Hormonal and developmental regulation of the steroidogenic acute regulatory protein

A crucial event in the acute regulation of steroidogenesis by trophic hormones is the delivery of cholesterol into the mitochondria where it is converted to pregnenolone by the cholesterol side chain cleavage enzyme. Although considerable controversy exists regarding the exact mechanisms that underlie this acute response to hormone stimulation, recent studies suggest that the Steroidogenic Acute Regulatory (StAR) protein, a hormone-induced 30-kilodalton mitochondrial protein, plays an essential role. We now extend these studies by establishing in MA-10 mouse Leydig tumor cells a temporal relationship between levels of StAR expression and steroidogenesis in response to hormone stimulation. These data indicate that trophic hormones regulate StAR mRNA and protein within a time frame concomitant with the acute production of steroid hormones and provide the first evidence implicating changes in StAR transcription and/or mRNA stability in the functional response of steroidogenic cells to hormone action. In addition, in situ hybridization analyses of StAR expression in embryonic and adult mice demonstrated a precise spatial and temporal relationship in vivo between StAR expression and the capacity to produce steroid hormones. These experiments strengthen considerably the evidence that StAR is the key mediator of the acute induction of steroidogenesis and provide new insights into the mechanisms by which trophic hormones activate steroidogenesis in steroidogenic cells.

Steroidogenic factor 1 is the essential transcript of the mouse Ftz-F1 gene

Targeted disruption of the mouse Ftz-F1 gene, which encodes the orphan nuclear receptors steroidogenic factor 1 (SF-1) and embryonal long terminal repeat-binding protein (ELP), established that this gene is essential for development of the primary steroidogenic tissues and for male sexual differentiation. Associated with these dramatic developmental abnormalities, all Ftz-F1-disrupted mice died in the immediate postnatal period and had very low glucocorticoid levels. In this report, we show that treatment with corticosteroids markedly prolonged survival of the Ftz-F1-disrupted mice, proving that steroid hormone deficiency causes their death. We also generated SF-1-specific knockout mice with a targeting construct that specifically disrupted the SF-1 coding sequence without impairing the ELP protein. The phenotype of the SF-1-specific knockout mice was indistinguishable from that observed in Ftz-F1-disrupted mice that lack both SF-1 and ELP. Taken together, these results indicate that SF-1 is the Ftz-F1-encoded protein that is required for multiple aspects of endocrine development and for postnatal survival.

Cholesterol side-chain cleavage cytochrome P450 gene expression in the primitive gut of the mouse embryo does not require steroidogenic factor 1

In situ hybridization studies reveal novel sites of expression of cholesterol side-chain cleavage cytochrome P450 (P450scc) during murine embryonic development. In addition to fetal adrenals and testes, P450scc transcripts localize in situ to the primitive gut and to a subset of unidentified cells in the dermal mesenchyme of embryonic skin. In the gut, transcripts are most abundant in luminal epithelia of the hindgut, which will form the colon. P450scc transcript abundance at these novel sites is a fraction of that in fetal adrenals or testes, suggesting a local rather than an endocrine function. Immunocytochemical analyses localize P450scc protein to the fetal hindgut, indicating that the transcripts are translated in vivo. RNA isolated from microdissected embryonic hindgut and skin was reverse transcribed and amplified by polymerase chain reaction. DNA sequence analyses of polymerase chain reaction products confirmed that specific hybridization in situ represents authentic P450scc gene (Cyp11A) transcripts and that 3 beta-hydroxysteroid dehydrogenase/delta 5-->delta 4-isomerase transcripts are also present, demonstrating the potential of these fetal tissues to produce pregnenolone and progesterone. P450scc transcripts are also detectable by in situ hybridization in primitive gut and skin of Fushi tarazu factor 1 null mice, which lack the nuclear receptor steroidogenic factor 1, proving that steroidogenic factor 1 is not required for steroid hydroxylase gene expression at these sites. The capacity for C21 steroid biosynthesis in primitive gut and skin during organogenesis raises the question whether local production of steroid hormones may be required for normal cellular growth and differentiation of these tissues during embryogenesis.

