Molten globule structure and steroidogenic activity of N-218 MLN64 in human placental mitochondria

Progesterone synthesis by the human placenta requires the conversion of mitochondrial cholesterol to pregnenolone by cytochrome P450scc. Most steroidogenic tissues use the steroidogenic acute regulatory protein (StAR) to deliver cholesterol to the inner mitochondrial membrane where P450scc is located, but StAR is not expressed in the human placenta. However, the human placenta does express MLN64, which has a C-terminal domain homologous to StAR that can also transport cholesterol. We investigated the ability of bacterially expressed N-218 MLN64 and N-62 StAR to transport cholesterol between artificial membranes and to its inner membrane site of use in placental mitochondria. Urea denaturation experiments show that N-218 MLN64 undergoes a pH-dependent and denaturant-dependent structural transition to a molten globule state, as reported previously for N-62 StAR. N-218 MLN64 stimulated cholesterol transfer between artificial phospholipid vesicles with an initial rate of 6.5 mol/min.mol N-218 MLN64. Both N-218 MLN64 and N-62 StAR stimulated cholesterol transfer to the inner mitochondrial membrane, as evidenced by a 6-fold stimulation of pregnenolone synthesis with saturating transporter. This stimulation was seen only after the endogenous cholesterol in the steroidogenic pool of the isolated mitochondria was first depleted. No stimulation was observed by N-218 MLN64 or N-62 StAR when 20alpha-hydroxycholesterol was added as substrate for P450scc, confirming that these proteins stimulate P450scc activity by enhancing cholesterol transport. MLN64 levels in placental JEG-3 cells were unresponsive to stimulation by 8-bromo-cAMP over 24 h. These data show that human N-218 MLN64 and N-62 StAR have similar biophysical and functional properties and are able to stimulate steroidogenesis in a human placental system, which normally lacks StAR. The results reveal that with saturating MLN64, steroidogenesis by placental mitochondria proceeds at near-maximal rate.     

Simultaneous transfection of COS-1 cells with mitochondrial and microsomal steroid hydroxylases: incorporation of a steroidogenic pathway into nonsteroidogenic cells.

Transfected, nonsteroidogenic COS-1 cells derived from monkey kidney are found to be capable of supporting the initial and rate-limiting step common to all steroidogenic pathways, the side-chain cleavage of cholesterol to produce pregnenolone. Endogenous COS-1 kidney cell renodoxin reductase and renodoxin are able to sustain low levels of this activity catalyzed by bovine cholesterol side-chain cleavage cytochrome P450 (P450scc) whose synthesis is directed by a transfected plasmid containing P450scc cDNA. Double transfection with both P450scc and adrenodoxin plasmids leads to greater pregnenolone production and indicates that adrenodoxin plays a role as a substrate for this reaction or that bovine adrenodoxin serves as a better electron donor than the endogenous iron-sulfur protein renodoxin. Also it is found that both the bovine adrenodoxin and P450scc precursor proteins are proteolytically processed upon their uptake by COS-1 cell mitochondria to forms having the same electrophoretic mobility as mature bovine adrenodoxin and P450scc. Following triple transfection of COS-1 cells with P450scc, adrenodoxin, and 17 alpha-hydroxylase cytochrome P450 plasmids, pregnenolone produced in mitochondria by the side-chain cleavage reaction can be further metabolized in the endoplasmic reticulum to 17 alpha-hydroxypregnenolone and dehydroepiandrosterone. Although this functional steroidogenic pathway can be incorporated into this nonsteroidogenic cell type, it is found to be nonresponsive to cAMP, a potent activator of steroid hormone biosynthesis in adrenal cortex, testis, and ovary. Thus the cellular mechanisms necessary to support both microsomal and mitochondrial steroid hydroxylase activities appear not to be tissue specific, whereas the acute cAMP-dependent regulation of steroidogenesis is not present in transformed kidney (COS-1) cells.     

