Separate induction of the two isozymes of cytochrome P-45011β in rat adrenal zona glomerulosa cells

In the rat adrenal cortex, two isozymes of cytochrome P-450_11β (CYP11B1 and CYP11B2) have been identified. They are encoded by two different genes with a homology much higher in their coding than in their 5′-flanking regions. CYP11B1 is found in all the zones of the gland and catalyzes a single hydroxylation of deoxycorticosterone (DOC) in the 11β- or the 18-position. CYP11B2 is produced exclusively in the zona glomerulosa and catalyzes all three reactions involved in the conversion of DOC to aldosterone. In vivo and in vitro, the expression of the genes encoding CYP11B1 and CYP11B2 is regulated by two separate control systems which appear to operate both independently and interdependently. In vivo, zona glomerulosa expression of CYP11B1 was enhanced by ACTH treatment or potassium depletion and was lowered by potassium repletion. CYP11B2 expression disappeared upon potassium depletion or ACTH treatment, but reappeared during potassium repletion. In vitro, only CYP11B1 activity was detectable and responsive to ACTH treatment in zona glomerulosa cells cultured at a potassium concentration of 6.4 mmol/1. Aldosterone biosynthetic activity and mRNA encoding CYP11B2 could be detected only after at least 1 day of exposure to a high extracellular potassium concentration ( 12 mmol/1).     

Molecular biology of rat steroid 11 beta-hydroxylase [P450(11 beta)] and aldosterone synthase [P450(11 beta, aldo)].

The molecular features of rat steroid 11ß-hydroxylase [P450(11ß)] and aldosterone synthase [P450(11ß, aldo)] are discussed. P450(11ß) is biosynthesized as a precursor form composed of 499 amino acids, having a 24-amino acid extension peptide. Two species of P450(11ß, aldo) were identified; a precursor form of P450(11ß, aldo)-1 is 510 amino acids long and has a 34-amino acid extension peptide, while that of P450(11ß, aldo)-2 is 500 amino acids long and has a 24-amino acid extension peptide. The 286th amino acid of P450(11ß, aldo)-1 is Glu, while that of P450(11ß, aldo)-2 is Lys. The cDNA-expression studies showed that P450(11ß, aldo)-1 had the aldosterone producing activity whereas P450(11ß, aldo)-2 had no activity, suggesting that Glu286 of P450(11ß, aldo) plays an important role in the catalysis. The amino acid sequence of a region in P450(11ß) from Leu337 through Pro352 is highly conserved among the steroidogenic P450s. Functional expression studies on the cDNAs for two P450(11ß)s showed that P450(11ß) catalyzes the 11ß-, 18- and 19-hydroxylations of 11-deoxycorticosterone, but not the aldosterone synthesis. P450(11ß, aldo), on the other hand, catalyzes the conversion of 11-deoxycorticosterone to corticosterone, 18-hydroxycorticosterone and aldosterone. The two P450(11ß)s were also shown to catalyze the conversion of 11-deoxycortisol to cortisol, 18-hydroxycortisol and cortisone.     

Functional expression of cDNAs for bovine 11 beta-hydroxylase-aldosterone synthases, P450(11 beta)-2 and -3 and their chimeras.

Two molecular species of bovine P450(11β), P450(11β)-2 and P450(11β)-3 have been identified, in which the amino acid differences were found at the 6th, 36th and 82nd positions from the NH₂-termini of the mature proteins. They catalyzed the 11β-, 18- and 19-hydroxylation and aldosterone formation from 11-deoxycorticosterone, and the rate of production of 18-hydroxycorticosterone and aldosterone by P450(11β)-3 was greater than that by P450(11β)-2 [Morohashi et al., J. Biochem. 107 (1990) 635–640].

In this study, chimeric clones were constructed whose 6th, 36th and 82nd amino acid residues were exchanged with each other. Two original clones and six chimeric clones were expressed in COS-7 cells, and their steroidogenic activities studied. The ratio of aldosterone or 18-hydroxycorticosterone production to corticosterone production by one clone was compared with that of the other. The ratios for the four clones having Gly36 [P450(11β)-3 type] were 0.08–0.22, whereas those for the clones having Ser36 [P450(11β)-2 type] were 0.03–0.05, suggesting that the Gly36 structure is important for aldosterone production.     

