Localization of the metabolic processes affected by calcium during corticotropin action

To define the role of calcium during corticotropin-induced steroidogenesis, adrenal sections were incubated under conditions of varying degrees of calcium depletion. Corticosterone production, [¹⁴C]leucine incorporation into protein, and tissue cyclic AMP levels were measured concomitantly. Omitting calcium from the incubation inhibited all three processes to variable extents, thus limiting conclusions regarding which process is most dependent on calcium.While calcium was required during the early phase of corticotropin action, it was not required during later phases; rapid induction of calcium defiency did not diminish the heightened rate of steroidogenesis previously induced by corticotropin in the presence of calcium. Thus, while calcium is required for induction of steroidogenesis factor(s), the operation of the latter is not dependent upon calcium in the extracellular fluid.     

Steroidogenesis in isolated adrenocortical cells. Correlation with receptor-bound adenosine 3′:5′-cyclic monophosphate

Because several groups have recently questioned a mediating role for cyclic AMP in adrenocortical steroidogenesis, we analysed the problem in more detail by measuring three different cyclic AMP pools in cells isolated from decapsulated rat adrenals. Extra-cellular, total intracellular and bound intracellular cyclic AMP were determined by radioimmunoassay in comparison with corticosterone production induced by low corticotropin concentrations. The increase in extracellular and total intracellular cyclic AMP with low corticotropin concentrations was dependent on the presence of a phosphodiesterase inhibitor and short incubation times. Bound intracellular cyclic AMP was less dependent on these two parameters. In unstimulated cells cyclic AMP bound to its receptor represents only a small fraction of the total intracellular cyclic AMP. After stimulation by a concentration of corticotropin around the threshold for corticosterone production, an increase in bound cyclic AMP was observed which correlated very well with steroidogenesis both temporally and with respect to corticotropin concentration. This finding was complemented by measuring a concomitant decrease in free receptor sites. Full occupancy of the receptors was not necessary for maximal steroidogenesis. Binding kinetics of cyclic [(3)H]AMP in concentrations equivalent to the intracellular cyclic AMP concentration suggest the presence of at least three different intracellular cyclic AMP pools. These observations are in agreement with a possible role for cyclic AMP as a mediator of acute steroidogenesis induced by low corticotropin concentrations.     

Mechanism of corticotropin action on adrenal protein synthesis. The effects of inhibitors of protein synthesis and calcium chelators

We have recently shown that beside a general stimulation of most adrenal proteins, corticotropin induces a marked increase in a specific adrenal cytosolic protein, protein E, in intact and hypophysectomized rats. To further clarify the mechanisms by which corticotropin exerts its trophic action we have investigated the effects of cycloheximide, calcium and calcium chelator administration on intact and hypophysectomized animals. These substances were injected in rats with or without corticotropin, and slices of adrenal glands from control and treated animals were removed 5 h later, incubated with [14C]- or [3H]-leucine for 2 h, and cytosolic proteins analyzed by polyacrylamide gel electrophoresis using a dual labelling technique. When high doses of cycloheximide (higher than 500 micrograms) were injected in rats, incorporation of labelled leucine in adrenal slices of control and corticotropin-treated animals was inhibited. With 500 micrograms cycloheximide per rat, incorporation of labelled leucine in adrenal slices of control animals was normal, but the corticotropin stimulation of both protein E and total protein synthesis was inhibited. Lower doses of cycloheximide (100 micrograms per rat) completely inhibited the stimulatory effect of corticotropin on total protein synthesis but did not affect protein E synthesis, while after 50 micrograms per rat both stimulatory effects were preserved. The two higher doses of cycloheximide (500 and 100 micrograms per rat) could not completely block the steroidogenic effect of the hormone. The effects of calcium and calcium chelators were studied in 1-day hypophysectomized rats. Calcium alone or injected simultaneously with corticotropin has no effect. Calcium chelators injected simultaneously with corticotropin partially inhibited the stimulatory effects of corticotropin on steroidogenesis but totally inhibited stimulation of total protein synthesis, while the stimulation of protein E persisted. Our results show that after corticotropin, stimulation of protein E synthesis correlates better with steroidogenesis than with total protein synthesis.     

