Cytochalasin-stimulated steroidogenesis from high density lipoproteins

The cytochalasins stimulate steroid secretion of Y-1 adrenal tumor cells two-to threefold. The order of potencies is cytochalasin E is greater than D is greater than B, but the maximum response is the the same and always less than with ACTH. Like that with ACTH, the stimulation has a rapid onset, is easily reversible, is inhibited by cucloheximide and aminoglutethimide, and occurs at a stage before pregnenolone. Although the cytochalasin, like ACTH, produce cell rounding, it is shown that this morphological change is not necessarily coupled to steridogenesis. Unlike ACTH, cytochalasin B does not measurably increase cellular levels of cAMP at concentrations that lead to maximal steroidogenesis. The cytochalasin B-induced stimulation of steroidogenesis, unlike the short-term ACTH effect, fails to occur in the absence of serum. This lack of response can be corrected by even low concentrations of human high density lipoproteins (HDL) but not by low density lipoproteins (LDL). We, therefore, propose that cytochalasin B enhances the availability of cholesterol bound to HDL for steroidogenesis by Y-1 adrenal cells.     

Changes in the pattern of androgen formation in vitro by the baboon fetal adrenal gland at mid- and late gestation

In the present study, baboon fetal adrenal cells were obtained at mid- and late gestation and incubated for various intervals to determine simultaneously the effects of length of incubation and stage of development on the pattern of adrenal steroidogenesis. Cells were treated with adrenocorticotropic hormone (ACTH) from 0 to 48 h of incubation, and the concentrations of dehydroepiandrosterone (DHA), DHA-sulfate (DHAS), and androstenedione (delta 4A) were determined in the medium. The secretion of DHA and DHAS by untreated or ACTH-treated cells of midgestation increased linearly throughout the 48-h incubation period. In fetal adrenal incubates of late gestation, however, DHA and DHAS concentrations peaked at 3 h and declined thereafter, suggesting that the DHA secreted into the medium was further metabolized by this tissue. Baboon fetal adrenal cells formed similar amounts of DHAS and DHA at midgestation, but greater quantities of DHAS were formed at term. In fetal adrenal incubates of midgestation, DHA concentrations exceeded those of delta 4A by threefold, a relationship which was reversed at late gestation, probably due to the increase in the activity of 3 beta-hydroxy-steroid dehydrogenase with advancing gestation. Because the decline in DHA with time of incubation was also associated with a concomitant decrease in DHAS and no change in delta 4A, it does not appear that formation of these steroids account for the loss of DHA. We conclude that the pattern of androgen metabolism exhibited by fetal adrenal cells obtained at midgestation is different from that at term.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

The relationship between adrenal vascular events and steroid secretion: the role of mast cells and endothelin.

The actions of ACTH on the adrenal cortex are known to be 2-fold. In addition to increased steroidogenesis, ACTH also causes marked vasodilation, reflected by an increased rate of blood flow through the gland. Our studies, using the in situ isolated perfused rat adrenal preparation, have shown that zona fasciculata function and corticosterone secretion are closely related to vascular events, with an increase in perfusion medium flow rate causing an increase in corticosterone secretion, in the absence of any known stimulant. These observations give rise to two important questions: how does ACTH stimulate blood flow; and how does increased blood (or perfusion medium) flow stimulate steroidogenesis? Addressing the first question, we have recently identified mast cells in the adrenal capsule, and shown that Compound 48/80, a mast cell degranulator, mimics the actions of ACTH on adrenal blood flow and corticosterone secretion. We have also demonstrated an inhibition of the adrenal vascular response to ACTH in the presence of disodium cromoglycate, which prevents mast cell degranulation. We conclude, therefore, that ACTH stimulates adrenal blood flow by its actions on mast cells in the adrenal capsule. Addressing the second question, we looked at the role of endothelin in the rat adrenal cortex. Endothelin 1, 2 and 3 caused significant stimulation of steroid secretion by collagenase dispersed cells from both the zona glomerulosa and the zona fasciculata. A sensitive response was seen, with significant stimulation at an endothelin concentration of 10(-13) mol/l or lower. Endothelin secretion by the in situ isolated perfused rat adrenal gland was measured using the Amersham assay kit. Administration of ACTH (300 fmol) caused an increase in the rate of immunoreactive endothelin secretion, from an average of 28.7 +/- 2.6 to 52.6 +/- 6 fmol/10 min (P less than 0.01, n = 5). An increase in immunoreactive endothelin secretion was also seen in response to histamine, an adrenal vasodilator, which stimulates corticosterone secretion in the intact gland, but has no effect on collagenase-dispersed cells. From these data we conclude that endothelin may mediate the effects of vasodilation on corticosterone secretion, and this mechanism may explain some of the differences in response characteristics between the intact gland and dispersed cells.     

