The Serum Cortisol:Cortisone Ratio in the Postoperative Acute-Phase Response

Endogenously released or exogenously administered glucocorticosteroids are relevant hormones for controlling inflammation. Only 11β-hydroxy glucocorticosteroids, but not 11-keto glucocorticosteroids, activate glucocorticoid receptors. Since we found that glomerular mesangial cells (GMC) express 11β-hydroxysteroid dehydrogenase 1 (11β-OHSD1), which interconverts 11-keto glucocorticosteroids into 11β-hydroxy glucocorticosteroids (cortisone/cortisol shuttle), we explored whether 11β-OHSD1 determines the antiinflammatory effect of glucocorticosteroids. GMC exposed to interleukin (IL)-1β or tumor necrosis factor α (TNF-α) release group II phospholipase A2 (PLA2), a key enzyme producing inflammatory mediators. 11β-hydroxy glucocorticosteroids inhibited cytokine-induced transcription and release of PLA2 through a glucocorticoid receptor–dependent mechanism. This inhibition was enhanced by inhibiting 11β-OHSD1. Interestingly, 11-keto glucocorticosteroids decreased cytokine-induced PLA2 release as well, a finding abrogated by inhibiting 11β-OHSD1. Stimulating GMC with IL-1β or TNF-α increased expression and reductase activity of 11β-OHSD1. Similarly, this IL-1β– and TNF-α–induced formation of active 11β-hydroxy glucocorticosteroids from inert 11-keto glucocorticosteroids by the 11β-OHSD1 was shown in the Kiki cell line that expresses the stably transfected bacterial β-galactosidase gene under the control of a glucocorticosteroids response element. Thus, we conclude that 11β-OHSD1 controls access of 11β-hydroxy glucocorticosteroids and 11-keto glucocorticosteroids to glucocorticoid receptors and thus determines the anti-inflammatory effect of glucocorticosteroids. IL-1β and TNF-α upregulate specifically the reductase activity of 11β-OHSD1 and counterbalance by that mechanism their own proinflammatory effect.

11beta-Hydroxysteroid dehydrogenase (11beta-HSD) enzymes interconvert active cortisol and inactive cortisone. There is growing evidence that local tissue concentrations of cortisol are generally modulated by site specific different 11beta-HSD actions. While 11beta-HSD type 2 unidirectionally inactivates cortisol, type 1 isoform acts bidirectionally. 11beta-HSD type 1 is mainly localized in the liver and may thus restore circulating biologically inactive cortisone to active cortisol thereby modulating systemic glucocorticoid action; such a mechanism might be of importance in stressful situations. To study this hypothesis we investigated the influence of exogenous ACTH on serum cortisol/cortisone ratio. Paired serum samples that were submitted for routine analysis of cortisol before and 1 h after stimulation with 250 microg ACTH (1-24) (Synacthen) were collected prospectively if the routine tests indicated normal adrenal function; 40 patients were included in the study, 29 patients were female, 11 male, median age was 31 yr (range 14-70). Serum cortisol and cortisone were determined using LC-ESI/MS/MS with an online sample extraction system and tri-deuterated cortisol as the internal standard. While mean serum cortisol increased by 109% (mean basal concentration 373 nmol/L (SD 151 nmol/L), stimulated 781 nmol/L (SD 194 nmol/L)), mean serum cortisone significantly decreased after ACTH administration by 31% (p < 0.001, paired t-test for differences). Mean serum cortisone was 70 nmol/L (SD 16 nmol/L) before and 48 nmol (SD 16 nmol/L) after ACTH administration; decrease in serum cortisone was observed in 34 (85%) of the patients. The ratio of serum cortisol/cortisone increased in all subjects (mean 5.4 (SD 1.9) before ACTH, and 16.2 (SD 6.2) after ACTH; p < 0.001). The data of our observational study suggest a modulation of peripheral metabolism of cortisol by ACTH with a stimulation of systemic 11beta-HSD type 1 activity, leading to restoration of inactive cortisone to biologically active cortisol.