Sarah Eimerl

CCAAT Enhancer-binding Protein β and GATA-4 Binding Regions within the Promoter of the Steroidogenic Acute Regulatory Protein (StAR) Gene Are Required for Transcription in Rat Ovarian Cells

Steroidogenic acute regulatory protein (StAR) is a vital accessory protein required for biosynthesis of steroid hormones from cholesterol. The present study shows that in primary granulosa cells from prepubertal rat ovary, StAR transcript and protein are acutely induced by gonadotropin (FSH). To determine the sequence elements required for hormone inducibility of the StAR promoter, truncated regions of the −1002/+6 sequence of the mouse gene were ligated to pCAT-Basic plasmid and transfected by electroporation to freshly prepared cells. FSH inducibility determined over a 6-h incubation was 10–40-fold above basal levels of chloramphenicol acetyltransferase activity. These functional studies, supported by electrophoretic mobility shift assays indicated that two sites were sufficient for transcription of the StAR promoter constructs: a non-consensus binding sequence (−81/−72) for CCAAT enhancer-binding protein β (C/EBPβ) and a consensus motif for GATA-4 binding (−61/−66). Western analyses showed that GATA-4 is constitutively expressed in the granulosa cells, while all isoforms of C/EBPβ were markedly inducible by FSH. Site-directed mutations of both binding sequences practically ablated both basal and hormone-driven chloramphenicol acetyltransferase activities to less than 5% of the parental −96/+6 construct. Unlike earlier notions, elimination of potential binding sites for steroidogenic factor-1, a well known tissue-specific transcription factor, did not impair StAR transcription. Consequently, we propose that C/EBPβ and GATA-4 represent a novel combination of transcription factors capable of conferring an acute response to hormones upon their concomitant binding to the StAR promoter.

Regulation of Steroidogenic Genes by Insulin-Like Growth Factor-1 and Follicle-Stimulating Hormone: Differential Responses of Cytochrome P450 Side-Chain Cleavage, Steroidogenic Acute Regulatory Protein, and 3β-Hydroxysteroid Dehydrogenase/Isomerase in Rat Granulosa Cells

Abstract The present study sought to characterize the concerted action of FSH and insulin-like growth factor-1 (IGF-1) on functional differentiation of prepubertal rat ovarian granulosa cells in culture. To this end, we examined the regulation of three key genes encoding pivotal proteins required for progesterone biosynthesis, namely, side-chain cleavage cytochrome P450 (P450scc), steroidogenic acute regulatory (StAR) protein, and 3β-hydroxysteroid dehydrogenase/isomerase (3β-HSD). Time-dependent expression profiles showed that P450scc, StAR, and 3β-HSD gene products accumulate in chronic, acute, and constitutive patterns, respectively. Each of these genes responded to FSH and/or IGF-1 in a characteristic manner: A synergistic action of IGF-1 was indispensable for FSH induction of P450scc mRNA and protein; IGF-1 did not affect FSH-mediated upregulation of StAR products; and IGF-1 alone was enough to promote expression of 3β-HSD. The responsiveness of the genes to IGF-1 correlated well with their apparent susceptibility to the inhibitory impact of tyrphostin AG18, a potent inhibitor of protein tyrosine kinase receptors. Thus, IGF-1-dependent P450scc and 3β-HSD expression was completely arrested in the presence of AG18, whereas StAR expression was unaffected in the presence of tyrphostin. These findings suggest that FSH/cAMP signaling and IGF-1/tyrosine phosphorylation events are interwoven in rat ovarian cells undergoing functional differentiation. We also sought the mechanism of IGF-1 synergy with FSH. In this regard, our studies were unable to demonstrate a stabilizing effect of IGF-1 on P450scc mRNA, nor could IGF-1 augment FSH-induced transcription examined using a proximal region of the P450scc promoter (−379/+6). Thus, the mechanism of IGF-1 and FSH synergy remains enigmatic and provides a major challenge for future studies.

