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Oxoreductase and Dehydrogenase Activities of the Human and Rat 11ß-Hydroxysteroid Dehydrogenase Type 2 Enzyme¹

Laboratory of Molecular Hypertension, Baker Institute of Medical Research, Prahran, Victoria 3181, Australia

Address all correspondence and requests for reprints to: Paolo Ferrari, M.D., Laboratory of Molecular Hypertension, Baker Institute of Medical Research, Prahran, Victoria 3181, Australia.

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
The 11ß-hydroxysteroid dehydrogenase type 2 enzyme (11ßHSD2) metabolizes glucocorticoids into their inactive 11-keto metabolites. Although the type 1 enzyme (11ßHSD1) displays both oxidative and reductive activity, to date 11ßHSD2 has been shown to have dehydrogenase activity only.

In this study we compared both dehydrogenase and reductase characteristics of the cloned rat 11ßHSD1 and rat and human 11ßHSD2 for three different 11-hydroxysteroid substrates, cortisol (F), corticosterone (B), and dexamethasone (Dex), and the corresponding 11-keto metabolites, cortisone (E), 11-dehydrocorticosterone (A), and 11-dehydrodexamethasone (DH-Dex), respectively.

In cell homogenates expressing either the rat or the human 11ßHSD2, the relative potency for the dehydrogenase reaction was B > F > Dex. Although there was no reduction of A or E, DH-Dex was readily converted to Dex with an equilibrium far on the side of the 11-hydroxy metabolite. DH-Dex reduction in homogenates was inhibited by both glycyrrhetinic acid and carbenoxolone, with a 50% inhibition at 80 and 100 nM, respectively. In intact cells transfected with rat 11ßHSD1, the equilibrium was on the reductase side for all substrates. Dehydrogenation of B or F was more potent with rat 11ßHSD2 than with rat 11ßHSD1. There was no detectable 11ßHSD1 oxidation of Dex.

These data indicate that both the cloned human and rat 11ßHSD2 reduce DH-Dex and do this more readily than they oxidize Dex. Thus, 11ßHSD2 seems also to be a bidirectional enzyme, although no reduction of the physiological compounds A and E was observed.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
11ß-HYDROXYSTEROID dehydrogenase (11ßHSD) is a microsomal enzyme responsible for the conversion of cortisol (F) in man, and corticosterone (B) in rodents, to the receptor-inactive 11-keto-metabolites (1, 2). This enzyme functions as a protective mechanism, preventing glucocorticoids binding to both the mineralocorticoid receptor (1, 3) and glucocorticoid receptors (4) in aldosterone target tissues such as the cortical collecting tubules of the kidney (1, 3). To date, two kinetically distinct forms of 11ßHSD (11ßHSD1 and 11ßHSD2), differentiated in addition by cofactor specificity and tissue distribution, have been characterized (5, 6). 11ßHSD1 is found in most tissues; its K_m for F is more than an order of magnitude higher than that of 11ßHSD2; it is NADP preferring and has been shown to have predominantly reductase activity (7, 8). In contrast, 11ßHSD2 has been identified in a limited range of tissues (6, 9, 10, 11); it has a high affinity for cortisol, is NAD requiring, and appears to show only dehydrogenase activity (6, 10, 12, 13). Importantly, localization studies have identified message in the distal tubule and have detected high levels of immunostaining in the distal convoluted tubule and collecting duct in man, colocalizing 11ßHSD2 with mineralocorticoid receptors (14, 15, 16).

When 11ßHSD2 activity is compromised, as occurs in licorice intoxication or in the congenital syndrome of apparent mineralocorticoid excess (AME), sodium retention, hypokalemia, and hypertension ensue, suggesting that F acts as a mineralocorticoid in these circumstances (17, 18). Recent studies have unequivocally established a link between 11ßHSD2 and AME by the demonstration of mutations in the HSD11B2 gene of AME patients (19, 20, 21, 22). Based on these observations, 11ßHSD2 is the most likely candidate to confer aldosterone selectivity on the mineralocorticoid receptor, whereas the role of 11ßHSD1 may include modulation of glucocorticoid bioavailability in glucocorticoid target tissues. High levels of 11ßHSD2 are also present in the human placenta (16), where it is thought to protect the fetus from high levels of maternal glucocorticoids, and there appears to be a correlation among placental enzyme activity, birth weight, and the development of hypertension latter in life (23, 24, 25).