Androgen biosynthesis from cholesterol to DHEA

Androgens and estrogens are made from dehydroepiandrosterone (DHEA), which is made from cholesterol via four steps. First, cholesterol enters the mitochondria with the assistance of the steroidogenic acute regulatory protein (StAR). Mutations in the StAR gene cause congenital lipoid adrenal hyperplasia. Second, within the mitochondria, cholesterol is converted to pregnenolone by the cholesterol side chain cleavage enzyme, P450scc. Third, pregnenolone undergoes 17alpha-hydroxylation by microsomal P450c17. Finally, 17-OH pregnenolone is converted to DHEA by the 17,20 lyase activity of P450c17. The ratio of the 17,20 lyase to 17alpha-hydroxylase activity of P450c17 determines the ratio of C21 to C19 steroids produced. This ratio is regulated post-translationally by at least three factors: the abundance of the electron-donating protein P450 oxidoreductase, the presence of cytochrome b(5), and the serine phosphorylation of P450c17. Study of these and related factors may yield important information about the pathophysiology of adrenarche and the polycystic ovary syndrome (PCOS).     

Creation and activity of COS-1 cells stably expressing the F2 fusion of the human cholesterol side-chain cleavage enzyme system

A fusion construct for the human cholesterol side-chain cleavage enzyme system termed F2 (H(2)N-P450scc-adrenodoxin reductase-adrenodoxin-COOH), was stably expressed in nonsteroidogenic COS-1 cells. Multiple clones were obtained and analyzed, identifying the clone COS-F2-130 as the most active in converting 22R-hydroxycholesterol (22R-OH-C) to pregnenolone. The F2 fusion construct was properly transcribed and translated in COS-F2-130 cells, indicating that these cells did not proteolytically cleave the F2 protein. Steroid analyses show that the COS-F2-130 cells do not convert appreciable quantities of pregnenolone to other steroids. Isolated COS-F2-130 mitochondria showed enhanced steroidogenesis when incubated with biosynthetic N-62 StAR protein in vitro. The cells were easily transfectable with StAR expression vectors, showing that COS-F2-130 cells exhibited both StAR-independent and StAR-dependent activity. Transient expression of either full-length or N-62 StAR stimulated steroidogenesis to approximately 45% of the maximal steroidogenic capacity, as indicated by incubation with 22R-OH-C. Single, double, and triple transfections of individual vectors expressing P450scc, adrenodoxin reductase, and adrenodoxin demonstrated that the P450 moiety of the F2 fusion protein could only receive electrons from the covalently linked adrenodoxin moiety, but that free adrenodoxin reductase could foster activity of the fusion enzyme. COS-F2-130 cells provide a useful system for studying steroidogenesis, as these are the only cells described to date that convert cholesterol to pregnenolone but lack downstream enzymes that catalyze other steroidogenic reactions.     

Immunoelectron microscopic localization of three key steroidogenic enzymes (cytochrome P450(scc), 3 beta-hydroxysteroid dehydrogenase and cytochrome P450(c17)) in rat adrenal cortex and gonads.

The biosynthesis of steroid hormones in endocrine steroid-secreting glands results from a series of successive steps involving both cytochrome P450 enzymes, which are mixed-function oxidases, and steroid dehydrogenases. So far, the subcellular distribution of steroidogenic enzymes has been mostly studied following subcellular fractionation, performed in placenta and adrenal cortex. In order to determine in situ the intracellular distribution of some steroidogenic enzymes, we have investigated the ultrastructural localization of the three key enzymes: P450 side chain cleavage (scc) which converts cholesterol to pregnenolone; 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) which catalyzes the conversion of 3 beta-hydroxy-5-ene steroids to 3-oxo-4-ene steroids (progesterone and androstenedione); and P450(c17) which is responsible for the transformation of C(21) into C(19) steroids (dehydroepiandrosterone and androstenedione). Immunogold labeling was used to localize the enzymes in rat adrenal cortex and gonads. The tissues were fixed in 1% glutaraldehyde and 3% paraformaldehyde and included in LR gold resin. In the adrenal cortex, both P450(scc) and 3 beta-HSD immunoreactivities were detected in the reticular, fascicular and glomerular zones. P450(scc) was exclusively found in large mitochondria. In contrast, 3 beta-HSD antigenic sites were mostly observed in the endoplasmic reticulum (ER) with some gold particles overlying crista and outer membranes of the mitochondria. P450(c17) could not be detected in adrenocortical cells. In the testis, the three enzymes were only found in Leydig cells. Immunolabeling for P450(scc) and 3 beta-HSD was restricted to mitochondria, while P450(c17) immunoreactivity was exclusively observed in ER. In the ovary, P450(scc) and 3 beta-HSD immunoreactivities were found in granulosa, theca interna and corpus luteum cells. The subcellular localization of the two enzymes was very similar to that observed in adrenocortical cells. P450(c17) could also be detected in theca interna cells of large developing and mature follicles. As observed in Leydig cells, P450(c17) immunolabeling could only be found in the ER. These results indicate that in different endocrine steroid-secreting cells P450(scc), 3 beta-HSD and P450(c17) have the same association with cytoplasmic organelles (with the exception of 3 beta-HSD in Leydig cells), suggesting similar intracellular pathways for biosynthesis of steroid hormones.     

