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.     

Regulation of mitochondrial compartment volumes in rat adrenal cortex by ether stress

In vivo ether stress of rats causes release of pituitary adrenocorticotropin (ACTH) leading to activation of steroidogenesis in adrenal cortex mitochondria. The present studies show that this treatment also induces a decrease in the volume of the intermembrane space in isolated adrenal mitochondria. This decrease is accompanied by an increase in the volume of the matrix, thus leaving the total mitochondrial volume approximately constant. These effects are prevented by the protein synthesis inhibitor, cycloheximide, and are specific to the adrenal gland. The decrease in the intermembrane space (or increase in the matrix volume) is correlated with activation of the cholesterol side chain cleavage reaction (the regulated step in steroidogenesis). We propose as a working hypothesis that these changes reflect a hormonally regulated alteration in the relationship between the outer and inner mitochondrial membranes, which may facilitate the rate-limiting movement of cholesterol from the outer to the inner membrane where the side chain cleavage enzyme is located.     

Cytosol stimulation of pregnenolone synthesis by isolated adrenal mitochondria

Hypophysectomized male rats were injected with either ACTH or saline (control) and killed 15 min later. Mitochondrial and 235, 000 x g supernatant (cytosol) fractions were prepared from the adrenal glands. When cytosol from ACTH-treated animals was mixed with isolated mitochondria from the control animals, a dose-dependent increase in pregnenolone production occurred. Liver cytosol caused no increase in the production of pregnenolone. Thus, ACTH elicits a soluble adrenal factor(s) which activates the mitochondrial cholesterol side-chain cleavage system which is the rate-limiting step in steroidogenesis. The cytosol stimulatory factor was found to be nondialyzable, heat-sensitive, and resistant to trypsinization.     

A mechanism for the in vitro stimulation of adrenal cortisol biosynthesis by epidermal growth factor

EGF stimulates adrenal steroidogenesis in ewes and in ovine adrenal slices. In vitro, The stimulation is blocked by the cholesterol synthesis inhibitors compactin and AY 9944. EGF stimulates the incorporation of [14C]acetate into cholesterol. EGF increases the activity of the rate limiting enzyme in cholesterol biosynthesis, HMG CoA reductase. EGF has no effect on the levels of any intermediates involved in the conversion of pregnenolone to cortisol, although ACTH produced changes consistent with 17 alpha-hydroxylase activation. We propose that EGF increases adrenal cortisol synthesis in vitro by a stimulation of cholesterol precursor biosynthesis mediated through activation of HMG CoA reductase.     

The influence of cytochalasin B on the response of adrenal tumor cells to ACTH and cyclic AMP.

Cytochalasin B inhibits increase in steroid synthesis by mouse adrenal tumor cells (Y-1), produced either by ACTH or cyclic AMP. Basal levels of steroid synthesis are not decreased and the inhibitor acts by decreasing the response of the side-chain cleavage step (cholesterol → pregnenolone) to ACTH. Inhibition is reversible and is seen in medium without glucose. These observations suggest that microfilaments may play a role in the response of adrenal cells to ACTH.     

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.     

Inhibition of ACTH action on cultured bovine adrenal cortical cells by 2,3,7,8-tetrachlorodibenzo-p-dioxin through a redistribution of cholesterol

The conversion of cholesterol to cortisol by cultured bovine adrenal cortical cells is stimulated 6-fold by adrenocorticotropin and is limited by the movement of cholesterol to the mitochondria (DiBartolomeis, M.J., and Jefcoate, C.R. (1984) J. Biol. Chem. 259, 10159-10167). Exposure of confluent cultures to the potent environmental toxicant, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) (10(-8)M), for 24 h prior to adrenocorticotropin (ACTH) addition decreased the rate of ACTH-stimulated steroidogenesis but did not affect the basal rate. TCDD was more effective against stimulation at 10(-11) M ACTH (4-fold) than at 10(-7) M ACTH (10%), consistent with an increase in EC50 for ACTH. Stimulation of bovine adrenal cortical cells by cAMP was similarly decreased by TCDD. In both cases the effectiveness of TCDD increased with time of exposure to the stimulant. The transfer of cholesterol to mitochondria in intact cells was quantitated by means of the 2-h accumulation of mitochondrial cholesterol in the presence of aminoglutethimide, an inhibitor of cholesterol side chain cleavage. Although cholesterol accumulated in the presence of ACTH (13 to 28 micrograms/mg), pretreatment of cells with TCDD caused a decrease in mitochondrial cholesterol (13 to 8 micrograms/mg). The effect of TCDD was produced relatively rapidly (t1/2 approximately 4 h). In absence of TCDD, the mitochondria of ACTH-stimulated cells also eventually lose cholesterol (after 2 h). It is concluded that TCDD pretreatment may increase the presence of a protein(s) that cause mitochondrial cholesterol depletion when the cells are stimulated by ACTH or cAMP. TCDD-enhanced cholesterol efflux from mitochondria diminishes cholesterol side chain cleavage when mitochondrial cholesterol is sufficiently depleted (after 2-4 h).     