Effect of temperature during preparation of rat adrenal quarters and isolated cell suspension of their ACTH responsiveness.

The effect of temperature during preparation of rat adrenal quarters or isolated adrenal cell suspension on their response to ACTH was examined through a comparison of amounts of corticosterone produced after their incubation. The response to ACTH added in vitro was considerably higher when adrenal quarters and isolated adrenal cell suspension were prepared at room temperature (25 degree C) than when prepared at ice-cold. Endogenous steroidogenesis was not affected by the temperature. It seemed unlikely that this higher response to ACTH of adrenal quarters or isolated adrenal cell suspension prepared at room temperature was due to an activation of the cells. A possibility was discussed that cooling adrenal quarters or isolated adrenal cell suspension during the preparation may create an unphysiological state in some place to related the cell membrane.     

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.     

The effect of hypocholesterolemic drug treatment on adrenocortical cell function

The role of exogenous lipoprotein cholesterol versus endogenous cholesteryl esters as substrates in adrenal steroidogenesis was studied in isolated rat adrenal cells. Hypocholesterolemic drugs were used in rats to depress the plasma cholesterol concentration and the adrenal cholesterol concentration. Adrenal cortical cells were prepared in the usual way. The steroidogenic response to ACTH in normal adrenal cells and in cells which have been cholesterol-depleted was studied. Normal adrenal cells responded specifically over a 6 h incubation period to low doses of ACTH (half-maximal response equivalent to 40 microunits ACTH). These normal cells exhibited no altered response over a 3 h period to ACTH in the presence of serum or serum lipoproteins. The hypocholesterolemic drugs, 4-aminopyrazolo-[3,4-d]-pyrimidine, hexestrol and 17 alpha-ethinyl estradiol were used to lower plasma cholesterol, and after 1 day of 4-aminopyrazolo-[3,4-d]-pyrimidine and 5 days of hexestrol or 17 alpha-ethinyl estradiol treatment the plasma total cholesterol concentrations were similar. After 3 days of 4-aminopyrazolo-[3,4-d]-pyrimidine treatment the adrenal total cholesterol content was lower than after 1 day of this treatment, or 5 days of hexestrol treatment or 5 days of 17 alpha-ethinyl extradiol treatment. Lipoproteins had no significant effect on ACTH-stimulated steroidogenesis in cells isolated from rats treated for 1 day with 4-aminopyrazolo-[3,4-d]-pyrimidine, or for 5 days with hexestrol or 17 alpha-ethinyl estradiol. However, lipoproteins did stimulate steroidogenesis in cells from rats treated for 3 days with 4-aminopyrazolo-[3,4-d]-pyrimidine. The results show that normal adrenal cells contain a reserve of intracellular cholesterol so that the supply of endogenous cholesterol for steroidogenesis does not limit the response to ACTH and exogenous lipoproteins have no effect on steroidogenesis. However, if the cells are severely depleted of cholesterol then exogenous lipoproteins must be added for maximal steroidogenesis to occur.     

Failure of somatostatin and beta-endorphin to affect bovine adrenal cortex cells in vitro

The main intention of this study was to examine the effect of cyclic somatostatin (SRIF) on bovine adrenal cell activity in vitro. beta-Endorphin was applied in another course of experiments. Basal aldosterone secretion when measured was found to be 0.86 +/- 0.33 ng per 10(5) cells and 1.5 h incubation time in the glomerulosa cell fractions. Cortisol production was 1.6 +/- 0.3 ng per 10(5) cells in the fasciculata/reticularis cell incubates respectively. No effect was observed when cyclic somatostatin (SRIF) was added to cell incubates of the bovine adrenal cortex. However, aldosterone secretion was increased 4.5-fold in the presence of 10(-9)M ACTH or 10(-8)M At II. Cortisol production was enhanced similarly after addition of 10(-9)M ACTH.     