Preparation of antiserum to rat cytochrome P-450 cholesterol side chain cleavage, and its use for ultrastructural localization of the immunoreactive enzyme by protein A-gold technique

Rabbit antiserum to rat cytochrome P-450 cholesterol side chain cleavage (P-450scc) was produced without a previous biochemical purification of the enzyme. Instead, for immunization we used a single protein band of mol wt 53,000, which was isolated from sodium dodecyl sulfate polyacrylamide gel electrophoresis of rat steroidogenic mitochondrial membranes. The resulting antiserum cross-reacted in a protein-blotting test with affinity purified and biologically active bovine adrenocortical P-450scc enzyme. The antiserum to the rat P-450scc also substantially blocked the conversion of cholesterol to pregnenolone in sonicated steroidogenic mitochondria, suggesting a successful cross-reactivity with the native form of the enzyme, despite the fact that the immunizing antigen was sodium dodecyl sulfate-denatured protein. The antiserum was applied for ultrastructural immunocytochemical visualization of the P-450scc in thin sections of adrenal cortex and immature ovary. Immunoreactive enzyme was identified by the protein-A-gold technique which showed that the gold particles concentrated exclusively in the steroidogenic mitochondria of adrenal zona glomerulosa and fasciculata cells. In the immature ovary, the only zone which was heavily stained with colloidal gold was the population of the interstitial cells. Part of the theca cell population contained P-450scc before PMSG treatment. The granulosa cells were devoided of the enzyme in any follicles before the preovulatory stage. The high resolution of the pAg technique allowed to visualize the localization of the P-450scc antigen in the matrix side of the inner mitochondrial membranes. Moreover, a clear coupling could be demonstrated between the morphological and functional maturation of the steroidogenic mitochondrion in the ovary: from a few lamella cristae devoid of P-450scc in the unstimulated granulosa mitochondria, to numerous tubulovesicular inner membranes, heavily loaded with the enzyme, in the mitochondria of the interstitial cells.     

Heterozygous mutation in the cholesterol side chain cleavage enzyme (p450scc) gene in a patient with 46,XY sex reversal and adrenal insufficiency

Cytochrome P450scc, the mitochondrial cholesterol side chain cleavage enzyme, is the only enzyme that catalyzes the conversion of cholesterol to pregnenolone and, thus, is required for the biosynthesis of all steroid hormones. Congenital lipoid adrenal hyperplasia is a severe disorder of steroidogenesis in which cholesterol accumulates within steroidogenic cells and the synthesis of all adrenal and gonadal steroids is impaired, hormonally suggesting a disorder in P450scc. However, congenital lipoid adrenal hyperplasia is caused by mutations in the steroidogenic acute regulatory protein StAR; it has been thought that P450scc mutations are incompatible with human term gestation, because P450scc is needed for placental biosynthesis of progesterone, which is required to maintain pregnancy. In studying patients with congenital lipoid adrenal hyperplasia, we identified an individual with normal StAR and SF-1 genes and a heterozygous mutation in P450scc. The mutation was found in multiple cell types, but neither parent carried the mutation, suggesting it arose de novo during meiosis, before fertilization. The patient was atypical for congenital lipoid adrenal hyperplasia, having survived for 4 yr without hormonal replacement before experiencing life-threatening adrenal insufficiency. The P450scc mutation, an in-frame insertion of Gly and Asp between Asp271 and Val272, was inserted into a catalytically active fusion protein of the P450scc system (H2N-P450scc-Adrenodoxin Reductase-Adrenodoxin-COOH), completely inactivating enzymatic activity. Cotransfection of wild-type and mutant vectors showed that the mutation did not exert a dominant negative effect. Because P450scc is normally a slow and inefficient enzyme, we propose that P450scc haploinsufficiency results in subnormal responses to ACTH, so that recurrent ACTH stimulation leads to a slow accumulation of adrenal cholesterol, eventually causing cellular damage. Thus, although homozygous absence of P450scc should be incompatible with term gestation, haploinsufficiency of P450scc causes a late-onset form of congenital lipoid adrenal hyperplasia that can be explained by the same two-hit model that has been validated for congenital lipoid adrenal hyperplasia caused by StAR deficiency.     