Steroidogenic action of calcium ions in isolated adrenocortical cells

The corticotropin-induced increase of total intracellular and receptor-bound cyclic AMP in isolated rat adrenocortical cells was strictly dependent on extracellular Ca²⁺. A rise in bound cyclic AMP with rising Ca²⁺ concentrations was accompanied by a decrease in free cyclic AMP-receptor sites. A Ca²⁺-transport inhibitor abolished the rise in bound cyclic AMP induced by corticotropin. These data suggested that during stimulation by corticotropin some Ca²⁺ has to be taken up in order to promote the rise of the relevant cyclic AMP pool. In agreement with this view, adenylate cyclase activity from isolated cells proved also to be dependent on a sub-millimolar Ca²⁺ concentration in the presence of corticotropin and GTP. When cells were treated under specific conditions, corticosterone production could be activated by Ca²⁺ in the absence of corticotropin (cells primed for Ca²⁺). Ca²⁺-induced steroidogenesis of these cells, in the absence of corticotropin, was also accompanied by an increase in total intracellular and receptor-bound cyclic AMP, as was found previously with corticotropin-induced steroidogenesis in non-primed cells. Calcium ionophores increasing the cell uptake of Ca²⁺ were not able, however, to increase the cyclic AMP pools in non-primed cells, unlike corticotropin in nonprimed cells or Ca²⁺ in cells primed for Ca²⁺. It was concluded that during stimulation by either corticotropin or Ca²⁺ a possible cellular uptake of Ca²⁺ must be very limited and directed to a specific site which may affect the coupling of the hormone-receptor–adenylate cyclase complex.     

The role of calcium in luteinizing hormone-releasing hormone agonist (ICI 118630)-stimulated steroidogenesis in rat Leydig cells.

The luteinizing hormone-releasing hormone (LHRH) agonist ICI 118630 was found to increase testosterone production in purified rat testis Leydig cells in a concentration- and time-dependent manner, but no consistent changes in cyclic AMP levels were detectable. The stimulation of steroidogenesis by LHRH agonist was found to be dependent on the concentration of Ca2+ in the incubation medium; at least 1 mM was required. The calcium ionophore A23187 mimicked the effects of the LHRH agonist on steroidogenesis, and addition of both compounds together did not further increase testosterone production. The calcium ionophore caused a small increase in cyclic AMP which was independent of the concentration of the ionophore and of the calcium concentrations. The evidence obtained in this study indicates that LHRH agonist-stimulated steroidogenesis in rat testis Leydig cells is primarily mediated by calcium and not cyclic AMP.     

The effect of calcium concentration on ACTH stimulation of steroidogenesis in mouse adrenal tumor cells

Calcium is required for ACTH stimulated steroidogenesis in adrenal tumor cells in tissue culture. In the absence of calcium, the dose of ACTH required to induce half maximum steroidogenesis was increased 30 fold. In contrast to intact adrenal glands or isolated adrenal cells, high doses of ACTH (50 mU/ml) maximally stimulated steroidogenesis in the absence of calcium. Growth for up to six days in medium with low calcium did not affect basal or ACTH induced steroidogenesis. The addition of calcium to cells incubated with ACTH produced a maximum steroidogenic response in 15 minutes. In contrast to intact adrenal glands, calcium is not required for adenosine-3′,5′-cyclic monophosphate (cyclic AMP) stimulated steroidogenesis in adrenal tumor cells. These experiments support the concept that calcium is important at the level of ACTH-membrane receptor site interaction or activation of adenyl cyclase in adrenal tumor cells.     

