Role of cyclic AMP and protein kinase on the steroidogenic action of ACTH, prostaglandin E1 and dibutyryl cyclic AMP in normal adrenal cells and adrenal tumor cells from humans.

The role of the cyclic AMP-protein kinase system in mediating the steroidogenic effect of ACTH, prostaglandin E1 and dibutyryl cyclic AMP, induced similar stimulations of protein kinase activity, cyclic AMP was studied using human adrenal cells isolated from normal and adrenocortical secreting tumors. At high concentrations of ACTH, complete activation of protein kinase of normal adrenal cells was observed within 3 min, at the time when cyclic AMP production was slightly increased and there was still no stimulation of steroidogenesis. At supramaximal concentrations, ACTH, PGE1 and dibutyryl cyclic AMP and cortisol productions in adrenal cells isolated from normal and from one adrenocortical tumor. In one tumor in which the adenylate cyclase activity was insensitive to ACTH, the hormone was unable to stimulate protein kinase or steroidogenesis, but the cells responded to both PGE1 and dibutyryl cyclic AMP. In another tumor in which the adenylate cyclase was insensitive to PGE1, this compound also did not increase protein kinase activity or steroidogenesis, but both parameters were stimulated by ACTH and dibutyryl cyclic AMP. After incubation of normal adrenal cells with increasing concentrations of ACTH (0.01-100 nM) marked differences were found between cyclic AMP formation and cortisol production. However at the lowest concentrations of ACTH exerting an effect on steroid production a close linked correlation was found between protein kinase activation and cortisol production, but half-maximal and maximal cortisol production occurs at lower concentration of ACTH than was necessary to induce the same stimulation of protein kinase. Similar findings were found after incubating the adrenal cells with dibutyryl cyclic AMP (0.01-10 mM). The results implicate an important role of the cyclic AMP-protein kinase system during activation of adrenal cell steroidogenesis by low concentrations of steroidogenic compounds.     

Effects of dibutyryl cyclic AMP and cytochalasin B on cultured human glioma cells.

Cultured human glioma cells (138 MG) exposed to dibutyryl cyclic AMP (dbc-AMP; 0.1--5 mM) attained an arborized shape with thin processes extending from a rounded cell body. Cytochalasin B (CB; 1--1 muM) induced similar morphological changes. The processes in both dbc-AMP and CB treated cells were formed by retraction of the cell margin. Colchicine (1muM) completely and liver treated phalloidin (0.1 mg/ml) partially inhibited the morphological alterations induced by dbc-AMP and CB. Dbc-AMP was found to arrest cell movement, cell division and uptake of 2-deoxy-D-glucose. CB has the same effects but was more potent. The effects of dbc-AMP and CB could be due to interference with a common cellular structure, e.g. microfilaments.     

Cinemicrographic observations of cultured adrenocortical tumor cells. Dynamic responses to ACTH and cytochalasin B

ACTH increases the basal steroidogenic activity of cultured adrenocortical tumor cells, whereas moderate-high doses of cytochalasin B (CB) inhibit both basal and ACTH-induced steroidogenesis. Previous ultrastructural studies have revealed that ACTH rearranges microfilaments in these adrenal cells, whereas CB causes microfilaments to aggregate into felt-like masses. It has been postulated that the ACTH effects may facilitate organelle motility and increase organelle interactions that are required for steroid biosynthesis, and that the CB-created "foci" may impede or prevent the organelle meetings. To shed light on these possibilities, we have employed 16 mm cinemicrography of unstimulated adrenal tumor cells and cells incubated for 1-2 h with ACTH (10 mU/ml), or low (10 micrograms/ml), or high (50 micrograms/ml) doses of CB. ACTH caused initial increases in membrane ruffling and a "flurry" of particle (organelle) activity above that seen in unstimulated cells. The stimulated cells then retracted from each other and began their characteristic "rounding up" in response to the hormone. Particles appeared to move towards the nucleus, and in fully-rounded cells were extremely congested. Steroid production rose several fold above basal levels. CB10 produced slight-marked cell convexities, nearly stopped particle motility and inhibited steroid production moderately. CB50 produced an asymmetrical, spidery cell form, stopped membrane ruffling and particle motility and abolished steroidogenesis. After a washout of CB50, particle motility resumed nearly immediately. Our CB data indicate that associations between particles, presumably between mitochondria and various sources of cholesterol, are prerequisite for basal steroidogenesis in the adrenal tumor cells. In ACTH-stimulated cells, increases in steroid output correspond with increased opportunities for particle associations. These opportunities appear to arise directly or indirectly from ACTH effects on microfilaments. The responses of microfilaments to the hormone may be particularly intense in tumorous forms. By these means, the cells may express their differentiated function, although their cytoplasm has a distinctly unspecialized appearance.     

