased sodium retention in preeclampsia, renal disease and liver cirrhosis. Relative deficiency of 11beta-HSD2 activity can occur in Cushings syndrome due to saturation of the enzyme and explains the mineralocorticoid excess state that characterizes ectopic ACTH syndrome. Reduced placental 11beta-HSD2 expression might explain the link between reduced birth weight and adult hypertension. Polymorphic variability in the HSD11B2 gene in part determines salt sensitivity, a forerunner for adult hypertension onset. AME represents a spectrum of mineralocorticoid hypertension with severity reflecting the underlying genetic defect in the 11beta-HSD2; although AME is a genetic disorder, several exogenous compounds can bring about the symptoms by inhibiting 11beta-HSD2 enzyme. Substrate excess as seen in Cushings syndrome and ACTH ectopic production can overwhelm the capacity of 11beta-HSD2 to convert F to E, leading up to an acquired form of AME.

Licorice reduces serum testosterone in healthy women

UNLABELLED Licorice has been considered a medicinal plant for thousands of years. The most common side effect is hypokalemic hypertension, which is secondary to a block of 11beta-hydroxysteroid dehydrogenase type 2 at the level of the kidney, leading to an enhanced mineralocorticoid effect of cortisol. We have investigated the effect of licorice on androgen metabolism in nine healthy women 22-26 years old, in the luteal phase of the cycle. They were given 3.5 g of a commercial preparation of licorice (containing 7.6% W.W. of glycyrrhizic acid) daily for two cycles. They were not on any other treatment. Plasma renin activity, serum adrenal and gonadal androgens, aldosterone, and cortisol were measured by radioimmunoassay. Total serum testosterone decreased from 27.8+/-8.2 to 19.0+/-9.4 in the first month and to 17.5+/-6.4 ng/dL in the second month of therapy (p<0.05). It returned to pre-treatment levels after discontinuation. Androstenedione, 17OH-progesterone, and LH levels did not change significantly during treatment. Plasma renin activity and aldosterone were depressed during therapy, while blood pressure and cortisol remained unchanged. CONCLUSIONS Licorice can reduce serum testosterone probably due to the block of 17-hydroxysteroid dehydrogenase and 17-20 lyase. Licorice could be considered an adjuvant therapy of hirsutism and polycystic ovary syndrome.

Reduction of serum testosterone in men by licorice

To the Editor: Extracts of licorice root are widely used in many countries as flavoring agents, breath fresheners, or candy. The active component of licorice is glycyrrhizic acid, which is hydrolyz...

Mutants of 11β-Hydroxysteroid Dehydrogenase (11-HSD2) With Partial Activity: Improved Correlations Between Genotype and Biochemical Phenotype in Apparent Mineralocorticoid Excess

Mutations in the kidney isozyme of human 11-hydroxysteroid dehydrogenase (11-HSD2) cause apparent mineralocorticoid excess, an autosomal recessive form of familial hypertension. We studied 4 patients with AME, identifying 4 novel and 3 previously reported mutations in the HSD11B2 (HSD11K) gene. Point mutations causing amino acid substitutions were introduced into a pCMV5/11HSD2 expression construct and expressed in mammalian CHOP cells. Mutations L179R and R208H abolished activity in whole cells. Mutants S180F, A237V, and A328V had 19%, 72%, and 25%, respectively, of the activity of the wild-type enzyme in whole cells when cortisol was used as the substrate and 80%, 140%, and 55%, respectively, of wild-type activity when corticosterone was used as the substrate. However, these mutant proteins were only 0.6% to 5.7% as active as the wild-type enzyme in cell lysates, suggesting that these mutations alter stability of the enzyme. In regression analyses of all AME patients with published genotypes, several biochemical and clinical parameters were highly correlated with mutant enzymatic activity, demonstrated in whole cells, when cortisol was used as the substrate. These included the ratio of urinary cortisone to cortisol metabolites (R(2)=0.648, P<0.0001), age at presentation (R(2)=0.614, P<0.0001), and birth weight (R(2)=0.576, P=0.0004). Approximately 5% conversion of cortisol to cortisone is predicted in subjects with mutations that completely inactivate HSD11B2, suggesting that a low level of enzymatic activity is mediated by another enzyme, possibly 11-HSD1.

Apparent mineralocorticoid excess : Type I and type II

The syndrome of apparent mineralocorticoid excess (AME) is a heritable form of hypertension due to an inborn error of cortisol metabolism and is characterized by hypokalemia and low renin levels despite subnormal or normal levels of aldosterone and other known mineralocorticoids. The syndrome is attributable to congenital deficiency of the enzyme 11 beta-hydroxydehydrogenase (11 beta-HSD), which converts cortisol (F) to biologically inactive cortisone. This results in a prolonged half-life of F, which acts at the kidney level as a potent mineralocorticoid (MC). In fact, both F and aldosterone have similar affinities in vitro for type I MC receptor (MR), and 11 beta-HSD activity protects the MR in vivo from the higher circulating levels of F. The biochemical marker of this disorder is an increased ratio of tetrahydrocortisol (THF) + allo-THF/tetrahydrocortisone (THE) in the urine, which has been found in more than 20 patients described to date, together with evidence of a more general defect in steroid ring A reduction. Only a few cases (the so-called type II form) described in Italy differ from the classic form having a normal THF/THE ratio, but in both forms the ratio of free urinary F/E has recently been found to be similarly high. Dexamethasone is the treatment of choice but is often inadequate in long term control of high blood pressure. Acquired forms of AME are those consequent on abuse of licorice or carbenoxolone, which both inhibit 11 beta-HSD; the latter also inhibits the reverse 11-oxoreductase reaction leading to somewhat different abnormalities of urinary cortisol/cortisone. So far, two isoenzymes of 11 beta-HSD have been purified and cloned; 11 beta-HSD type 1 is NADP-dependent, abundant in liver, lung, and testis, and catalyzes both 11 beta-dehydrogenation and 11 beta-oxoreduction; no mutation in its gene was detected in patients with AME. A second NAD-dependent isoenzyme is present in kidney and placenta and catalyzes dehydrogenation only. Very recently (1995) two groups have independently demonstrated the presence of mutations in its gene, located in chromosome 16q22. New and co-workers found a point mutation in exon 6 of two affected siblings of an Iranian family, while White and co-workers in parallel studies showed point mutations or small deletions in both alleles in nine unrelated patients; importantly, expression studies showed minimal or absent activity for almost all the mutant sequences. No definite mutations have been so far identified in patients with AME type II. AME is thus the third single gene cause of human hypertension to be described, after glucocorticoid remediable aldosteronism in 1992 and Liddles syndrome in 1994.