ACTH diazotized to agarose: effects on isolated adrenal cells

ACTH coupled in an azo linkage to an agarose support induces steroidogenesis in free adrenal cells in the same manner as does free ACTH. Observation of incubates of adrenal cells and ACTH-agarose indicates that 1) agarose-ACTH is not adherent to the cell surface, 2) entrance of ACTH into the cell may not be a prerequisite to the initiation of steroidogenesis, 3) the continuous presence of ACTH is not necessary to maintain maximal steroid production in cellular incubates, and 4) induction does not alter the functional integrity of the bound corticotropin.     

Preparation and characterization of specifically tritiated adrenocorticotropin

The catalytic dehalogenation of iodinated derivatives of corticotropin in the presence of tritium was investigated. In 0.1 M acetic acid, complete and rapid removal of iodine was achieved in the presence of freshly prepared palladium or palladium oxide as catalyst, but the specific radioactivity of the product was only 10–20% of the theoretically attainable value. Synthetic human corticotropin containing a 3,5-diiodo tyrosine in position 23 in place of tyrosine was successfully dehalogenated in solvent mixture 0.1 M acetic acid : hexamethylphosphoramide : di dimethylformamide (1 : 10 : 90, v/v) in the presence of palladium oxide and calcium carbonate. The product was obtained in 30% yield after purification by carboxymethyl cellulose chroatography. The tritiated hormone had a specific radioactivity of 46 Ci/mmol (80% of the theoretical value) and was as potent as synthetic human corticotropin in stimulating steroidogenesis and lipolysis.     

Mechanisms of corticotropin action in rat adrenal cells. I. The effects of inhibitors of protein synthesis and of microfilament formation on corticosterone synthesis.

The contributions of protein synthesis and formation of microtubules and microfilaments to corticotropin-stimulated steroidogenesis in rat adrenal cell suspensions has been assessed by use of a series of inhibitors to each function. Five inhibitors of protein synthesis (cycloheximide, puromycin, blastocidin S, anisomycin, and trichodermin) each exhibited time-dependent inhibition of corticotropin-stimulated steroidogenesis. For the first 30 min, steroidogenesis was more extensively inhibited than protein synthesis, after which the effectiveness of the inhibitors diminished on steroidogenesis but not on protein synthesis. The reversal effect was not observed at high levels of inhibitors. One inhibitor of microfilament formation (cytochalasin B) and four inhibitors of microtubule formation (colchicine, podophyllotoxin, vinblastine sulfate and griseofulvin) inhibited steroidogenesis without inhibiting protein synthesis and without any reversal effect with prolonged incubation. The actions of all ten inhibitors were shown to be fully reversible. Cell superfusion of adrenal cells showed that the decay of steroidogenesis upon addition of all the protein synthesis inhibitors was similar to decay upon removal of corticotropin from the medium (t1/2 = 4--6 min). Recoveries from inhibition upon removal of the inhibitors were similar to each other and comparable to initial corticotropin stimulation of the cells (lag of 3--5 min, t1/2=7--9 min). Similar kinetics of inhibition and recovery were observed for vinblastine sulfate while a direct inhibition of cytochrome P-450scc by aminoglutethimide was complete within 1 min and was rapidly reversed. Injection of each inhibitor (all classes) into hypophysectomized rats inhibited the elevation of plasma corticosterone by corticotropin. The extent of cholesterol combination with cytochrome P-450scc in adrenal mitochondria isolated from these rats was also decreased by all of the inhibitors. Decreases in plasma corticosterone correlated directly with decreases in cholesterol combination with cytochrome P-450scc (r=0.94). It is concluded that protein synthesis and steroidogenesis must be intimately coupled probably due to the requirement of a labile protein for cholesterol transport to cytochrome P-450scc. An involvement of microtubules and microfilaments in this process is clearly indicated.     