Calf adrenocortical fasciculata cells secrete aldosterone when placed in primary culture

Aldosterone production occurs in the outer area of the adrenal cortex, the zona glomerulosa. The glucocortocoids cortisol and corticosterone, depending upon the species, are synthesized in the inner cortex, the zona fasciculata. Calf zona glomerulosa cells rapidly lose the ability to synthesize aldosterone when placed in primary culture unless they are incubated in the presence of the antioxidants butylated hydroxyanisol and selenous acid, the radioprotectant DMSO, and the cytochrome P-450 inhibitor metyrapone. In the presence of these additives, calf zona fasciculata cells in primary culture synthesize aldosterone at rates which can approach those from cells isolated from the zona glomerulosa. Calf zona glomerulosa and fasciculata cells both responded well to ACTH and angiotensin II, but the zona fasciculata cells respond very poorly compared to glomerulosa cells to increased potassium in the media. Rat zona fasciculata cells in primary culture under similar conditions did not synthesize aldesterone, suggesting that the regulation of the expression of the enzymes responsible for the biosynthesis of aldosterone in the two species is different. Two distinct cytochrome P-450 cDNAs which hydroxylate deoxycorticosterone at the 11β position have been described in the rat, human and mouse. Both cytochrome P-450 cDNAs have been cloned and expressed in non-steroidogenic cells, but only one is expressed in the zona glomerulosa and only this glomerulosa cytochrome P450 can further hydroxylate deoxycorticosterone to generate aldosterone. Two bovine adrenal cDNAs have been described with 11β-hydroxylase activity and their expression products in transiently transfected COS cells can convert deoxycorticosterone into aldosterone. Both enzymes are expressed in all zones of the adrenal cortex. Zonal regulation of aldosterone synthesis in the bovine adrenal gland may be due to an 11β-hydroxylase with aldosterone synthesizing capacity which has not yet been isolated. Alternatively, a single enzyme might be responsible for the several hydroxylations in the pathway between deoxycorticosterone and aldosterone and zonal synthesis might be controlled by unknown factors regulating the expression of C-18 hydroxylation. The incubation of zona fasciculata with antioxidants and metyrapone results in atypical expression of this activity by an unclear mechanism.     

Adrenal P-450scc modulates activity of P-45011 beta in liposomal and mitochondrial membranes. Implication of P-450scc in zone specificity of aldosterone biosynthesis in bovine adrenal.

Bovine adrenal P-45011 beta catalyzes the 11 beta- and 18-hydroxylation of corticosteroids as well as aldosterone synthesis. These activities of P-45011 beta were found to be modulated by another mitochondrial cytochrome P-450 species, P-450scc. The presence together of P-45011 beta and P-450scc in liposomal membranes was found to remarkably stimulate the 11 beta-hydroxylase activity of P-45011 beta and also stimulate the cholesterol desmolase activity of P-450scc. The stimulative effect of P-450scc on 11 beta-hydroxylase activity diminished by the addition of protein-free liposomes to proteoliposomes containing P-45011 beta and P-450scc, thus showing P-450scc to interact with P-45011 beta in the same membranes. Kinetic analysis of this effect indicated the formation of an equimolar complex between P-45011 beta and P-450scc on liposomal membranes. P-45011 beta in the complex had not only stimulated activity for 11 beta- and 18-hydroxylation of 11-deoxycorticosterone but also suppressed activity for production of 18-hydroxycorticosterone and aldosterone. When the inner mitochondrial membranes of zona fasciculata-reticularis from bovine adrenal were treated with anti-P-450scc IgG, aldosterone formation was stimulated to a greater extent than that of zona glomerulosa. This indicates the aldosterone synthesizing activity of P-45011 beta in the zona fasciculata-reticularis to be suppressed by interaction with P-450scc. The zone-specific aldosterone synthesis of P-45011 beta in bovine adrenal may possibly be induced by differences in interactions with P-450scc of mitochondrial membranes in each zone.     