ACTH regulation of cholesterol movement in isolated adrenal cells

Confluent bovine adrenal cell primary cultures respond to stimulation by adrenocorticotropin (ACTH) to produce steroids (initially predominantly cortisol and corticosterone) at about one-tenth of the output of similarly stimulated rat adrenal cells. The early events of steroidogenesis, following ACTH stimulation, have been investigated in primary cultures of bovine adrenal cortical cells. Steroidogenesis was elevated 4-6-fold within 5 min of exposure to 10(-7) M ACTH and increased linearly for 12 h and declined thereafter. Cholesterol side-chain cleavage (SCC) activity was increased 2.5-fold in mitochondria isolated from cells exposed for 2 h to ACTH and 0.5 mM aminoglutethimide (AMG), even though cytochrome P-450scc only increases after 12 h. Mitochondrial-free cholesterol levels increased during the same time period (16.5-25 micrograms/mg of protein), but then both cholesterol levels and SCC activity declined in parallel. More prolonged exposure to ACTH prior to addition of AMG caused the elevation in mitochondrial cholesterol to more than double, possibly due to enhanced binding capacity. Early ACTH-induced effects on cellular steroidogenesis result from these changes in mitochondrial-free cholesterol. The maximum rate of cholesterol transport to mitochondria in AMG-blocked cells was consistent with the maximum rate of cellular steroidogenesis. Cycloheximide (0.2 mM) rapidly blocked (less than 10 min) cellular steroidogenesis, cholesterol SCC activity, and access of cholesterol to cytochrome P-450scc without affecting mitochondrial-free cholesterol. Exposure of confluent cultures to the potent environmental toxicant, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) (10(-8) M), for 24 h prior to ACTH addition decreased the rates of ACTH- and cAMP-stimulated steroidogenesis but did not affect the basal rate. In both cases, the effectiveness of TCDD increased with time of exposure to the stimulant. Although cholesterol accumulated in the presence of ACTH and AMG (13-28 micrograms/mg), pretreatment of cells with TCDD caused a decrease in mitochondrial cholesterol (13-8 micrograms/mg). The effect of TCDD was produced relatively rapidly (t1/2 approximately 4 h). Since even in the absence of TCDD, the mitochondria of ACTH-stimulated cells also eventually lose cholesterol (after 2 h) TCDD pretreatment may increase the presence of a protein(s) that cause this mitochondrial-cholesterol depletion following stimulation by ACTH or cAMP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cholesterol sulfate is a naturally occurring inhibitor of steroidogenesis in isolated rat adrenal mitochondria

We previously reported (Lambeth, J. D., Xu, X. X., and Glover, M. (1987) J. Biol. Chem. 262, 9181-9188) that exogenously added cholesterol sulfate inhibits the conversion of cholesterol to pregnenolone in isolated adrenal mitochondria, and does so by affecting intramitochondrial cholesterol movement but not its subsequent metabolism to pregnenolone by cytochrome P-450scc. We now report that a major kinetic component of the inhibition is noncompetitive with respect to cholesterol, consistent with an allosteric effect at a site other than the substrate binding site of cytochrome P-450scc. We now also report that cholesterol sulfate is present as an endogenous compound in preparations of adrenal mitochondria. Its content varied from 0.05 to 0.8 nmol/mg protein. Cholesterol sulfate level correlated inversely with the mitochondrial cholesterol side-chain cleavage activity. Endogenous cholesterol sulfate thus appeared to account for the variable rates of pregnenolone synthesis which were seen in different mitochondrial preparations. Cholesterol sulfate was metabolized to pregnenolone sulfate by a mitochondrial side-chain cleavage system, but proved to be a relatively poor substrate for an extramitochondrial steroid sulfatase activity present in adrenal cortex. Confirming a role as a naturally occurring inhibitor, removal of endogenous mitochondrial cholesterol sulfate by metabolism to pregnenolone sulfate correlated with a 3-fold activation of cholesterol side-chain cleavage. We suggest that cholesterol sulfate functions in steroidogenic tissues to regulate the magnitude of the steroidogenic response.     