The nuclear receptor steroidogenic factor 1 is essential for the formation of the ventromedial hypothalamic nucleus

The nuclear receptor steroidogenic factor 1 (SF-1) regulates the biosynthesis of the two essential mediators of male sexual differentiation, androgens and Müllerian-inhibiting substance, and is required for adrenal and gonadal development and gonadotropin expression. SF-1 is also expressed in the embryonic ventral diencephalon, subsequently localizing to the ventromedial hypothalamic nucleus, a region important for reproductive behavior. Mice lacking SF-1 secondary to targeted disruption of the Ftz-F1 gene had normal numbers and location of GnRH neurons but exhibited grossly impaired ventromedial hypothalamic nucleus structure. Despite their apparently normal GnRH neurons, treatment of Ftz-F1-disrupted mice with GnRH restored pituitary gonadotropin expression. These studies define SF-1's essential role within a discrete hypothalamic nucleus previously linked to reproduction.

A cell-specific nuclear receptor plays essential roles in adrenal and gonadal development

Recent analyses of the cytochrome P450 steroid hydroxylases have established a key role for an orphan nuclear receptor, designated steroidogenic factor 1 (SF-1), in their coordinate, cell-selective expression. SF-1 was proposed to regulate the steroid hydroxylases by interacting with shared promoter elements in their 5'-flanking regions. During mouse embryonic development, SF-1 was expressed from the earliest stages of organogenesis of the steroidogenic tissues, suggesting a key role in steroidogenic cell differentiation. Finally, disruption of the gene encoding SF-1 revealed its essential function in the development of the adrenal glands and gonads and in pituitary gonadotrope function. These studies suggest that SF-1 acts at multiple levels of the reproductive axis to maintain reproductive competence.

Adrenal-specific transgene expression and derivation of conditionally immortal rat adrenocortical cell lines

Conditional immortalisation of cells is a powerful tool for establishing in vitro models maintaining a differentiated phenotype. We are utilising this approach to derive cell lines that maintain the characteristics of glomerulosa and fasciculata cells of the adrenal cortex. Such cell lines should provide a system in which to study aspects of adrenocortical function that are relevant to hypertension, such as the effects of the renin-angiotensin system on steroidogenesis.

Homologs of Drosophila Fushi-Tarazu factor 1 map to mouse chromosome 2 and human chromosome 9q33

SF-1, a nuclear receptor that regulates gene expression of the cytochrome P450 steroid hydroxylases, and ELP, an embryonal protein that suppresses expression of the Moloney murine leukemia virus LTR, are isoforms transcribed from the same gene by alternative promoter usage and splicing. This gene is the mammalian homolog of the Drosophila fushi-tarazu factor 1 (FTZ-F1) gene. We have mapped the mouse gene Ftzf1 to the proximal quarter of Chr 2 by a linkage analysis using interspecific backcross mice, and its human homolog FTZ1 to Chr 9q33 by fluorescence in situ hybridization. The mouse and human genes are located in the homologous regions of mouse Chr 2 and human Chr 9, respectively.

Transcriptional regulation of the genes encoding the cytochrome P-450 steroid hydroxylases

Steroid hormone biosynthesis requires the concerted action of a related group of cytochrome P-450 steroid hydroxylases. In recent years considerable effort has been directed toward defining the molecular basis for the cell-selective expression of these genes and their transcriptional regulation by trophic hormones. The orphan nuclear receptor SF-1, acting through a conserved element found in the proximal promoter regions of all steroid hydroxylase genes, seems to be a major, but not exclusive, determinant of cell-selective gene expression. In contrast, the coordinate responses of the steroid hydroxylases to trophic hormones apparently involves an interplay of multiple proteins that collectively lead to a synchronous induction of gene expression. In some instances these interactions apparently involve transcription factors that also contribute to the cell-selective expression of these genes.

A cell-specific nuclear receptor regulates the steroid hydroxylases

Recent studies of the gene regulation of the cytochrome P450 steroid hydroxylases have established a key role for an orphan nuclear receptor, designated steroidogenic factor 1 (SF-1). SF-1 binds to shared promoter elements upstream of the steroid hydroxylases to mediate their coordinate expression in steroidogenic cells. Analyses of SF-1 expression during mouse embryonic development showed that SF-1 is expressed from the earliest stages of organogenesis of the steroidogenic tissues, suggesting an intimate link between SF-1 and steroidogenic cell differentiation. Finally, in gene disruption experiments, the gene encoding SF-1 was shown to be essential for development of the adrenal glands and gonads. These results establish the essential role of this orphan nuclear receptor in the development and function of the primary steroidogenic tissues.

