Adipose tissue expression of 11beta-hydroxysteroid dehydrogenase type 1 in Cushing's syndrome and in obesity

Glucocorticoids have a major role in determining adipose tissue metabolism and distribution. 11beta-hydroxysteroid dehydrogenase type 1 (11betaHSD1) is a NADPH-dependent enzyme highly expressed in the liver and adipose tissue. In most intact cells and tissues it functions as a reductase (to convert inactive cortisone to active cortisol). It has been hypothesized that tissue-specific deregulation of cortisol metabolism may be involved in the complex pathophysiology of the metabolic syndrome (MS) and obesity. Transgenic mice overexpressing 11betaHSD1 in adipose tissue develop obesity with all features of the MS, whereas 11betaHSD1-knockout mice are protected from both. The bulk of evidences points to an overexpression and increased activity of 11betaHSD1 also in human adipose tissue. However, 11betaHSD1 seems to adjust local cortisol concentrations independently of its plasma levels. In Cushing's syndrome, 11betaHSD1 is downregulated and may not be responsible for the abdominal fat depots; it also undergoes downregulation in response to weight loss in human obesity. The nonselective 11betaHSD1 inhibitor carbenoxolone improves insulin sensitivity in humans, and selective inhibitors enhance insulin action in diabetic mice liver, thereby lowering blood glucose. Thus, 11betaHSD1 is now emerging as a modulator of energy partitioning and a promising pharmacological target to treat the MS and diabetes.     

Lack of relationship between 11beta-hydroxysteroid dehydrogenase setpoint and insulin sensitivity in the basal state and after 24h of insulin infusion in healthy subjects and type 2 diabetic patients

OBJECTIVES: To test whether insulin resistance in type 2 diabetes mellitus is associated with an altered overall setpoint of the 11beta-hydroxysteroid dehydrogenase (11betaHSD) mediated cortisol to cortisone interconversion towards cortisol, and to evaluate whether changes in insulin sensitivity induced by antecedent hyperinsulinaemia are related to changes in the 11betaHSD setpoint. PATIENTS AND MEASUREMENTS: The urinary ratio of (tetrahydrocortisol + allo-tetrahydrocortisol)/tetrahydrocortisone ((THF + allo-THF)/THE) and of free cortisol/free cortisone (UFF/UFE), as well as the plasma cortisol/cortisone ratio were measured in 8 male type 2 diabetic patients and 8 healthy male subjects without and after 24 h of insulin infusion. Insulin was infused at a rate of 30 mU/kg/h with blood glucose being clamped at euglycaemic levels in healthy subjects and at isoglycaemic levels in diabetic patients. Insulin sensitivity was assessed by measurement of whole body glucose uptake (M-value) during a 3-4 h euglycaemic clamp, directly after the 24 h insulin infusion and compared to the M-value on a control day, at least 1 week apart from the 24 h insulin infusion. RESULTS: Despite impaired insulin sensitivity (M-value, 11.6 +/- 7.7 vs. 28.5 +/- 11.6 micromol/kg/minutes, in type 2 diabetic and healthy subjects, respectively, P < 0.05), urinary (THF + allo-THF)/THE ratio and baseline plasma cortisol/cortisone ratio at 0800 h were similar in type 2 diabetic patients (0.82 +/- 0.07 and 3. 77 +/- 0.70, respectively) and healthy subjects (0.76 +/- 0.14 and 3. 81 +/- 0.88, respectively, ns). Insulin sensitivity was not correlated with urinary (THF + allo-THF)/THE ratio nor with baseline plasma cortisol/ cortisone. In type 2 diabetic patients, insulin sensitivity was further impaired by antecedent hyperinsulinaemia (P < 0.05), but the urinary (THF + allo-THF)/THE ratio (0.80 +/- 0.14, ns) and the plasma cortisol/cortisone at 0800 h (3.66 +/- 0.72, ns) did not change. In healthy subjects, insulin sensitivity did not change significantly (M-value, 22.5 +/- 9.7 micromol/kg/minutes, ns), although the urinary (THF + allo-THF)/THE ratio (0.92 +/- 0.25, P < 0.05) and the plasma cortisol/cortisone (4.59 +/- 0.63, P < 0.05) increased. Insulin did not affect the UFF/UFE ratio in either group. CONCLUSION: The present study does not support the hypothesis that insulin resistance in type 2 diabetes mellitus is associated with an overall change in the 11betaHSD set point towards cortisol. In view of the stimulatory effects of insulin and cortisol on adipogenesis, long-term stimulation of 11betaHSD reductase activity by insulin could aggravate visceral obesity.     

Regulation of glucocorticoid receptor alpha and beta isoforms and type I 11beta-hydroxysteroid dehydrogenase expression in human skeletal muscle cells: a key role in the pathogenesis of insulin resistance?