The role of extracellular calcium in corticotropin-stimulated steroidogenesis

The role of extracellular Ca2+ in the binding of corticotropin (ACTH) to adrenocortical cell receptors as well as in the post-binding events involved in steroidogenesis were investigated. Binding studies using [125I-Tyr23,Phe2,Nle4]ACTH (1-38) peptide showed that extracellular Ca2+ is essential not only for the interaction of ACTH with its receptor, but also for continued occupancy of the receptor. In view of the requirement of Ca2+ for binding the hormone to the receptor, the role of Ca2+ in post-receptor events was investigated by covalently attaching the hormone to its receptor by photoaffinity labeling in the presence of Ca2+. Persistent activation of steroidogenesis induced by photoaffinity labeling in the presence of Ca2+ was depressed when cells were incubated in medium containing EGTA but was unaffected when the cells were merely washed and incubated in Ca2+-free medium. In the presence of EGTA, 8-Br-cAMP partially restored persistent activation of steroidogenesis. The concentration of extracellular Ca2+ required for restoring steroidogenesis was 10-fold lower than the concentration of Ca2+ needed for optimal binding of ACTH to its receptor. These results suggest that the primary role of extracellular Ca2+ in the action of ACTH is to facilitate the association of the hormone with its receptor.     

Modulation and role of Ca2+ in LH and LHRH agonist action in rat Leydig cells

The results of our recent studies on purified rat Leydig cells indicate that there are no major qualitative differences in the stimulating effects of LH and LHRH agonists on steroidogenesis via mechanisms that are dependent on calcium. This was demonstrated by using inhibitors of calmodulin and the lipoxygenase pathways of arachidonic acid metabolism. Using the fluorescent indicator quin-2, it was shown that LH and LHRH agonist increase intracellular calcium levels; LH was more potent than LHRH agonist (max increase in concentrations obtained were 500 nM and 60 nM respectively). This difference was probably the result of a direct effect of cyclic AMP (whose production is stimulated by LH but not by LHRH) because cyclic AMP analogues were as potent as LH in increasing calcium levels. These studies indicate a major role for calcium in the control of steroidogenesis in testis Leydig cells.     

Choleragen stimulates steroidogenesis and adenylate cyclase in cells lacking functional hormone receptors.

Choleragen stimulates steroid secretion and adenylate cyclase in three cell lines, adrenal tumor line (Y-1), a corticotropin-resistant mutant derived from Y-1 called OS-3, and a receptor-deficient Leydig tumor line (I-10). Sensitivity for half-maximal stimulation varies from 3 to 36 pM choleragen, the I-10 line being the most sensitive. Latency before the onset of steroidogenesis is longer in OS-3 and I-10 cells than in the Y-1 line. In both OS-3 and I-10 cells choleragen stimulates adenylate cyclase whether ITP or 5'-guanylylimidodiphosphate is the regulatory cofactor used. In addition to the responses of the receptor-deficient lines, choleragen does not, during its latency, block the response to corticotropin in Y-1 cells; corticotropin does not block binding of 125I-labeled choleragen to Y-1 cells; gangliosides do not interfere with the corticotropin-induced stimulation of Y-1 cells. We conclude that the corticotropin and choleragen receptors are different.     

Choleragen stimulates steroidogenesis and adenylate cyclase in cells lacking functional hormone receptors

Choleragen stimulates steroid secretion and adenylate cyclase in three cell lines, adrenal tumor line (Y-1), a corticotropin-resistant mutant derived from Y-1 called OS-3, and a receptor-deficient Leydig tumor line (I-10). Sensitivity for half-maximal stimulation varies from 3 to 36 pM choleragen, the I-10 line being the most sensitive. Latency before the onset of steroidogenesis is longer in OS-3 and I-10 cells than in the Y-1 line. In both OS-3 and I-10 cells choleragen stimulates adenylate cyclase whether ITP or 5′-guanylylimidodiphosphate is the regulatory cofactor used. In addition to the responses of the receptor-deficient lines, choleragen does not during its latency, block the response to corticotropin in Y-1 cells; corticotropin does not block binding of ¹²⁵I-labeled choleragen to Y-1 cells; gangliosides do not interfere with the corticotropin-induced stimulation of Y-1 cells.We conclude that the corticotropin and choleragen receptors are different.     