Differential response to adrenocorticotropic hormone analogs of bovine adrenal plasma membranes and cells.

The ability of three analogs of ACTH1-24 ([Gln5, Phe9] ACTH1-24, [Gln5, Ala9[Acth1-24, and [Gln5, Lys8, Phe9[ ACTH1-24) embodying tryptophan substitutions to activate the adenylate cyclase system of a bovine adrenal plasma membrane preparation was compared to the effect of the analogs on adenosine 3':5'-monophosphate (cyclic AMP) accumulation and steroidogenesis in viable bovine adrenocortical cells. The results were not comparable. Whereas the analogs antagonized the ACTH1-24-activated membrane cyclase they stimulated cyclic AMP accumulation as well as steroid production of the cells. None of the analogs inhibited steroidogenesis of ACTH1-24-stimulated cells, but two of them, at very high dose levels, inhibited cyclic AMP production. The ability of the analogs to stimulate steroidogenesis of the adrenal cells half-maximally decreased in the order tryptophan greater than phenylalanine greater than alanine, indicating that the aromaticity of the indole ring of tryptophan is necessary for maximal interaction between hormone and receptor. Both the absolute and relative steroidogenic potencies were the same for several analogs when assayed with rat adrenal cells. Although only a small fraction of the cell's potential to produce cyclic AMP was necessary to induce maximum steroid production, the relative activities of a series of analogs were the same for steroidogenesis as for cyclic AMP accumulation. Furthermore, the concentration of cyclic AMP necessary for full steroidogenesis was practically identical for a series of peptides that differed widely in potency. These findings support the postulate that cyclic AMP accumulation and steroidogenesis in adrenocortical cells are coupled processes. The differential behavior of bovine adrenal plasma membranes and bovine adrenocortical cells toward ACTH analogs indicates that structure-function studies using cyclase assays may not reflect events that take place in the intact adrenal or in cell preparations derived therefrom.     

Regulation of rat and bovine adrenal metabolism of polycyclic aromatic hydrocarbons by adrenocorticotropin and 2,3,7,8-tetrachlorodibenzo-p-dioxin

The effects of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) on polycyclic aromatic hydrocarbon (PAH) metabolism and steroidogenesis in primary cultures of bovine adrenal cortical (BAC) and rat adrenal cortical (RAC) cells have been examined. Remarkably TCDD is an ineffective inducer (15-50%) of PAH metabolism in confluent BAC cells and completely antagonizes a 5-fold induction by benz[alpha]anthracene (BA). In the same concentration range (EC50 5 X 10(-11) M) TCDD suppresses steroidogenesis through an effect on cholesterol metabolism. Adrenocorticotropin (ACTH) and cAMP also suppress PAH metabolism at concentrations which stimulate steroidogenesis (10(-7) M). In RAC cells ACTH potently induces PAH metabolism (7-fold) at a comparable concentration to the stimulation of steroidogenesis. Parallel stimulation of PAH metabolism and steroidogenesis by cAMP suggest that ACTH induction of PAH metabolism is mediated by cAMP. TCDD induces PAH metabolism (2.8-fold, EC50 8 X 10(-11) M) at similar concentrations to the inhibitory effect in BAC cells and this action is additive with ACTH induction. In male rats in vivo TCDD induces adrenal microsomal PAH metabolism (72%) and is more effective in this respect than 3-methylcholanthrene (3MC). Rabbit antibodies against rat liver cytochrome P-450c (the major TCDD-inducible liver form) inhibited the TCDD-induced adrenal metabolism of 7,12-dimethylbenz[alpha]anthracene (DMBA), which also exhibited regioselectivity typical of metabolism by P-450c. Constitutive adrenal microsomal metabolism, which exhibited regioselectivity of DMBA metabolism comparable to the ACTH-sensitive cellular metabolism, was not affected by anti-P-450c. It is concluded that ACTH and TCDD induce distinct forms of cytochrome P-450 in RAC cells and that the latter represents a typical Ah-receptor mediated response. The anomalous effect on PAH metabolism in BAC cells that parallels inhibition of steroidogenesis may derive from repression of a distinct adrenal form of P-450 by the TCDD-Ah-receptor complex.     