The differential regulation of aldosterone output in hamster adrenal by angiotensinII and adrenocorticotropin.

Aldosterone was isolated from hamster adrenal cells and was identified by high performance liquid chromatography and thermospray mass spectroscopy analysis. Basal outputs from adrenal cell suspensions were of the same order of magnitude, 8.4 ± 1.9 ng and 8.0 ± 0.7 ng/2 h/50,000 cells, for aldosterone and corticosteroid, respectively. The outputs of aldosterone and corticosteroid increased with K⁺ concentrations to reach maxima of 3.3- and 1.6-fold at 10 meq/l of K⁺. Angiotensin_II (A_II) produced dose-dependent increases in aldosterone and corticosteroid outputs with maxima of 3- and 4-fold, respectively. In contrast, ACTH induced relatively no changes in aldosterone output, whereas dose-dependent increases in corticosteroid output were found. In time study experiments, with 10⁻⁸ M A_II, aldosterone and corticosteroid outputs were maximally increased after 1 h (6-fold) and 3 h (1.8-fold), respectively. At 10⁻⁸ M, ACTH had a small stimulatory effect on aldosterone output after 6 h, whereas it provoked a gradual increase in corticosteroid output (up to 7-fold after 8 h of incubation). The effects of A_II and ACTH on adrenal cytochrome P-450_11β involved in the last steps of aldosterone formation were evaluated by c combined in vivo andin vitro experiments. The P-450_11β mRNA level was increased by a low sodium intake but not by a 24 h ACTH stimulus. These results taken together indicate that ACTH and A_II differentially regulate P-450_11β. It is postulated that these two regulatory peptides regulate the hamster adrenal steroidogenesis by different P-450 genes.     

Conditionally immortalized adrenocortical cell lines at undifferentiated states exhibit inducible expression of glucocorticoid-synthesizing genes.

To facilitate studies on differentiation of adrenocortical cells and regulation of steroidogenic genes, we established cell lines from adrenals of adult transgenic mice harboring a temperature-sensitive large T-antigen gene of simian virus 40. Adrenal glands of the mice exhibited normal cortical zonation including a functionally undifferentiated cell-layer between the aldosterone-synthesizing zona glomerulosa cells and the corticosterone-synthesizing zona fasciculata cells. At a permissive temperature (33 degrees C), established cell lines AcA201, AcE60 and AcA101 expressed steroidogenic genes encoding steroidogenic factor-1, cholesterol side-chain cleavage P450scc, and steroidogenic acute regulatory protein, which are expressed throughout adrenal cortices and gonads. Genes encoding 3 beta-hydroxysteroid dehydrogenase and steroid 21-hydroxylase P450c21, which catalyze the intermediate steps for syntheses of both aldosterone and corticosterone, were inducible in the three cell lines in temperature- and/or dibutyryl cAMP-dependent manners. Notably, these cell lines displayed distinct expression patterns of the steroid 11 beta-hydroxylase P45011 beta gene responsible for the zone-specific synthesis of corticosterone. AcA201 cells expressed the P45011 beta gene at 33 degrees C, showing the property of the zona fasciculata cells, while AcE60 cells expressed it upon a shift to a nonpermissive temperature (39 degrees C). On the other hand, AcA101 expressed the P45011 beta gene at 39 degrees C synergistically with exposure to dibutyryl cAMP. None of these clones express the zona glomerulosa-specific aldosterone synthase P450aldo gene under the conditions we tested. These results show that AcE60 and AcA101 cells display a pattern of the steroidogenic gene expression similar to that of the undifferentiated cell-layer and are capable of differentiating into the zona fasciculata-like cells in vitro.     