The kinetics of 11ßHSD have been investigated largely in tissue homogenates of both rat liver, an organ in which message for 11ßHSD2 is undetectable (6, 9) and rat kidney, where both forms of 11ßHSD are present (11, 26). We recently established kinetics, concentration dependence, and saturability, as well as inhibition by other steroids, and described dexamethasone (Dex) dehydrogenation by the cloned human 11ßHSD2 (27). Oelkers et al. and Diedrich et al. recently reported oxoreduction of 11-dehydrodexamethasone (DH-Dex) by human kidney slices and human kidney microsomal preparations (28, 29). It is, however, unclear, whether DH-Dex reduction is catalyzed by 11ßHSD1 or 11ßHSD2 or by another, as yet unidentified 11ßHSD isoform. Thus, in the present study we used complementary DNAs coding for the rat 11ßHSD1, rat 11ßHSD2, and human 11ßHSD2 as well as mutated 11ßHSD2 plasmids derived from patients with AME to investigate DH-Dex oxidoreductase activity of the cloned 11ßHSD enzymes.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Steroids
Radiolabeled Dex ([1,2,4,6,7-N-³H]Dex; SA, 83 Ci/mmol; 3.07 TBq/mmol) and radiolabeled cortisone ([1,2-N-³H]E; SA, 29 Ci/mmol; 1.07 TBq/mmol) were obtained from Amersham International (Aylesbury, UK). Radiolabeled F ([1,2,6,7-N-³H]F; SA, 78 Ci/mmol; 2.9 TBq/mmol) and radiolabeled B ([1,2,6,7-N-³H]B; SA, 88 Ci/mmol; 3.3 TBq/mmol) were purchased from DuPont-New England Nuclear Products (Boston, MA). Radiolabeled 11-dehydrocorticosterone (A) and DH-Dex were produced in-house after metabolism of the parent compound and purification by TLC in parallel with radioinert standards. Radioinert A, B, E, F, and Dex were obtained from Sigma Chemical Co. (St. Louis, MO). Radioinert DH-Dex was purchased from Steraloids (Wilton, NH). All compounds were more than 95% pure.

Cell culture and preparation of homogenates
Modified Chinese hamster ovary cells (CHOP-C4) cells (30) were cultured and transfected as previously reported (27). Experiments in intact cells were performed 48 h after transfection in 35-mm wells. CHOP cell homogenates were obtained 60 h after transfection of cells. Confluent cells from 100-mm plates were homogenized and stored at -70 C until use (27).

Analysis of enzyme activity in intact cells and homogenates
The 11ßHSD activity of rat or human 11ßHSD2 clones or that of the rat 11ßHSD1 clone was determined by measuring the conversion of radiolabeled 11-hydroxysteroid substrates F, B, and Dex to their corresponding 11-keto metabolites E, A, and DH-Dex, respectively. Similarly, 11ßHSD reductase activity was assessed by measuring the conversion of radiolabeled 11-keto substrates to their respective 11-hydroxy metabolites.

Dehydrogenase and oxoreductase activities for F/E, B/A, and Dex/DH-Dex were determined in intact cells after transfection of CHOP cells with 1 µg rat 11ßHSD2 or rat 11ßHSD1 plasmids. After 48 h, 2–5 nM of the corresponding ³H-labeled substrate was incubated for 30–60 min with the cells in serum-free medium. Culture medium was then extracted in 3 vol ethyl acetate. Steroid metabolites were assayed by TLC as described below. Determination of rat 11ßHSD2 enzyme kinetics for Dex was performed by incubating transfected CHOP cells with substrate concentrations of 2 nM [³H]Dex and 400–12,800 nM unlabeled Dex for 60 min. Determination of rat 11ßHSD2 or rat 11ßHSD1 kinetics for DH-Dex was performed by incubating transfected CHOP cells with substrate concentrations of 2 nM [³H]DH-Dex and 400–25,600 nM unlabeled DH-Dex for 60 min. F dehydrogenation and DH-Dex oxoreduction were measured in CHOP cells after transfection with 1 µg wild-type human 11ßHSD2 or the mutated AME plasmids R186C, L250P.L251S, R337C, E356-1nt, and R374X (31, 32). Cells transfected with mutated AME plasmids were incubated with the substrate for 180 min.

