The influence of plasma lipoproteins on steroidogenesis of cultured ovine fetal and neonatal adrenal cells

Scavenger receptor class BI and selective cholesteryl ester uptake: partners in the regulation of steroidogenesis

The steroidogenic tissues have a special requirement for cholesterol, which is used as a substrate for steroid hormone biosynthesis. In many species this cholesterol is obtained from plasma lipoproteins by a unique pathway in which circulating lipoproteins bind to the surface of the steroidogenic cells and contribute their cholesteryl esters to the cells by a 'selective' process in which the whole lipoprotein particle does not enter the cell. This review describes the lipoprotein selective cholesteryl ester uptake process and its specific partnership with the HDL receptor, scavenger receptor class BI (SR-BI). It describes the characteristics of the selective pathway, and the molecular properties, localization, regulation, anchoring sites and potential mechanisms of action of SR-BI in facilitating cholesteryl ester uptake by steroidogenic cells.

Apolipoprotein A-I is required for cholesteryl ester accumulation in steroidogenic cells and for normal adrenal steroid production

In addition to its ability to remove cholesterol from cells, HDL also delivers cholesterol to cells through a poorly defined process in which cholesteryl esters are selectively transferred from HDL particles into the cell without the uptake and degradation of the lipoprotein particle. The HDL-cholesteryl ester selective uptake pathway is known to occur in human, rabbit, and rodent hepatocytes where it may contribute to the clearance of plasma cholesteryl ester. The selective uptake pathway has been studied most extensively in steroidogenic cells of rodents in which it accounts for 90% or more of the cholesterol destined for steroid production or cholesteryl ester accumulation. In this study we have used apo A-I-, apo A-II-, and apo E-deficient mice created by gene targeting in embryonic stem cells to test the importance of the three major HDL proteins in determining cholesteryl ester accumulation in steroidogenic cells of the adrenal gland, ovary, and testis. apo E and apo A-II deficiencies were found to have only modest effects on cholesteryl ester accumulation. In contrast, apo A-I deficiency caused an almost complete failure to accumulate cholesteryl ester in steroidogenic cells. These results suggest that apo A-I is essential for the selective uptake of HDL-cholesteryl esters. The lack of apo A-I has a major impact on adrenal gland physiology causing diminished basal corticosteroid production, a blunted steroidogenic response to stress, and increased expression of compensatory pathways to provide cholesterol substrate for steroid production.

Ontogenesis of cholesterol side-chain cleavage activity in the ovine adrenal during late gestation

The present study examined the activity of the cholesterol side-chain cleavage system, and the amount of cytochrome P450scc in adrenal glands of sheep fetuses and newborn lambs as well as the in vitro regulation of these parameters. Freshly isolated fetal adrenal cells incubated in the presence of 1 mM 8Br-cAMP or 25 microM 22R-OH cholesterol, produced 4- to 5-fold less pregnenolone than neonatal cells under similar conditions. Likewise, pregnenolone production by isolated fetal adrenal mitochondria was lower than that of neonatal mitochondria when endogenous cholesterol was used as a substrate or when 22R-OH cholesterol was added to the incubation medium. Also, the amount of P450scc, determined by immunoblot, was lower in fetal mitochondria than in neonatal mitochondria. In culture, ACTH, despite enhancing both the production of pregnenolone and the incorporation of [14C]acetate in cholesterol and its end-products by fetal adrenal cells, neither increased the amount of pregnenolone formed from 22R-OH cholesterol nor the amount of immunoreactive P450scc. By contrast, during the first 48 h of culture under standard conditions, there was a "spontaneous" increase in the activity of P450scc which reached values observed in neonatal adrenal cells. Such a development was inhibited when 5% ovine fetal serum was added to the culture medium. These results reinforce the view that in the ovine fetal adrenal gland, the development of P450scc is not ACTH-dependent but involves most probably a decrease in inhibitory factors present in fetal blood.

The role of bovine lipoproteins in the regulation of steroidogenesis and HMG-CoA reductase in bovine adrenocortical cells

The sources of cholesterol for steroid hormone production were examined using bovine adrenocortical (BAC) cells in primary culture. The experiments were designed to determine the effects of lipoproteins on cortisol production and the level of BAC cell 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase. Most studies on BAC cell lipoprotein requirements have been conducted using human low-density lipoprotein (hHDL); none have used the homologous bovine lipoproteins. BAC cells treated with corticotropin (ACTH) in a medium devoid of lipoproteins increased and maintained cortisol production 7- to 20-fold above basal levels. Under such conditions ACTH also increased the rate of HMG-CoA reductase activity. Inhibition of HMG-CoA reductase with mevinolin inhibited cortisol production by 85%, indicating that the cells were using cholesterol synthesized de novo for steroid production. Cortisol production was increased almost 40-fold above basal levels if hLDL (100 micrograms/ml) was included in the incubation medium. Human LDL also suppressed the levels of HMG-CoA reductase in a concentration-dependent fashion. Human HDL was without effect on either BAC cell steroidogenesis of HMG-CoA reductase. Addition of bovine LDL (bLDL) to the incubation medium also caused an increase in cortisol production and inhibited cholesterol synthesis. By contrast to hHDL, bHDL (100 micrograms/ml) increased the ability of BAC cells to produce cortisol production. Bovine HDL (bHDL) also was able to decrease HMG-CoA reductase, but not to the extent caused by hLDL or bLDL. These data demonstrate that bovine adrenal cells can use bHDL as a source of cholesterol for steroid hormone production. These findings may be of particular importance when one considers that in vivo, the bHDL content of bovine serum greatly surpasses the level of bLDL.

