Lyne Ducharme

Phosphorylation and function of the hamster adrenal steroidogenic acute regulatory protein (StAR)

In order to study the effect of phosphorylation on the function of the steroidogenic acute regulatory protein (StAR), 10 putative phosphorylation sites were mutated in the hamster StAR. In pcDNA3.1-StAR transfected COS-1 cells, decreases in basal activity were found for the mutants S55A, S185A and S194A. Substitution of S185 by D or E to mimic phosphorylation resulted in decreased activity for all mutants; we concluded that S185 was not a phosphorylation site and we hypothesized that mutations on S185 created StAR conformational changes resulting in a decrease in its binding affinity for cholesterol. In contrast, the mutation S194D resulted in an increase in StAR activity. We have calculated the relative rate of pregnenolone formation (App. V(max)) in transfected COS-1 cells with wild type (WT) and mutant StAR-pcDNA3.1 under control and (Bu)(2)-cAMP stimulation. The App. V(max) values refer to the rate of cholesterol transported and metabolized by the cytochrome P450scc enzyme present in the inner mitochondrial membrane. The App. V(max) was 1.61 +/- 0.28 for control (Ctr) WT StAR and this value was significantly increased to 4.72 +/- 0.09 for (Bu)(2)-cAMP stimulated preparations. App. V(max) of 5.53 (Ctr) and 4.82 ((Bu)(2)-cAMP) found for S194D StAR preparations were similar to that of the WT StAR stimulated preparations. At equal StAR quantity, an anti-phospho-(S/T) PKA substrate antibody revealed four times more phospho-(S/T) in (Bu)(2)-cAMP than in control preparations. The intensity of phosphorylated bands was decreased for the S55A, S56A and S194A mutants and it was completely abolished for the S55A/S56A/S194A mutant. StAR activity of control and stimulated preparations were diminished by 73 and 72% for the mutant S194A compared to 77 and 83% for the mutant S55A/S56A/S194A. The remaining activity appears to be independent of phosphorylation at PKA sites and could be due to the intrinsic activity of non-phosphorylated StAR or to an artefact due to the pharmacological quantity of StAR expressed in COS-1. In conclusion we have shown that (Bu)(2)-cAMP provokes an augmentation of both the quantity and activity of StAR, and that an enhancement in StAR phosphorylation increases its activity. The increased quantity of StAR upon (Bu)(2)-cAMP stimulation could be due to an augmentation of its mRNA or protein synthesis stability, or both; this is yet to be determined.

The in Vivo Effects of Adrenocorticotropin and Sodium Restriction on the Formation of Different Species of Steroidogenic Acute Regulatory Protein in Rat Adrenal

We have studied the in vivo expression of steroidogenic acute regulatory protein (StAR) in adrenals of control, ACTH-treated, and Na+-restricted rats. Indirect immunofluorescence by microscopy revealed the presence of StAR in the zonae glomerulosa (ZG) and fasciculata-reticularis (ZFR). An increased signal was observed in the ZG and zona fasciculata, 5 h after ACTH injection; a few cells of the medulla were also positive. Immunogold electron microscopy showed that StAR was mainly located over mitochondria (MT). By immunoblotting, a major 29-kDa and other minor StAR bands migrating between 30 and 39 kDa were increased 5 h after ACTH treatment but remained unchanged after 1 h. By two-dimensional-PAGE, four StAR species were revealed in homogenates of control ZG, and their intensity was increased 5 h after ACTH treatment but not after 1 h. Also, additional acidic species were seen 5 h after treatment. Other bands with basic isoelectric point were revealed between 29 and 37 kDa. Analyses on whole gland MT and...

The hamster adrenal cytochrome P450C11 has equipotent 11β-hydroxylase and 19-hydroxylase activities, but no aldosterone synthase activity