To determine the amount of protein per well, cells from each dish were removed and homogenized with homogenizing buffer, and the amount of protein was determined colorimetrically by the Bradford method (33) using Bio-Rad protein dye and calibration against standards of -globulin. The amounts of product generated per dish and per min were standardized for the amount of protein of the corresponding dish.

11ßHSD2 activity in homogenates was determined by incubating 100 µg/ml CHOP cell homogenates at 37 C in a total volume of 500 µl assay buffer (0.25 M sucrose and 10 mM sodium phosphate, pH 7.4) containing 2 nM tritiated steroid and 500 µM cofactor (NAD or NADP for the dehydrogenase and NADH or NADPH for the reductase reaction). The reaction was terminated by the addition of 3 vol ethyl acetate. The inhibition of 11ßHSD2 reductase activity for DH-Dex by carbenoxolone (CBX) or glycyrrhetinic acid (GA) was assayed by incubating 50 µg transfected CHOP cell homogenates in 500 µl assay buffer at 37 C for 60 min with 2 nM [³H]DH-Dex in the presence of inhibitor concentrations between 10 nM and 10 µM. In all reactions, metabolism of substrate was always less than 25%.

For whole cell assays replicates were performed on separate plates, whereas assays on homogenates were conducted by homogenizing cells from one or more plates and performing the reaction in replicate tubes.

Extraction and quantitation of steroids
Ethyl acetate was used to extract steroids from culture medium or assay buffer. The ethyl acetate was then transferred into a fresh tube and evaporated under air. The dried steroids were resuspended in 100 µl ethanol containing unlabeled standards for visualization of steroid migration under UV light. Separation of substrates and metabolites was performed by TLC on plastic-backed silica gel plates (Merck, Darmstadt, Germany). Redissolved steroids (10 µl) were applied to the TLC plate, allowed to dry completely, and placed in an equilibrated TLC tank with chloroform-ethanol (92:8) as solvent. Areas corresponding to steroids were identified under UV light, cut out, transferred to vials containing liquid scintillant, and counted in a ß-counter.

Western blot analysis
Total proteins (100 µg) from CHOP cells transfected with rat 11ßHSD2 were separated by 5–15% gradient SDS-PAGE under reducing conditions and transferred to nitrocellulose filters (Schleicher and Schuell, Dassel, Germany) for 2 h on ice. After blocking nonspecific sites on nitrocellulose, the blot was incubated overnight at 4 C with 1 µg/ml immunopurified RAH23 polyclonal antibody (34) diluted with 0.5% skim milk powder in PBS, pH 7.4, and 0.1% Tween-20. The blots were then incubated at room temperature for 60 min with the second antirabbit IgG labeled with peroxidase at a dilution of 1:1000 and washed in PBS-0.1% Tween-20 four times for 15 min each time before revelation using a chemiluminescence kit (DuPont-New England Nuclear, North Ryde, Australia) according to the manufacturer’s instructions. For proteins from cells transfected with rat 11ßHSD1, rabbit anti-HSD1 polyclonal antibody 56–126 (a gift from Dr. Carl Monder and Dr. Brendan Waddell) was used at a dilution of 1:1000 (35).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
We first examined 11ßHSD dehydrogenase and reductase activity for F/E, B/A, or Dex/DH-Dex in intact CHOP cells transfected with either the rat 11ßHSD1 or rat 11ßHSD2 clones (Fig. 1a). When dehydrogenase activity was examined in the presence of Dex in intact mammalian cells the cloned 11ßHSD2 showed marked conversion of Dex to DH-Dex. Dehydrogenase activity of 11ßHSD1 for Dex was not different from background. In intact cells transfected with rat 11ßHSD1, the equilibrium was on the reductase side for all substrates, whereas for 11ßHSD2 with F/E and B/A as substrates it was on the oxidative side exclusively, but with DH-Dex/Dex it was on the reductive side. Western blot analysis showed the presence of a similar amount of immunoreactive 11ßHSD2 protein in the cells transfected with 11ßHSD2 (Fig. 1b), so it was possible to compare the relative activities of the 11ßHSD2 enzyme for the six different substrates. The detection of equivalent amounts of immunoreactive 11ßHSD1 protein in the cells transfected with 11ßHSD1 also allowed a direct comparison of enzymatic activity (Fig. 1b). Assuming expression of equal levels of both proteins, the dehydrogenase activity of 11ßHSD2 was consistently higher than that of 11ßHSD1, and the relative reduction of DH-Dex with 11ßHSD2 was almost 90% higher than that with 11ßHSD1.