Glucocorticoid excess frequently results in obesity, insulin resistance, glucose intolerance, and hypertension and may be the product of altered glucocorticoid hormone action. Tissue sensitivity to glucocorticoid is regulated by the expression of glucocorticoid receptor isoforms (GRalpha and GRbeta) and 11beta-hydroxysteroid dehydrogenase type I (11betaHSD1)-mediated intracellular synthesis of active cortisol from inactive cortisone. We have analyzed the expression of GRalpha, GRbeta, and 11betaHSD1 and their hormonal regulation in skeletal myoblasts from men (n = 14) with contrasting levels of adiposity and insulin resistance. Immunohistochemical, Northern blot, and Western blot analysis indicated abundant expression of GRalpha and 11betaHSD1 under basal conditions. The apparent K(m) and maximum velocity for the conversion of cortisone to cortisol were 440 +/- 14 nmol/L and 75 +/- 7 pmol/mg protein.h and 437 +/- 16 nmol/L and 33 +/- 6 pmol/mg protein.h (mean +/- SEM; n = 4) in the presence and absence of 20% serum. Incubation of myoblasts with increasing concentrations of glucocorticoid (50-1000 nmol/L) resulted in a dose-dependent decline in GRalpha expression and a dose-dependent increase in GRbeta expression. 11betaHSD1 activity was sensitively up-regulated by increasing concentrations of glucocorticoid (50-1000 nmol/L: P < 0.05). Abolition of these effects by the GR antagonist, RU38486, indicates that regulation of GRalpha, GRbeta, and 11betaHSD1 expression is mediated exclusively by the GRalpha ligand-binding variant. In contrast, 11betaHSD1 was down-regulated by insulin (20-100 mU/mL: P < 0.01) in the presence of 20% serum, whereas incubation with insulin under serum-free conditions resulted in a dose-dependent increase in 11betaHSD1 activity (P < 0.05). Incubation with insulin-like growth factor I resulted in a similar pattern of 11betaHSD1 activity. Although neither testosterone nor androstenedione (5-200 nmol/L) affected 11betaHSD1 activity, incubation of myoblasts with dehydroepiandrosterone (500 nmol/L) resulted in a decline in 11betaHSD1 activity (P < 0.05). These data suggest that glucocorticoid hormone action in skeletal muscle is determined principally by autoregulation of GRalpha, GRbeta, and 11betaHSD1 expression by the ligand-binding GRalpha isoform. Additionally, insulin and insulin-like growth factor I regulation of 11betaHSD1 may represent a novel mechanism that maintains insulin sensitivity in skeletal muscle tissue by diminishing glucocorticoid antagonism of insulin action.     

Cortisol metabolism in human obesity: impaired cortisone-->cortisol conversion in subjects with central adiposity

For a given body mass index (BMI), mortality is higher in patients with central compared to generalized obesity. Glucocorticoids play an important role in determining body fat distribution, but circulating cortisol concentrations are reported to be normal in obese patients. Our recent studies show enhanced conversion of inactive cortisone (E) to active cortisol (F) through the expression of 11beta-hydroxysteroid dehydrogenase type 1 (11betaHSD1) in cultured omental adipose stromal cells; the autocrine production of F may be a crucial factor in the pathogenesis of central obesity. We have now analyzed F metabolism in subjects with BMIs between 20-25 kg/m2 (group A), 25-30 kg/m2 (group B), and more than 30 kg/m2 (group C; n 12 in each group; six males and six premenopausal females; aged 23-44 yr). Glucose/insulin were measured using a 75-g oral glucose tolerance test, and each subject had total body and regional fat (scapular, waist, hip, and thigh) quantified using dual energy x-ray absorptiometry. Urinary total F metabolites (measured by gas chromatography/mass spectrometry) were increased in subjects with obesity [group A, 11,176 +/- 1,530 microg/24 h (mean +/- SE); group C, 13,661 +/- 1,444], although not significantly so (P = 0.08). There was a significant reduction in the urinary tetrahydrocortisol (THF) +/- 5alpha-THF/tetrahydrocortisone (THE) and the cortol/cortolone ratio in obesity (group A vs. C, 1.06 +/- 0.08 vs. 0.84 +/- 0.04 and 0.41 +/- 0.03 vs. 0.34 +/- 0.03, respectively; both P < 0.05). Urinary free F (UFF) excretion was similar in all three groups, as was the UFF/urinary free E (UFE) ratio. The 0900 h circulating F, E, and ACTH pre- and postovernight 1-mg dexamethasone suppression values were similar in all three groups, but a reduction in the generation of serum F from dexamethasone-suppressed values after oral cortisone acetate (25 mg) was evident in both obese groups [e.g. 546 +/- 37 nmol/L in group A vs. 412 +/- 40 in group B (P < 0.05) and 388 +/- 38 in group C (P < 0.01) 180 min post-E]. Insulin resistance was present in groups B and C, but regression analysis revealed no relationship between F metabolites or the THF +/- 5alpha-THF/THE ratio and insulin action (homeostasis model assessment analysis and insulin values in the oral glucose tolerance test). There was, however, a highly significant relationship between the THF +/- 5alpha-THF/THE ratio and BMI (t = -3.44; P < 0.01) and total body fat (t = -2.27; P < 0.05). Stepwise regression analyses indicated an inverse relationship between THF+/-5alpha-THF/THE and scapular and waist fat (t = -2.25; P = 0.03) and a direct relationship with hip and thigh fat (t = 2.42; P = 0.02) in both sexes. The fall in the THF + 5alpha-THF/THE ratio but unchanged UFF/UFE ratio together with impaired F concentrations after oral E indicates inhibition of 11betaHSD1 in subjects with obesity. This results in an increased MCR for F, explaining the increased F secretion rate in obesity in the face of normal circulating F concentrations. 11BetaHSD1 activity is highly related to body fat distribution, with android or central obesity, but not gynoid obesity, associated with reduced activity in both sexes. This reduction in 11betaHSD1 activity raises new questions as to the primary role of 11betaHSD1 in the pathogenesis of insulin resistance and central obesity.     