Response of adrenal tumor cells to adrenocorticotropin: site of inhibition by cytochalasin B.

The ability of cytochalasin B to inhibit the steroidogenic response of mouse adrenal tumor cells (Y-1) to adrenocorticotropin (ACTH) was examined with two aims: to consider the specificity of the inhibitor and to determine at what point(s) in the steroidogenic pathway it acts. Cytochalasin B did not inhibit protein synthesis or transport of [3H]-cholesterol into the cells nor did it alter total cell concentration of ATP. Together with previous evidence, this suggests that the effects of cytochalasin observed are relatively specific in these cells. Cytochalasin inhibits the increase in conversion of [3H]cholesterol to 20alpha-[3H]dihydroprogesterone (20alpha-hydroxypregn-4-en-3-one: a major product of the steroid pathway in Y-1 cells) produced by ACTH but does not inhibit conversion of cholesterol to pregnenolone by mitochondrial and purified enzyme preparations from Y-1 cells and bovine adrenal, respectively. Cytochalasin does not inhibit the conversion of pregnenolone to 20alpha-dihydroprogesterone but was shown to inhibit increased transport of [3H]cholesterol to mitochondria resulting from the action of ACTH. These findings indicate that cytochalasin acts after cholesterol has entered the cells and before it is subjected to side-chain cleavage in mitochondria. In view of the known action of cytochalasin on microfilaments, it is proposed that these organelles are necessary for the transport of cholesterol to the mitochondrial cleavage enzyme and that at least one effect of ACTH (and cyclic AMP) is exerted upon this transport process. The specificity of the effects of cytochalasin is considered in relation to this conclusion.     

Role of actin in the responses of adrenal cells to ACTH and cyclic AMP: inhibition by DNase I

Erythrocyte ghosts were loaded with pancreatic DNase I and fused with Y- 1 adrenal tumor cells to test the possibility that this enzyme might inhibit the steroidogenic responses of the cells to ACTH and cyclic AMP. Fusion of erythrocyte ghosts loaded with DNase I, but not those containing albumin, ovalbumin, boiled DNase I, or DNase I with excess G- actin, inhibited the increase in production of 20 alpha- dihydroprogesterone produced by ACTH and dibutyryl cyclic AMP; inhibition was concentration-dependent with 50% inhibition by 3 X 10(7) molecules of DNase I per cell. It was found that inhibition by DNase I was exerted at the step in the steroidogenic pathway at which cholesterol is transported to mitochondria where steroidogenesis begins. This was shown by measuring transport of cholesterol into the inner mitochondrial membrane, by measuring the production of pregnenolone by isolated mitochondria and by demonstrating that DNase I was without effect on the conversion of pregnenolone to 20 alpha- dihydroprogesterone (an end-product of steroid synthesis). The actin content of Y-1 cells was measured by two methods based upon inhibition of DNase I and by SDS gels following centrifugation. The cells were found to contain 2-3 X 10(7) molecules of actin per cell of which two- thirds is present as G-actin. Since DNase I is known to bind to G-actin to give a one to one complex, these and other findings suggest that at least some of the G-actin in the cells may be necessary for the steroidogenic responses to ACTH and cyclic AMP.     

Effect of cyclic AMP and cytochalasin B on tissue cultured melanophores of Xenopus laevis

The effects of cytochalasin B or low concentrations of adenosine 3′,5′-monophosphate (cyclic AMP) were tested on melanophores in hanging drop preparations of neural fold explants from Xenopus laevis embryos in Barths' solution. After one week in culture, the melanophores were punctate in this medium. Cyclic AMP at 5 mM consistently caused reversible morphological transformation of these cells to the stellate state, whether they were situated within an epithelial outgrowth or isolated on the surface of the coverglass. Only the isolated melanophores consistently responded to 1 mM cyclic AMP. Cytochalasin B at 1–10 μg/ml caused aggregation of melanin granules in stellate cells, but left long, narrow cell branches containing some melanosomes. Its effect was at least partially reversible and appeared to be dose dependent. At 1% concentration, dimethyl sulfoxide caused melanin dispersion.     

