Differential estrogenic 17β-hydroxysteroid dehydrogenase activity and type 12 17β-hydroxysteroid dehydrogenase expression levels in preadipocytes and differentiated adipocytes

Estradiol (E2) is produced locally in adipose tissue and could play an important role in fat distribution and accumulation, especially in women. It is well recognized that aromatase is expressed in adipose tissue; however the identity of its estrogenic 17β-hydroxysteroid dehydrogenase (17β-HSD) partner is not identified. To gain a better knowledge about the enzyme responsible for the conversion of estrone into estradiol, we determined the activity and expression levels of known estrogenic 17β-HSDs, namely types 1, 7 and 12 17β-HSD in preadipocytes before and after differentiation into mature adipocytes using an adipogenic media. Estrogenic 17β-HSD activity was assessed using [¹⁴C]-labelled estrone, while mRNA expression levels of types 1, 7 and 12 17β-HSD were quantified using real-time PCR and protein expression levels of type 12 17β-HSD was determined using immunoblot analysis. The data indicate that there is a low conversion of E1 into E2 in preadipocytes; however this activity is increased 5-fold (p < 0.0001) in differentiated adipocytes. The increased estrogenic 17β-HSD activity is consistent with the increase in protein expression levels of 17β-HSD12.     

Intrinsic sterol- and phosphatidylcholine transfer activities of 17β-hydroxysteroid dehydrogenase type IV

Previous studies have shown that the 80 kDa 17β-hydroxysteroid dehydrogenase (17β-HSD) type IV comprises distinct domains, including an N-terminal region related to the short chain alcohol dehydrogenase multigene family and a C-terminal part related to the lipid transfer protein sterol carrier protein 2 (SCP2). In this study, we have investigated whether the SCP2-related part of the 80 kDa protein leads to an intrinsic sterol and phospholipid transfer activity, as shown earlier for the 60 kDa SCP2-related peroxisomal 3-ketoacyl CoA thiolase with intrinsic sterol and phospholipid transfer activity called sterol carrier protein x (SCPx). Our results indicate that a fraction rich in the 80 kDa form of 17β-HSD type IV exhibits high transfer activities for 7-dehydrocholesterol and phosphatidylcholine. In addition, a purified recombinant peptide derived from the SCP2-related domain of the 17β-HSD type IV has about 30% of the transfer activities for 7-dehydrocholesterol and phosphatidylcholine seen with purified recombinant human SCP2. We conclude that the 80 kDa type IV 17β-HSD represents a potentially multifunctional protein with intrinsic in vitro sterol and phospholipid transfer activity in addition to its enzymatic activity.     

Molecular characterization of mouse 17β-hydroxysteroid dehydrogenase IV

17β-hydroxysteroid dehydrogenases (17β-HSD) catalyze the conversion of estrogens and androgens at the C17 position. The 17β-HSD type I, II, III and IV share less than 25% amino acid similarity. The human and porcine 17β-HSD IV reveal a three-domain structure unknown among other dehydrogenases. The N-terminal domains resemble the short chain alcohol dehydrogenase family while the central parts are related to the C-terminal parts of enzymes involved in peroxisomal β-oxidation of fatty acids and the C-terminal domains are similar to sterol carrier protein 2. We describe the cloning of the mouse 17β-HSD IV cDNA and the expression of its mRNA. A probe derived from the human 17β-HSD IV was used to isolate a 2.5 kb mouse cDNA encoding for a protein of 735 amino acids showing 85 and 81% similarity with human and porcine 17β-HSD IV, respectively. The calculated molecular mass of the mouse enzyme amounts to 79,524 Da. The mRNA for 17β-HSD IV is a single species of about 3 kb, present in a multitude of tissues and expressed at high levels in liver and kidney, and at low levels in brain and spleen. The cloning and molecular characterization of murine, human and porcine 17β-HSD IV adds to the complexity of steroid synthesis and metabolism. The multitude of enzymes acting at C17 might be necessary for a precise control of hormone levels.     