Regulation of expression of 11beta-hydroxysteroid dehydrogenase type 1 in adipose tissue: tissue-specific induction by cytokines

Patients with glucocorticoid excess develop central obesity, yet in simple obesity, circulating glucocorticoid levels are normal. We have suggested that the increased activity and expression of the enzyme 11beta-hydroxysteroid dehydrogenase type 1 (11betaHSD1) generating active cortisol from cortisone within adipose tissue may be crucial in the pathogenesis of obesity. In this study primary cultures of human hepatocytes and adipose stromal cells (ASC) were used as in vitro models to investigate the tissue-specific regulation of 11betaHSD1 expression and activity. Treatment with tumor necrosis factor-alpha (TNFalpha) caused a dose-dependent increase in 11betaHSD1 activity in primary cultures of both sc [1743.1 +/- 1015.4% (TNFalpha, 10 ng/ml); P < 0.05 vs. control (100%)] and omental [375.8 +/- 57.0% (TNFalpha, 10 ng/ml); P < 0.01 vs. control (100%)] ASC, but had no effect on activity in human hepatocytes [90.2 +/- 2.8% (TNFalpha, 10 ng/ml); P = NS vs. control (100%)]. Insulin-like growth factor I (IGF-I) caused a dose-dependent inhibition of 11betaHSD1 activity in sc [49.7 +/- 15.0% (IGF-I, 100 ng/ml]; P < 0.05 vs. control (100%)] and omental [71.6 +/- 7.5 (IGF-I, 100 ng/ml); P < 0.01 vs. control (100%)] stromal cells, but not in human hepatocytes [101.8 +/- 15.7% (IGF-I, 100 ng/ml); P = NS vs. control (100%)]. Leptin treatment did not alter 11betaHSD1 activity in human hepatocytes, but increased activity in omental ASC [135.8 +/- 14.1% (leptin, 100 ng/ml); P = 0.08 vs. control (100%)]. Treatment with interleukin-1beta induced 11betaHSD1 activity and expression in sc and omental ASC in a time- and dose-dependent manner. 15-Deoxy-12,14-PGJ2, the putative endogenous ligand of the orphan nuclear receptor peroxisome proliferator-gamma, significantly increased 11betaHSD1 activity in omental cells [179.7 +/- 29.6% (1 microM); P < 0.05 vs. control (100%)] and sc [185.3 +/- 12.6% (1 microM); P < 0.01 vs. control (100%)] ASC, and it is possible that expression of this ligand may ensure continued cortisol generation to permit adipocyte differentiation. Protease inhibitors used in the treatment of human immunodeficiency virus infection are known to cause a lipodystrophic syndrome and central obesity, but saquinavir, indinavir, and neflinavir caused a dose-dependent inhibition of 11betaHSD1 activity in primary cultures of human omental ASC. 11betaHSD1 expression is increased in human adipose tissue by TNFalpha, interleukin-1beta, leptin, and orphan nuclear receptor peroxisome proliferator-gamma agonists, but is inhibited by IGF-I. This autocrine and/or paracrine regulation is tissue specific and explains recent clinical data and animal studies evaluating cortisol metabolism in obesity. Tissue-specific 11betaHSD1 regulation offers the potential for selective enzyme inhibition within adipose tissue as a novel therapy for visceral obesity.     

Influence of short-term dietary weight loss on cortisol secretion and metabolism in obese men

OBJECTIVES: Obesity is associated with increased inactivation of cortisol by hepatic A-ring 5alpha- and 5beta-reductases, impaired hepatic regeneration of cortisol from cortisone by 11beta-hydroxysteroid dehydrogenase type 1 (11HSD1), but increased subcutaneous adipose 11HSD1 activity enhancing local cortisol levels in fat. Cause and effect between obesity and abnormal cortisol metabolism is untested. DESIGN: Acute weight loss was induced by very low calorie diet (VLCD) or starvation in obese men. METHODS: Otherwise healthy males (aged 20-55 years; body mass index (BMI) 30-40 kg/m2) were studied after 6 days on a weight maintenance diet; then after either 6 days of starvation (n=6) or 3 weeks of VLCD (2.55 MJ; n=6); then after 1 week of weight maintenance; and finally after 2 weeks of being allowed to feed ad libitum. Plasma samples were obtained from indwelling cannulae at 0930 h and 1815 h and a 24 h urine collection was completed for analysis of cortisol metabolites by gas chromatography/mass spectrometry. RESULTS: Data are mean+/-S.E.M. BMI fell (kg/m3) from 34.8+/-0.8 at baseline to 31.8+/-1.4 on VLCD and 32.7+/-1.1 on starvation. Starvation caused a rise in plasma cortisol (at 0930 h from 143+/-17 to 216+/-11 nM, P<0.001) but no change in total urinary cortisol metabolites. VLCD did not alter plasma cortisol and markedly reduced cortisol metabolite excretion (from 15.8+/-1.1 mg/day at baseline to 7.0+/-1.1 mg/day, P<0.001). Relative excretion of 5alpha-reduced cortisol metabolites fell on both diets, but there were no changes in cortisol/cortisone metabolite ratios reflecting 11HSD activities. CONCLUSIONS: Weight loss with VLCD in obesity reverses up-regulation of hepatic A-ring reductases and normalises cortisol production rate; in contrast, starvation produces acute stress and further activation of cortisol secretion. We suggest that activation of cortisol secretion is not an irreversible intrinsic abnormality in obese patients, and speculate that dietary content has an important influence on the neuroendocrine response to weight loss.     