The role of nuclear receptors in steroid hormone production

Epidemiological studies implicate steroid hormones as important factors in the development of neoplasia, and hormonal manipulation constitutes an important treatment arm in cancer therapy. Recent studies demonstrate a key role for nuclear receptor proteins in the expression of genes encoding the cytochrome P450 enzymes responsible for steroid hormone biosynthesis. Two orphan nuclear receptors, SF-1 and NGFI-B, regulate steroid hydroxylase transcription; the gene encoding SF-1 is also essential for adrenal and gonadal development. These results highlight the importance of specific nuclear receptors in regulating the enzymes that make essential steroid hormones and in the differentiation of the primary steroidogenic tissues. Ultimately, these nuclear receptors may provide new targets for the design of novel therapies for hormone-dependent cancers.

The nuclear receptor steroidogenic factor 1 acts at multiple levels of the reproductive axis

Steroidogenic factor 1 (SF-1), an orphan nuclear receptor, regulates the enzymes that produce sex steroids, and disruption of the Ftz-F1 gene encoding SF-1 precludes adrenal and gonadal development. We now study the role of SF-1 at other levels of the hypothalamic/pituitary/gonadal axis. In Ftz-F1-disrupted mice, immunohistochemical analyses with antibodies against pituitary trophic hormones showed a selective loss of gonadotrope-specific markers, supporting the role of SF-1 in gonadotrope function. In situ hybridization analyses confirmed these results; pituitaries from Ftz-F1-disrupted mice lacked transcripts for three gonadotrope-specific markers (LH beta, FSH beta, and the receptor for gonadotropin-releasing hormone), whereas they exhibited decreased but detectable expression of the alpha-subunit of glycoprotein hormones. SF-1 transcripts in the developing mouse pituitary, which first became detectable at embryonic day 13.5-14.5, preceded the appearance of FSH beta and LH beta transcripts. In adult rat pituitary cells, SF-1 transcripts colocalized with immunoreactivity for the gonadotrope-specific LH. Finally, SF-1 interacted with a previously defined promoter element in the glycoprotein hormone alpha-subunit gene, providing a possible mechanism for the impaired gonadotropin expression in Ftz-F1-disrupted mice. These studies establish novel roles of this orphan nuclear receptor in reproductive function.

Nuclear receptor steroidogenic factor 1 regulates the müllerian inhibiting substance gene: a link to the sex determination cascade

Normal male sex differentiation requires that Sertoli cells in the embryonic testes produce müllerian inhibiting substance (MIS), a TGF beta-like hormone that causes müllerian duct regression. In primary Sertoli cells, the orphan nuclear receptor, steroidogenic factor 1 (SF-1), regulates the MIS gene by binding to a conserved upstream regulatory element. In heterologous (HeLa) cells, MIS gene activation by SF-1 requires removal of the SF-1 ligand-binding domain, implicating a Sertoli cell-specific ligand or cofactor. Finally, the sexually dimorphic expression of SF-1 during development coincides with MIS expression and müllerian duct regression. We propose that SF-1 regulates MIS in vivo and participates directly in the process of mammalian sex determination.

A cell-specific nuclear receptor is essential for adrenal and gonadal development and sexual differentiation

Studies in adrenocortical cells have implicated the orphan nuclear receptor SF-1 in the gene regulation of the steroid hydroxylases. We used targeted disruption of the Ftz-F1 gene, which encodes SF-1, to examine its role in intact mice. Despite normal survival in utero, all Ftz-F1 null animals died by postnatal day 8; these animals lacked adrenal glands and gonads and were severely deficient in corticosterone, supporting adrenocortical insufficiency as the probable cause of death. Male and female Ftz-F1 null mice had female internal genitalia, despite complete gonadal agenesis. These studies establish that the Ftz-F1 gene is essential for sexual differentiation and formation of the primary steroidogenic tissues.

Developmental expression of mouse steroidogenic factor-1, an essential regulator of the steroid hydroxylases

As an initial step toward understanding its role in steroidogenesis, we studied the developmental profile of steroidogenic factor-1 (SF-1), a nuclear receptor that regulates the steroid hydroxylases. SF-1 transcripts first appear on embryonic day 9 (E9) in the urogenital ridge, the probable source of steroidogenic cells of both adrenals and gonads. By E11, after the adrenals and gonads are clearly separate, SF-1 transcripts are detected throughout the adrenal primordium. Thereafter, adrenal expression of SF-1 localizes to the cortex. Consistent with its proposed role in regulating cholesterol side-chain cleavage enzyme (SCC), SF-1 is expressed before SCC. During the sexually undifferentiated stage of gonadal development (E9-E12), all embryos express SF-1 in the genital ridge. As testicular cords form in males, SF-1 transcripts are diffusely expressed throughout the testis, whereas SCC mRNA is limited to the interstitium. These differences between SF-1 and SCC reflect SF-1 expression by Sertoli cells, as shown by Northern blotting and in situ hybridization. In contrast to its persistent expression in the embryonic testis, SF-1 transcripts disappear from the ovary between E13.5-E16.5, reappearing only during late gestation (E18.5). Thus, expression of SF-1 in the embryonic gonad is sexually dimorphic. Coupled with the demonstration of SF-1 mRNA in Sertoli cells, these data suggest that SF-1 plays a role in gonadal development distinct from regulating the steroidogenic enzymes. Additionally, SF-1 is expressed in the embryonic forebrain, implying a role in neural development.