Role of 17β-hydroxysteroid dehydrogenase type 1 in endocrine and intracrine estradiol biosynthesis

Enzymes with 17β-hydroxysteroid dehydrogenase (17β-HSD) activity catalyse reactions between the low-active female sex steroid, estrone, and the more potent estradiol, for example. 17β-HSD activity is essential for glandular (endocrine) sex hormone biosynthesis, but it is also present in several extra-gonadal tissues. Hence, 17β-HSD enzymes also take part in local (intracrine) estradiol production in the target tissues of estrogen action. Four distinct 17β-HSD isozymes have been characterized so far, and the data strongly suggests that different 17β-HSD isozymes have distinct roles in endocrine and intracrine metabolism of sex steroids. Current data suggest that 17β-HSD type 1 is the principal isoenzyme involved in glandular estradiol production both in humans and rodents. During ovarian follicular development and luteinization, rat 17β-HSD type 1 is regulated by gonadotropins, and the effects of gonadotropins are modulated by steroid hormones and paracrine growth factors. Human 17β-HSD type 1 favors the reduction reaction, thereby converting estrone to estradiol both in vitro and in cultured cells. Hence, the enzymatic properties of the enzyme are also in line with its suggested role in estradiol biosynthesis. Interestingly, 17β-HSD type 1 is also expressed in certain target tissues of estrogen action such as normal and malignant human breast and endometrium. Hence, 17β-HSD type 1 could be one of the factors leading to a relatively high tissue/plasma ratio of estradiol in breast cancer tissues of postmenopausal women. We conclude that 17β-HSD type 1 has a central role in regulating the circulating estradiol concentration as well as its local production in estrogen target cells.     

Expression of human 17β-hydroxysteroid dehydrogenase in mammalian cells

The insert of 1278 bp containing the entire coding region of cDNA encoding human 17β-hydroxysteroid dehydrogenase (17β-HSD) was inserted into a pHS1 vector and expressed in HeLA human cervical carcinoma cells and COS-1 monkey kidney tumor cells. Western blot analysis indicated that the expressed protein migrates at the same position as the purified enzyme and is recognized by the antibody raised against purified human placental 17β-HSD. The expressed enzyme efficiently catalyzes the interconversion of estrone and estradiol while dehydroepiandrosterone and 5-androstene-3β,17β-diol are interconverted at a lower rate. The present data suggest the existence of two 17β-HSDs.     

Parallel solid-phase synthesis of 3β-peptido-3α-hydroxy-5α-androstan-17-one derivatives for inhibition of type 3 17β-hydroxysteroid dehydrogenase

Type 3 17β-hydroxysteroid dehydrogenase (17β-HSD), a key steroidogenic enzyme, transforms 4-androstene-3,17-dione (Δ⁴-dione) into testosterone. In order to produce potential inhibitors, we performed solid-phase synthesis of model libraries of 3β-peptido-3α-hydroxy-5α-androstan-17-ones with 1, 2, or 3 levels of molecular diversity, obtaining good overall yields (23–58%) and a high average purity (86%, without any purification steps) using the Leznoff's acetal linker. The libraries were rapidly synthesized in a parallel format and the generated compounds were tested as inhibitors of type 3 17β-HSD. Potent inhibitors were identified from these model libraries, especially six members of the level 3 library having at least one phenyl group. One of them, the 3β-(N-heptanoyl- -phenylalanine- -leucine-aminomethyl)-3α-hydroxy-5α-androstan-17-one (42) inhibited the enzyme with an IC₅₀ value of 227 nM, which is twice as potent as the natural substrate Δ⁴-dione when used itself as an inhibitor. Using the proliferation of androgen-sensitive (AR⁺) Shionogi cells as model of androgenicity, the compound 42 induced only a slight proliferation at 1 μM (less than previously reported type 3 17β-HSD inhibitors) and, interestingly, no proliferation at 0.1 μM.     