Subcutaneous adipose 11 beta-hydroxysteroid dehydrogenase type 1 activity and messenger ribonucleic acid levels are associated with adiposity and insulinemia in Pima Indians and Caucasians

Metabolic effects of cortisol may be critically modulated by glucocorticoid metabolism in tissues. Specifically, active cortisol is regenerated from inactive cortisone by the enzyme 11 beta-hydroxysteroid dehydrogenase type 1 (11-HSD1) in adipose and liver. We examined activity and mRNA levels of 11-HSD1 and tissue cortisol and cortisone levels in sc adipose tissue biopsies from 12 Caucasian (7 males and 5 females) and 19 Pima Indian (10 males and 9 females) nondiabetic subjects aged 28 +/- 7.6 yr (mean +/- SD; range, 18-45). Adipose 11-HSD1 activity and mRNA levels were highly correlated (r = 0.51, P = 0.003). Adipose 11-HSD1 activity was positively related to measures of total (body mass index, percentage body fat) and central (waist circumference) adiposity (P < 0.05 for all) and fasting glucose (r = 0.43, P = 0.02), insulin (r = 0.60, P = 0.0005), and insulin resistance by the homeostasis model (r = 0.70, P < 0.0001) but did not differ between sexes or ethnic groups. Intra-adipose cortisol was positively associated with fasting insulin (r = 0.37, P = 0.04) but was not significantly correlated with 11-HSD1 mRNA or activity or with other metabolic variables. In this cross-sectional study, higher adipose 11-HSD1 activity is associated with features of the metabolic syndrome. Our data support the hypothesis that increased regeneration of cortisol in adipose tissue influences metabolic sequelae of human obesity.     

Understanding the role of glucocorticoids in obesity: tissue-specific alterations of corticosterone metabolism in obese Zucker rats

The role of glucocorticoids in obesity is poorly understood. Observations in obese men suggest enhanced inactivation of cortisol by 5alpha-reductase and altered reactivation of cortisone to cortisol by 11betahydroxysteroid dehydrogenase type 1 (11betaHSD1). These changes in glucocorticoid metabolism may influence corticosteroid receptor activation and feedback regulation of the hypothalamic-pituitary-adrenal axis (HPA). We have compared corticosterone metabolism in vivo and in vitro in male obese and lean Zucker rats, aged 9 weeks (n = 8/group). Steroids were measured in 72-h urine and 0900 h trunk blood samples. 5alpha-Reductase type 1 and 11betaHSD activities were assessed in dissected tissues. Obese animals were hypercorticosteronemic and excreted more total corticosterone metabolites (2264+/-623 vs. 388+/-144 ng/72 h; P = 0.003), with a greater proportion being 5alpha-reduced or 11-oxidized. 11-Dehydrocorticosterone was also elevated in plasma (73+/-9 vs. 18+/-2 nM; P = 0.001) and urine (408+/-111 vs. <28 ng/72 h; P = 0.01). In liver of obese rats, 5alpha-reductase type 1 activity was greater (20.6+/-2.7% vs. 14.1+/-1.5%; P<0.04), but 11betaHSD1 activity (maximum velocity, 3.43+/-0.56 vs. 6.57+/-1.13 nmol/min/mg protein; P = 0.01) and messenger RNA levels (0.56+/-0.08 vs. 1.03+/-0.15; P = 0.02) were lower. In contrast, in obese rats, 11betaHSD1 activity was not different in skeletal muscle and sc fat and was higher in omental fat(36.4+/-6.2 vs. 19.2+/-6.6; P = 0.01), whereas 11betaHSD2 activity was higher in kidney (16.7+/-0.6% vs. 11.3+/-1.5%; p = 0.01). We conclude that greater inactivation of glucocorticoids by 5alpha-reductase in liver and 11betaHSD2 in kidney combined with impaired reactivation of glucocorticoids by 11betaHSD1 in liver may increase the MCR of glucocorticoids and decrease local glucocorticoid concentrations at these sites. By contrast, enhanced 11betaHSD1 in omental adipose tissue may increase local glucocorticoid receptor activation and promote obesity.     

Body fat distribution and cortisol metabolism in healthy men: enhanced 5beta-reductase and lower cortisol/cortisone metabolite ratios in men with fatty liver