Further characterization of the inhibitory effect of monensin on adrenal steroidogenesis

We have previously reported that treatment of cultured mouse adrenal tumor cells with 0.6-1.2 microM monensin, a monovalent carboxylic ionophore, results in disruption of the organized structure of the Golgi complex. This is associated with an inhibition of adrenocorticotropic hormone (ACTH) or dibutyryl cAMP-stimulated steroidogenesis and impairment of mitochondrial cholesterol side-chain cleavage activity. The present report describes further investigations regarding possible mechanisms for the inhibition. Monensin inhibits both synthesis of fluorogenic steroids and incorporation of [14C]acetate into the end-product steroid 11 beta,20 alpha-dihydroxy-4-pregnen-3-one. Supplementation of monensin-treated cells with 25-hydroxycholesterol, a readily available substrate for steroidogenesis, does not reverse the inhibitory effect on the reaction. The incorporation of L-[35S]methionine into trichloroacetic acid precipitable proteins in the isolated mitochondria of monensin-treated cells is inhibited approximately by 40%, whereas the inhibitory effect on the proteins in the cell homogenate is marginal. These findings suggest that a deficiency of newly synthesized proteins in mitochondria, rather than the availability of the substrate cholesterol, may be the primary factor causing impairment of steroidogenesis.     

Corticotropin-induced changes in a soluble desmolase preparation

Following simple homogenization, substantial desmolase activity is recovered in rat adrenal 105 000 × g supernatant. The desmolase complex sediments at 3–4 S on sucrose gradients, is found in the clear cytosol, requires NADPH, is derived from mitochondria and is inhibited by aminoglutethimide and pregnenolone. The lipid fraction contains little or no desmolase activity but greatly enhances pregnenolone synthesis in soluble desmolase preparations, presumably by supplying free cholesterol substrate. Prior adrenocorticotropin (ACTH) administration enhances pregnenolone synthesis in the 105 000 × g supernatant, and cycloheximide, an inhibitor of adrenal protein synthesis, does not block this effect of ACTH (but rather potentiates it). The ACTH effect may be largely explained by an increase in free cholesterol, which enhances the activity of both the lipid fraction and clear cytosol, since: free cholesterol levels are increased by ACTH, particularly with cycloheximide pretreatment; type I and inverted type I difference spectrum changes, indicating greater cholesterol availability for binding to cytochrome P-450, are enhanced by ACTH with or without cycloheximide treatment; cholesterol-rich lipid fraction enhances such spectral changes and obliterates the differences in spectral and pregnenolone-synthesizing activities betwen control and ACTH-stimulated soluble desmolase preparations; and desmolase stimulatory properties of clear cytosol co-chromatographs with [¹⁴C]cholesterol. Since cycloheximide blocks ACTH-induced effects in intact mitochondria but not in the soluble desmolase preparation, it is postulated that the labile protein required during ACTH action functions to overcome a ?restraining influence’ which is present in intact mitochondria but not in the soluble desmolase system. The ‘restraining influence’ may be due to limited cholesterol-desmolase interaction.     

Side-chain cleavage of cholesterol sulfate by ovarian mitochondria

Mitochondria isolated from porcine corpora lutea and from the luteinized ovaries of gonadotropin-treated immature rats were found to efficiently cleave the side-chain of cholesterol sulfate to produce 3 beta-hydroxy-5-pregnen-20-one sulfate (pregnenolone sulfate). When mitochondria were preincubated with cholesterol sulfate, the time-course for the side-chain cleavage of cholesterol sulfate was biphasic. With 200 microM cholesterol sulphate, the initial rate of the reaction was the same as that observed for 25-hydroxycholesterol. This rate was not increased when both cholesterol sulfate and 25-hydroxycholesterol were incubated together. The rate of side-chain cleavage by isolated mitochondria supplied with 75 microM cholesterol sulfate as substrate was inhibited by 97% by aminoglutethimide, a specific inhibitor of cytochrome P-450scc. The slow phase of side-chain cleavage of cholesterol sulfate appeared to be limited by the rate of substrate movement to the mitochondrial site of the reaction. Cholesterol sulfate translocation rates were however up to 8 times greater than those observed for cholesterol when equivalent concentrations of the two substrates were added to the mitochondria. We conclude that cholesterol sulfate is a better substrate than cholesterol for side-chain cleavage by isolated mitochondria and that both reactions are catalysed by the same cytochrome P-450scc enzyme.     