Expression and regulation of aromatase and 17β-hydroxysteroid dehydrogenase type 4 in human THP 1 leukemia cells

Estradiol is active in proliferation and differentiation of sex-related tissues like ovary and breast. Glandular steroid metabolism was for a long time believed to dominate the estrogenic milieu around any cell of the organism. Recent reports verified the expression of estrogen receptors in “non-target” tissues as well as the extraglandular expression of steroid metabolizing enzymes. Extraglandular steroid metabolism proved to be important in the brain, skin and in stromal cells of hormone responsive tumors. Aromatase converts testosterone into estradiol and androstenedione into estrone, thereby activating estrogen precursors. The group of 17β-hydroxysteroid dehydrogenases catalyzes the oxidation and/or reduction of the forementioned compounds, e.g. estradiol/estrone, thereby either activating or inactivating estradiol. Aromatase is expressed and regulated in the human THP 1 myeloid leukemia cell line after vitamin D/GMCSF-propagated differentiation. Aromatase expression is stimulated by dexamethasone, phorbolesters and granulocyte/macrophage stimulating factor (GMCSF). Exons I.2 and I.4 are expressed in PMA-stimulated cells only, exon I.3 in both PMA- and dexamethasone-stimulated cells. Vitamin D-differentiated THP 1 cells produce a net excess of estradiol in culture supernatants, if testosterone is given as aromatase substrate. In contrast, the 17β-hydroxysteroid dehydrogenase type 4 (17β-HSD 4) is abundantly expressed in unstimulated THP 1 cells and is further stimulated by glucocorticoids (2-fold). The expression is unchanged after vitamin D/GMCSF-propagated differentiation. 17β-HSD 4 expression is not altered by phorbolester treatment in undifferentiated cells but is abolished after vitamin D-propagated differentiation along with downregulation of β-action. Protein kinase C activation therefore appears to dissociate the expression of aromatase and 17β-HSD 4 in this differentiation stage along the monocyte/phagocyte pathway of THP 1 myeloid cells. The expression of steroid metabolizing enzymes in myeloid cells is able to create a microenvironment which is uncoupled from dominating systemic estrogens. These findings may be relevant in the autocrine, paracrine or iuxtacrine cellular crosstalk of myeloid cells in their respective states of terminal differentiation, e.g. in bone metabolism and inflammation.     

The human 11β-hydroxysteroid dehydrogenase type II enzyme: Comparisons with other species and localization to the distal nephron

Effective glucocorticoid inactivation is currently thought to be an indispensable feature of mineralocorticoid target cells. The enzyme 11β-hydroxysteroid dehydrogenase (11β-HSD) inactivates glucocorticoids and prevents them from binding to the non-selective mineralocorticoid receptor. In the kidney it is the NAD dependent high affinity isoform (11β-HSD2) which is thought to endow specificity on the receptor. The recet cloning of the human, sheep and rabbit 11β-HSD2 enzymes permits a comparison of the enzyme from the three species. Human and rabbit enzymes are 87% identical and of similar length, while the human and sheep enzymes have only 75% identity. The last 12 residues in all three species were found to be highly divergent, but most of the ovine dishomology can be accounted for by the deletion of a single nucleotide toward the C-terminus of the protein resulting in a shift in reading frame generating a protein 27 residues longer than the human isoform. Numerous other deletions were also observed in this region of the sheep cDNA sequence. Furthermore, the rabbit cDNA also displayed a large degree of dishomology with the human sequence a short distance downstream from the termination codon. Conserved overlapping cytoplasmic translocation signals were observed in all three species, suggesting a topology whereby the enzyme is anchored into the endoplasmic reticulum by multiple hydrophobic regions in the N-terminus and the bulk of the 11β-HSD2 peptide is sited in the cytoplasm. A polyclonal antibody generated against the C-terminus of human 11β-HSD2 was used to localize the enzyme within the kidney. A high level of immunoreactivity was observed in distal tubules and collecting ducts, localizing the enzyme to the same part of the nephron as the mineralocorticoid receptor. Moderate levels of staining were also seen in vascular smooth muscle cells. These results support the notion that 11β-HSD2 is an autocrine protector of the mineralocorticoid receptor and that it plays an important role in cardiovascular homeostatic mechanisms.     