View larger version (24K): [in this window] [in a new window]   Figure 1. a, Reductase and dehydrogenase activity of rat 11ßHSD2 (solid bars) or rat 11ßHSD1 (hatched bars) in intact CHOP cells. Values are the mean ± SD (n = 4). b, Western blot analysis of homogenates from CHOP cells transfected with rat 11ßHSD1 or rat 11ßHSD2 for the analysis of reductase and dehydrogenase activity. Samples are from the reaction using as substrate B (lane 1), F (lane 2), Dex (lane 3), A (lane 4), E (lane 5), and DH-Dex (lane 6). 11ßHSD protein sizes for both blots are shown on the left.

View larger version (17K): [in this window] [in a new window]   Figure 2. Double reciprocal plot of a) the concentration-dependent oxidation of dexamethasone by rat 11ßHSD2 (solid squares) and b) reduction of 11-dehydrodexamethasone by rat 11ßHSD2 (solid squares) or rat 11ßHSD1 (open diamonds) in intact transfected CHOP cells. The abscissa is expressed as molar concentrations-1.

View larger version (20K): [in this window] [in a new window]   Figure 3. Reductase and dehydrogenase activities of rat 11ßHSD2 (solid bars) or human 11ßHSD2 (hatched bars) homogenates. Homogenates (50 µg) were incubated in 500 µl buffer in the presence of 500 µM NAD or NADH for 30 min at 37 C. Values are the mean ± SD (n = 4).

View larger version (16K): [in this window] [in a new window]   Figure 4. Inhibition by GA or CBX of the conversion of DH-Dex to Dex by homogenates of rat 11ßHSD2-transfected CHOP cells. Conversion without added competitor is taken as 100%. Inhibitor concentrations ranged from 10-8-10-5 M. Homogenates (50 µg) were incubated in 500 µl buffer in the presence of 500 µM NADH for 60 min at 37 C. Values are the mean ± SD (n = 4). Filled circles, GA; open squares, CBX.

View larger version (15K): [in this window] [in a new window]   Figure 5. Metabolism of F (solid bars) or DH-Dex (hatched bars) by CHOP cells transfected with plasmids expressing wild-type and mutant enzymes after 3 h. Cells were transfected with 1 µg 11ßHSD2, R186C, L250P, L251S, R337C, E356-1nt, and R374X plasmids. Values are the mean ± SD (n = 3).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

In intact cells and in cell homogenates expressing either the rat or the human 11ßHSD2, the relative potency of the dehydrogenase reaction with various substrates was B > F > Dex. We recently reported Dex dehydrogenation by the cloned human 11ßHSD2 (27), a finding consistent with that of Brown et al. (36); Dex is not metabolized by human 11ßHSD1 (27). There was no reduction of A or E by either the rat or human 11ßHSD2 clones in either intact cells or homogenates using NADH or NADPH as cofactors, and this observation is consistent with previous findings (6, 10, 11, 12, 13). DH-Dex was, however, readily converted to Dex, and a consideration of kinetic parameters shows that the equilibrium for this reaction was far on the side of the 11-hydroxy metabolite. The 11ßHSD2-mediated DH-Dex reduction was exclusively NADH dependent, with no NADPH-dependent reductase activity detectable.

Probable explanations for the ability of 11ßHSD2 to reduce DH-Dex, but not E or A, could be that either the reduction of the 9-halogenated compound DH-Dex is catalyzed by a site of the 11ßHSD2 enzyme distinct from that driving the dehydrogenase reaction, or alternatively, that the presence of the halogen group at the 9 position propels the reaction in the reductase direction only. Although the existence of a distinct catalytic site cannot be ruled out, it seems unlikely that this is the case for 11ßHSD2. First, most of the enzymes that physiologically operate as reductases preferably use NADPH as cofactor, whereas NAD is used primarily for the generation of NADH (37). We were unable to show any reductase activity using 11ßHSD2 homogenates when NADPH was used as a cofactor with DH-Dex, E, or A. Secondly, the similar pattern of relative activity of 11ßHSD2 mutants derived from patients with AME for F and DH-Dex suggests that the point mutations affected the oxidative and reductive enzymatic activities similarly. Although this observation does not rule out distinct catalytic sites, if DH-Dex reduction by mutant enzymes would have been observed when no F oxidation was measured, it would have supported this hypothesis.