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

The present study examined the effects of serum and lipoproteins on the function of cultured adrenal cells from 115-127-day-old ovine fetuses and from newborn lambs. On day 1 of culture, corticosteroid output was similar in medium containing 2% horse serum or in serum-free medium, both for fetal and neonatal cells. However, on day 5, cells cultured in the absence of serum produced smaller amounts of these steroids than cells maintained in medium containing serum; the difference was more marked under ACTH1-24 stimulation. Conversely, cAMP production was never lower in the absence than in the presence of serum. When stimulated by ACTH1-24 on day 2 of culture, fetal or neonatal adrenal cells incubated in the presence of a saturating concentration of ovine LDL produced more corticosteroids than cells incubated in serum-free medium; HDL also enhanced ACTH1-24-induced steroidogenesis, but to a lesser extent. VLDL was effective only with neonatal cells. In fetal and neonatal cells cultured for 6 days in ACTH-free medium, VLDL and LDL increased ACTH-induced steroidogenesis, but HDL did not. On the other hand, when cells were cultured in the presence of ACTH1-24, LDL and HDL were equipotent in supporting ACTH1-24-induced steroid output. Three major lipoprotein fractions were observed in serum of fetal and newborn lambs. The concentration of cholesterol was very low in the VLDL fraction of fetuses, but it was similar to that of newborns in LDL. Conversely, 4 times more cholesterol was present in HDL of newborns than in HDL of fetuses. These results suggest that: (i) after several days of cell culture, cholesterol availability is an important limiting factor for the steroidogenesis of cells maintained under serum-free conditions; (ii) both an "LDL pathway" and an "HDL pathway" are operating in adrenal cells from fetal as well as newborn sheep; (iii) LDL and HDL are important physiological sources of cholesterol to support steroidogenesis by fetal and neonatal adrenal cells.     

Studies on lipoprotein and adrenal steroidogenesis: I. Roles of low density lipoprotein- and high density lipoprotein-cholesterol in steroid production in cultured human adrenocortical cells

The roles of human low density lipoprotein (LDL)- cholesterol and high density lipoprotein (HDL)- cholesterol on adrenal steroidogenesis were investigated using cultured human adult and fetal adrenocortical cells and the findings were then compared to those obtained with bovine adrenocortical cells. The secretion of cortisol in both human and bovine adrenocortical cells was dose-dependently increased by the administration of LDL- or HDL-cholesterol in the presence of adrenocorticotropin (ACTH). LDL-cholesterol was utilized to a greater extent than HDL-cholesterol in both human and bovine adrenal steroidogenesis in the presence of ACTH. Exogenous lipoprotein-derived cholesterol was less utilized in human adrenal steroidogenesis than in bovine adrenal steroidogenesis, compared to the endogenous cholesterol. An increase in the secretion of cortisol and dehydroepi androsterone sulfate (DHEA-S) continued for the 5-day culture period, in the presence of lipoprotein cholesterol and ACTH in both human adult and fetal adrenocortical cells. The secretion of aldosterone increased on the first day of the culture period, then gradually decreased for the 5-day culture period in human adult adrenocortical cells, but not in human fetal adrenocortical cells in the presence of lipoprotein cholesterol and ACTH. These findings demonstrate that exogenous cholesterol utilized in the biosynthesis of steroids is mainly from LDL-cholesterol in both human adult and fetal adrenals and bovine adrenal and the proportion of cholesterol synthesized de novo is significantly larger in the human adult adrenal than in the bovine adrenal.     