Transcriptional activation of the steroidogenic acute regulatory protein (StAR) gene : GATA-4 and CCAAT/enhancer-binding protein β confer synergistic responsiveness in hormone-treated rat granulosa and HEK293 cell models

Steroidogenic acute regulatory protein (StAR) mediates translocation of cholesterol to the inner membranes of steroidogenic mitochondria, where it serves as a substrate for steroid synthesis. Transcription of StAR in the gonads and adrenal cells is upregulated by trophic hormones, involves downstream signaling pathways and a cohort of trans-factors acting as activators or suppressors of StAR transcription. This study suggests that a 21 basepair long sequence positioned at -81/-61 of the murine StAR promoter is sufficient to confer a robust hormonal activation of transcription in ovarian granulosa cells treated with FSH. We show that recombinant GATA-4 and CCAAT/enhancer-binding protein beta (C/EBPbeta) bind to the promoter at -66/-61 and -81/-70 and activate transcription of a reporter gene when co-expressed in heterologous human embryonic kidney 293 (HEK293) cells. In this cell model, C/EBPbeta and GATA-4 synergize in a sequence dependent manner and p300/CBP further maximizes their joint activities. Inhibitors of the transcriptional activators, such as liver-enriched inhibiting protein (C/EBPbeta-LIP), Friend of GATA-4 (FOG-2) protein and the viral E1A protein abolished the respective factor-dependent activities in HEK293 cells. Binding assays suggest that a dual binding of C/EBPbeta and GATA-4 to the promoter depends on the molar ratio of the factors present while demonstrating GATA-4 predominant association with the promoter DNA. This pattern may reflect on StAR expression at the time of corpus luteum formation when C/EBPbeta levels peak, as does StAR expression.

Effects of disruption of the mitochondrial electrochemical gradient on steroidogenesis and the Steroidogenic Acute Regulatory (StAR) proteinProceedings of Xth International Congress on Hormonal Steroids, Quebec, Canada, 17–21 June 1998.

The steroidogenic acute regulatory (StAR) protein, which mediates cholesterol delivery to the inner mitochondrial membrane and the P450scc enzyme, has been shown to require a mitochondrial electrochemical gradient for its activity in vitro. To characterize the role of this gradient in cholesterol transfer, investigations were conducted in whole cells, utilizing the protonophore carbonyl cyanide m-chlorophenylhydrazone (m-CCCP) and the potassium ionophore valinomycin. These reagents, respectively, dissipate the mitochondrial electrochemical gradient and inner mitochondrial membrane potential. Both MA-10 Leydig tumor cell steroidogenesis and mitochondrial import of StAR were inhibited by m-CCCP or valinomycin at concentrations which had only minimal effects on P450scc activity. m-CCCP also inhibited import and processing of both StAR and the truncated StAR mutants, N-19 and C-28, in transfected COS-1 cells. Steroidogenesis induced by StAR and N-47, an active N-terminally truncated StAR mutant, was reduced in transfected COS-1 cells when treated with m-CCCP. This study shows that StAR action requires a membrane potential, which may reflect a functional requirement for import of StAR into the mitochondria, or more likely, an unidentified factor which is sensitive to ionophore treatment. Furthermore, the ability of N-47 to stimulate steroidogenesis in nonsteroidogenic HepG2 liver tumor cells, suggests that the mechanism by which StAR acts may be common to many cell types.

The life cycle of the steroidogenic acute regulatory (StAR) protein: from transcription through proteolysis.

The Steroidogenic Acute Regulatory (StAR) protein is a mitochondrial protein required for the transport of cholesterol substrate to the P450scc enzyme located in the inner mitochondrial membranes of steroid producing cells. This study suggests that the acute regulation of the rodent StAR gene in the ovary is mediated by two factors, C/EBPβ and GATA-4. Once translated, the StAR precursor protein is either imported into the mitochondria, or it is rapidly degraded in the cytosol. We predicted that in order to perpetuate StAR activity cycles, imported StAR should turn over rapidly to avoid a potentially harmful accumulation of the protein in sub-mitochondrial compartments. Pulse-chase experiments in metabolically labeled cells showed that: (a) the turnover rate of mature mitochondrial StAR protein (30 kDa) is much faster (t1/2 = 4–5 h) than that of other mitochondrial proteins; (b) dissipation of the inner membrane potential (−Δψ) by carbonyl cyanide m-chlorophenylhydrazone (mCCCP) accelerates the mitochondrial degradation of StAR; (c) unexpectedly, the mitochondrial degradation of StAR is inhibited by MG132 and lactacystin, but not by epoxomicin. Furthermore, StAR degradation becomes inhibitor-resistant two hours after import. Therefore, these studies suggest a bi-phasic route of StAR turnover in the mitochondria. Shortly after import, StAR is degraded by inhibitor-sensitive protease(s) (phase I), whereas at later times, StAR turnover proceeds to completion through an MG132-resistant proteolytic activity (phase II). Collectively, this study defines StAR as a unique protein that can authentically be used to probe multiple proteolytic activities in mammalian mitochondria.