Regulation of mRNAs encoding the steroidogenic acute regulatory protein and cholesterol side-chain cleavage enzyme in the elasmobranch interrenal gland

The rate-limiting and regulated step in steroidogenesis, the conversion of cholesterol to pregnenolone, is facilitated by the steroidogenic acute regulatory protein (StAR) and cytochrome P450 cholesterol side-chain cleavage (P450scc). We have isolated cDNAs encoding StAR and P450scc from the Atlantic stingray, Dasyatis sabina, and characterized the steroidogenic activity of the encoded proteins using a heterologous expression system. Green monkey kidney (COS-1) cells cotransfected with D. sabina StAR and human P450scc/adrenodoxin reductase/adrenodoxin fusion (F2) constructs produced significantly more pregnenolone than cells transfected with the F2 construct alone. COS-1 cells transfected with a modified F2 construct (F2DS) in which human P450scc is replaced by D. sabina P450scc had higher rates than cells transfected with D. sabina P450scc alone. In other vertebrates, the stress peptide adrenocorticotropic hormone (ACTH) elicits its effects on corticosteroidogenesis in part through regulation of StAR and P450scc mRNAs. In vitro incubation of D. sabina interrenal tissue with porcine ACTH significantly increased intracellular cAMP and corticosteroid production. As demonstrated by quantitative PCR, ACTH also induced significant increases in mRNA abundance of both StAR and P450scc. Our results suggest that, as in higher vertebrates, chronic ACTH-induced glucocorticoid synthesis in elasmobranchs is mediated by regulation of primary steroidogenic mRNAs. This study is the first to demonstrate steroidogenic activity of an elasmobranch P450scc protein and express a composite elasmobranch steroidogenic pathway in a heterologous cell line. Also, the regulation of StAR and P450scc mRNAs has not previously been demonstrated in elasmobranch fishes.     

Resveratrol stimulates cortisol biosynthesis by activating SIRT-dependent deacetylation of P450scc

In the human adrenal cortex, cortisol is synthesized from cholesterol by members of the cytochrome P450 superfamily and hydroxysteroid dehydrogenases. Both the first and last steps of cortisol biosynthesis occur in mitochondria. Based on our previous findings that activation of ACTH signaling changes the ratio of nicotinamide adenine dinucleotide (NAD) phosphate to reduced NAD phosphate in adrenocortical cells, we hypothesized that pyridine nucleotide metabolism may regulate the activity of the mitochondrial NAD(+)-dependent sirtuin (SIRT) deacetylases. We show that resveratrol increases the protein expression and half-life of P450 side chain cleavage enzyme (P450scc). The effects of resveratrol on P450scc protein levels and acetylation status are dependent on SIRT3 and SIRT5 expression. Stable overexpression of SIRT3 abrogates the cellular content of acetylated P450scc, concomitant with an increase in P450scc protein expression and cortisol secretion. Mutation of K148 and K149 to alanine stabilizes the expression of P450scc and results in a 1.5-fold increase in pregnenolone biosynthesis. Finally, resveratrol also increases the protein expression of P450 11β, another mitochondrial enzyme required for cortisol biosynthesis. Collectively, this study identifies a role for NAD(+)-dependent SIRT deacetylase activity in regulating the expression of mitochondrial steroidogenic P450.     