In vitro studies of nuclear volume of rat adrenocortical cells: lace of ACTH effect

The effect of ACTH on nuclear volume of adrenocortical cells in the zona fasciculata of rat adrenal cortex was examined in vitro. Sections of adrenal gland were incubated for 60 or 90 min in Krebs-Ringer's solution with 1% glucose in the presence of ACTH, actinomycin D, cycloheximide and aminoglutethimide. ACTH, despite its clear effect in stimulating steroidogenesis, did not exert a direct effect on the nuclear volume of cells studied. This phenomenon is not dependent upon the stimulation of steroidogenesis, since aminoglutethimide does not influence the nuclear volume of adrenocortical cells studied; rather, ACTH in the presence of aminoglutethimide leads to a decrease in their volume. Actinomycin D does not influence nuclear volume while after incubation with cycloheximide nuclei were larger than the control. The presence of ACTH did not alter this effect. These results indicate no relationship between the degree of corticosterone output and nuclear volume in rat adrenocortical cells of the zona fasciculata in vitro.     

The phosphorylation of adrenal proteins in response to adrenocorticotropic hormone

The phosphorylation of rat adrenal protein components in response to adrenocorticotropin has been studied in adrenal quarters, isolated cells, and in vivo. In adrenal quarters, adrenocorticotropic hormone (ACTH)-stimulated phosphorylation or dephosphorylation of proteins was not affected by the presence of protein synthesis inhibitors despite a total inhibition of steroidogenesis. (The term dephosphorylation refers to an apparent decrease in the labeling of a particular protein with 32P at various times after the addition of ACTH. This may be due to enzymatic removal of phosphate or protein degradation or complexation of this protein with another cellular component.) Studies with isolated cell preparations identified several proteins that are phosphorylated or dephosphorylated in response to hormone. These changes in phosphorylation were also observed in adrenal quarters and correlated well with ACTH-stimulated steroidogenesis as determined by temporal analysis and dose-response studies of corticosterone production. In vivo injection of male hypophysectomized rats with [32P]phosphate and ACTH demonstrated changes in the labeling of six adrenal proteins. Many of the proteins phosphorylated in vivo were also demonstrated to be phosphorylated in both in vitro systems. Finally, the injection of a physiological dose of ACTH appeared to selectively activate the type I cAMP-dependent protein kinase within the microsomal fraction as determined by the binding of a photoaffinity-labeled reagent. These results suggest that alterations in phosphorylation of adrenal proteins in response to ACTH is proximal to or independent of the obligatory role of protein synthesis in acute steroidogenesis.     

Effect of ethanol on corticosterone production by dispersed adrenal cells of the rat

The action of ethanol on adrenal steroidogenesis "in vitro" has been studied. It has been found that ethanol did not change the basal production of corticosterone by dispersed adrenal cells, but significantly reduced its response to ACTH stimulation. It is suggested that the inhibitory action of ethanol on steroidogenesis "in vitro" could have a physiological meaning, because the response to ACTH stimulation of adrenal cells from rats treated "in vivo" with ethanol showed a clear dose-related inhibition.     

Inhibition of DNA synthesis in adrenocortical cells by cytochalasin B

ACTH inhibits DNA synthesis in normal rat and mouse tumor Y-1 adrenocortical cells within the same concentration range that it stimulates steroidogenesis. These processes can be independently regulated as demonstrated by the divergent actions of cytochalasin B on these cells. In the normal cells, cytochalasin B does not increase steroidogenesis in serum-free or serum-containing media, and it decreases the stimulation produced by ACTH. In the absence of serum, the Y-1 cells respond in a similar way. However, in serum-containing media, cytochalasin B increases steroidogenesis in these cells and does not inhibit the response to ACTH. In both cell types, cytochalasin B inhibits [3H]thymidine incorporation into DNA by a mechanism different than that of ACTH. In the Y-1 cells, this inhibition is caused by a decreased uptake of [3H]thymidine into the cell, which probably reflects a decreased transport across the cell membrane. In the normal cells, cytochalasin B, like ACTH, does not affect [3H]thymidine transport, but it decreases DNA synthesis much more rapidly than does ACTH. This inhibition may be the result of the disruption of microfilaments by cytochalasinB, because our evidence indicates that it is not caused by a decrease in glucose uptake by the cells.     