The molecular biology of androgenic 17β-hydroxysteroid dehydrogenases

The enzyme 17β-hydroxysteroid dehydrogenase (17β-HSD) catalyzes the 17β-oxidation/reduction of C₁₈- and C₁₉-steroids in a variety of tissues. Three human genes encoding isozymes of 17β-HSD, designated 17β-HSD types 1, 2 and 3 have been cloned. 17β-HSD type 1 (also referred to as estradiol 17β-dehydrogenase) catalyzes the conversion of estrone to estradiol, primarily in the ovary and placenta. The 17β-HSD type 2 is expressed to high levels in the liver, secretory endometrium and placenta. The type 2 isozyme catalyzes the oxidation of androgens and estrogens equally efficiently. Also, the enzyme possesses 20-HSD activity demonstrated by its ability to convert 20-dihydro-progesterone to progesterone. Testicular 17β-HSD type 3 catalyzes the conversion of androstenedione to testosterone, dehydroepiandrosterone to 5-androstenediol and estrone to estradiol. The 17β-HSD3 gene is mutated in male pseudohermaphrodites with the genetic disease 17β-HSD deficiency.     

Molecular basis of human 3β-hydroxysteroid dehydrogenase deficiency

The enzyme 3β-hydroxysteroid dehydrogenase (3β-HSD) catalyses an essential step in the biosynthesis of all classes of steroid hormones. Classical 3β-HSD deficiency is responsible for CAHII, a severe form of congenital adrenal hyperplasia (CAH) that impairs steroidogenesis in both the adrenals and gonads. Newborns affected by 3β-HSD deficiency exhibit signs and symptoms of adrenal insufficiency of varying degrees associated with pseudohermaphroditism in males, whereas females exhibit normal sexual differentiation or mild virilization. Elevated ratios of 5-ene-to 4-ene-steroids appear as the best biological parameter for the diagnosis of 3β-HSD deficiency. The nonclassical form has been suggested to be related to an allelic variant of the classical form of 3β-HSD as described for steroid 21-hydroxylase deficiency. To elucidate the molecular basis of the classical form of 3β-HSD deficiency, we have analysed the structure of the highly homologous type I and II 3β-HSD genes in 12 male pseudohermaphrodite 3β-HSD deficient patients as well as in four female patients. The 14 different point mutations characterized were all detected in the type II 3β-HSD gene, which is the gene predominantly expressed in the adrenals and gonads, while no mutation was detected in the type I 3β-HSD gene predominantly expressed in the placenta and peripheral tissues. The finding of a normal type I 3β-HSD gene provides the explanation for the intact peripheral intracrine steroidogenesis in these patients and increased androgen manifestations at puberty. The influence of the detected mutations on enzymatic activity was assessed by in vitro expression analysis of mutant enzymes generated by site-directed mutagenesis in COS-1 cells. The mutant type II 3β-HSD enzymes carrying mutations detected in patients affected by the salt-losing form exhibit no detectable activity in intact tranfected cells, whereas those with mutations found in nonsalt-loser index cases have some residual activity ranging from 1–10% compared to the wild-type enzyme. Although in general, our findings provide a molecular explanation for the enzymatic heterogeneity ranging from the severe salt-losing form to the clinically inapparent salt-wasting form of the disease, we have observed that the mutant L108W or P186L enzymes found in a compound heterozygote male presenting the salt-wasting form of the disease, has some residual activity (1%) similar to that observed for the mutant N100S enzyme detected in an homozygous male patient suffering from a nonsalt-losing form of this disorder. Unlike the classical 3β-HSD deficiency, our study in women presenting nonclassical 3β-HSD deficiency strongly suggests that this disorder is not due to a mutant type II 3β-HSD.     

