Aldosterone biosynthesis in mitochondria of isolated zones of adrenal cortex

An assumption that the aldosterone-synthesizing enzyme exists only in zona glomerulosa cells apparently contradicts our recent findings that a purified bovine adrenocortical cytochrome P-45011 beta catalyzes the aldosterone formation and the enzyme exists in both zones of the adrenal cortex. To gain more insight into the zone specificity of aldosterone production, the aldosterone-synthesizing activity of mitochondria prepared from the isolated zones of adrenal cortex of various animal species was investigated. The intact mitochondria from the bovine or porcine zonae fasciculata-reticularis could not produce aldosterone whereas those from the zona glomerulosa produced it at a significant rate. When the mitochondria from the zonae fasciculata-reticularis were solubilized by the addition of cholate, they produced aldosterone from corticosterone at a rate comparable to that of those from the zona glomerulosa. The presence of specific factor(s) in the zonae fasciculata-reticularis mitochondria inhibiting expression of the aldosterone synthetic activity is discussed. The mitochondria of the rat zonae fasciculata-reticularis could hardly catalyze aldosterone synthesis under the detergent-solubilized conditions, whereas those of the zona glomerulosa could. Immunoblot analysis revealed that the mitochondria of the zonae fasciculata-reticularis contained a protein of Mr 51,000 which was immunocrossreactive with a monoclonal antibody directed against P-45011 beta, whereas those of the zona glomerulosa contained two immunocrossreactive proteins of Mr 51,000 and 49,000. These results suggest that in the case of rat adrenal cortex, a specific aldosterone-synthesizing enzyme exists in the zona glomerulosa.     

Hypertrophy of the adrenal cortex

The human adrenal cortex in essential hypertension and in the salt-losing form of the adrenogenital syndrome and the adrenal cortex in spontaneously hypertensive rats were studied by morphometry. Under long-term functional loading hypertrophy of adrenocortical cells is the common way of increasing the mass of the cortex. The correlation between the morphological parameters of the adrenocortical structures increases in this condition. Hyperplasia along with hypertrophy has been found in man at an early age. The differences in the degree of hypertrophy of the nuclei and nucleoli may be connected with different intensity of adrenocortical function in different pathological conditions.     

Melatonin-induced suppression of the pinealectomy-stimulated rat adrenal cortex mitotic activity

Pineal involvement in the regulation of adrenocortical mitotic activity has recently been suggested. It has been shown that melatonin (Mel) decreased the mean mitotic activity rate (MMAR) of the adrenal cortex both in vivo and in organ culture. The goal of the present study was to test the influence of pinealectomy (PX) and/or Mel-treatment on the MMAR of adrenocortical cells, as well as on the adrenal weight in rats. The stathmokinetic method was used in the study. It was found that PX significantly increased the MMAR of the adrenocortical cells. Moreover, Mel suppressed the proliferogenic effect of PX on the rat adrenocortical cells. Melatonin alone did not significantly affect the mitotic activity of the adrenal cortex. None of the three experimental procedures, i.e. Mel, PX and Mel-treatment of pinealectomized animals significantly affected the adrenal weight. The present data suggest that Mel may be involved in the inhibitory control of adrenocortical cell proliferation.     

Modulation of the effects of ascorbic acid on lipid peroxidation by tocopherol in adrenocortical mitochondria

Studies were done to evaluate the role of alpha-tocopherol in modulating the effects of ascorbic acid (AA) on lipid peroxidation (LP) by adrenocortical mitochondria. In control mitochondria from the inner (zona reticularis) or outer (zona fasciculata plus zona glomerulosa) zones of the guinea pig adrenal cortex, subphysiological concentrations of AA stimulated LP but higher levels had little or no effect. However, after depletion of adrenal tocopherol, even physiological concentrations of AA exerted prooxidant effects, stimulating LP. To assess the antioxidant potency of AA, its effects to inhibit ferrous ion (Fe2+)-induced LP were determined. Mitochondria from the outer zone contained far more alpha-tocopherol than those from the inner zone and were more sensitive to the antioxidant effects of AA. After tocopherol depletion, the antioxidant potency of AA in outer zone mitochondria decreased, but there was little change in the inner zone. The results indicate that the actions of AA are determined in part by mitochondrial tocopherol content, and, as a result, vary in the different zones of the adrenal cortex.     