The role of the cytoskeleton in the regulation of steroidogenesis

The slow step in steroid synthesis involves the transport of cholesterol from lipid droplets in the cytoplasm to the first enzyme in the pathway—the cytochrome P450 that converts cholesterol to pregnenolone (P450scc) which is located in the inner mitochondrial membrane. ACTH stimulates this intracellular transport of cholesterol in adrenal cells (Y-1 mouse adrenal tumour cells and cultured bovine fasciculata cells) and this effect of the trophic hormone is inhibited by cytochalasins, by anti-actin antibodies and DNase I suggesting that the response to ACTH requires a pool of monomeric (G-) actin that can be polymerized to F-actin. Recent studies have shown that lipid droplets and mitochondria of adrenal cells are both attached to intermediate filaments. Moreover ACTH reorganizes the cytoskeleton and changes the shape of the cell. These observations suggest a mechanism for transport of cholesterol that involves reorganization and contraction of actin microfilaments which may, in turn, cause movement of droplets and mitochondria together through their common attachment to intermediate filaments.     

Estimation of pregnenolone synthesis in rat adrenal homogenates: some cofactor requirements: effects of stress, hypophysectomy, cortisone and ACTH.

Pregnenolone synthesis was estimated in whole adrenal homogenates incubated in the presence of cyanoketone (2alpha-cyano-4,4,17alpha-trimethyl-androst-5-en-17beta-ol-3-one). The yield of pregnenolone depended on the type of incubation medium employed. Both Ca++ and bovine serum albumin (BSA) markedly stimulated the rate of pregnenolone synthesis as did NADPH or NADPH generating system. Aminoglutethimide added in vitro inhibited cholesterol sidechain cleavage activity. Ether stress in vivo stimulated pregnenolone synthesis in vitro, and hypophysectomy of 24 hours duration resulted in a decrease. Cortisone administration for 8 days reduced the formation of pregnenolone by rat adrenal homogenates, an effect prevented by concomitant treatment with ACTH. Similarly, hypophysectomy of 8 days duration resulted in a marked diminution of pregnenolone synthesis and ACTH replacement reversed this effect. Changes in pregnenolone synthesis were paralleled by changes in corticosterone and total steroid production.     

GTP stimulates pregnenolone generation in isolated rat adrenal mitochondria

Pregnenolone synthesis from cholesterol by adrenal mitochondria isolated from ether-stressed rats exhibits a biphasic time course: upon the addition of a reducing substrate (e.g. malate), a rapid phase of pregnenolone formation occurs during the first 5 min, which has been interpreted as the metabolism of a steroidogenic pool of cholesterol, probably in the inner membrane. A slower rate follows, which is interpreted as translocation of cholesterol into the steroidogenic pool. While a 30-min preincubation of mitochondria with cholesterol alone did not affect the extent of the rapid phase, preincubation with GTP plus cholesterol extended the first phase, resulting in an up to 2-fold increase in pregnenolone synthesis by 20-30 min. The apparent Km for GTP was 0.1-0.4 mM, and stimulation was maximal with preincubation times of 10-30 min, depending upon incubation conditions. Exogenous cholesterol was not required to observe a stimulatory effect, indicating that GTP reorganizes the endogenous mitochondrial cholesterol pools. Nevertheless, stimulation was greater when exogenous cholesterol was provided, consistent with enhanced utilization of both endogenous and exogenous cholesterol. Stimulation by GTP was also seen in mitochondria isolated from cycloheximide-injected/ether-stressed rats, although the activity in these preparations was always lower than that in mitochondria from ether-stressed rats. The stimulation was specific for GTP, since many other nucleotides (e.g. ATP, GDP, and ITP) and GTP analogues (guanosine 5'-O-(3-thiotriphosphate and guanosine 5'-(beta,gamma-imino)triphosphate) had no effect. The GTP-activated state was reversible: after GTP hydrolysis by a mitochondrial GTPase, pregnenolone synthesis returned to the basal level. Sonic disruption of mitochondria abolished the stimulatory effect of GTP. These results suggest that GTP enhances pregnenolone synthesis by promoting the movement of cholesterol to the steroidogenic pool, consistent with a recently proposed general role for GTP in some vectorial transport processes (Bourne, H. R. (1988) Cell 53, 669-671).     