Cholesterol pools in rat adrenal mitochondria: use of cholesterol oxidase to infer a complex pool structure.

ACTH stimulates the side-chain cleavage of cholesterol in the adrenal cortex in a cycloheximide-inhibitable manner. Its mechanism involves mobilizing cholesterol to a "steroidogenic pool" where the sterol can be metabolized to pregnenolone. This pool has been proposed to be in the inner mitochondrial membrane where cytochrome P-450scc resides, and regulation may involve transport of cholesterol from the outer to the inner membrane. To investigate the structure of the mitochondrial cholesterol pools, cholesterol oxidase has been used as a membrane-impermeant probe which should have selective access to outer membrane cholesterol. At 37 C, almost all the cholesterol in mitochondria from ether-stressed rats was metabolized by cholesterol oxidase. Depletion of an intermembrane space but not a matrix marker enzyme indicated partial disruption of the outer membrane. However, at 16 C, mitochondria remained largely intact, and cholesterol oxidase identified a unique pool of cholesterol, which was about two-thirds of the total. In experiments using mitochondria from ether-stressed rats, the size of the 16 C cholesterol oxidase accessible and inaccessible pools was compared with that of the steroidogenic pool. The steroidogenic pool was enhanced by pretreatment of some animals with aminoglutethimide (a P-450scc inhibitor) or eliminated with cycloheximide, both of which increased the total mitochondrial cholesterol. This approach reveals that the steroidogenic pool is not equivalent to the cholesterol oxidase-inaccessible pool. Rather, it overlaps both the cholesterol oxidase accessible and inaccessible pools. These results are not consistent with a simple two pool model, but can be explained by assuming a minimum of three cholesterol pools.     

The molecular biology, biochemistry, and physiology of human steroidogenesis and its disorders

Steroidogenesis entails processes by which cholesterol is converted to biologically active steroid hormones. Whereas most endocrine texts discuss adrenal, ovarian, testicular, placental, and other steroidogenic processes in a gland-specific fashion, steroidogenesis is better understood as a single process that is repeated in each gland with cell-type-specific variations on a single theme. Thus, understanding steroidogenesis is rooted in an understanding of the biochemistry of the various steroidogenic enzymes and cofactors and the genes that encode them. The first and rate-limiting step in steroidogenesis is the conversion of cholesterol to pregnenolone by a single enzyme, P450scc (CYP11A1), but this enzymatically complex step is subject to multiple regulatory mechanisms, yielding finely tuned quantitative regulation. Qualitative regulation determining the type of steroid to be produced is mediated by many enzymes and cofactors. Steroidogenic enzymes fall into two groups: cytochrome P450 enzymes and hydroxysteroid dehydrogenases. A cytochrome P450 may be either type 1 (in mitochondria) or type 2 (in endoplasmic reticulum), and a hydroxysteroid dehydrogenase may belong to either the aldo-keto reductase or short-chain dehydrogenase/reductase families. The activities of these enzymes are modulated by posttranslational modifications and by cofactors, especially electron-donating redox partners. The elucidation of the precise roles of these various enzymes and cofactors has been greatly facilitated by identifying the genetic bases of rare disorders of steroidogenesis. Some enzymes not principally involved in steroidogenesis may also catalyze extraglandular steroidogenesis, modulating the phenotype expected to result from some mutations. Understanding steroidogenesis is of fundamental importance to understanding disorders of sexual differentiation, reproduction, fertility, hypertension, obesity, and physiological homeostasis.     