The possibility that 9-halogenated steroid molecules are more readily reduced than oxidized at the C-11 position deserves consideration. 9-Halogenated 11-hydroxysteroids seem to be metabolized by 11ßHSD enzymes in a different manner than the nonhalogenated compounds. In a cell-free system, 9-fluorocortisol (9FF), F, and aldosterone have the same affinity for the mineralocorticoid receptor. In vivo, however, 9FF is 2- to 400-fold more potent than F as a mineralocorticoid (28). The explanation for the 9FF mineralocorticoid potency is thought to be an impaired renal 11ß-oxidation of 9-halogenated 11-hydroxysteroids (28). Diedrich et al. addressed this issue by studying the metabolism of 9-fluorinated steroids in human kidney slices and microsomes (29). They found a distinct preference for the reductase reaction for both Dex/DH-Dex and 9FF/9-flurocortisone. However, the kinetics for Dex dehydrogenation and DH-Dex oxoreduction using human kidney preparations showed a high affinity for both reactions.

Using NADH as a cofactor, Diedrich et al. reported reduction of E to F by human kidney microsomes (29). These results are in contrast with the present observations of the cloned 11ßHSD type I and II enzymes expressed in mammalian cells. The most likely explanation for this discrepancy is the existence of another, yet uncharacterized isoform of the 11ßHSD family. This isoform would convert DH-Dex to Dex more readily than the reverse reaction and would also convert E to F, using NADH as a cofactor. An alternative explanation might be that tissue-specific factors complex with the enzyme and facilitate bidirectional activity in mineralocorticoid target cells under some conditions. Further studies using stably transfected cell lines (38) from mineralocorticoid target cells are needed to address this issue.

When comparing rat 11ßHSD1 and 11ßHSD2 activities in intact transfected cells at equilibrium, 11ßHSD1 invariably favored the oxoreductase reaction with all substrates. In previous studies in the cell-free system oxoreductase activity was undetectable in preparations of purified hepatic 11ßHSD1 (39), or rate constants were equivalent to the dehydrogenase activity, but increased substantially with removal of NADP using the recombinant enzyme (7). There was no detectable Dex oxidation by 11ßHSD1, consistent with previous observations (27), and dehydrogenation of B or F appeared more potent with 11ßHSD2 than with 11ßHSD1. Our studies using competitors would appear to support this observation. As it seems that a permeability barrier slows the entry of GA into intact cells (40), we used homogenates to assess inhibition of 11ßHSD2 oxoreductase activity by GA or CBX. We found that the concentration of GA (80 nM) needed to inhibit half the oxoreductase activity in cell homogenates was comparable with the GA concentration required to inhibit half the cortisol metabolism of 11ßHSD2 (6), but was higher than previously found (10–20 nM) for 11ßHSD1 (7). These observations suggest that GA is a more potent inhibitor of 11ßHSD1 than 11ßHSD2.

Our results in the cell-free system as well as in intact cells show that the oxidoreductase activity of 11ßHSD2 with 9-fluorinated glucocorticoids is greater than that of the dehydrogenase. Thus, the equilibrium of the reaction favors formation of the active synthetic glucocorticoid. A similar conclusion was reach by others using preparations of kidney slices (29). This observation would appear to explain the mechanism by which synthetic glucocorticoids are efficacious when administered to enhance fetal lung maturation, as the human placenta expresses large amounts of 11ßHSD2 protein (16). These data indicate that both the cloned human and rat 11ßHSD2 reduce DH-Dex and do this more readily than they oxidase Dex. Thus, 11ßHSD2 seems also to be a bidirectional enzyme, although no reduction of the physiological compounds A and E is observed.

	Acknowledgments

 
The authors thank Drs. Carl Monder and B. J. Waddell for providing the anti-11ßHSD1 antibody.

	Footnotes

 
¹ This work was supported by a block grant from the National Health and Medical Research Council of Australia.

² Recipient of a Foreign Research Grant from the Swiss National Science Foundation.

Received November 25, 1996.

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