Effect of P-450scc inhibitors on corticosterone production by rat adrenal cells

Suspensions of rat adrenocortical cells produce corticosterone as the major glucocorticoid. Cholesterol side-chain cleavage, the initial and rate-limiting step in the glucocorticoid biosynthetic pathway, is catalyzed by P-450scc. We have examined the effect of a variety of P-450scc inhibitors on corticosterone production by isolated rat adrenocortical cells. These inhibitors include reversible, noncovalently interacting inhibitors as well as mechanism-based inhibitors which irreversibly inactivate P-450scc in vitro. (20S)-22-nor-22-thiacholesterol and (22R)-22-aminocholesterol cause 50% inhibition of corticosterone production at 4 microM and 30 nM, respectively. Inhibition by these compounds was essentially not time-dependent. (20R)-20-(1-hexynyl)-pregn-5-en-3 beta, 20-diol and (20R)-20-(1,5-hexdiynyl)-pregn-5-en-3 beta, 20-diol at 10 microM inhibited corticosterone production in a time-dependent manner, resulting in 30% inhibition of corticosterone production during a 100-min incubation. (20S)-20-(2-trimethylsilyl ethyl)-pregn-5-en-3 beta, 20-diol inhibited in a strongly time-dependent manner. At 10 microM this compound irreversibly inhibited more than 90% of the side-chain cleavage capacity of the cell during a 40-min incubation. Cells treated with this steroid did not regain their capacity for side-chain cleavage after removal of free steroid. None of the inhibitors described above inhibited production of corticosterone by cells supplied with pregnenolone, the product of the P-450scc reaction. We suggest that the only significant effect of these compounds under these conditions is inhibition of the side-chain cleavage enzyme.     

An oxidized metabolite of linoleic acid stimulates corticosterone production by rat adrenal cells

Oxidized derivatives of linoleic acid have the potential to alter steroidogenesis. One such derivative is 12,13-epoxy-9- keto-10-(trans)-octadecenoic acid (EKODE). To evaluate the effect of EKODE on corticosterone production, dispersed rat zona fasciculata/reticularis (subcapsular) cells were incubated for 2 h with EKODE alone or together with rat ACTH (0, 0.2, or 2.0 ng/ml). In the absence of ACTH, EKODE (26 microM) increased corticosterone production from 5.3 +/- 2.3 to 14.7 +/- 5.0 ng. 10(6) cells. h(-1). The stimulatory effect of ACTH was increased threefold in the presence of EKODE (26.0 microM). Cholesterol transport/P-450scc activity was assessed by measuring basal and cAMP-stimulated pregnenolone production in the presence of cyanoketone (1.1 microM). EKODE (13.1 and 26.0 microM) significantly increased basal and cAMP-stimulated (0.1 mM) pregnenolone production. In contrast, EKODE decreased the effect of 1.0 mM cAMP. EKODE had no effect on early or late-pathway activity in isolated mitochondria. We conclude that EKODE stimulates corticosterone biosynthesis and amplifies the effect of ACTH. Increased levels of fatty acid metabolites may be involved in the increased glucocorticoid production observed in obese humans.     

The influence of transcortin on adrenocorticotropin-stimulated corticosterone production in monolayer cultured rat adrenal cells

To verify the influence of the protein binding status of steroids adjacent to adrenal cells on steroidogenesis, the effect of transcortin, a specific binding protein of cortisol or corticosterone, on adrenocorticotropin (ACTH)-stimulated corticosterone production in monolayer cultured rat adrenal cells was studied. The transcortin in concentration of 5 x 10(-7) M was loaded with 0, 2.5, 5 and 10 pg/ml ACTH-(1-24), and the cells were incubated for 2 and 4 hours. Since molar concentrations of corticosterone produced in the medium were below the transcortin concentration at all levels of stimulation, protein-unbound corticosterone in the medium may have been largely reduced by the addition of transcortin. However, the total corticosterone production was not influenced by the transcortin added to the medium. It was speculated that protein-unbound steroid within the concentration range modulated by transcortin in the area surrounding the adrenal cells may not affect adrenal steroidogenesis.     

