Effects of Obesity and Insulin on Tissue-Specific Recycling Between Cortisol and Cortisone in Men.

CONTEXT: 11ß-Hydroxysteroid dehydrogenase 1 (11ßHSD1) reduces inert cortisone into active cortisol but also catalyzes reverse dehydrogenase activity. Drivers of cortisol/cortisone equilibrium are unclear. With obesity, 11ßHSD1 transcripts are more abundant in adipose, but the consequences for oxidation vs reduction remain unknown. OBJECTIVE: This work aimed to determine whether 11ßHSD1 equilibrium in metabolic tissues is regulated by insulin and obesity. METHODS: A 2-phase, randomized, crossover, single-blinded study in a clinical research facility was conducted of 10 lean and obese healthy men. 11ß-Reductase and 11ß-dehydrogenase activities were measured during infusion of 9,11,12,12-[2H]4-cortisol and 1,2-[2H]2-cortisone, respectively, on 2 occasions: once during saline infusion and once during a hyperinsulinemic-euglycemic clamp. Arterialized and venous samples were obtained across forearm skeletal muscle and abdominal subcutaneous adipose. Steroids were quantified by liquid chromatography-tandem mass spectrometry and adipose tissue transcripts by quantitative polymerase chain reaction. RESULTS: Neither whole-body nor tissue-specific rates of production of cortisol or cortisone differed between lean and obese men, however insulin attenuated the diurnal decrease. Whole-body 11ß-HSD1 reductase activity tended to be higher in obesity (~ 10%) and was further increased by insulin. Across adipose tissue, 11ß-reductase activity was detected in obese individuals only and increased in the presence of insulin (18.99 ±â€…9.62 vs placebo 11.68 ±â€…3.63 pmol/100 g/minute; P < .05). Across skeletal muscle, 11ß-dehydrogenase activity was reduced by insulin in lean men only (2.55 ±â€…0.90 vs 4.50 ±â€…1.42 pmol/100 g/minute, P < .05). CONCLUSIONS: Regeneration of cortisol is upregulated by insulin in adipose tissue but not skeletal muscle. In obesity, the equilibrium between 11ß-reductase and 11ß-dehydrogenase activities likely promotes cortisol accumulation in adipose, which may lead to adverse metabolic consequences.

Neutrophil elastase-cleaved corticosteroid-binding globulin is absent in human plasma.

Corticosteroid-binding globulin (CBG) transports glucocorticoids in blood and is a serine protease inhibitor family member. Human CBG has a reactive center loop (RCL) which, when cleaved by neutrophil elastase (NE), disrupts its steroid-binding activity. Measurements of CBG levels are typically based on steroid-binding capacity or immunoassays. Discrepancies in ELISAs using monoclonal antibodies that discriminate between intact vs RCL-cleaved CBG have been interpreted as evidence that CBG with a cleaved RCL and low affinity for cortisol exists in the circulation. We examined the biochemical properties of plasma CBG in samples with discordant ELISA measurements and sought to identify RCL-cleaved CBG in human blood samples. Plasma CBG-binding capacity and ELISA values were consistent in arterial and venous blood draining skeletal muscle, liver and brain, as well as from a tissue (adipose) expected to contain activated neutrophils in obese individuals. Moreover, RCL-cleaved CBG was undetectable in plasma from critically ill patients, irrespective of whether their ELISA measurements were concordant or discordant. We found no evidence of RCL-cleaved CBG in plasma using a heat-dependent polymerization assay, and CBG that resists immunoprecipitation with a monoclonal antibody designed to specifically recognize an intact RCL, bound steroids with a high affinity. In addition, mass spectrometry confirmed the absence of NE-cleaved CBG in plasma in which ELISA values were highly discordant. Human CBG with a NE-cleaved RCL and low affinity for steroids is absent in blood samples, and CBG ELISA discrepancies likely reflect structural differences that alter epitopes recognized by specific monoclonal antibodies.

Carbonyl reductase 1 catalyzes 20ß-reduction of glucocorticoids, modulating receptor activation and metabolic complications of obesity.