On the role of intra-adrenal unesterified cholesterol in the steroidogenic effect of corticotropin.

Since ACTH (corticotropin) increases intra-adrenal and intramitochondrial free cholesterol levels, the relative importance of these effects during ACTH-induced steroidogenesis was examined. Rats were treated in vivo with ACTH plus aminoglutethimide to increase free cholesterol (2--3-fold), and the latter was tested as a steroidogenic factor after removal of aminoglutethimide blockade and subsequent prolonged incubation of the cholesterol-rich adrenal sections in vitro. The increased free cholesterol served as a positive steroidogenic factor only during the early phase of the incubation when other ACTH-induced steroidogenic factors were operative. At later times of incubation, the increased free cholesterol did not, of itself, enhance steroidogenesis unless ACTH was added. These results suggest that the ACTH-induced enhancement of intraadrenal (and mitochondrial) free cholesterol may be important in determining the amount of steroids produced in response to a given ACTH stimulus, but another ACTH-induced factor is more important in initiating the steroidogenic process. This factor (? labile protein) appears to control a metabolic process which is distal to the mitochondrial uptake of free cholesterol.     

Relevance of c-fos proto-oncogene induction for the steroidogenic response to ACTH,dcAMP and phorbol ester in adrenocortical cells

We previously reported that ACTH, but not dibutyryl cAMP, rapidly induces the c-fos proto-oncogene in Y-1 adrenocortical cells.Here we show that PMA induces c-fos with similar kinetics when compared with ACTH (0.5–1 h peak) but reaches only 60% of the maximal ACTH induction and dcAMP is a weak c-fos inducer (15% of ACTH). However, combination of PMA and dcAMP has a synergistic effect leading to maximal c-fos induction. c-fos expression may play a role in the RNA synthesis-dependent corticosteroidogenesis response and/or growth regulation by ACTH.We also show that, in contrast to dcAMP, PMA is a poor steroidogenesis stimulator (15 to 17% of maximum ACTH-stimulated level), its activity being completely dependent on RNA synthesis. Combination of dcAMP and PMA yields an additive steroidogenesis stimulation, an effect that is also dependent on RNA synthesis. Although no strict correlation was found between c-fos induction and early steroidogenesis stimulation, particularly with respect to cAMP derivatives, the results suggest that a PKC pathway is likely to cooperate with the classical cAMP-PKA pathway in adrenal cells' RNA-dependent steroidogenesis.Abbreviations ACTH Adrenocorticotropic Hormone - PMA Phorbol-12-Myrystate-13-Acetate - dcAMP dibutyryl cyclic AMP - DME Dulbecco's Modified Eagle's minimal medium - FCS Fetal Calf Serum     

Endotoxic lipopolysaccharides stimulate steroidogenesis and adenylate cyclase in adrenal tumor cells.

Lipopolysaccharides (endotoxins) from Escherichia coli, Serratia marcesens and Salmonella typhosa stimulated steroid production in Y-1 adrenal tumor cells in culture with a latent period of 3-4 h. Lipid A, derived from Escherichia coli lipopolysaccharide, also stimulated steroidogenesis. Lipopolysaccharides and lipid A also stimulate adenylate cyclase activity and cause rounding of the cells. In contrast, lipopolysaccharides do not stimulate steroidogenesis in receptor-deficient adrenal tumor cells (OS-3) or Leydig tumor cells (I-10). This tends to rule out contamination by enterotoxin to which these lines respond. Although both hormone and lipopolysaccharide responses are lost in these lines, there was no interaction between these sites as judged by the failure of lipopolysaccharides to block, during their latency, the response to corticotropin in Y-1 cells. The possibility that the lipopolysaccharide effect is one on membrane conformation is discussed.     