In Cushing's syndrome, cortisol causes fat accumulation in specific sites most likely to be associated with insulin resistance, notably in omental adipose and also perhaps in the liver. In idiopathic obesity, cortisol-metabolizing enzymes may play a key role in determining body fat distribution. Increased regeneration of cortisol from cortisone within adipose by 11beta-hydroxysteroid dehydrogenase (HSD) type 1 (11HSD1) has been proposed to cause visceral fat accumulation, whereas decreased hepatic 11HSD1 may protect the liver from glucocorticoid excess. Increased inactivation of cortisol by 5alpha- and 5beta-reductases in the liver may drive compensatory activation of the hypothalamic-pituitary-adrenal axis, hence increasing adrenal androgens and 'android' central obesity. This study aimed to examine relationships between these enzymes and detailed measurements of body fat distribution. Twenty-five healthy men (age, 22-57 yr; body mass index, 20.6-35.6 kg/m(2)) were recruited from occupational health services. Body composition was assessed by anthropometric measurements, bioimpedance, and cross-sectional abdominal magnetic resonance imaging scans. Liver fat content was assessed by magnetic resonance imaging spectroscopy. Insulin sensitivity was measured in a euglycemic hyperinsulinemic clamp. Cortisol metabolites were measured in a 24-h urine sample by gas chromatography-mass spectrometry. In vivo hepatic 11HSD1 activity was measured by generation of plasma cortisol after an oral dose of cortisone. In vitro 11HSD1 activity and mRNA were measured in 18 subjects who consented to provide abdominal sc adipose biopsies. Indices of obesity (body mass index, whole-body percentage fat, waist/hip ratio) were associated with higher urinary excretion of 5alpha- and 5beta-reduced cortisol metabolites (for percentage fat, P < 0.05 and P < 0.01, respectively) and increased adipose 11HSD1 activity (P < 0.05). Liver fat accumulation was associated with a selective increase in urinary excretion of 5beta-reduced cortisol and cortisone metabolites (P < 0.01) and a lower ratio of cortisol/cortisone metabolites in urine (P < 0.001) but no difference in in vivo cortisone-to-cortisol conversion or in vitro adipose 11HSD1. Higher excretion of 5beta-reduced cortisol metabolites was independently associated with insulin resistance and hypertriglyceridemia. Lower conversion of cortisone to cortisol was associated with lower fasting plasma cortisol (P < 0.01). However, visceral adipose fat mass was not associated with indices of cortisol metabolism; indeed, after adjusting for the effects of whole-body and liver fat, increased visceral fat was associated with lower cortisol metabolite excretion. We conclude that alterations in 11HSD1 and hepatic 5alpha-reductase activity are associated with generalized, rather than central, obesity in humans. Activation of 5beta-reductase in men with fat accumulation in the liver may confound the interpretation of cortisol metabolite excretion when liver fat content is unknown, and may contribute to altered bile acid and cholesterol metabolism in nonalcoholic steatohepatitis.     

Cortisol metabolism in healthy young adults: sexual dimorphism in activities of A-ring reductases, but not 11beta-hydroxysteroid dehydrogenases.

Cortisol is metabolized irreversibly by A-ring reductases (5alpha- and 5beta-reductases) and reversibly (to cortisone) by 11beta-hydroxysteroid dehydrogenases (11betaHSDs). In rats, estradiol down-regulates 11betaHSD1 expression. In humans, ratios of urinary cortisol/cortisone metabolites differ in men and women. In this study, urinary cortisol metabolites and hepatic 11betaHSD1 activity were measured in healthy young men and women at different phases of the menstrual cycle. Ten men and 10 women with regular menstrual cycles collected a 24-h urine sample, took 250 microg oral dexamethasone at 2300 h, took 25 mg oral cortisone at 0900 h (after fasting), and had blood sampled for plasma cortisol estimation over the subsequent 150 min. Women repeated the tests in random order in menstrual, follicular, and luteal phases. Women excreted disproportionately less A-ring-reduced metabolites of cortisol [median 5alpha-tetrahydrocortisol, 1811 (interquartile range, 1391-2300) microg/day in menstrual phase vs. 2723 (interquartile range, 2454-3154) in men (P = 0.01); 5beta-tetrahydrocortisol, 1600 (interquartile range, 1419-1968) vs. 2197 (interquartile range, 1748-2995; P = 0.03)] but similar amounts of cortisol, cortisone, and tetrahydrocortisone. Analogous differences were observed in urinary excretion of androgen metabolites. Conversion of cortisone to cortisol on hepatic first pass metabolism was not different (peak plasma cortisol, 733 +/- 60 nmol/L in women vs. 684 +/- 53 nmol/L in men; mean +/- SEM; P = 0.55). There were no differences in cortisol or androgen metabolism between phases of the menstrual cycle. We conclude that sexual dimorphism in cortisol metabolite excretion is attributable to less A-ring reduction of cortisol in women, rather than less reactivation of cortisone to cortisol by 11betaHSD1. This difference is not influenced acutely by gonadal steroids. 11BetaHSD1 has been suggested to modulate insulin sensitivity and body fat distribution, but caution must be exercised in extrapolating inferences about its regulation from rodents to man. A-Ring reductases may have an equally important influence on metabolic clearance of cortisol and intracellular cortisol concentrations.     

Low-dose growth hormone inhibits 11 beta-hydroxysteroid dehydrogenase type 1 but has no effect upon fat mass in patients with simple obesity

GH has potent effects on adipocyte biology, stimulating lipolysis but also promoting preadipocyte proliferation. In addition, GH, acting through IGF-I, inhibits 11 beta-hydroxysteroid dehydrogenase type 1 (11 beta-HSD1), which converts the inactive glucocorticoid, cortisone (E), to active cortisol (F) in adipose tissue. Although F is an essential requirement for adipocyte differentiation, it also inhibits preadipocyte proliferation. We hypothesized that inhibition of 11 beta-HSD1 activity in adipose tissue by GH may alter fat tissue mass through changes in local F concentrations. We conducted a randomized, double-blind, placebo-controlled study using low-dose GH (Genotropin 0.4 mg/d) for 8 months in 24 patients with obesity. Although GH treatment significantly raised IGF-I, we were unable to demonstrate significant differences in body composition or metabolic profiles between GH- and placebo-treated groups. In addition, there was no alteration in total fat mass over time in the GH-treated group [total fat mass 41.0 +/- 3.0 vs. 41.3 +/- 3.4 kg (8 months), mean +/- SE, P = ns]. However, in comparison with baseline values, systolic blood pressure increased (119 +/- 3 vs. 130 +/- 4 mm Hg, P < 0.05 vs. baseline) and serum F/E ratio decreased (6.1 +/- 0.5 vs. 3.9 +/- 0.5, P < 0.05 vs. baseline) in the GH-treated group only. Furthermore, although the urinary tetrahydrometabolites of F/E ratio fell in the GH-treated group, it rose in the placebo group (mean ratio change, -0.13 +/- 0.05 vs. +0.09 +/- 0.09, GH vs. placebo, P = 0.07). Treatment with low-dose GH in obesity fails to alter fat mass despite a significant elevation in IGF-I and a shift in the global set point of E to F conversion consistent with inhibition of 11 beta-HSD1.     