Steroidogenic factor-1 binding and transcriptional activity of the cholesterol side-chain cleavage promoter in rat granulosa cells

The cholesterol side-chain cleavage cytochrome P450 (CYP11A; P450scc) gene is expressed in rat ovarian follicles in response to gonadotropins (FSH/LH) and cAMP. To identify functional regions within the rat P450scc promoter, 894 basepairs (bp) of 5'-flanking sequence and 5'-deletions (at -379, -101, -73, and -38 bp) were linked to the human GH reporter gene and transfected into cultured rat granulosa cells. cAMP inducibility of the rat promoter was localized to a region (between -73/-38 bp) that contains one of two AGGT/CC/TA motifs, designated SCC1 (-51/-43 bp) and SCC2 (-79/-71 bp), within the rat promoter. One of the nuclear proteins in granulosa cells that binds to SCC1 was identified as the orphan receptor, steroidogenic factor-1 (SF-1). In contrast, multiple protein-DNA complexes formed with SCC2, only one of which was clearly identified as SF-1. Nuclear extract binding was sequence specific; SCC1 bound SF-1 more strongly than did SCC2. Thus, the two AGGT/CC/TA motifs of the rat promoter appear to differ structurally and functionally. Furthermore, because the expression of SF-1 mRNA precedes hormonal/cAMP induction of P450scc mRNA and is not regulated in vitro by cAMP, the functional role of SF-1 in transcriptional regulation of the P450scc gene, including its induction by cAMP, is not entirely clear and is probably dependent on other factors and/or the modification (phosphorylation?) of SF-1.

Spatial-frequency-tuned channels in early infancy: VEP evidence

Spatial frequency (SF) adaptation of 3-, 6-, and 12-week-old infants produced changes in steady-state VEP amplitude to SF sweeps that closely resemble post-adaptation changes reported previously in adults. Following SF adaptation, VEP amplitude was attenuated to SFs near the adapting SF, and enhanced at SFs removed from the adapting SF in all age groups. This is interpreted as evidence for bandpass SF-tuned channels with coinhibitory interactions. The data presented here, in combination with VEP estimates of infant acuity, imply the existence of multiple bandpass SF-tuned channels with inhibitory relationships by 3 weeks of age. We hypothesize that neonatal spatial frequency filters are qualitatively adultlike.

Disorders of puberty: a practical imaging approach

The child presenting with abnormal pubertal development elicits great parental concern and presents a diagnostic challenge to the managing pediatrician. The appropriate workup of children with disorders of pubertal development relies heavily on the synthesis of history, physical examination, pertinent laboratory tests, and medical imaging. This review addresses female and male disturbances in pubertal development and includes isosexual and heterosexual precocious puberty and delayed development. Discussion is focussed on the tailored algorithmic approach to imaging; integrating clinical and laboratory information. Bone-age determination, ultrasonography, and MRI are emphasized as they relate to this complex and challenging clinical problem.

Characterization of the mouse FTZ-F1 gene, which encodes a key regulator of steroid hydroxylase gene expression