We have isolated a hamster adrenal P45OC11 cDNA which shared 90 and 84% homology, respectively, with the nucleotide sequence and the amino acid sequence of the hamster adrenal P450aldo. Both P450C11 and P450aldo cDNA coding sequences were inserted in the plasmid pBluescript SK, transcribed and then translated using a rabbit reticulocyte system in the presence of [35S]methionine. The reaction products were immunoprecipitated with an anti-bovine P450C11 antibody for P450C11 and with an anti-hamster P450aldo for P450aldo. Immunoprecipitated proteins were analyzed by polyacrylamide gel electrophoresis. A single 35S-labeled protein band was detected for P450C11 and for P450aldo, respectively. P450C11 and P450aldo cDNAs were then both inserted into the expression vector pCMV5 containing a viral sequence specific for the attachment of ribosomes to mRNA. These constructions were transfected in COS-1 cells. 24 h after transfection, the presence of P450C11 and P450aldo mRNAs was determined by Northern blot analysis. In a time study experiment we found that P450C11 transformed the labeled-steroid into [14C]corticosterone, [14C]19-OH-deoxycorticosterone and [14C]18-OH-deoxycorticosterone in ratios of 1:1.11:0.07, after 2 h of incubation; no [14C]aldosterone could be detected. Cells transfected with plasmids harboring the P450aldo cDNA transformed [14C]deoxycorticosterone to [14C]corticosterone, [14C]aldosterone, [14C]18-OH-corticosterone, [14C]18-OH-deoxycorticosterone, [14C]19-OH-deoxycorticosterone and [14C]11-dehydrocorticosterone in ratios of 1:0.25:0.45:0.04:0.04:0.04 after 12 h of incubation. These results indicate that one P450 catalyzes the ultimate step of glucocorticoid formation and a separate P450 is involved in the final steps of aldosterone formation in hamster adrenals. The capacity of the hamster adrenal P450C11 to hydroxylate at positions 11beta and 19 in nearly equal ratio makes this animal an excellent model to study the mechanism of synthesis and inhibition of 19-OH-deoxycorticosterone, the precursor of 19-nor-deoxycorticosterone, a very potent mineralocorticoid involved in the development of essential hypertension.

ADRENOCORTICOTROPIN REGULATES THE LEVEL OF THE STEROIDOGENIC ACUTE REGULATORY (STAR) PROTEIN MRNA IN HAMSTER ADRENALS

In this study, we report the cloning of a StAR cDNA from a hamster adrenal cDNA library. The library was screened using a PCR fragment specific for the hamster adrenal StAR cDNA. Several clones of different lengths were obtained and one of these was sequenced. Northern blotting analysis revealed the presence of the StAR mRNA in male and female adrenals, in tests and ovaries, but not in the liver or kidneys of either sex. Whole hamster adrenals revealed the presence of four mRNAs of 0.65, 1.7, 3.1 and 5.25 kb, respectively. In addition, ACTH regulates the expression of StAR mRNA in hamster adrenals. Indeed, when groups of hamsters were injected with ACTH and sacrificed at different times after treatment, only the 0.65 kb form of the StAR mRNA did not increase, whereas the other forms increased at varying levels. These results might suggest that the expression of the StAR protein in hamster adrenals depends upon different genes, different promoters, or different polyadenylation signal sites. In conclusion, these results indicate that in vivo, StAR is regulated by ACTH, suggesting the participation of this protein in controlling the transformation of cholesterol to pregnenolone, a key regulatory step in corticosteroidogenesis.

The Regulation of the Formation of Glucocorticoids and Mineralocorticoids In Vivo

Publisher Summary This chapter discusses the regulation of the formation of glucocorticoids and mineralocorticoids in vivo . Recent findings clearly demonstrate a different regulation for the biosynthesis of glucocorticoids and mineralocorticoids. The renin–angiotensin system is the main regulator of aldosterone synthesis. Recent findings have also clearly established that a low sodium or high potassium intake are factors that control the expression of the early and final steps of mineralocorticoid formation. It is suggested that adrenocorticotropin (ACTH) is the principal factor involved in the control of glucocorticoid biosynthesis and secretion, whereas many other factors participate in mineralocorticoid metabolism. ACTH binds to specific cell membrane receptors and induces the formation of cyclic adenosine monophosphate (cAMP) and the activation of protein kinase A. At short term, ACTH activates the transport and the availability of cholesterol to mitochondrial P450scc to facilitate the formation of pregnenolone. The synthesis of new P450scc protein does not appear necessary, at least for the short term effect of ACTH. It is suggested that a predominant role is played by P450 17α in the control of glucocorticoid synthesis.