Dual subcellular localization of the 3β-hydroxysteroid dehydrogenase isomerase: Characterization of the mitochondrial enzyme in the bovine adrenal cortex

The enzyme 3β-hydroxysteroid dehydrogenase isomerase (3β-HSD/I) in an essential step in the biosynthesis of steroid such as progesterone, mineralo- and gluco-corticoids, estrogens and androgens in steroidogenic tissues. It is considered to be mainly localized in microsomes; however, 3β-HSD/I activity has also been described to be associated with mitochondrial preparations. In this study, we examined the subcellular distribution of 3β-HSD/I in bovine adrenocortical tissue and we characterized the catalytic properties of the enzyme present in the various cell compartments. About 30% of the total 3β-HSD/I activity was found to remain tightly associated with the purified mitochondrial pellet. The 3β-HSD/I and 3-ketoreductase activities were found in microsomes as well as in mitochondria. The 3β-HSD/I associated with the mitochondrial fraction did not required addition of exogenous NAD⁺. When the pyridine nucleotide was reduced ollowing addition of substrate of the tricarboxyllic acids cycle, the mitochondrial 3β-HSD/I activity decreased, suggesting that the enzyme utilizes NAD⁺ available from the matrix space. By contrast, the microsomal enzyme was inactive in the absence of exogenous NAD⁺. Submitochondrial fraction disclosed that 3β-HSD/I was associated (i) with the inner membrane and (ii) with a particulate fraction sedimenting in a density gradient between inner and outer membranes. This fraction was characterized as contact sites between the two membranes. 3β-HSD/I specific activity was much higher in this fraction than in the inner mitochondrial membrane. Altogether, these observations suggest that these mitochondrial intermembrane contact sites may represent a spacial organization of functional significance, facilitating both the access of cholesterol to the inner membrane where cytochrome P-450_scc is located and the rapid transformation of its product, pregnenolone, to progesterone, through 3β-HSD/I activity.     

3β-hydroxysteroid dehydrogenase activity in tissues of the human fetus determined with 5α-androstane-3β,17β-diol and dehydroepiandrosterone as substrates

3β-Hydroxysteroid dehydrogenase (3β-HSD)/Δ^5→4-isomerase activity in steroidogenic tissues is required for the synthesis of biologically active steroids. Previously, by use of dehydroepiandrosterone (3β-hydroxy-5-androsten-17-one, DHEA) as substrate, it was established that in addition to steroidogenic tissues 3β-HSD/Δ^5→4-isomerase activity also is expressed in extraglandular tissues of the human fetus. In the present study, we attempted to determine whether the C-5,C-6-double bond of DHEA serves to influence 3β-HSD activity. For this purpose, we compared the efficiencies of a 3β-hydroxy-5-ene steroid (DHEA) and a 3β-hydroxy-5α-reduced steroid (5α-androstane-3β,17β-diol, 5α-A-diol) as substrates for the enzyme. The apparent Michaelis constant (K_m) for 5α-A-diol in midtrimester placenta, fetal liver, and fetal skin tissues was at least one order of magnitude higher than that for DHEA, viz the apparent K_m of placental 3β-HSD for 5α-A-diol was in the range of 18 to 40 μmol/l (n = 3) vs 0.45 to 4 μmol/l for DHEA (n = 3); for the liver enzyme, 17 μmol/l for 5α-A-diol and 0.60 μmol/l for DHEA, and for the skin enzyme 14 and 0.18 μmol/l, respectively. Moreover, in 13 human fetal tissues evaluated the maximal velocities obtained with 5α-A-diol as substrate were higher than those obtained with DHEA. A similar finding in regard to K_ms and rates of product formation was obtained by use of purified placental 3β-HSD with DHEA, pregnenolone, and 3β-hydroxy-5α-androstan-17-one (epiandrosterone) as substrates: the K_m of 3β-HSD for DHEA was 2.8 μmol/l, for pregnenolone 1.9 μmol/l, and for epiandrosterone 25 μmol/l. The specific activity of the purified enzyme with pregnenolone as substrate was 27 nmol/mg protein·min and, with epiandrosterone, 127 nmol/mg protein·min. With placental homogenate as the source of 3β-HSD, DHEA at a constant level of 5 μmol/l behaved as a competitive inhibitor when the radiolabeled substrate, [³H]5α-A-diol, was present in concentrations of 20 to 60 μmol/l, but a lower substrate concentrations the inhibition was of the mixed type; similar results were obtained with [³H]DHEA as the substrate at variable concentrations in the presence of a fixed concentration of 5α-A-diol (40 μmol/l). These findings are indicative that both steroids bind to a common site on the enzyme, however, the binding affinity for these steroids appear to differ markedly as suggested by the respective K_ms. Studies of inactivation of purified placental 3β-HSD/Δ^5→4-isomerase by an irreversible inhibitor, viz 5,10-secoestr-4-yne-3,10,17-trione, were suggestive that the placental protein adopts different conformations depending on whether the steroidal substrate has a 5α-configuration, e.g. epiandrosterone, or a C-5,C-6-double bond e.g. DHEA or pregnenolone. The lower rates of product formation obtained with placenta and fetal tissues by use of 3β-hydroxy-5-ene steroids as substrates when compared with those obtained with 3β-hydroxy-5α-reduced steroids may be explained by a combination of factors, including: (i) inhibition of 3β-HSD activity by end products of metabolism of 3β-hydroxy-5-ene steroids, e.g. 4-androstene-3,17-dione formed with DHEA as substrate; (ii) higher binding affinity of the enzyme for 3β-hydroxy-5-ene steroids—and possibly for their 3-oxo-5-ene metabolites; (iii) lack of a requirement for the isomerization step with 5α-reduced steroids as substrates, and (iv) the possible presence in fetal tissues of an enzyme with 3β-HSD activity only (i.e. no Δ^5→4-isomerase).     