Transcription of Steroidogenic Acute Regulatory Protein in the Rodent Ovary and Placenta: Alternative Modes of Cyclic Adenosine 3′, 5′-Monophosphate Dependent and Independent Regulation

Steroid hormone synthesis is a vital function of the adrenal cortex, serves a critical role in gonadal function, and maintains pregnancy if normally executed in the placenta. The substrate for the synthesis of all steroid hormones is cholesterol, and its conversion to the first steroid, pregnenolone, by the cholesterol side-chain cleavage cytochrome P450 (CYP11A1) enzyme complex takes place in the inner mitochondrial membranes. Steroidogenic acute regulatory protein (STAR) facilitates the rate-limiting transfer of cholesterol from the outer mitochondrial membrane to CYP11A1 located in the inner organelle membranes. The current study explored the mechanisms controlling transcription of the Star gene in primary cell cultures of mouse placental trophoblast giant cells and rat ovarian granulosa cells examined throughout the course of their functional differentiation. Our findings show that the cis-elements required for Star transcription in the rodent placenta and the ovary are centered in a relatively small proximal region of the promoter. In placental trophoblast giant cells, cAMP is required for activation of the Star promoter, and the cis-elements mediating a maximal response were defined as cAMP response element 2 and GATA. EMSA studies show that placental cAMP-responsive element binding protein (CREB)-1 and activating transcription factor-2 (ATF2) bind to a -81/-78 sequence, whereas GATA-2 binds to a -66/-61 sequence. In comparison, patterns of Star regulation in the ovary suggested tissue-specific and developmental controlled modes of Star transcription. During the follicular phase, FSH/cAMP induced CREB-1 dependent activity, whereas upon luteinization STAR expression becomes cAMP and CREB independent, a functional shift conferred by FOS-related antigen-2 displacement of CREB-1 binding, and the appearance of a new requirement for CCAAT enhancer-binding protein beta and steroidogenic factor 1 that bind to upstream elements (-117/-95). These findings suggest that during evolution, the promoters of the Star gene acquired nonconsensus sequence elements enabling expression of a single gene in different organs, or allowing dynamic temporal changes corresponding to progressing phases of differentiation in a given cell type.

Release of d-[3H]aspartate and [14C]GABA in rat hippocampus slices: effects of fatty acid-free bovine serum albumin and Ca2+ withdrawal

Extended incubation of hippocampus slices in the presence of fatty acid-free bovine serum albumin (FAF-BSA) strongly enhanced the release of D-[3H]aspartate and [14C]GABA induced by veratridine. Saturation of the FAF-BSA with oleic acid abolished the enhancing effect. Spontaneous release and K+-induced release were not significantly changed by the addition of FAF-BSA. Amino-oxyacetic acid in the medium enhanced the veratridine-induced release of D-[3H] aspartate. The spontaneous release of [14C]GABA was greatly increased by Ca2+ withdrawal. With the further addition of EGTA the spontaneous release in the absence of Ca2+ increased more than 8-fold over the measured in the presence of 1.5 mM Ca2+. The enhanced release caused by Ca2+ withdrawal was totally blocked by tetrodotoxin. The toxin was effective even when added after the spontaneous release in the absence of Ca2+ was already proceeding at a high rate. The veratridine-induced release of [14C]GABA was also considerably augmented by Ca2+ withdrawal. D-[3H]aspartate release, studied simultaneously with [14C]GABA by double labeling, did not show enhanced spontaneous release upon Ca2+ withdrawal. The findings provide evidence that the enhanced [14C]GABA release caused by Ca2+ withdrawal is mediated by voltage-dependent Na+ channels.