Discriminatory processing of the precursor forms of cytochrome P-450scc and adrenodoxin by adrenocortical and heart mitochondria

The mitochondrial proteins involved in adrenocortical steroidogenesis are synthesized as higher molecular weight precursors which require processing by the mitochondria to their mature sizes. The post-translational maturation of two of these proteins has been examined: the cholesterol side chain cleavage cytochrome P-450 (P-450scc) and the iron-sulfur protein, adrenodoxin. Total translation products synthesized in a cell-free system programmed by bovine adrenocortical poly(A+) RNA were incubated with isolated bovine adrenocortical or heart mitochondria followed by immunoisolation of radiolabeled P-450scc or adrenodoxin. In the presence of adrenocortical mitochondria, the precursor form of P-450scc was converted into a trypsin-resistant form that had the same molecular weight as mature P-450scc. Unlike adrenocortical mitochondria, heart mitochondria were unable to process the P-450scc precursor which remained unaltered and trypsin-sensitive. In addition, a matrix fraction of heart mitochondria did not cleave the P-450scc precursor. In contrast, the adrenodoxin precursor did not exhibit similar specificity as it was processed to the mature form by both adrenocortical and heart mitochondria. Also, the adrenocortical mitochondria were not restricted to processing endogenous proteins as they imported and cleaved the precursor to ornithine transcarbamylase. The results indicate that some mitochondrial precursor proteins have tertiary structures which allow them to be recognized by all mitochondria while other mitochondrial precursor proteins have structures recognizable by only specialized mitochondria.     

Population dynamics of mitochondria II. Turnover and ageing of rat liver mitochondria

Membrane-bound multi-protein complexes in mitochondria are provisionally classified into four categories based on possible mechanism of their assembly and degradation. These mechanisms may be investigated by the use of pulse-labeled radioactive markers which are not re-utilizable. Age dependent assembly is defined as that mechanism by which one or more of the pulse-labeled subunits are assembled into a complex, only while this complex is assembled. If the labeled sub-units can be taken up by the complex randomly during its life-span, then the mechanism is called age-independent assembly. Age-dependent degradation was defined as that mechanism by which the labeled subunits are decomposed, only when the complex is being degraded as an entity. If the labeled subunits are decomposed randomly, the mechanism is called age-independent degradation. Four categories are made by combining each of the assembly and degradation mechanisms. A differential equation was obtained to describe the fate of labeled sub-units that follow the age-dependent assembly and age-dependent degradation. Also derived was an equation for the age-independent assembly and age-dependent degradation. The other two categories which involve the age-independent degradation after age-dependent or age-independent assembly are described by single exponential kinetics. Practical application of the equations is illustrated with the use of experimental data on mitochondrial turnover found in the literature which suggests that the pulse-labeled proteins in rat liver mitochondria may follow the age-dependent assembly and degradation. The present attempts to introduce the concept of ageing into multi-protein complexes in mitochondria are the extensions of the steady state theory of mutation by Eyring & Stover (1970).     

Primary structure of hepatoredoxin from bovine liver mitochondria

The primary structure of hepatoredoxin from bovine liver mitochondria was established. It consists of 117 amino acid residues. The identity of the amino acid sequences of bovine hepatoredoxin and adrenodoxin from bovine adrenal cortex mitochondria was shown. It is assumed that the role of a ferredoxin component in mitochondrial steroid-hydroxylating systems from different organs is played by the same [2Fe-2S]-protein.     

Immunogold cytochemistry of cytochromes P-450 in porcine adrenal cortex. Two enzymes (side-chain cleavage and 11 beta-hydroxylase) are co-localized in the same mitochondria

In order to study the distribution of mitochondrial cytochromes P-450 in porcine adrenal glands, the glands of anesthetized pigs were fixed in situ. Polyclonal antibodies against two cytochromes P-450, i.e., C27 side-chain cleavage enzyme and 11 beta-hydroxylase, were used to study the distribution of these enzymes in cryosections of the adrenal cortex. Ultrathin cryosections were evaluated by both protein-A/gold/silver immunocytochemistry and immunoelectron microscopy using double labeling with protein-A/colloidal-gold. At light microscopy, the two cytochrome P-450 enzymes were found to be broadly distributed in both the fasciculata and glomerulosa zones of the adrenal cortex. Quantitative immunoelectron microscopy revealed that both enzymes were localized only in mitochondria, in which they were present on the inner aspects of the inner mitochondrial membrane. Both cytochromes P-450 were demonstrable in all of the mitochondria examined, and statistical evaluation of the ratios of the two enzymes present in individual mitochondria yielded a normal distribution curve. Since no evidence was found for the preferential localization of either enzyme in a special population of mitochondria, we conclude that all mitochondria of the adrenal cortex contain both enzymes. We discuss implications of these findings with respect to the regulation of steroidogenesis.     

Studies on the transition of the cristal membrane from the orthodox to the aggregated configuration. I: Topology of bovine adrenal cortex mitochondria in the orthodox configuration

Bovine adrenal cortex mitochondria examined by electron microscopyin situ orin vitro in 0·25 M sucrose have an unusual cristal membrane structure. The cristae usually appear as unconnected vesicles within a double membrane system. A few of the vesicles appear to be attached to the inner boundary membrane or to one or more other vesicles. The configuration of such mitochondria will be defined as the orthodox configuration. In this communication we will provide evidence that the inner membrane is not composed of multiple vesicles, but is one continuous membrane with tubular invaginations, and that these invaginations alternately are ballooned out and squeezed down. A mechanism has been proposed to account for the differentiated structure of the cristae of adrenal cortex mitochondria.     