The occurrence and subcellular localization of 3 -hydroxysteroid dehydrogenase in adult rat brain

The subcellular localization of 3α-hydroxysteroid dehydrogenase, the dependency of the rate of reaction on time, concentration of protein, cofactor requirements and the substrate stereospecificity were investigated in the adult rat brain. The $\text{in vitro}$ conversion of 3-keto-5β-cholanoic-24-¹⁴C acid to lithocholic acid was shown to occur in the cytosol without added cofactors. Incubation of ¹⁴C labeled 3α,7α-dihydroxy-5β-cholanoic and 3α,12α-dihydroxy-5β-cholanoic acids with adult rat brain cell-free preparations resulted in the production of less polar metabolites identified as 3-keto-7α-hydroxy-5β-cholanoic and 3-keto-12α-hydroxy-5β-cholanoic acids by TLC, GLC combined with a radioactive monitoring detection system and by cocrystallization to constant specific activity.     

Immunochemical distribution and immunohistochemical localization of 20β-hydroxysteroid dehydrogenase in neonatal pig tissues

Immunochemical distribution of 20β-hydroxysteroid dehydrogenase (HSD) in neonatal pig tissues was investigated by Western blot analysis of the proteins reacting with anti-20β-HSD antibody. 20β-HSD was present in all organs investigated: brain, lung, thymus, submandibular gland, heart, liver, kidney, spleen, adrenal gland, testis, epididymis, prostate, vas deferens and seminal vesicle. In particular, high concentrations of 20β-HSD were detected in the testis, followed by the kidney and liver, by the [¹²⁵I]-protein A binding method. Immunohistochemical localization of the enzyme was achieved in paraffin sections of the testis, kidney, liver, epididymis, and vas deferens by the streptoavidin-biotin complex method. In the testis, very strong immunostaining was found only in interstitial Leydig cells, whereas the cells in seminiferous tubules, such as Sertoli cells and spermatogenic cells, were entirely negative. In the kidney, strong immunostaining was detected in epithelial cells of Henle's loop. The immunoreactive proteins were also localized in the hepatic lobules of the liver, tall columnar cells of the ductus epididymidis of the epididymis, and mucosal epithelium cells and muscularis of the vas deferens. These observations indicate that tissue distribution of 20β-HSD is similar to that of carbonyl reductase in the human and rat. However, the specific and abundant expression of 20β-HSD in testicular Leydig cells of the neonatal pig, which are concerned with the synthesis of androgens, suggests that 20β-HSD has a very important physiological role in testicular function during the neonatal stage.     