Tissue-specific changes in peripheral cortisol metabolism in obese women: increased adipose 11beta-hydroxysteroid dehydrogenase type 1 activity

Cushing's syndrome and the metabolic syndrome share clinical similarities. Reports of alterations in the hypothalamic-pituitary-adrenal (HPA) axis are inconsistent, however, in the metabolic syndrome. Recent data highlight the importance of adipose 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1), which regenerates cortisol from cortisone and, when overexpressed in fat, produces central obesity and glucose intolerance. Here we assessed the HPA axis and 11beta-HSD1 activity in women with moderate obesity and insulin resistance. Forty women were divided into tertiles according to body mass index (BMI; median, 22.0, 27.5, and 31.4, respectively). Serum cortisol levels were measured after iv CRH, low dose dexamethasone suppression, and oral cortisone administration. Urinary cortisol metabolites were measured in a 24-h sample. A sc abdominal fat biopsy was obtained in 14 participants for determination of 11beta-HSD type 1 activity in vitro. Higher BMI was associated with higher total cortisol metabolite excretion (r = 0.49; P < 0.01), mainly due to increased 5alpha- and, to a lesser extent, 5beta-tetrahydrocortisol excretion, but no difference in plasma cortisol basally, after dexamethasone, or after CRH, and only a small increase in the ACTH response to CRH. Hepatic 11beta-HSD1 conversion of oral cortisone to cortisol was impaired in obese women (area under the curve, 147,736 +/- 28,528, 115,903 +/- 26,032, and 90,460 +/- 18,590 nmol/liter.min; P < 0.001). However, 11beta-HSD activity in adipose tissue was positively correlated with BMI (r = 0.55; P < 0.05). In obese females increased reactivation of glucocorticoids in fat may contribute to the characteristics of the metabolic syndrome. Increased inactivation of cortisol in liver may be responsible for compensatory activation of the HPA axis. These alterations in cortisol metabolism may be a basis for novel therapeutic strategies to reduce obesity-related complications.     

Overexpression of 11beta-hydroxysteroid dehydrogenase-1 in adipose tissue is associated with acquired obesity and features of insulin resistance: studies in young adult monozygotic twins

11beta-Hydroxysteroid dehydrogenase type 1 (11beta-HSD-1) catalyzes the interconversion of inactive cortisone to active cortisol. Overexpression of 11beta-HSD-1 in murine adipose tissue results in glucocorticoid receptor (GR)alpha overexpression, central obesity, and insulin resistance. It is controversial whether 11beta-HSD-1 or GRalpha expression are increased in human adipose tissue in obesity. We studied effects of acquired obesity on 11beta-HSD-1 gene (real-time PCR) and protein (Western blotting) expression in sc adipose tissue in 17 monozygotic twin pairs aged 24-27 yr with a mean intrapair difference in body mass index (BMI) of 3.8 kg/m(2) (range 0.4-10.1 kg/m(2)). Intrapair correlations were calculated to study effects of acquired obesity on 11beta-HSD-1 expression. Western blot analysis of adipose tissue homogenates identified approximately 50- and approximately 68-kDa proteins specific for 11beta-HSD-1. Both structural forms correlated positively with 11beta-HSD-1 mRNA concentrations. Intrapair differences in 11beta-HSD-1 mRNA, and the 50- and 68-kDa proteins in sc adipose tissue correlated positively with those in BMI (kilograms per square meter) (r = 0.78 for 11beta-HSD-1 mRNA, P = 0.0002; r = 0.87 for the 11beta-HSD-1 50-kDa protein, P = 0.0003; and r = 0.62 for the 11beta-HSD-1 68-kDa protein, P = 0.033), total body fat (percent) (r = 0.65, P = 0.005; r = 0.83, P = 0.001; and r = 0.69, P = 0.013, respectively) and sc fat (cubed centimeters) (r = 0.66, P = 0.004; r = 0.94, P = 0.0001; and r = 0.71, P = 0.009, respectively). Furthermore, 11beta-HSD-1 mRNA and 50-kDa protein expression, but not 68-kDa protein expression, correlated positively with intrapair differences in intraabdominal fat mass (cubed centimeters) (r = 0.62, P = 0.008; r = 0.69, P = 0.013; r = 0.48, P = 0.112) and serum fasting insulin concentration (milliunits per liter) (r = 0.76, P = 0.0004; r = 0.60, P = 0.037; and r = 0.43, P = 0.160, respectively). Intrapair differences in GRalpha expression were significantly inversely correlated with those in BMI and total and sc fat mass. In conclusion, expression of 11beta-HSD-1 in sc adipose tissue is increased in human acquired obesity and is closely related to accumulation of sc and intraabdominal fat and features of insulin resistance.     