Investigations on the turnover of adrenocortical mitochondria

Summary The effects of ACTH on the mitochondria of adult human adrenocortical cells cultured in vitro were investigated by electron microscopic and stereological methods. It was found that ACTH induces an increase in the volume of the mitochondrial compartment, which is due to both a hypertrophy and an increase in number of the organelles. The hypothesis that ACTH controls the growth and proliferation of human adrenocortical mitochondria is discussed.     

Ferrous ion-mediated cytochrome P-450 degradation and lipid peroxidation in adrenal cortex mitochondria.

The relationship between the degradation reaction of cytochrome P-450 and lipid peroxidation was studied utilizing bovine adrenal cortex mitochondria. The two reactions were found to be closely correlated in terms of their response to storage of the mitochondrial preparation, stimulation by Fe2+, inhibition by EDTA and their initiation by cumene hydroperoxide. Both reactions were also found not to be inhibited by catalase, superoxide dismutase, 1,4-diazabicyclo-(2,2,2)-octane and alcohols, indicating that H2O2, superoxide, singlet oxygen and hydroxyl radicals do not participate in these reactions. Yet, diphenylamine proved to be a powerful inhibitor for both reactions, suggesting the involvement of a radical species. Cumene hydroperoxide could induce these two reactions at below 0.1 mM concentrations in the presence of molecular oxygen. The chemiluminescence observed during the Fe2+-mediated lipid peroxidation reaction which was not inhibited by either superoxide dismutase or 1,4-diazabicyclo-(2,2,2)-octane, was biphasic: one was a rapid burst; and the other was a slowly increasing emission. The latter portion of the emission of light coincided with the formation of malondialdehyde. These results indicate that in adrenal cortex mitochondria the degradation of cytochrome P-450 is closely related to lipid peroxidation.     

The active form of cytochrome P-450 from bovine adrenocortical mitochondria.

Cytochrome P-450 from bovine adrenocortical mitochondria exists in three forms of molecular weight: 850,000 (protein 16), of one-half (protein 8), and of one-quarter of this value (protein 4). The forms of the enzyme are named according to the number of subunits and all appear to be active in converting cholesterol to 3beta-hydroxy-5-pregnen-20-one (side chain cleavage) (Shikita, M., and Hall, P.F. (1973) J. Biol. Chem. 248, 5606). To determine whether all three forms are active at their characteristic molecular weights, the three cytochromes were each layered onto separate sucrose density gradients and centrifuged at 49,000 rpm for 60 min; the gradients contained all the factors necessary for side chain cleavage including one of the following substrates: cholesterol, 20S-hydroxycholesterol, and 20S,22R-dihydroxycholesterol. Regardless of the form of P-450 layered onto the gradient and regardless of the substrate, enzyme activity (side chain cleavage) was observed only in fractions corresponding to a sedimentation coefficient of 20 to 22 S which is that for protein 16. No activity was observed at S values corresponding to either protein 8 or protein 4. These findings indicate that the active form of cytochrome P-450 from adrenocortical mitochondria is that containing 16 subunits, i.e. the form in which the cytochrome is normally isolated from adrenal mitochondria. Forms consisting of eight and four subunits which can be prepared from protein 16 become active only by forming protein 16, at least in an aqueous medium in vitro.     

Electron spin resonance studies of membrane proteins in erythrocytes in myotonic muscular dystrophy.

A goat antibody produced against bovine adrenal ferredoxin has been employed to establish immunochemically the involvement of adrenal ferredoxin in the cholesterol side-chain cleavage reaction catalyzed by mammalian adrenal mitochondria. When added to preparations of bovine adrenocortical mitochondria, this antibody was found to inhibit the conversion of cholesterol to pregnenolone and progesterone, the 11β-hydroxylation of deoxycorticosterone and the NADPH-dependent reduction of cytochrome c. These observations demonstrate that, similar to the NADPH-cytochrome c reductase and steroid 11β-hydroxylase reactions, adrenal ferredoxin is also required for the oxidative cleavage of the cholesterol side-chain catalyzed by bovine adrenocortical mitochondria.The goat antibody to bovine adrenal ferredoxin was also found to interact with the comparable iron-sulfur proteins present in mitochondria prepared from sheep, rat, mouse, cat, dog, guinea pig, rabbit, and human adrenals. The interaction of the antibody with these iron-sulfur proteins resulted in the inhibition of both the cholesterol side-chain cleavage and NADPH-cytochrome c reductase activities catalyzed by these adrenal mitochondria. The NADH-dependent reduction of cytochrome c catalyzed by mammalian adrenal mitochondria was not inhibited by the goat antibody to adrenal ferredoxin. These results demonstrate the immunochemical similarity existing among mammalian adrenal ferredoxins and their involvement in the adrenal cholesterol side-chain cleavage reaction.     