The reversibility of the effects of ACTH and cytochalasin B on the ultrastructure and steroidogenic activity of adrenocortical tumor cells in vitro

We have demonstrated previously that the steroidogenic activity of ACTH on cultured adrenal tumor cells is associated with cell rounding and a rearrangement of microfilaments. Cytochalasin B (CB) also induces cell rounding, but changes the conformation of microfilaments and severely inhibits steroidogenesis. ACTH and CB may have different modes of action on the contractile machinery which are related to their opposing actions on steroidogenesis. To investigate this possibility further, we have examined the reversibility of the morphological and functional effects of these agents. Cultures were incubated for 1 hr, with and without ACTH (10 microU/ml of media), or with CB (50 micrograms/ml), or with both agents simultaneously. After a media wash, the cultures were incubated for 1 hr, with and without ACTH. The steroid production of the cells during pre- and post-washout incubations was determined, and some cultures were fixed for electron microscopy at the end of both incubation periods. The three- to ten-fold increases in steroidogenic activity of ACTH-stimulated cells declined during recovery incubations, but remained well above basal values. These cells nearly reflattened and began to regain stress fibers which had been 'pulled apart'. The 'washed out' ACTH-stimulated cells were often refractory to restimulation. Cells recovering from CB also reflattened. Masses of filamentous felt induced by the drug disappeared from the cytoplasm, lost microvilli reappeared and stress fibers reformed. The 20-50% inhibition of basal steroidogenesis by CB was completely reversed. When ex-CB-treated cells were incubated with ACTH, their morphology and steroid production were typical of acutely stimulated cells. The recovery behavior of cells incubated with ACTH and CB simultaneously reflected the observation that there were cell-specific responses to one agent or the other during initial incubations. The persistence of heightened steroidogenic activity following a washout of ACTH and the rapid reversal of the effects of CB strongly support the concept that regulated actomyosin interactions are an integral part of the steroidogenic process.     

Angiotensin II potentiates the effect of ACTH on the production of cyclic AMP by bovine adrenal cells in primary culture

The effect of Angiotensin II (AII) on ACTH-induced cyclic AMP production was studied in bovine adrenocortical cells cultured in a chemically defined serum-free medium. Immediately after collagenase dispersion, AII did not modify either the basal or the ACTH-induced cAMP production by the isolated cells. During cell culture, AII alone did not affect cAMP production. But 2 days after plating, AII increased significantly the ACTH-induced cAMP production by the culture. This potentiating effect increased with the age of culture. Sar1Ala8AII (Saralasin), a potent AII antagonist, inhibited the AII potentiating effect indicating an AII specific action.     

Isolated adrenal cortex cells: ACTH agonists, partial agonists, antagonists; cyclic AMP and corticosterone production

Isolated adrenal cortex cells respond to the addition of ACTH_1–39 or analogs with increased production of cyclic AMP and corticosterone. It is estimated that cyclic AMP production need proceed at less than 20% of maximum to induce maximum corticosterone production. ACTH_1–24, [Lys¹⁷, Lys¹⁸]ACTH_1–8 amide, and ACTH_1–16 amide induce a maximum rate of cyclic AMP and of corticosterone production equal to those of ACTH_1–39. The relative potencies as determined by cyclic AMP and by corticosterone production are in excellent agreement. The analog, ACTH_5–24, induces maximum cyclic AMP production equal to 45% of that of the natural hormone, but as predicted, induces maximum corticosterone production equal to that of ACTH_1–39. The derivative, [Trp(Nps)⁹]ACTH_1–39 induces 77% of maximum corticosterone production and less than 1% of maximum cyclic AMP production. The fragment ACTH_11–24 is a competitive antagonist of ACTH_1–39 for both cyclic AMP and corticosterone production. The observations on agonists, a partial agonist and a competitive antagonist are in harmony with the “second messenger” role assigned to cyclic AMP. A provisional model, based on the fit of the experimental observations to a set of equations, provides expressions of “intrinsic activity,” “receptor reserve”, “sensitivity”, and “amplification” in terms of maximum cyclic AMP production, concentration of ACTH which induces $\text{1}\text{2}$ maximum cyclic AMP production and concentration of cyclic AMP which induces $\text{1}\text{2}$ maximum corticosterone production.     

Effects of ACTH and calcium on cyclic AMP production and steroid output by the zona glomerulosa of the adrenal cortex.