Effects of taktivin on corticosterone production by a suspension of mouse adrenal gland cells

The influence of the thymic hormone, not imported preparation, taktivin, on the corticosterone production by the mouse (females, BALB/c) isolated adrenocortical cells was investigated. Taktivin (0.08 and 2 micrograms/ml) reliably decreased corticosterone production by the intact cells. After stimulation of the cells by the adrenocorticotropin, the suppressive effect of the thymic hormone was expressed more strongly. On the background of ACTH (1.6 microIU/ml) taktivin (0.00064-0.4 microgram/ml) decreased corticosterone production to a basal level. When the cells were stimulated by ACTH (1600 microIU/ml) taktivin (0.000125-2 micrograms/ml) decreased corticosterone production to a marked degree. These facts witness the important role of taktivin polypeptide components in realization of cooperation between the immune and endocrine systems.     

Progesterone and testosterone production by dispersed rat placental cells

Isopycnic separation and unit gravity sedimentation were employed to identify the rat placental cell types capable of producing progesterone and testosterone. Subdivision of Day 12-dispersed placental cells in Percoll gradients revealed that fractions (less than 1.048 g/ml) containing giant cytotrophoblast cells produced greater quantities of progesterone (p less than 0.01) than did fractions (greater than 1.048 g/ml) with equal numbers of placental cells but void of giant cytotrophoblasts. Unit gravity sedimentation of Day 16-dispersed placental cells revealed that when incubated, isolated giant cytotrophoblast cells were capable of producing both progesterone and testosterone. Both of the separation studies strongly suggested that other cell types also produce steroids. However, the biosynthetic capacity of the giant cytotrophoblast cell appeared to be 1000-fold greater than that of the other cell types. Incubation of Day 12-dispersed placental cells with human chorionic gonadotropin or 3',5'-cyclic adenosine monophosphate did not further increase progesterone production as compared to untreated control incubates, suggesting rat placental steroidogenesis is not under trophic hormone control. Electron microscopic observations of giant cytotrophoblast cells revealed a complex ultrastructure suggesting a variety of physiological functions.     

Effect of ACTH on biosynthesis of aldosterone and corticosterone by monolayer cultures of rat adrenal zona glomerulosa cells

A method is described for preparing monolayer cultures of zona glomerulosa cells isolated from the rat adrenal cortex. Aldosterone and corticosterone were secreted by the cultures when maintained with medium containing 11 mM K⁺. ACTH, while stimulating aldosterone biosynthesis at first, did not maintain its long-term secretion, yet caused corticosterone production to rise to a steadily maintained level. The significance of this effect is discussed.     

Effects of ionophore A23187 on in vitro rat adrenal corticosterone production.

The administration of the ionophore A23187 to superfused rat adrenal cortical tissue slices resulted in a significant elevation in corticosterone production. Removal of calcium from the superfusion medium prevented this ionophore induced corticosteroidogenesis. Threshold amounts of ionophore potentiated the steroidogenic action of 1 mU but not 10 mU ACTH under $\text{in vitro}$ conditions. This potentiation by ionophore on ACTH stimulated steroid production was not observed when calcium was omitted from the superfusing medium. Potentiation by the ionophore on dbCAMP or CAMP stimulated steroid formation was not observed for any dose of cyclic nucleotide employed.     

beta-Endorphin stimulates corticosterone synthesis in isolated rat adrenal cells.

Studies are presented which demonstrate that β-endorphin induces corticosterone synthesis in isolated fasciculata cells. This activation of steroidogenesis has a lag period of 3 to 5 minutes and is cycloheximide-sensitive. The data suggest that β-endorphin exhibits steroidogenic activity by binding to the adrenocorticotropic hormone receptors of the cells.     

Okadaic acid interferes with lipoprotein-supported corticosterone production in adrenal cells.