Control of steroidogenesis in Leydig cells.

Luteinizing hormone (LH) interacts with its plasma membrane receptor to stimulate steroidogenesis not only via cyclic AMP but also other pathways which include arachidonic acid and leukotrienes and regulation of chloride and calcium channels. The same stimulatory pathways may lead to desensitization and down-regulation of the LH receptor and steroidogenesis. The LH receptor exists in a dynamic state, being truncated, or internalized, degraded or recycled. Desensitization is controlled by protein kinase C (PKC) in the rat and by cyclic AMP dependent protein kinase and PKC in the mouse Leydig cells. Using an adapted anti-sense oligonucleotide strategy we have shown that the cytoplasmic C-terminal sequence of the LH receptor is essential for desensitization to occur. In contrast, these sequences of the LH receptor are not required for the stimulation of cyclic AMP and steroid production. We have also shown that the extracellular domain of the LH receptor is secreted from the Leydig cell and may act as a LH-binding protein.     

Comparison of the calcium requirement for the induction and maintenance of B cell class II molecule expression and for B cell proliferation stimulated by mitogens and purified growth factors

As an important intracellular second-messenger, the concentration of calcium in the cytosol [Ca+2]i influences diverse cellular activities. To investigate the calcium requirement for distinct phases of B cell activation, we studied the effect of altering the quantity of extracellular calcium on the induction of increased B cell MHC class II molecule (Ia) expression and DNA synthesis by different B cell mitogens. During short-term cultures (less than 24 hr), the induction of class II molecules by anti-immunoglobulin (anti-Ig) and calcium ionophore were dependent on the presence of extracellular calcium, whereas activation induced by B cell stimulation factor-1 (BSF-1) was minimally dependent on extracellular calcium, and that induced by LPS was independent of it. During longer-term cultures (i.e., greater than 24 hr), the heightened class II molecule expression that was induced by all of the B cell mitogens used was significantly compromised by depletion of extracellular free calcium. Although the anti-Ig-stimulated increase in expression of Ia could be restored by the addition of calcium to the medium at 12 hr, it could not be restored when the addition of calcium was delayed to 24 hr after the onset of culture. This was in marked contrast to the finding that BSF-1-stimulated B cell responses which were suppressed after 24 hr of culture in the presence of EGTA could be restored by the addition of calcium. Activation of B cells along the pathway leading to DNA synthesis demonstrated a requirement for extracellular calcium which was greater than that required for induction of MHC class II molecule expression. Thus, LPS-stimulated size increases of B cells after 12 hr of culture was dependent on extracellular calcium while its induction of MHC class II molecule expression was independent of extracellular calcium at this early time point. These observations indicate that the extracellular calcium requirement for B cell activation is dependent both on the activation pathway utilized by the mitogenic signal and on the duration of cell activation. Furthermore, they demonstrate that B cell stimuli that can initiate B cell activation in the relative absence of extracellular calcium may require extracellular calcium for maintenance of this activational state.     

Effect of high and low density lipoproteins on corticotropin-mediated cortisol synthesis by bovine zona fasciculata cells

The role of bovine HDL and LDL in supporting corticotropin-stimulated steroidogenesis has been investigated, using acutely dispersed zona fasciculata cells. Using a dose of corticotropin sufficient to maximally stimulate steroidogenesis (in the absence of lipoproteins) both HDL and LDL increased steroidogenesis in a dose-dependent manner. At higher concentrations of lipoprotein, HDL caused approx 3-fold greater increase in steroid production than did LDL. Taken with the knowledge that HDL is the major cholesterol carrier in bovine serum, these findings suggest that in cattle HDL is a major source of cholesterol for steroidogenesis.