Relationship between ovarian cortisol:cortisone ratios and the clinical outcome of in vitro fertilization and embryo transfer (IVF-ET)

OBJECTIVE: Previously, we have reported an association between low levels of intraovarian cortisol metabolism, mediated by 11beta-hydroxysteroid dehydrogenase (11betaHSD), and the establishment of pregnancies by in vitro fertilization and embryo transfer (IVF-ET). The objective of the present study was to investigate the relationship between the clinical outcome of IVF-ET and the intraovarian concentrations of cortisol and cortisone and the cortisol:cortisone ratios in random samples of ovarian follicular fluid (FF). DESIGN: Retrospective, double-blind correlation analyses. PATIENTS: FF samples (n = 41) were obtained from 23 women undergoing gonadotrophin-stimulated IVF-ET cycles at the Cardiff Assisted Reproduction Unit. MEASUREMENTS: Clinical pregnancy was confirmed by ultrasonography. Intrafollicular steroid concentrations were measured by radioimmunoassays. RESULTS: Concentrations of both cortisol and cortisone were significantly lower in FF samples obtained from 6 patients that conceived than in samples obtained from 17 patients that did not achieve pregnancy (cortisol (mean +/- SEM) = 304 +/- 29 vs. 407 +/- 26 nmol/l, P = 0. 0411; cortisone = 32 +/- 3 vs. 65 +/- 7 nmol/l, P = 0.0002). Intrafollicular cortisol:cortisone ratios were significantly higher in samples from conception cycles than in those samples obtained from nonconception cycles (9.7 +/- 0.7 vs. 6.9 +/- 0.5, respectively, P = 0.0060). Whereas 5 of 10 women with intrafollicular cortisol:cortisone ratios greater than the outcome-independent mean of 7.7 became pregnant, only 1 of the 13 patients with intrafollicular cortisol:cortisone ratios < 7.7 conceived (chi2 = 5. 247, P = 0.0220). CONCLUSIONS: Concentrations of both cortisol and cortisone were significantly lower in FF samples obtained from patients that conceived by IVF-ET than in those obtained from nonconception cycles. Conception by gonadotrophin-stimulated IVF-ET was associated with an elevated intrafollicular ratio of cortisol:cortisone, consistent with a low level of intraovarian cortisol oxidation by 11betaHSD.     

Modulation of 11beta-hydroxysteroid dehydrogenase isozymes by growth hormone and insulin-like growth factor: in vivo and in vitro studies

The interconversion of hormonally active cortisol (F) and inactive cortisone (E) is catalyzed by two isozymes of 11beta-hydroxysteroid dehydrogenase (11betaHSD), an oxo-reductase converting E to F (11betaHSD1) and a dehydrogenase (11betaHSD2) converting F to E. 11betaHSD1 is important in mediating glucocorticoid-regulated glucose homeostasis and regional adipocyte differentiation. Earlier studies conducted with GH-deficient subjects treated with replacement GH suggested that GH may modulate 11betaHSD1 activity. In 7 acromegalic subjects withdrawing from medical therapy (Sandostatin-LAR; 20-40 mg/month for at least 12 months), GH rose from 7.1 +/- 1.5 to 17.5 +/- 4.3 mU/L (mean +/- SE), and insulin-like growth factor I (IGF-I) rose from 43.0 +/- 8.8 to 82.1 +/- 13.7 nmol/L (both P < 0.05) 4 months after treatment. There was a significant alteration in the normal set-point of F to E interconversion toward E. The fall in the urinary tetrahydrocortisols/tetrahydocortisone ratio (THF+allo-THF/THE; 0.82 +/- 0.06 to 0.60 +/- 0.06; P < 0.02) but unaltered urinary free F/urinary free E ratio (a marker for 11betaHSD2 activity) suggested that this was due to inhibition of 11betaHSD1 activity. An inverse correlation between GH and the THF+allo-THF/THE ratio was observed (r = -0.422; P < 0.05). Conversely, in 12 acromegalic patients treated by transsphenoidal surgery (GH falling from 124 +/- 49.2 to 29.3 +/- 15.4 mU/L; P < 0.01), the THF+allo-THF/THE ratio rose from 0.53 +/- 0.06 to 0.63 +/- 0.07 (P < 0.05). Patients from either group who failed to demonstrate a change in GH levels showed no change in the THF+allo-THF/THE ratio. In vitro studies conducted on cells stably transfected with either the human 11betaHSD1 or 11betaHSD2 complementary DNA and primary cultures of human omental adipose stromal cells expressing only the 11betaHSD1 isozyme indicated a dose-dependent inhibition of 11betaHSD1 oxo-reductase activity with IGF-I, but not GH. Neither IGF-I nor GH had any effect on 11betaHSD2 activity. GH, through an IGF-I-mediated effect, inhibits 11betaHSD1 activity. This reduction in E to F conversion will increase the MCR of F, and care should be taken to monitor the adequacy of function of the hypothalamo-pituitary-adrenal axis in acromegalic subjects and in GH-deficient, hypopituitary patients commencing replacement GH therapy. Conversely, enhanced E to F conversion occurs with a reduction in GH levels; in liver and adipose tissue this would result in increased hepatic glucose output and visceral adiposity, suggesting that part of the phenotype currently attributable to adult GH deficiency may be an indirect consequence of its effect on tissue F metabolism via 11betaHSD1 expression.     

Distinguishing the activities of 11beta-hydroxysteroid dehydrogenases in vivo using isotopically labeled cortisol.