Glucocorticoid enhancement of glucocorticoid production by cultured ovine adrenocortical cells

The present study examines the effect of chronic treatment with glucocorticoids on the steroidogenic activity of ovine adrenocortical cells in vitro. Cells cultured in the presence of 10(-9) to 10(-5) M dexamethasone produced more glucocorticosteroids in response to ACTH1-24, forskolin or 8 BrcAMP than did control cells. Such an enhancing effect required more than 5 h of treatment and was maximal at 30 h; it was both concentration-dependent and steroid-specific. The maximal secretion of corticosteroids was observed when cells were exposed to 10(-7) M dexamethasone; with higher concentrations the response to ACTH1-24 decreased steadily; the ED50 was 2.8 +/- 0.8 nM. Cortisol and corticosterone enhanced ACTH1-24-induced steroidogenesis to the same extent as dexamethasone, but at concentrations roughly 100-fold higher than for dexamethasone. Testosterone and 17 beta-oestradiol had no enhancing effect. Dexamethasone not only enhanced the maximal steroidogenic response to ACTH1-24 but also decreased its ED50 3-fold. Treatment of cultures with the antiglucocorticoid RU 38486 resulted in a dose-dependent, time-dependent, decrease in ACTH1-24-induced corticosteroid output. Moreover, RU 38486 antagonized the enhancing effect of dexamethasone. The production of corticosteroids by dexamethasone-treated cells incubated in the presence of 22(R)-hydroxycholesterol or of exogenous pregnenolone was similar to that of control cells. The enhancing effect of dexamethasone was also observed when cultures were performed in the absence of insulin and/or in serum-free media. These data suggest that chronic exposure to glucocorticoids is necessary for the full steroidogenic activity of ovine adrenocortical cells. Moreover, they indicate that glucocorticoids exert their effect at least at two different levels in the cell: (i) on the adenylate cyclase system and (ii) at step(s) beyond cAMP but before pregnenolone formation.

De novo synthesis of cholesterol by ovine fetal and neonatal adrenocortical cells

The present study compared the stocks of cholesterol present in adrenal cells from 120-day-old ovine fetuses and from newborn lambs, as well as the capacity of these cells to regulate their stock by de novo synthesis from C2 units. Both free cholesterol and cholesteryl ester concentrations of mitochondrial fractions of adrenal glands from fetuses were lower than those from newborn lambs. In addition, the 3-hydroxy-3-methylglutaryl-coenzyme A reductase (HMG-CoA reductase) and the cholesterol side-chain cleavage activities were 2- and 5-fold lower, respectively, in fetal than in neonatal adrenals. After 2 days of culture in serum-free media, the cellular contents of cholesterol were similar in control and ACTH1-24-treated cells for both fetuses and newborns. Moreover, ACTH1-24 increased HMG-CoA reductase activity of both fetal and neonatal cells to the same extent. When cells were cultured in the presence of 2% horse serum, the cellular content of cholesterol on day 2 was enhanced only in the case of neonatal cells, but [14C]acetate incorporation in free cholesterol was decreased in both fetal and neonatal cells, while its incorporation in cholesteryl ester was increased. The presence of serum in the medium prevented the enhancing effect of ACTH1-24 on the fetal HMG-CoA reductase activity but had no effect on that of neonatal cells. These data, together with preceding results, suggest that the low stores of cholesterol of ovine fetal adrenal cells result from a limited capacity to synthesize cholesterol and to some alteration in the uptake and/or metabolism of plasma lipoproteins, which in turn might reflect the low steroidogenic capacity of these cells.

Optimizing testosterone production by purified adult rat Leydig cells in vitro

We sought to establish conditions that increased the duration of testosterone production by fully differentiated adult rat Leydig cells in primary culture. A freshly isolated suspension of highly purified adult rat Leydig cells produced 83 ng testosterone/10(6) Leydig cells.h-1 when incubated in Medium 199 in a 1.5 ml microfuge tube with shaking for 3 h with a maximally stimulating concentration of ovine luteinizing hormone (LH). Unfortunately, adult rat Leydig cells that were allowed to attach only to a plastic culture dish flattened out, and testosterone production diminished rapidly. Leydig cells in Dulbecco's modified Eagles' medium-Ham's F12 (1:1; vol/vol) containing Cytodex 3 beads pre-equilibrated in culture medium containing fetal bovine serum attached to the beads and remained viable, but produced only 30 ng testosterone/10(6) Leydig cells.h-1 when incubated for 24 h with similar stimulation. Leydig cells similarly cultured and maximally stimulated with LH, responded to bovine lipoproteins (less than 1.222 g/ml) producing 105 ng of testosterone/10(6) Leydig cells.h-1 when incubated with 1 mg/ml bovine lipoprotein. Therefore, lipoproteins maintain the steroidogenic capacity of purified adult rat Leydig cells in primary culture for 24 h.