The role of cytokines in the regulation of Leydig cell P450c17 gene expression

Cytokines produced by immune-activated testicular interstitial macrophages (TIMs) may play a fundamental role in the local control mechanisms of testosterone biosynthesis in Leydig cells. We investigated whether in vivo immune-activation of TIMs can modulate Leydig cell steroidogenesis. To immune activate TIMs in vivo, mice were injected intraperitoneally (i.p.) with lipopolysaccharide (LPS, 6 mg/kg). TIMs and Leydig cells were purified for RNA analysis. LPS treatment resulted in a 47-fold increase in interleukin-1β (IL-1β) mRNA in TIMs. P450c17 mRNA levels in the Leydig cells from the same animals, decreased to less than 10% compared to control. The effect of LPS on IL-1β and P450c17 mRNA levels was reversible on both TIMs and Leydig cells, respectively. To determine if the effect of LPS on P450c17 was mediated by a possible decrease in pituitary LH secretion, mice were co-injected with LPS and hCG. Treatment with hCG did not change the effect observed with LPS alone, in TIMs or in Leydig cells. In vitro, LPS treatment of TIMs resulted in marked induction of IL-1β mRNA expression. In parallel, in vitro treatment of Leydig cells with recombinant IL-1 resulted in a dose-dependent inhibition of P450c17 mRNA expression and testosterone production. These data demonstrate that LPS treatment, in vivo and in vitro, induced IL-1 gene expression in TIMs, and that IL-1 inhibits P450c17 mRNA in vitro. Therefore, we suggest that immune-activation of TIMs might have caused the observed inhibition of P450c17 gene expression in Leydig cells in vivo.     

Cytochrome P450(11β): Structure-function relationship of the enzyme and its involvement in blood pressure regulation

Cytochrome P450(11β) is deeply involved in the final steps of biosynthesis of mineralocorticoids. This paper deals with following issues about this enzyme. (1) The structure and function of the enzymes of various animal species are discussed. By making alignment of amino acid sequences of the enzymes, we identified peptide domains essential for the enzyme actions such as a putative steroid binding domain and a heme binding region. Estimates of molecular similarity among the P450(11β) family enzymes suggested that the enzymes having both 11β-hydroxylation activity and aldosterone (ALDO) synthetic activity of certain animals such as frog, cattle and pig are more similar to the ALDO synthases of the other animals, such as rat, mouse and human, than the 11β-hydroxylases of these animals. (2) The molecular nature of the P450(11β) family enzymes of genetically hypertensive rats as well as adrenal regeneration hypertension (ARH) rats is examined. (i) Mutation was found in the P450(11β) gene of Dahl's salt-resistant normotensive rat. Steroidogenic activity expressed by the mutated gene accounted well for abnormal plasma levels of steroid hormones in this rat. (ii) 11β-, 18- and 19-Hydroxylation activities of adrenal mitochondria prepared from spontaneously hypertensive rat (SHR), Wistar-Kyoto rat (WKY), and stroke-prone (SP)-SHR were not significantly different from each other. Levels of mRNA of ALDO synthase in adrenal glands of 50-week-old SHR was significantly lower than those of 10-week-old SHR, WKY and SHR-SP. (iii) No significant difference in 19-hydroxylation activity was found between adrenal mitochondria prepared from ARH rat and those from control rat. The level of message of ALDO synthase was lower in adrenal glands of ARH rat.     

Molecular genetic studies on the biosynthesis of aldosterone in humans

Corticosterone methyl oxidase Type I (CMO I) and II (CMO II) have been postulated to be the enzymes involved in the final two steps of aldosterone biosynthesis in humans. We have isolated human cDNAs for P450c11 and P450c18 as well as the corresponding genes, CYP11B1 and CYP11B2. Both protein products of these two genes as expressed in COS-7 cells exhibit steroid 11β-hydroxylase activity, but only P450c18, a product of CYP11B2, carried steroid 18-hydroxylase activity to form aldosterone. These results indicate that CYP11B2 encodes CMO, the actual catalytic function of which is retained by P450c18, a multifunctional enzyme. This conclusion is further supported by the finding that the P450c18 gene, CYP11B2, is mutated at several different loci in patients deficient in CMO I or II.     