The isozymes of 11beta-hydroxysteroid dehydrogenase (11betaHSDs) catalyze the interconversion of cortisol and cortisone. The type 2 dehydrogenase inactivates cortisol to cortisone, whereas the type 1 catalyzes predominantly the reverse reductive reaction. These reactions take place in different tissues, where they are subject to distinct regulation, and may be important in common pathologies. Current methods to determine the activities of these enzymes in vivo rely only on the balance between cortisol and cortisone, do not measure turnover, and cannot distinguish between the two reactions. We have investigated the use of [9,11,12,12-2H4]cortisol (d4F) to distinguish the dehydrogenase and reductase activities. On metabolism by dehydrogenation, d4F loses 11alpha- deuterium, forming trideuterated cortisone (d3E) and is regenerated by reduction to trideuterated cortisol (d3F). Healthy men (n = 6) participated in a randomized, double blind, cross-over study comparing oral placebo and the 11betaHSD inhibitor, carbenoxolone (100 mg every 8 h for 7 d). d4F and its metabolites were measured in plasma and urine during a steady state infusion. Inhibition of 11betaHSDs by carbenoxolone was measured by increased steady state concentrations of d4F (41 +/- 5.1 vs. 48 +/- 7.7 nM; P < 0.05) and a fall in the rate of appearance of d3F (P < 0.05). 11betaHSD1 reductase activity could be measured specifically as conversion of d3E to d3F (28 +/- 4.2 vs. 17 +/- 3.1 nM; P < 0.05), whereas 11betaHSD2 could be measured by initial rates of appearance of d3E or from urinary ratios of d4F/(d3E + d3F) (0.73 +/- 0.06 vs. 1.02 +/- 0.03; P < 0.05). This technique offers a significant advance in the methods available to measure turnover in 11betaHSDs and isozymes of 11betaHSDs in vivo in human studies, and this study confirms that carbenoxolone inhibits both isozymes of 11betaHSD.     

11beta-hydroxysteroid dehydrogenase type 1 activity in lean and obese males with type 2 diabetes mellitus

Glucocorticoids play an important role in the pathogenesis of obesity and insulin resistance. Impaired conversion of cortisone (E) to cortisol (F) by the type 1 isoenzyme of 11beta-hydroxysteroid dehydrogenase (11beta-HSD) in obesity may represent a protective mechanism preventing ongoing weight gain and glucose intolerance. We have studied glucocorticoid metabolism in 33 male subjects with type 2 diabetes mellitus [age, 44.2 +/- 13 yr; body mass index (BMI), 31.1 +/- 7.5 kg/m(2) (mean +/- sd)] and 38 normal controls (age, 41.4 +/- 14 yr; BMI, 38.2 +/- 12.8 kg/m(2)).Circulating F:E ratios were elevated in the diabetic group and correlated with serum cholesterol and homeostasis model assessment-S. There was no difference in 11beta-HSD1 activity between diabetic subjects and controls. In addition, 11beta-HSD1 activity was unaffected by BMI in diabetic subjects. However, in control subjects, increasing BMI was associated with a reduction in the urinary tetrahydrocortisol+5alpha-tetrahydrocortisol:tetrahydrocortisone ratio (P < 0.05) indicative of impaired 11beta-HSD1 activity. The degree of inhibition correlated tightly with visceral fat mass. Changes in 11beta-HSD1 activity could not be explained by circulating levels of adipocytokines.Impaired E to F metabolism in obesity may help preserve insulin sensitivity and prevent diabetes mellitus. Failure to down-regulate 11beta-HSD1 activity in patients with diabetes may potentiate dyslipidemia, insulin resistance, and obesity. Inhibition of 11beta-HSD1 may therefore represent a therapeutic strategy in patients with type 2 diabetes mellitus and obesity.     

Tissue-specific dysregulation of cortisol metabolism in human obesity

Cortisol has been implicated as a pathophysiological mediator in idiopathic obesity, but circulating cortisol concentrations are not consistently elevated. The tissue-specific responses to cortisol may be influenced as much by local prereceptor metabolism as by circulating concentrations. For example, in liver and adipose tissue cortisol is regenerated from inactive cortisone by 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1). In obese Zucker rats 11beta-HSD1 activity is reduced in liver but enhanced in adipose tissue. This study addressed whether the same tissue-specific disruption of cortisol metabolism occurs in human obesity. 34 men were recruited from the MONICA population study in Northern Sweden to represent a wide range of body composition and insulin insensitivity. Plasma cortisol was measured at 0830h and 1230h, after overnight low-dose dexamethasone suppression, after intravenous corticotropin releasing hormone (CRH), and after oral cortisone administration. Urinary cortisol metabolites were measured in a 24 h sample. A subcutaneous fat biopsy was obtained from 16 participants to measure cortisol metabolism in vitro. Higher body mass index was associated with increased total cortisol metabolite excretion (r = 0.47, p < 0.01), but lower plasma cortisol at 1230 h and after dexamethasone, and no difference in response to CRH. Obese men excreted a greater proportion of glucocorticoid as metabolites of cortisone rather than cortisol (r = 0.43, p < 0.02), and converted less cortisone to cortisol after oral administration (r = 0.49, p < 0.01), suggesting impaired hepatic 11beta-HSD1 activity. By contrast, in vitro 11beta-HSD1 activity in subcutaneous adipose tissue was markedly enhanced in obese men (r = 0.66, p < 0.01). We conclude that in obesity, reactivation of cortisone to cortisol by 11beta-HSD1 in liver is impaired, so that plasma cortisol levels tend to fall, and there may be a compensatory increase in cortisol secretion mediated by a normally functioning hypothalamic-pituitary-adrenal axis. However, changes in 11beta-HSD1 are tissue-specific: strikingly enhanced reactivation of cortisone to cortisol in subcutaneous adipose tissue may exacerbate obesity; and it may be beneficial to inhibit this enzyme in adipose tissue in obese patients.