Structures important in mammalian 11β- and 17β-hydroxysteroid dehydrogenases

We have used the X-ray crystallographic structures of rat and human dihydropteridine reductase and Streptomyces hydrogenans 20β-hydroxysteroid dehydrogenase to model parts of the 3-dimensional structure of human 11β- and 17β-hydroxysteroid dehydrogenases. We use this information along with previous results from studies of Drosophila alcohol dehydrogenase mutants to analyze the structures in binding sites for NAD(H) and NADP(H) in 11β-hydroxysteroid dehydrogenase-types 1 and 2. We also examine the structure of an -helix at catalytic site of 17β-hydroxysteroid dehydrogenase-types 1, 2, 3, and 4. This -helix contains a highly conserved tyrosine and lysine. Adjacent to the carboxyl side of this lysine is a site proposed to be important in subunit association. We find that 11β- and 17β-hydroxysteroid dehydrogenases-type 1 have the same residues at the “anchor site” and conserve other stabilizing features, despite only 20% sequence identity between their entire sequences. Similar conservation of stabilizing structures is found in the 11β- and 17β-hydroxysteroid dehydrogenases-type 2. We suggest that interactions of the dimerization surface of -helix F with proteins or membranes may be important in regulating activity of hydroxysteroid dehydrogenases.     

Human 17β-hydroxysteroid dehydrogenase: overproduction using a baculovirus expression system and characterization

Estrogenic 17β-hydroxysteroid dehydrogenase (17β-HSD) plays a pivotal role in the synthesis of estrogens. We overproduced human placental estrogenic 17β-HSD using a baculovirus expression system for the study of the enzyme mechanism. A cDNA encoding the entire open reading frame of human 17β-HSD was inserted into the genome of Autographa californica nuclear polyhedrosis virus and expressed in Spodoptera frugiperda (Sf9) insect cells. Metabolic labeling and Western blot analysis using polyclonal antibodies raised against native human 17β-HSD indicated that a molecule with an apparent mass of 35 kDa was maximally expressed 60 h after infection. At that time interval, intracellular 17β-HSD activity reached 0.26 U/mg of protein in crude homogenate, about 70 times the level measured in human placenta. Purification of recombinant 17β-HSD was achieved by a single affinity fast liquid protein chromatography step yielding 24 mg of purified 17β-HSD protein per liter of suspension culture, with a specific activity of about 8 μmol/min/mg of protein for conversion of estradiol into estrone, at pH 9.2. In addition, the recombinant protein purified from infected Sf9 cells was assembled as a dimer with molecular mass and specific activity identical to those of the enzyme purified directly from placenta. The present data show that the baculovirus expression system can provide active 17β-HSD that is functionally identical to its natural counterpart and easy to purify in quantities suitable for its physico-chemical studies.     

Unusual evolution of 11β- and 17β-hydroxysteroid and retinol dehydrogenases

11β-hydroxysteroid dehydrogenases regulate glucocorticoid concentrations and 17β-hydroxysteroid dehydrogenases regulate estrogen and androgen concentrations in mammals. Phylogenetic analysis of the sequences from two 11β-hydroxysteroid dehydrogenases and four mammalian 17β-hydroxysteroid dehydrogenases indicates unusual evolution in these enzymes. Type 1 11β- and 17β-hydroxysteroid dehydrogenases are on the same branch; Type 2 enzymes cluster on another branch with β-hydroxybutyrate dehydrogenase, 11-cis retinol dehydrogenase and retinol dehydrogenase; Type 3 17β-hydroxysteroid dehydrogenase is on a third branch; while the pig dehydrogenase clusters with a yeast multifunctional enzyme on a fourth branch. Pig 17β-hydroxysteroid dehydrogenase appears to have evolved independently from the other three 17β-hydroxysteroid dehydrogenase dehydrogenases; in which case, the evolution of 17β-hydroxysteroid dehydrogenase activity is an example of functional convergence. The phylogeny also suggests that independent evolution of specificity toward C11 substituents on glucocorticoids and C17 substituents on androgens and estrogens has occurred in Types 1 and 2 11β- and 17β-hydroxysteroid dehydrogenases.     