Cholesterol side-chain cleavage activity in rat fetal gonads: a limiting step for ovarian steroidogenesis

The aim of this study was to examine the first step in steroidogenesis in male and female gonads of fetal rats. Pregnenolone production was measured by radioimmunoassay in organ culture, conversion of [3H]cholesterol to [3H]pregnenolone was evaluated in isolated mitochondria and cytochrome P-450scc was revealed by immunoblotting and immunocytochemical techniques. Our results clearly showed that in fetal testes (1) pregnenolone was produced in media where testes were cultured in the presence of trilostane and spironolactone, indicating an important metabolism of pregnenolone, (2) [3H]cholesterol was converted into [3H]pregnenolone in mitochondria, (3) cytochrome P-450scc was revealed in immunoblots with a molecular weight of 50,000, (4) cytochrome P-450scc was localized in Leydig cells from 15.5-day-old fetal testes onwards. With respect to fetal ovaries, we were unable to detect any scc activity, except after treatment with dibutyryl cyclic AMP. A lag period of 18 h was necessary to induce pregnenolone synthesis. However, the immunoperoxidase staining did not localize ovarian positive cells. Cytochrome P-450scc could be revealed in postnatal ovaries by immunoblotting and some interstitial positive cells were observed with immunostaining; the reaction was enhanced in luteinizing hormone-pretreated ovaries. These data indicate that (a) the cholesterol scc activity is present in fetal testes, (b) the conversion of cholesterol to pregnenolone is a limiting step for steroidogenesis in fetal ovaries. The inductive effect of the nucleotide on the enzyme suggests that the absence of gonadotrophic receptors in fetal female gonads could explain the lack of steroidogenesis before birth.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inherited congenital adrenal hyperplasia in the rabbit: absent cholesterol side-chain cleavage cytochrome P450 gene expression.

We investigated adrenal steroidogenic enzymes, their activity and mRNA expression, and in vitro biosynthesis of an enzyme in rabbits with congenital adrenal hyperplasia (CAH; weight: CAH, 19 +/- 5 mg/adrenal; normal, 2.7 +/- 1.0 mg/adrenal). Serum pregnenolone (delta 5-P) levels in CAH newborn rabbits (12-36 h) were normal (mean/range, 438/51-2191 ng/dl), but corticosterone levels were low [0.05 +/- 0.05 microgram/dl; P less than 0.001 vs. normal (0.66 +/- 0.57)]. Serum Na+ levels in CAH newborn rabbits were in the normal range (143 +/- 30 meq/liter), but K+ levels were elevated [7 +/- 1.1 meq/liter; P less than 0.05 vs. normal (5.9 +/- 0.6 meq/liter)]. Minced normal adrenal tissue incubated with [3H] cholesterol (30-100 pmol/flask) and ACTH (100 mU/flask) produced [3H]delta 5-P (newborn, 21 and 45 fmol/100 mg; adult, 3 and 5 fmol/100 mg) and [3H]corticosterone (newborn, 23 fmol/100 mg; adult, 11.3 fmol/100 mg), but CAH adrenals produced no product (less than 1.3 fmol/100 mg). Adrenal mitochondria from normal newborn rabbits produced delta 5-P (4.4-7 nmol/mg protein), but CAH adrenals did not, while CAH adrenal mitochondria demonstrated over 4 times greater 11 beta-hydroxylase activity. A Western blot of adrenal homogenate from normal newborn rabbits revealed a cholesterol side-chain cleavage cytochrome P450 (P450scc)-immunoreactive species (mol wt, 53 x 10(3), but this species was absent in CAH adrenals; CAH adrenals had a normal adrenodoxin and intensified 17 alpha-hydroxylase cytochrome P450 (P450(17)alpha) band compared to normal adrenals. In vitro translation of RNA in a cell-free rabbit reticulocyte lysate system containing [35S] methionine yielded a precursor P450scc protein (mol wt, 58.5 x 10(3)) with normal adrenal RNA, but not with CAH adrenal RNA. P450scc mRNA was detected in all normal adrenals, but was not detected in all CAH adrenals. 21-Hydroxylase cytochrome P450 mRNA expression was detected at a similar level in both normal and CAH adrenals. We conclude that CAH in the rabbit is caused by inherited absent P450scc gene expression. The clinical, pathological, and biochemical manifestations of P450scc deficiency in the rabbit are nearly identical to the human disorder. Increased 11 beta-hydroxylase activity and increased P450(17)alpha on Western blot of CAH adrenals indicate altered gene expression of other steroidogenic enzymes due to CAH. Further molecular analysis of the P450scc gene in this animal CAH model will facilitate understanding of P450scc deficiency CAH.     