Glucocorticoid control of steroidogenesis in isolated rat adrenocortical cells

The role of end-product glucocorticoids in the regulation of corticosteroidogenesis in isolated adrenocortical cells was investigated. Trypsin-isolated cells from male rat adrenal glands were incubated with or without corticotropin (ACTH) and with or without corticosterone. Endogenous corticosterone production was determined by radioimmunoassay at the end of incubation. Cessation of ACTH-induced corticosterone production was apparent after 2-4 h of incubation. The suppression occurred later with lower cell concentrations. Corticosterone production was partially restored after washing the suppressed cells. Supernatant fluid from suppressed cell suspensions also suppressed steroidogenesis of a fresh population of cells. However, the suppressing property of the supernatant fluid was abolished after the removal of corticosterone by charcoal-dextran treatment, suggesting that corticosterone or other steroids caused the suppression. Exogenous corticosterone induced suppression over a wide range of ACTH concentrations, but did not change the half-maximal steroidogenic concentration of ACTH, indicating that the suppression does not change the sensitivity of the cells to ACTH. Suppression occurred within 30-60 min after corticosterone had been added to the incubation medium either at the start of incubation or while steroidogenesis was in progress. Suppression varied directly with the concentration of exogenous corticosterone. These data indicate that glucocorticoids can directly and acutely suppress corticosteroidogenesis and thus control adrenocortical function in concert with other regulators such as ACTH and Ca2+.     

The adrenal gland and progesterone stimulates testicular steroidogenesis in the rat in vivo

Administration of pharmacological doses of glucocorticoid to male rats in vivo suppresses adrenal steroidogenesis and inhibits testicular steroidogenesis by inhibiting the anterior pituitary secretion of LH. In contrast, administration of ACTH to these pharmacologically-suppressed rats stimulates the adrenal secretion of progesterone and testicular steroidogenesis. The mechanism by which ACTH increases testicular steroidogenesis is dependent on the presence of the adrenal gland and is reproduced by the administration of progesterone. The conclusion from these data is that the adrenal gland has an important role in generating external signals that modulate the hypothalamic-pituitary-gonadal axis in male rats. The adrenal secretion of glucocorticoid acts as a negative signal to testicular steroidogenesis whereas progesterone acts as a positive signal. The adrenal secretion of progesterone and its conversion to testosterone by steroidogenic enzymes in the cytoplasm of the Leydig cell may provide an alternative pathway for testosterone biosynthesis and may account for the increased plasma testosterone levels during the acute phase of stress and mating.     

The ultrastructure of functional mouse adrenal cortical tumor cells in vitro.

Cells derived from a transplantable mouse adrenal cortical tumor maintain their differentiated function in vitro and secrete steroids in response to ACTH and other stimulatory agents. The cell line has been widely employed for various biochemical investigations but there have been few attempts to correlate this work with morphologic data. This communication describes the electron microscopic appearance of the tumor transplant in vivo and primary cultures derived from it at various intervals after the cells are placed in culture. Tumor cells in vivo bear considerable resemblance to normal adult mouse adrenal cortical cells. Organelles generally considered to be directly involved in steroid biosynthesis (mitochondria, smooth endoplasmic reticulum and lipid droplets) are not drastically altered. Certain modifications of the vasculature and cell membrane, seemingly related to steroidogenesis, are present in both the tumor and normal adrenal cortex. Within 2 days after the tumor cells are introduced to culture, their cytoplasm assumes a more simplified appearance. Smooth endoplasmic reticulum is less conspicuous and free ribosomes and polysomes are very abundant. Mitchondrial inner membranes are reorganized from a saccular arrangement in the cells in vivo into distinct lamellar cristae. The tumor cells now resemble undifferentiated embryonic adrenal cells, or cultured adrenal cells from various mammalian sources which have dedifferentiated in the absence of ACTH. In their morphologically unspecialized state, the normal cells are incapable of functional responses to ACTH. In contrast, the cultured, dedifferentiated tumor cells respond within minutes to this hormone and can demonstrate 5-20 fold increases in their basal steroid output. These data suggest that substantial steroidogenic activity can occur although the characteristic appearance of adrenal mitochondria is absent.