The cytochrome P450 steroid hydroxylases are coordinately regulated by steroidogenic factor 1 (SF-1), a protein expressed selectively in steroidogenic cells. Based on its expression in steroidogenic tissues and DNA-binding specificity, we isolated a putative SF-1 cDNA from an adrenocortical cDNA library. As evidence that this cDNA encodes SF-1, we now show that it is selectively expressed in steroidogenic cells, that an antiserum against its protein product specifically abolishes the SF-1-related gel-shift complex, and that its coexpression increases promoter activity of the 21-hydroxylase 5'-flanking region in transfection experiments. Sequence analyses of the SF-1 cDNA revealed that it is the mouse homolog of fushi tarazu factor I (FTZ-F1), a nuclear receptor that regulates the fushi tarazu homeobox gene in Drosophila. A second FTZ-F1 homolog, embryonal long terminal repeat-binding protein (ELP), was recently isolated from embryonal carcinoma cells. SF-1 and ELP cDNAs are virtually identical for 1017 base pairs, including putative DNA-binding domains, but diverge at their 5'- and 3'-ends. One genomic clone contained both SF-1- and ELP-specific sequences, confirming their origin from a single gene. Characterization of this gene defined shared exons encoding common regions and alternative promoters and 3'-exons leading to differences between the two FTZ-F1 transcripts. We used in situ hybridization with transcript-specific probes to study the ontogeny of SF-1 and ELP expression. ELP transcripts were not detected from embryonic day 8 to adult, consistent with its previous isolation from embryonal carcinoma cells and its postulated role in early embryonic development.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth hormone in the treatment of growth failure in children after renal transplantation

Growth failure continues to be a problem in the management of children with renal failure. Children have improved growth after successful renal transplantation, but seldom have "catch-up" growth, or achieve normal adult height. Several investigators have reported the use of rhGH in children after renal transplantation and demonstrated improved height, growth velocity, and standard deviation score (SDS). We review the existing literature, present additional data from our center, and offer possible explanations.

Characterization of the mouse FTZ-F1 gene, which encodes a key regulator of steroid hydroxylase gene expression

The cytochrome P450 steroid hydroxylases are coordinately regulated by steroidogenic factor 1 (SF-1), a protein expressed selectively in steroidogenic cells. Based on its expression in steroidogenic tissues and DNA-binding specificity, we isolated a putative SF-1 cDNA from an adrenocortical cDNA library. As evidence that this cDNA encodes SF-1, we now show that it is selectively expressed in steroidogenic cells, that an antiserum against its protein product specifically abolishes the SF-1-related gel-shift complex, and that its coexpression increases promoter activity of the 21-hydroxylase 5'-flanking region in transfection experiments. Sequence analyses of the SF-1 cDNA revealed that it is the mouse homolog of fushi tarazu factor I (FTZ-F1), a nuclear receptor that regulates the fushi tarazu homeobox gene in Drosophila. A second FTZ-F1 homolog, embryonal long terminal repeat-binding protein (ELP), was recently isolated from embryonal carcinoma cells. SF-1 and ELP cDNAs are virtually identical for 1017 base pairs, including putative DNA-binding domains, but diverge at their 5'- and 3'-ends. One genomic clone contained both SF-1- and ELP-specific sequences, confirming their origin from a single gene. Characterization of this gene defined shared exons encoding common regions and alternative promoters and 3'-exons leading to differences between the two FTZ-F1 transcripts. We used in situ hybridization with transcript-specific probes to study the ontogeny of SF-1 and ELP expression. ELP transcripts were not detected from embryonic day 8 to adult, consistent with its previous isolation from embryonal carcinoma cells and its postulated role in early embryonic development.(ABSTRACT TRUNCATED AT 250 WORDS)

Steroidogenic factor 1, an orphan nuclear receptor, regulates the expression of the rat aromatase gene in gonadal tissues

In a concerted analysis of the genes encoding three mouse steroid hydroxylases, we identified and characterized a transcriptional regulatory protein, designated steroidogenic factor 1 (SF-1), that contributes to the coordinate expression in adrenocortical cells. SF-1, an orphan member of the nuclear receptor family, binds to PyCAAGGPyCPu motifs upstream of the steroid hydroxylases to regulate their expression. In the present study, we extend these findings by examining the role of SF-1 in regulation of the rat P450 aromatase gene in gonadal tissues. The 5'-flanking region of the rat aromatase gene was isolated by a polymerase chain reaction-based approach, using primers corresponding to the 5'- and 3'-ends of a published aromatase sequence. DNA sequence analysis revealed three differences between our sequence and the previously published sequence, including a 44-base pair (bp) insertion. Moreover, the transcription initiation site, as determined by primer extension analysis, differed from that previously proposed. The new transcription initiation site is located 23 bp 3' of a putative TATA box. When a revised rat sequence was compared to that of the human aromatase PII promoter by BEST-FIT analysis, a region of about 300 bp was identified that was 80% conserved between the two promoters. A potential SF-1 site, CCAAGGTCA, was identified at position -82 within this region. An oligonucleotide probe containing this putative SF-1 site was used in gel mobility shift assays. Consistent with previous studies, a specific complex was observed with nuclear extracts from gonadal steroidogenic tissues but was absent with nuclear extracts from nonsteroidogenic tissues. The role of SF-1 in this steroidogenic cell-specific complex was next addressed more directly. Bacterial extracts containing an SF-1-glutathione S-transferase fusion protein interacted specifically with the putative SF-1 site, and polyclonal antisera against SF-1-glutathione S-transferase specifically abolished the complex formed with nuclear extracts from rat ovaries or R2C rat Leydig tumor cells. Finally, the aromatase SF-1 element increased expression of an SV40 promoter/luciferase construct in transient transfection experiments in a steroidogenic cell-selective manner. Collectively, these studies implicate SF-1 in the regulation of steroid hydroxylase gene expression in nonadrenal tissues, significantly extending previous studies in adrenocortical cells.