Peptide hormone and growth factor regulation of nuclear proto-oncogenes and specific functions in adrenal cells

Among the large number of immediate early genes, nuclear proto-oncogenes of the Fos and Jun families, have been postulated to be involved in the long-term effects of several growth factors on cell differentiation and/or multiplication. Since adrenal cell differentiated functions appear to be regulated by specific hormones and growth factors, the effects of these factors on proto-oncogene mRNA levels were analysed in bovine adrenal fasciculata cells (BAC) in culture. Corticotropin (ACTH) and insulin-like growth factor I increased c-fos and jun-B mRNA, but had no effect on c-jun mRNA and these early changes were associated with a later increase in BAC specific function [ACTH receptors, cytochrome P 450 17) and 3β-hydroxysteroid dehydrogenase (3β-HSD)] and an enhanced steroidogenic responsiveness to both ACTH and angiotensin-II (A-II). On the other hand, A-II increased the three proto-oncogene (c-fos, c-jun and jun-B) mRNAs, induced a decreased of P 450 17 and 3β-HSD and caused a marked homologous and heterologous (ACTH) densitization. Transforming growth factor β₁ which only increased jun-B mRNA, markedly reduced BAC differentiated functions and the steroidogenic responsiveness to both ACTH and A-II. Thus, it is postulated that the proto-oncoproteins encoded by the immediate early genes may play a role in the long-term effects of peptide hormones and growth factors on BAC differentiated functions.     

Steroid 11ß-hydroxylation by a fungal microsomal cytochrome P450

The steroid 11ß-hydroxylase activity of the fungus Cochliobolus lunatus was increased about 100-fold by cultivation of mycelia for 4–5 h with 20-hydroxymethyl-1,4-pregnadien-3-one. Cell-free extracts revealed a maximum activity of 45 nmol 11ß-hydroxyprogesterone/h·mg protein in the 100,000 g pellet fraction. The 11ß-hydroxylation was dependent on NADPH. The formation of 11ß-hydroxyprogesterone correlated linearly with the cytochrome P450 concentration. The fungal 11ß-hydroxylase transformed both 21-methyl and 21-hydroxymethyl steroids. The enzyme showed a broader substrate specificity and lower regioselectivity as compared with the adrenal cytochrome P45011ß system. The fungal cytochrome P450 was partially purified to a specific content of 700 pmol P450/mg protein. Western blots showed that polyclonal antibodies against cytochrome P45011 from Rhizopus nigricans cross-react with a 60 kD protein of partially purified fractions. The NADPH-cytochrome c reductase was enriched up to a specific activity of 20 U/mg protein. Polyclonal antibodies against NADPH-cytochrome P450 reductases from Candida maltosa and rat liver cross-reacted with the fungal reductase. It is concluded that the 11ß-hydroxylase of Cochliobolus lunatus represents a microsomal two-component monooxygenase system which is composed of a cytochrome P450 (M_r 60 kD) and a NADPH-cytochrome P450 reductase (M_r 79 kD).     

Organization of 3β-hydroxysteroid dehydrogenase/isomerase and cytochrome P450scc into a catalytically active molecular complex in bovine adrenocortical mitochondria

We have previously reported the co-localization [Cherradi et al., Endocrinology 134 (1994) 1358–1364] of 3β-hydroxysteroid dehydrogenase/isomerase (3β-HSD) and cytochrome P450_scc (cyt. P450_scc) in the inner membrane and in the intermembrane contact sites of adrenocortical mitochondria. This observation raises the question of a possible functional association between the two proteins. Isolated bovine adrenocortical mitochondria are able to convert cholesterol to progesterone without the need of exogenous cofactors. An association of 3β-HSD and cyt. P450_scc is observed during the purification of 3β-HSD from mitochondria. The behaviour of 3β-HSD on a column of Heparin-Sepharose is modified by the presence of cyt. P450_scc. Immunoprecipitations from mitochondria with either anti-cyt. P450_scc or anti 3β-HSD antibodies result in a co-precipitation of the two proteins. Both proteins engaged in these immunocomplexes are catalytically active. The interaction was further demonstrated by the surface plasmon resonance method using purified components. An affinity constant of 0.12 μM between 3β-HSD and P450_scc was obtained. These observations suggest that P450_scc and 3β-HSD may associate into a molecular complex in the mitochondrial compartment and may constitute a functional steroidogenic unit, thus opening new possibilities in the regulation of the production of progesterone and its flow in the adrenocortical cell.     