Distribution of 17β-hydroxysteroid dehydrogenase gene expression and activity in rat and human tissues

The interconversion of estrone (E₁) and 17β-estradiol (E₂), androstenedione (4-ene-dione) and testosterone (T), as well as dehydroepiandrosterone and androst-5-ene-3β,17β-diol is catalyzed by 17β-hydroxysteroid dehydrogenase (17β-HSD). The enzyme 17β-HSD thus plays an essential role in the formation of all active androgens and estrogens in gonadal as well as extragonadal tissues. The present study investigates the tissue distribution of 17β-HSD activity in the male and female rat as well as in some human tissues and the distribution of 17β-HSD mRNA in some human tissues. Enzymatic activity was measured using ¹⁴C-labeled E₁, E₂, 4-ene-dione and T as substrates. Such enzymatic activity was demonstrated in all 17 rat tissues examined for both androgenic and estrogenic substrates. While the liver had the highestlevel of 17β-HSD activity, low but significant levels of E₂ as well as T formation were found in rat brain, heart, pancreas and thymus. The oxidative pathway (E₂→E₁, T→4-ene-dione) was favored over the reverse reaction in almost all rat tissues while in the human, almost equal rates were found in most of the 15 tissues examined. The widespread distribution of 17β-HSD in rat and human tissues clearly indicates the importance of this enzyme in peripheral sex steroid formation or intracrinology.     

Heterogeneity of 11β-hydroxysteroid dehydrogenase in rat tissues

Using specific antisera to purified rat liver 11β-hydroxysteroid dehydrogenase (11-HSD), we showed that the antigen is widely distributed in rat organs. Enzyme activity and immunoreactivity generally corresponded. Highest by both criteria were liver, testis, kidney and lung. In some tissues (epididymis, pancreas and duodenum) activity was found, but antigen corresponding to 11-HSD at a M_w of 34 kDa was absent. It is suggested that these tissues have alternate enzyme forms. The 11-HSD of brain and liver were compared. Brain enzyme may control selective binding of aldosterone to Type I receptors in the hippocampus and other regions. Rat brain 11-HSD resembled that of liver or kidney in most characteristics. It differed in (a) its steroid specificity: cortisol was a good substrate for liver 11-HSD, and a poor substrate for brain enzyme; (b) stability of 11-oxoreductase (11-OR) component. Brain 11-OR was not readily inactivated; 11-OR from other tissues lost activity rapidly and spontaneously. The variations in properties of 11-HSD in specific tissues may reflect aspects of its various specific functions.     

Selective inhibition of 17β-hydroxysteroid dehydrogenase type 1 (17βHSD1) reduces estrogen responsive cell growth of T47-D breast cancer cells

The most potent estrogen estradiol (E2) plays a pivotal role in the initiation and progression of estrogen dependent diseases. 17β-Hydroxysteroid dehydrogenase type 1 (17βHSD1) catalyses the NADPH-dependent E2-formation from estrone (E1). It is often overexpressed in breast cancer and endometriosis. For this reason, inhibition of 17βHSD1 is a promising strategy for the treatment of these diseases. In the present paper, we investigate the estrogen responsive cell growth of T47-D breast cancer cells, the intracellular inhibitory activity of non-steroidal 17βHSD1-inhibitors and their effects on estrogen dependent cell growth in vitro. At equal concentrations the estrogens E1 and E2 induced the same extent of growth stimulation indicating fast intracellular conversion of E1 into E2. Application of inhibitors selectively prevented stimulation of proliferation evoked by E1-treatment whereas E2-mediated stimulation was not affected. Furthermore, intracellular E2-formation from E1 was significantly inhibited with IC₅₀-values in the nanomolar range. In conclusion, our findings strongly support suitability of non-steroidal 17βHSD1-inhibitors for the treatment of estrogen dependent diseases.