P450ALDO IN HAMSTER ADRENAL CORTEX: IMMUNOFLUORESCENT AND IMMUNO-GOLD ELECTRON MICROSCOPIC STUDIES

The zonal distribution of aldosterone synthase cytochrome P450 (P450aldo) in the adrenal cortex of male hamsters was investigated by immunofluorescence and electron microscopy, using an anti-P450aldo peptide antibody. On cryostat sections the immunolocalization of P450aldo was confined to the zona glomerulosa cells. On semi-thin plastic sections, P450aldo was shown to be located in mitochondria. Studies in electron microscopy, using the colloidal gold technique, confirmed that P450aldo was located in mitochondria.

in vivo Effects of adrenocorticotropin on C-JUN, JUN-B, C-FOS and FOS-B in rat adrenal.

We have studied the in vivo effects of adrenocorticotropin (ACTH) on mRNA levels of c-jun, jun-B, c-fos and fos-B, in rat adrenals. In control rats, c-jun mRNA was abundant in both zona glomerulosa (ZG) and zona fasciculatareticularis (ZF-R). Although less abundant than c-jun, the mRNA of jun-B could be detected in both zones, whereas that of c-fos could barely be detected and that of fos-B could not. After an injection with short acting ACTH, mRNA levels of c-jun, c-fos, jun-B and fos-B were maximally increased in both zones within 30 min. Within 5h, the mRNA levels decreased towards control levels for c-jun, to below control levels for jun-B, and to undetectable levels for c-fos and fos-B. After a sustained stimulation by two daily administrations of long acting ACTH, the mRNA of c-jun was still abundant in both zones, although its level decreased by 50% and 80% after 36h and 9 days, respectively, after the first injection. Under such conditions, the mRNA level of jun-B was increased, that of fos-B could barely be detected, and that of c-fos could not be detected. To conclude, these results suggest that jun-B, fos-B, and also c-fos play a role in triggering early events leading to an increased steroidogenesis, as well as a basic role in maintaining the integrity of the adrenal cortex in the case of c-jun and jun-B.

A family of two patients with congenital lipoid adrenal hyperplasia due to StAR mutation

We are reporting the case of two sisters born to nonrelated French Canadian parents. Patient A is of female phenotype with 46,xy, and patient B with 46,xx. The children had severe manifestations of mineralocorticoid deficiency at the age of 11 and 4.5 months, respectively. Residual cortisol secretion seemed present until the age of 3 years for patient A and until 15 months in the case of her sister. Both patients responded to glucocorticoid and Florinef treatment. Patient A did not show any androgen secretion and gonadectomy was performed at the age of 13.4 years; estrogen therapy was started at the age of 14 years resulting in a good breast development and an increase of growth velocity. In patient B, a progressive development of secondary sex characters occurred at 11.6 years of age followed at 14 years by menarche associated with a normal secretion of LH, FSH and estradiol; regular menstruations continued up to her last visit at the age of 25 years. We identified a homozygous L275P mutation on the StAR gene of both patients and a heterozygous L275P mutation on that of their mother and father. In transfection analysis in COS‐1 cells, the mutant L275P was well‐expressed, but its StAR activity was 87% impaired. The remaining activity of the L275P StAR mutant is consistent with the moderate severity of clinical onset of manifestations.

Acute in vivo effects of acth on the expression of steroidogenic acute regulatory protein in rat adrenal

We have studied the effects of adrenocorticotropin (ACTH) on the expression of steroidogenic acute regulatory protein (StAR) in rat adrenals in vivo. Following ACTH stimulation, the level of StAR mRNA was increased within 1 h in zona glomerulosa (ZG) and zona fasciculata-reticularis (ZFR), with a maximum increase at 3 h. The increase in StAR protein was delayed when compared to its mRNA. The increase in the mitochondrial StAR protein at 3 h was concomitant with that of the homogenate indicating that the entry of StAR into mitochondria might not be necessary to increase steroidogenesis during the early stimulatory phase. In conclusion, we showed that ACTH increases StAR mRNA followed, after a delay, by an increase in the level of StAR protein; this suggests that post-translational modifications of StAR precursor occur during the early stimulatory phase and this occurs before the apparent translation of the newly formed mRNA.

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+. AngiotensinII (AII) 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 AII, 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 AII and ACTH on adrenal cytochrome P-450(11 beta) involved in the last steps of aldosterone formation were evaluated by combined in vivo and in vitro experiments. The P-450(11 beta) 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 AII differentially regulate P-450(11 beta). It is postulated that these two regulatory peptides regulate the hamster adrenal steroidogenesis by different P-450 genes.