18-Ethynyl-deoxycorticosterone inhibition of steroid production is different in freshly isolated compared to cultured calf zona glomerulosa cells

The inhibiting effects of 18-ethynyl-deoxycorticosterone (18-E-DOC) as a mechanism-based inhibitor on the late-steps of the aldosterone biosynthetic pathway were examined in calf adrenal zona glomerulosa cells in primary culture and in freshly isolated calf zona glomerulosa cells. 18-E-DOC inhibited the stimulated secretion of aldosterone and 18-hydroxycorticosterone in a similar dose-response and time fashion. No significant differences were found between the inhibition in cultured and freshly isolated cells (K_i of 0.25 vs 0.26 μM) Corticosterone secretion stimulated by ACTH or angiotensin II was also cultured in freshly isolated zona glomerulosa and fasciculata cells, but was not inhibited in cultured calf adrenal cells. Cortisol secretion stimulated by ACTH was not inhibited by 18-E-DOC in cultured zona fasciculata adrenal cells, but was inhibited in freshly isolated zona fasciculata cells with a K_i of 48 μM. The secretion of 18-hydroxyDOC or 19-hydroxyDOC stimulated by ACTH was not inhibited by 18-E-DOC. The bovine adrenal has been reported to have cytochrome P-450 11β-hydroxylases that can perform the various hydroxylations required for the synthesis of cortisol and aldosterone in the different areas of the adrenal. In other species a distinct 11β-hydroxylase which participates in the biosynthesis of aldosterone and is located in the zona glomerulosa has been described. These studies with the mechanism-based inhibitor, 18-E-DOC, suggest that the bovine adrenal functions in a manner very similar to that of other species and raises the possibility that a distinct 11β-hydroxylase with aldosterone synthase activity might be present, but has not been cloned as yet.     

Extraadrenal expression of steroid 21-hydroxylase and 11β-hydroxylase by a benign testicular leydig cell tumor

We present an unusual case with bilateral testicular Leydig cell tumors displaying extraadrenal expression of steroid 21-hydroxylase and 11β-hydroxylase. Histological examination of a 38-yr-old man infertile due to azoospermia showed him to have bilateral testicular Leydig cell tumors. The in vitro steroidogenic potential of the tumors and their adjacent testicular tissue was evaluated using organ culture. Tumor tissue was found to secrete deoxycorticosterone (DOC), corticosterone (B) and cortisol, which are not produced in normal adult testis, into the medium, while testicular tissue adjacent to the tumors secreted a small amount of DOC and B. Northern blot analysis with cytochrome P-450_C21 complementary DNA (cDNA) and P-450_11β cDNA as probes revealed that the tumor contained a considerable amount of mRNA for P-450_C21 and P-450_11β, while the mRNAs were not detected in the testicular tissues adjacent to the tumors. It is suggested that the high local levels of estrogen and/or progesterone within the Leydig cell tumors and their adjacent testicular tissues induced extraadrenal expression of steroid 21-hydroxylase and 11β-hydroxylase by the tumors and their adjacent testicular tissues.     

Characterisation of the beta-tubulin gene of Cylicocyclus nassatus?

mRNA and genomic DNA were isolated from adult Cylicocyclus nassatus, and the mRNA was reverse transcribed. The cDNA was PCR amplified using degenerate primers designed according to the alignment of the β-tubulin amino acid sequences of other species. To complete the coding sequence, the 3′ end was amplified with the 3′-RACE, and for amplification of the 5′ end the SL1-primer was used. The cDNA of the β-tubulin gene of C. nassatus spans 1429 bp and encodes a protein of 448 amino acids. Specific primers were developed from the cDNA sequence to amplify the genomic DNA sequence and to analyse the genomic organisation of the β-tubulin gene. The complete sequence of the genomic DNA of the β-tubulin gene of C. nassatus has a size of 2652 bp and is organised into nine exons and eight introns. The identities with the exons of the gru-1 β-tubulin gene of Haemonchus contortus range between 79% and 97%.