Effect of licorice on the reduction of body fat mass in healthy subjects

The history of licorice, as a medicinal plant, is very old and has been used in many societies throughout the millennia. The active principle, glycyrrhetinic acid, is responsible for sodium retention and hypertension, which is the most common side-effect. We show an effect of licorice in reducing body fat mass. We studied 15 normalweight subjects (7 males, age 22–26 yr, and 8 females, age 21–26 yr), who consumed for 2 months 3.5 g a day of a commercial preparation of licorice. Body fat mass (BFM, expressed as percentage of total body weight, by skinfold thickness and by bioelectrical impedance analysis, BIA) and extracellular water (ECW, percentage of total body water, by BIA) were measured. Body mass index (BMI) did not change. ECW increased (males: 41.8±2.0 before vs 47.0±2.3 after, p<0.001; females: 48.2±1.4 before vs 49.4±2.1 after, p<0.05). BFM was reduced by licorice: (male: before 12.0±2.1 vs after 10.8±2.9%, p<0.02; female: before 24.9±5.1 vs after 22.1±5.4, p<0.02); plasma renin activity (PRA) and aldosterone were suppressed. Licorice was able to reduce body fat mass and to suppress aldosterone, without any change in BMI. Since the subjects were consuming the same amount of calories during the study, we suggest that licorice can reduce fat by inhibiting 11β-hydroxysteroid dehydrogenase Type 1 at the level of fat cells.

Congenital deficiency of 11β-hydroxysteroid dehydrogenase (apparent mineralocorticoid excess syndrome): Diagnostic value of urinary free cortisol and cortisone

The syndrome of apparent mineralocorticoid excess (AME) is an inherited form of hypertension. This disorder results from an inability of the enzyme 11β-hydroxysteroid dehydrogenase (11β-OHSD) to inactivate cortisol to cortisone. The diagnosis of AME is usually based on an elevated ratio of cortisol to cortisone reduced metabolites in the urine [tetrahydrocortisol plus allotetrahydrocortisol to tetrahydrocortisone (THF+alloTHF/THE)]. The principal site of “A” ring reduction is the liver, But AME arises from mutation in the gene encoding 11β-OHSD2 in the kidney. We used a gas chromatographic/mass spectrometric method to measure the urinary free cortisol (UFF) and free cortisone (UFE) in 24 patients affected by the two variants of AME [19 with the classical form (type I) and 5 with the mild form called AME type II] in order to provide a more reproducible in vivo measure of the renal enzymatic activity. Type I patients were divided into two groups: children under 12 and adults. UFF levels (μg/24 h) did not differ between under-12 controls and AME type I children (mean±SD, 9±4 and 15±12, respectively), But was significantly higher in affected adults compared to controls: (62±32 vs 29±8, p<0.01). No differences were found between adult controls and AME type II patients (29±8 and 37.0±14, respectively). UFE was undetectable in 63% of AME type I and significantly lower in AME type II (p<0.05). As a consequence UFF/UFE ratio was significantly higher in AME type I patients both in children and adults compared to controls (AME children: 5.1±2.6; normal children: 0.43±0.2, p<0.01; AME type I adults: 17.7±19.6; normal adults: 0.54±0.3 p<0.01). For AME type II, Where UFE was detectable in every case, the UFF/UFE ratio was significantly higher than adult controls (2.75±1.5 vs 0.54±0.3, p<0.01). In conclusion, Our study indicates that UFE and UFF/UFE ratio are sensitive markers of 11β-OHSD2, Directly reflecting the activity of the renal isozyme and readily identifying patients with AME. The presence of an altered UFF/UFE ratio in both types of AME, Although with different degree of severity, Calls for re-evaluation and the classification of AME as a single disorder.

Dopaminergic and Cholinergic Influences on the Growth Hormone Response to Growth Hormone-Releasing Hormone in Man

It is well established that compounds that modify dopaminergic and cholinergic activity in man may induce changes in circulating growth hormone (GH). We have, therefore, investigated the effect of a dopamine agonist, bromocriptine, and a dopamine antagonist, domperidone, as well as a muscarinic cholinergic antagonist, pirenzepine, on the GH response to an analogue of GH-releasing hormone (GHRH) in normal male subjects. GHRH(1-29)NH2 induced a rise in serum GH that was augmented by bromocriptine, antagonized by pirenzepine, but was unaltered by domperidone. As this dose of GHRH(1-29) NH2 has been shown to be maximally stimulatory to GH release, it is suggested that there are dopamine stimulatory and cholinergic inhibitory receptors to GH release independent of GHRH in man.