Transcriptional regulation of the adrenal steroidogenic enzymes

Corticosteroid biosynthesis requires the concerted action of a related group of cytochrome P450 steroid hydroxylases. The genes encoding these steroid hydroxylases exhibit two distinct levels of transcriptional regulation: selective expression in steroidogenic cells and induction in response to trophic hormones. With respect to cell-selective expression, recent studies have identified a nuclear receptor protein expressed only in steroidogenic cells that is postulated to regulate the expression of all cytochrome P450 steroid hydroxylases through common promoter elements. In contrast, the coordinate responses of these genes to trophic hormones are not readily explained by a unifying mechanism, and their hormone responsive expression probably involves multiple promoter elements.

Treatment of growth failure in children after renal transplantation

Growth failure continues to be a problem in the management of children with renal failure. Children have improved growth after successful renal transplantation, but seldom have "catch-up" growth, or normal adult height. In this study we report the findings of an open label pilot study to determine the safety and efficacy of the use of recombinant human growth hormone (rhGH) in children with growth failure after successful renal transplantation. Eleven children completing at least 1 year of treatment had a mean age of 11.5 years (+/- 3.3) and mean bone age of 8.4 years (+/- 2.4), and were significantly growth-retarded (mean standard deviation score of -3.18 [+1.1]). After receiving rhGH (0.05 mg/kg) subcutaneously each day the height velocity increased from 5.2 cm/year to 8.4 cm/year (P = 0.003), and the standard deviation score improved from -3.18 to -2.23 (P = 0.004). Treatment was associated with advancement in Tanner stage from 1 to 2.8 (P = 0.004), increased bone age from 8.4 years to 10.9 years (P = 0.0002), and although it was not at the point of statistical significance, moderate decrease in creatinine clearance from 75 ml/1.73m2/min to 60 ml/1.73m2/min (P = 0.1). The advancement in Tanner stage and bone age was not out of proportion to the advancement in height age. These data suggest that children with functioning renal allografts have improved growth with supraphysiologic doses of rhGH.

Identification of promoter elements in the mouse 21-hydroxylase (Cyp21) gene that require a functional cyclic adenosine 3',5'-monophosphate-dependent protein kinase

The constitutive and cAMP-induced expression of the mouse steroid 21-hydroxylase gene (Cyp21) are impaired in adrenal cell mutants harboring mutations in cAMP-dependent protein kinase (cAMPdPK). These requirements for a functional cAMPdPK have been mapped to the proximal 330 basepairs of the Cyp21 promoter. This study attempts to identify specific promoter elements of Cyp21 that require cAMPdPK for constitutive activity by comparing their abilities to enhance the expression of a reporter gene in Y1 adrenocortical tumor cells and Y1 Kin mutants defective in cAMPdPK activity. As determined in transient transfection assays, Cyp21 promoter elements at -65, -140, -170, -210, and -280 each enhanced the expression of a human GH reporter gene in parent Y1 cells. The relative order of effectiveness of each of these elements was: -170 >> -280 > -140 > -65 > or = -210. The -170 element was 25-fold more effective in enhancing gene expression from the reporter construct in Y1 cells than in Kin mutant cells; the elements at -65, -140, and -210 were 3-fold more effective in Y1 cells than in Kin mutant cells; the -280 element was equally effective in the parent and Kin mutant clones. These studies suggest that the promoter elements at -170, -65, -140, and -210 mediate the requirement for a functional cAMPdPK in the expression of Cyp21. As determined by gel mobility shift assays with these elements, the dependence of the Cyp21 promoter elements on a functional cAMP-dependent protein kinase did not result from decreased expression or binding affinities of their respective DNA-binding proteins.(ABSTRACT TRUNCATED AT 250 WORDS)