Rat adrenocortical cells in culture respond to stimulation by ACTH alone (15 fold over basal) and to ACTH + added lipoproteins (as an exogeneous source of cholesterol), with an additional 25-30 fold rise in steroidogenesis. With the addition of okadaic acid (OKA, 100 nM), a potent protein phosphatase inhibitor, the lipoprotein-induced rise in steroidogenesis is blocked. If 20 alpha-hydroxycholesterol is provided instead of lipoprotein-cholesterol, OKA has no effect suggesting that OKA affects only actively transported cholesterol. Since the OKA block is preceded by specific morphological changes in the cell (i.e., the loss of Golgi-associated microtubules followed by the disruption of the Golgi apparatus itself), it is hypothesized that some OKA-sensitive phosphoprotein associated with the microtubule/Golgi network of adrenocortical cells is critical for lipoprotein-derived cholesterol uptake and/or transport during steroidogenesis.     

Effect of cyclosporin A on aldosterone production by dispersed rabbit adreno-capsular cells

The effect of cyclosporin A on aldosterone production by dispersed adreno-capsular cells from rabbit was examined. Cyclosporin A significantly stimulated aldosterone production at concentrations of 10(-7) M and 10(-6) M. The maximum stimulation of aldosterone production by cyclosporin A (at 10(-6) M) was comparable to that by angiotensin II at 10(-8) M). This stimulating effect of cyclosporin A on aldosterone production was not accompanied by an increase in cyclic AMP production, and was not inhibited by a calcium-channel blocker, nicardipine. These results suggest that the aldosterone-stimulating action of cyclosporin A at these concentrations is not mediated by a known second messenger system such as channel-linked Ca2+ inflow or cyclic AMP.     

The effects of corticotropin, opioid peptides and crude pituitary extract on the production of dehydroepiandrosterone and corticosterone by mature rat adrenal cells in tissue culture

In order to study the steroidogenic response to pituitary factors, a technique of monolayer tissue culture of mature female rat adrenal cells was used. During the first 24 h, rat adrenal cells produced dehydroepiandrosterone (DHEA) and small amount of corticosterone but in the absence of corticotropin (ACTH), the release of these two steroids were reduced to very low levels. The addition of synthetic alpha-ACTH-(1-24) [0.01-100 ng/ml] elicited a marked increase in the production of both steroids. This stimulating effect was not observed when synthetic methionine and leucine-enkephalins (1-100 ng/ml), human beta-endorphin (1-100 ng/ml) or human beta-lipotropin (1 ng/ml), were added to the culture medium. When these peptides were added concomitantly with alpha-ACTH (1-24) at half of the maximum response dose (1 ng/ml), no synergistic effect upon DHEA and corticosterone production was shown. The addition of crude extract from rat pituitary gland (1-100 ng/ml) with or without alpha-ACTH-(1-24) definitely showed both a stimulatory and synergistic effect upon the production of these two steroids. Furthermore, the ratio between DHEA production and corticosterone production was significantly higher when crude extract of the pituitary gland was given alone or concomitantly with alpha-ACTH(1-24) than when alpha-ACTH(1-24) was given alone. These data suggest the existence of a still undefined pituitary adrenal androgen stimulating which may preferentially stimulate DHEA production over corticosterone production.     

Aldosterone and corticosterone stimulation by ACTH in isolated rat adrenal glomerulosa cells: interaction with vasopressin

An interaction between ACTH and vasopressin on steroidogenesis was observed in isolated rat adrenal zona glomerulosa cell preparations. 1. The presence of 10(-11) M vasopressin further increased by 52% the output of aldosterone produced by 10(-12) M ACTH on those cells. 2. At a pharmacological concentration of ACTH (10(-7) M), the aldosterone output was increased 5 fold while the addition of 10(-12) M or 10(-8) M vasopressin decreased it by 17% and 48% respectively. 3. Vasopressin also produced a dose-dependent inhibition of the stimulatory effect of ACTH on the output of corticosterone. 4. We have thus shown for the first time, that vasopressin acts directly on adrenal zona glomerulosa cell preparations to modify the aldosterone output by modulating the action of ACTH. It is postulated that, in addition to other known aldosterone regulating factors, ACTH and vasopressin might synergistically act to regulate the secretion of aldosterone in vivo.