Carbonyl Reductase 1 (CBR1) is a ubiquitously expressed cytosolic enzyme important in exogenous drug metabolism but the physiological function of which is unknown. Here, we describe a role for CBR1 in metabolism of glucocorticoids. CBR1 catalyzes the NADPH- dependent production of 20ß-dihydrocortisol (20ß-DHF) from cortisol. CBR1 provides the major route of cortisol metabolism in horses and is up-regulated in adipose tissue in obesity in horses, humans and mice. We demonstrate that 20ß-DHF is a weak endogenous agonist of the human glucocorticoid receptor (GR). Pharmacological inhibition of CBR1 in diet-induced obesity in mice results in more marked glucose intolerance with evidence for enhanced hepatic GR signaling. These findings suggest that CBR1 generating 20ß-dihydrocortisol is a novel pathway modulating GR activation and providing enzymatic protection against excessive GR activation in obesity.

Acute physiological effects of glucocorticoids on fuel metabolism in humans are permissive but not direct.

BACKGROUND AND AIMS: The effects of glucocorticoids on fuel metabolism are complex. Acute glucocorticoid excess promotes lipolysis but chronic glucocorticoid excess causes visceral fat accumulation. We hypothesized that interactions between cortisol and insulin and adrenaline account for these conflicting results. We tested the effect of cortisol on lipolysis and glucose production with and without insulin and adrenaline in humans both in vivo and in vitro. MATERIALS AND METHODS: A total of 20 healthy men were randomized to low and high insulin groups (both n = 10). Subjects attended on 3 occasions and received low (c. 150 nM), medium (c. 400 nM) or high (c. 1400 nM) cortisol infusion in a randomized crossover design. Deuterated glucose and glycerol were infused intravenously along with a pancreatic clamp (somatostatin with replacement of glucagon, insulin and growth hormone) and adrenaline. Subcutaneous adipose tissue was obtained for analysis. In parallel, the effect of cortisol on lipolysis was tested in paired primary cultures of human subcutaneous and visceral adipocytes. RESULTS: In vivo, high cortisol increased lipolysis only in the presence of high insulin and/or adrenaline but did not alter glucose kinetics. High cortisol increased adipose mRNA levels of ATGL, HSL and CGI-58 and suppressed G0S2. In vitro, high cortisol increased lipolysis in the presence of insulin in subcutaneous, but not visceral, adipocytes. CONCLUSIONS: The acute lipolytic effects of cortisol require supraphysiological concentrations, are dependent on insulin and adrenaline and are observed only in subcutaneous adipose tissue. The resistance of visceral adipose tissue to cortisol's lipolytic effects may contribute to the central fat accumulation observed with chronic glucocorticoid excess.

Metformin Increases Cortisol Regeneration by 11ßHSD1 in Obese Men With and Without Type 2 Diabetes Mellitus.

CONTEXT: The mechanism of action of metformin remains unclear. Given the regulation of the cortisol-regenerating enzyme 11ßhydroxysteroid dehydrogenase 1 (11ßHSD1) by insulin and the limited efficacy of selective 11ßHSD1 inhibitors to lower blood glucose when co-prescribed with metformin, we hypothesized that metformin reduces 11ßHSD1 activity. OBJECTIVE: To determine whether metformin regulates 11ßHSD1 activity in vivo in obese men with and without type 2 diabetes mellitus. DESIGN: Double-blind, randomized, placebo-controlled, crossover study. SETTING: A hospital clinical research facility. PARTICIPANTS: Eight obese nondiabetic (OND) men and eight obese men with type 2 diabetes (ODM). INTERVENTION: Participants received 28 days of metformin (1 g twice daily), placebo, or (in the ODM group) gliclazide (80 mg twice daily) in random order. A deuterated cortisol infusion at the end of each phase measured cortisol regeneration by 11ßHSD1. Oral cortisone was given to measure hepatic 11ßHSD1 activity in the ODM group. The effect of metformin on 11ßHSD1 was also assessed in human hepatocytes and Simpson-Golabi-Behmel syndrome adipocytes. MAIN OUTCOME MEASURES: The effect of metformin on whole-body and hepatic 11ßHSD1 activity. RESULTS: Whole-body 11ßHSD1 activity was approximately 25% higher in the ODM group than the OND group. Metformin increased whole-body cortisol regeneration by 11ßHSD1 in both groups compared with placebo and gliclazide and tended to increase hepatic 11ßHSD1 activity. In vitro, metformin did not increase 11ßHSD1 activity in hepatocytes or adipocytes. CONCLUSIONS: Metformin increases whole-body cortisol generation by 11ßHSD1 probably through an indirect mechanism, potentially offsetting other metabolic benefits of metformin. Co-prescription with metformin should provide a greater target for selective 11ßHSD1 inhibitors.