Control of sterol metabolism in rat adrenal mitochondria

Steroidogenesis by adrenal mitochondria from endogenous precursors is stimulated by corticotropin (ACTH) and is sensitive to the protein-synthesis inhibitor cycloheximide. In the present investigation the effect of cycloheximide treatment on the metabolism of a number of analogues of the normal steroidogenic substrate, i.e. cholesterol, by rat adrenal mitochondria was studied. It was observed that the metabolism of analogues such as desmosterol, 26-norcholest-5-en-3β-ol and 5-cholen-3β-ol (that is with non-polar alkyl side chains like cholesterol), was sensitive to cycloheximide treatment. By contrast, the metabolism of those analogues with polar groupings on the side chain, i.e., 20α-, 24-, 25- and 26-hydroxycholesterols was insensitive to pretreatment with cycloheximide. The binding of added sterol to the cytochrome P-450 component of the mitochondrial sterol desmolase was studied. Similar studies on the equilibration time on addition of exogenous sterols to achieve maximum rates of pregnenolone production were also made. Both studies show that cholesterol, a non-polar sterol, penetrated slowly through the mitochondrial milieu to reach the cytochrome P-450 reaction centre whereas 24- and 26-hydroxycholesterols rapidly attained the enzymic environment. The cycloheximide-sensitive process in sterol metabolism appeared related to the transfer of non-polar sterols such as cholesterol within the mitochondria to a region in close proximity to the enzyme. The importance, and possible mechanism of action, of the cycloheximide-sensitive factor in the control of adrenal steroidogenesis is discussed.     

Peripheral-type benzodiazepine receptors are involved in the regulation of cholesterol side chain cleavage in adrenocortical mitochondria

In an attempt to elucidate the physiological relevance of the peripheral type of benzodiazepine receptor in adrenocortical mitochondria, we examined the effect of three different benzodiazepines (diazepam, Ro5-4864, and chlordiazepoxide) on the conversion of cholesterol to pregnenolone, the rate-limiting step in steroidogenesis, by using cholesterol-loaded mitochondria from bovine adrenal zona fasciculata. These benzodiazepines, except chlordiazepoxide, caused a dose-dependent stimulation of the cholesterol side chain cleavage in the mitochondria. The stimulatory effect of Ro5-4864 was approximately 10 times more potent than that of diazepam. No inhibitory effect of YM-684 (Ro15-1788), a potent antagonist to central-type benzodiazepine receptors, was observed in the stimulation induced by diazepam and Ro5-4864. Both external calcium ion and voltage-dependent calcium channel blocker, (+)-PN200-110, were without effect on the diazepam-induced steroidogenesis. By contrast, pretreatment of mitochondria with digitonin abolished the stimulatory effect of diazepam on the mitochondrial steroidogenesis. The present results indicate that the peripheral-type benzodiazepine receptor of adrenocortical mitochondria plays an essential role in regulating cholesterol side chain cleavage without any change of calcium channels.     

The effects of cytochalasin B and vinblastine on movement of cholesterol in rat adrenal glands.

Vinblastine (antimicrotubular agent) and cytochalasin B (antimicrofilament agent) block the build up of adrenal mitochondrial cholesterol seen in the presence of AMG. ACTH stimulated steroidogenesis is inhibited $\text{in vivo}$ by both agents via a reduction in the transfer of intra-adrenal cholesterol to adrenal mitochondria, resulting in a decrease in the synthesis of adrenal steroids. Both inhibitors also decrease ACTH stimulated formation of cholesterol cytochrome P450_SCC complex in adrenal mitochondria, as determined by difference spectroscopy. The effects of these inhibitors contrast with the actions of protein synthesis inhibitors which decrease cholesterol binding to P450_SCC while increasing mitochondrial cholesterol content.     

On the requirement for protein synthesis during corticotropin-induced stimulation of cholesterol side chain cleavage in rat adrenal mitochondrial and solubilized desmolase preparations.

Following simple homogenization, significant amounts of mitochondrial-derived, cholesterol side chain cleaving enzyme (desmolase) activity are recovered in rat adrenal 105 000 X g-supernatant fraction. Corticotropin administration enhances soluble desmolase activity, and cycloheximide potentiates this effect. The lipid droplet fraction which has no desmolase activity markedly enhances pregnenolone synthesis in the soluble desmolase preparations, presumably by supplying free cholesterol substrate. Corticotropin particularly with cycloheximide pretreatment, enhances lipid fraction activity. Thus increased cholesterol availability may largely explain the corticotropin effect on the soluble desmolase system. Since protein synthesis is required for corticotropin activity in intact mitochondria, but not in calcium-swollen mitochondria or the soluble enzyme system, the labile protein apparently required during corticotropin action may function to overcome a "barrier" which exists only in the intact mitochondria and restrains cholesterol side chain cleavage.