The four stereoisomers of a high potency congener of isoproterenol: Biological activity and the relationship between the native and the chemically inserted asymmetric carbon

The RR isomer of a para-trifluoromethyl anilide congener of isoproterenol (PTFMA) had an affinity eighty and one hundred times higher than (-)isoproterenol for the beta receptor of turkey erythrocytes and of S49 cells respectively. This affinity was also much higher than that of +/- hydroxybenzyl isoproterenol (HBI) tested in the same experiments. The chemically inserted asymmetric carbon seemed to be as important as the native asymmetric carbon of the catecholamines in determining the binding affinity. Thus the RS and SR isomers demonstrated similar affinities in the turkey erythrocyte membranes as well as in the S49 lysed cells. The RR isomer had the lowest Kact in activation of adenylate cyclase in both beta receptor systems. The three most potent PTFMA isomers showed a Kact/Kd ratio which was higher than that of (-)isoproterenol or (+/-)HBI. It is therefore possible that the large substituent on the amino group in PTFMA, which greatly increases the binding affinity, is not as efficient in receptor activation. Yet the RR isomer had a Kact considerably lower than that of (-)isoproterenol in both of the beta receptor systems. The type of beta receptor of the turkey erythrocyte could be distinguished from that of the S49 cells by comparing the relative order of affinities of the RS and SR isomers and also by comparing (+/-)HBI with (-)isoproterenol. A labeled RR isomer of PTFMA could become most useful as an agonist ligand for beta receptors because of its very high binding affinity for both beta 1 and beta 2 receptors.

Hybridization of Hormone Receptors with Adenylate Cyclase Systems of Different Cells

ABSTRACT Adenylate cyclase can be inactivated in the intact cell by N-ethylmaleimide or by heat while the hormone receptor remains functional. The hormone receptor in the treated cell can then be coupled to adenylate cyclase in another type of cell by fusing the two cells with each other (J. Orly and M. Schramm, Proc. Nat. Acad. Sci. U.S.A. 73 , 4410, 1976; M. Schramm, J. Orly, S. Eimerl and M. Korner, Nature 268 , 310, 1977). Protein synthesis is not required and it is therefore concluded that the newly formed system is constructed exclusively from the preexisting components. Thus, fusion of two different cell membranes produces a functional biochemical hybrid system in which the hormone receptor originating from one cell activates the adenylate cyclase originating from the other cell. Development of the concepts of receptor transfer and some very recent findings are also discussed. In the earlier experiments, both the β-adrenergic receptor and the prostaglandin E1 receptor have been successfully coupled with adenylate cyclase systems of various cultured cells. Studying the properties of the β-adrenergic receptor, it has been found that the dissociation constants for epinephrine, norepinephrine and propranolol do not change upon transfer of the receptor to a membrane of different properties. It is therefore thought that the dissociation constant is an intrinsic property of the receptor molecule which is not much influenced by the other natural components of the cell membrane. While the above studies involved measurement of adenylate cyclase activation in cell membranes prepared after fusion, function of the transferred receptor in the intact fused cell has also been demonstrated. Within 3 min. after onset of fusion the newly transferred β-adrenergic receptor is already able to cause an increase in intracellular cyclic AMP in response to hormone addition. The experiments indicate that the characteristic biological response of a cell to cyclic AMP can be induced by a foreign hormone receptor implanted in the membrane of that cell. Exploitation of the full potential of biochemical hybridization of membrane components requires that membranes of cells from any tissue could be readily fused with each other. Unfortunately, cell fusion by Sendai virus as used in the above noted work is limited to certain tissue-culture cells and erythrocytes. A new biochemical fusion method (non-viral) has therefore been developed. With the aid of this method the glucagon receptor of purified liver membranes has been successfully coupled to the adenylate cyclase of Friend erythroleukemia cells. It is thus demonstrated that even receptors for a peptide hormone in isolated membranes of a highly differentiated mamalian tissue can be transferred to the adenylate cyclase of a different cell. It is anticipated that hybridization of hormone receptors with adenylate cyclase of different cells will be used to analyze the function of these components in mutants and in diseased states. In addition, hormone receptors discovered by ligand binding could be tested for function by hybridization with a well characterized response system in the cell membrane of another type of cell. Obviously, this novel experimental approach need not be limited to hormone receptors coupled to the adenylate cyclase system. Other receptor-response systems could be analyzed by the same approach. In principle, it seems applicable to any dissociable multicomponent system residing in biological membranes.