Effects of ACTH and calcium on cyclic AMP production and steroid output by the zona glomerulosa (the capsular fraction) from the rat adrenal cortex have been studied. Although high concentrations of extracellular calcium potentiated the stimulatory action of ACTH on cyclic AMP and aldosterone output, tetracaine or verapamil inhibited aldosterone output but not cyclic AMP production during ACTH-stimulation. Lanthanum reduced both aldosterone and cyclic AMP accumulation induced by ACTH. These results suggest that an extracellular calcium would be essential in stimulating the capsular steroidogenesis without involvement of the cyclic AMP system.     

Dibutyryl cyclic AMP modulation of gap junctions in SW-13 human adrenal cortical tumor cells

Cultured human adrenal cortical adenocarcinoma cells (SW-13) form a confluent monolayer of epithelial-like cells when seeded into culture flasks. Following a 24-48 hr non-mitotic period, cells begin to divide and become confluent within a week after seeding at 5 X 10(4) cells/cm2. The SW-13 cells were exposed to dibutyryl cyclic AMP (DbcAMP), cyclic AMP (cAMP), sodium butyrate, and adrenocorticotropin (ACTH). The rate of SW-13 cell proliferation was measured with a DNA microfluorometric assay, as well as by procedures measuring the incorporation of 3H-thymidine. In addition, following administration of ACTH and DbcAMP, the fractional area of membrane covered by gap junctions was quantitated with freeze-fracture electron microscopic techniques. Dibutyryl cyclic AMP at a concentration of 1 X 10(-3) M decreased the growth rate of the cell population. There was a corresponding increase in the fractional area of gap junctions found on the cell membrane in 96-hr DbcAMP-treated cultures. ACTH (40 mU/ml) exposure failed to produce an increase in the fractional area of gap junctions or to alter the rate of cell proliferation. From these data it can be suggested that elevations in cAMP levels within the cell can be related to both the proliferation of gap junctions and the decrease in cell proliferation in the SW-13 tumor cell.     

Effect of dexamethasone on steroidogenesis and on adrenocortical cyclic AMP and cyclic GMP responses to ACTH

The inhibitory action of dexamethasone on the adrenal steroidogenic response to ACTH was confirmed by im administration of graded doses (5, 10 and 30 ng) of synthetic beta 1-24 ACTH to young adult male rats which had received dexamethasone (0.1 mg/100 g bw) 4 hr prior to sacrifice. Following this, kinetic studies were performed by measuring plasma corticosterone, adrenocortical cyclic AMP and cyclic GMP before and 4, 12 and 30 min after administration of either 10 or 30 ng of ACTH. These doses were selected because their effects could be either completely or partially inhibited by dexamethasone. In rats without dexamethasone all the doses of ACTH which were checked induced an increase in both corticosterone and cyclic AMP and a decrease in cyclic GMP. With the smallest dose of ACTH the earlier administration of dexamethasone resulted in complete suppression of both the steroidogenic response and the cyclic AMP response. With the largest dose of ACTH both responses were diminished. In dexamethasone-treated rats the decrease in cyclic GMP was significantly less pronounced 4 min after ACTH than it was in non-treated rats. These results support the view that cyclic AMP and cyclic GMP might both be concerned with the mechanism of acute adrenal steroidogenesis.     

Dexamethasone suppresses ACTH release without attenuating pituitary cyclic AMP response to stress in vivo

Dexamethasone, a synthetic glucocorticoid, has been shown to decrease basal and stress-elevated levels of the pituitary hormone ACTH. Glucocorticoids are known to bind to multiple sites within the brain and pituitary and it is not known which site(s) is most important in mediating the observed inhibition of ACTH release. At the level of the corticotroph, there is contradictory data from in vitro studies regarding whether dexamethasone acts proximal or distal to the formation of the cyclic AMP second messenger that has been shown to be involved in CRF-stimulated ACTH release. In the present report, we have examined the effects of dexamethasone pretreatment on stress-induced elevations in pituitary cyclic AMP and the release of ACTH in vivo. Acute stress (15 min of intermittent footshock) elevated levels of pituitary cyclic AMP and plasma ACTH consistent with previous studies. Dexamethasone administration (0.4 mg/kg 24 hr prior to sacrifice plus 0.2 mg/kg 2 hr prior to sacrifice) inhibited stress-induced elevations in plasma ACTH but did not affect pituitary cyclic AMP response to acute stress. These findings suggest that dexamethasone inhibits the release of ACTH via an action distal to the generation of cyclic AMP.