Hormonal and developmental regulation of adrenodoxin messenger ribonucleic acid in steroidogenic tissues

Adrenodoxin is an iron-sulfur protein found in the mitochondria of steroidogenic tissues. It participates in steroidogenesis as an electron transport intermediate for mitochondrial cytochromes P450, including P450scc, the cholesterol side-chain cleavage enzyme. Using a human adrenodoxin cDNA probe recently cloned in our laboratory, we examined the distribution and hormonal regulation of adrenodoxin mRNA in a variety of steroidogenic tissues. Adrenodoxin mRNA was found in all steroidogenic tissues examined. In human fetal testes, adrenodoxin mRNA was more abundant in early gestation, diminishing toward midterm in a pattern closely similar to that we reported previously for P450scc. Unlike P450scc, however, significant amounts of adrenodoxin mRNA were detected in human fetal ovaries, with no discernible gestation-dependent change. The abundance of adrenodoxin mRNA was increased in cultured human granulosa cells by treatment with hCG, FSH, cAMP, and cholera toxin. In human fetal adrenal cells, ACTH and cAMP stimulated accumulation of adrenodoxin mRNA, while in cultured human fetal testicular cells and cultured fetal rhesus monkey ovarian cells, both hCG and cAMP stimulated accumulation of adrenodoxin mRNA. In all of these systems, the accumulation of adrenodoxin mRNA closely paralleled the response of P450scc. These data suggest that the genes for these functionally related but structurally unrelated proteins are regulated in a coordinate manner.     

Estrogen increases precursor for pregnenolone synthesis with temperature-sensitive occupancy of P-450scc in mitochondria of rabbit corpus luteum

To examine the mechanism of estrogen's direct stimulation of steroidogenesis in the rabbit corpus luteum, we tested the hypothesis that the effect of estrogen on progestin production occurs at the site of processing of the precursor for pregnenolone (i.e. cholesterol) in the mitochondrion. For this purpose, we manipulated a model of estrogen stimulation by 1) removing sc estradiol-filled polydimethylsiloxane capsules from superovulated rabbits on day 9 of pseudopregnancy or 2) leaving the capsules in place to preserve a chronic estrogen stimulus. In the estrogen-deprived rabbits, the serum progesterone level fell precipitously in vivo within 24 h, but in rabbits with chronic estrogen stimulation, serum progesterone levels remained high. Our results show that the loss in progestin production caused by estrogen deprivation could not be attributed to loss of the mitochondrial cytochrome P-450 side-chain cleavage enzyme (P-450scc), a common rate-limiting step in progestin synthesis in many steroidogenic tissues. In addition, we confirmed that there was no loss in the catalytic activity of this enzyme. Treatment with aminoglutethimide in vivo followed by electron paramagnetic resonance spectroscopic analysis of mitochondria (prepared in aminoglutethimide-free buffers) showed that incubation of isolated mitochondria at 37 C and pH 6.2 caused an increased high spin state (g = 8.2 signal) and a concomitant decreased low spin state. This shift from low to high spin states, which is indicative of cholesterol-P-450scc complex formation, occurred in the luteal mitochondria from both estrogen-deprived and estrogen-stimulated rabbits. In further studies to localize estrogen's regulatory point, we determined that the initial (first minute) rate of production of pregnenolone (per mg protein or per U P-450scc) from endogenous precursor proceeded equally fast in mitochondria from estrogen-deprived and those from estrogen-stimulated rabbits. However, the rapid pregnenolone production in the estrogen-deprived group lasted for a shorter time and, after 30 min, yielded less pregnenolone per mg protein or per U P-450scc than did mitochondria from estrogen-stimulated rabbits. Addition of 25-hydroxycholesterol did not increase the initial rate of pregnenolone formation, indicating that precursor availability is not limiting during the initial period. In aggregate, these observations suggest that the effect of estrogen on progestin production in the rabbit corpus luteum is not regulation of the movement of cholesterol to the catalytic site on the inner mitochondrial membrane, even though this is a step in the regulation of protein hormone-stimulated steroidogenesis.(ABSTRACT TRUNCATED AT 400 WORDS)