Import and processing of the precursor of cytochrome P-450(SCC) by bovine adrenal cortex mitochondria

Isolated bovine adrenal cortex mitochondria imported in vitro synthesized pre-P-450(SCC) and processed it to the mature form. Partial radio-sequencing of the processed P-450(SCC) gave a result identical with that for authentic P-450(SCC). Rat liver mitochondria also imported pre-P-450(SCC) and processed it to the mature form, whereas bovine heart mitochondria were unable to import and process pre-P-450(SCC) although both mitochondrial preparations imported and processed pre-adrenodoxin. The pre-P-450(SCC) processing activity of bovine adrenal cortex mitochondria was associated with the matrix side surface of the inner membrane. The processing protease could be solubilized by sodium cholate and partially purified by ammonium sulfate fractionation. The partially purified processing protease cleaved pre-P-450(SCC) at the correct position. It was also active in processing pre-P-450(11 beta) but inactive toward pre-adrenodoxin. Bovine heart mitochondria lacked the processing activity to pre-P-450(SCC). The localization of pre-P-450(SCC) and mature P-450(SCC) in bovine adrenal cortex mitochondria was examined. Mature P-450(SCC) processed by the mitochondria was found associated with the matrix-side surface of the inner membrane, which is the correct location of P-450(SCC) in the cell. In the presence of o-phenanthroline, pre-P-450(SCC) was imported into the organelles without being processed and remained soluble in the matrix. The incorporation of newly processed mature P-450(SCC) into the inner membrane was also observed when pre-P-450(SCC) was incubated with inner membrane vesicles. Mature P-450(SCC) generated in vitro from pre-P-450(SCC) by the partially purified processing protease was incorporated not only into the inner membrane vesicles but also into bovine adrenal cortex microsomes. These findings suggested that the processing of pre-P-450(SCC) occurred prior to the incorporation of mature-P-450(SCC) into the inner membrane.     

The relationship between NADPH-dependent lipid peroxidation and degradation of cytochrome P-450 in adrenal cortex mitochondria

The relationship between NADPH-dependent lipid peroxidation and the degradation of cytochrome P-450 has been studied in bovine adrenal cortex mitochondria. Malondialdehyde formation is accompanied by a corresponding decrease in total cytochrome P-450 content. Inhibitors of lipid peroxidation also prevent the loss of cytochrome P-450, further demonstrating a direct relationship between NADPH-dependent lipid peroxidation and degradation of P-450. To differentiate between cytochrome P-450(11)beta and P-450scc, steroid-induced difference spectra were used to evaluate P-450 degradation. These measurements provide the first evidence that both P-450's are degraded during NADPH-dependent lipid peroxidation with P-450(11)beta being much more susceptible to this process.     

19-Hydroxylation of 18-hydroxy-11-deoxycorticosterone by adrenal mitochondria prepared from various animal species

We have recently reported that bovine adrenocortical cytochrome P-45011 beta catalyzes 19-hydroxylation of 18-hydroxy-11-deoxycorticosterone (18(OH)DOC) in addition to 11 beta-hydroxylation of the steroid. In this report, we examine the presence of these two activities in 18(OH)DOC and 11 beta- and 18-hydroxylation activities on deoxycorticosterone (DOC) among the adrenal mitochondria prepared from man, ox, pig, rabbit, guinea-pig and rat. The results indicate that these animals could be classified into three groups with respect of these hydroxylation activities. Mitochondria of the first group comprising ox and pig showed rather high 19- and 11 beta-hydroxylation activities on 18(OH)DOC compared to the hydroxylation activities on DOC. Mitochondria prepared from the second group which comprised rabbit, guinea-pig and man showed low 19-hydroxylation activity on 18(OH)DOC, whereas the 11 beta-hydroxylation of 18(OH)DOC well occurred in these species. The last group comprising rat had very low activity both of 11 beta- and 19-hydroxylations when 18(OH)DOC was used as the substrate, whereas both 11 beta- and 18-hydroxylations of DOC were high in rat adrenal mitochondria. No significant difference of these activities could be found between zona glomerulosa cells and zonae fasciculata-reticularis cells of bovine adrenal cortex, and between adrenal mitochondria from spontaneously hypertensive rat and those from WKY normotensive rat.     

Cholesterol-hydroxylating cytochrome P-450 from bovine adrenal cortex mitochondria and human placenta: immunochemical properties and structural characteristics

An immunochemical comparison of components of cholesterol side chain cleavage system from bovine adrenocortical and human placental mitochondria has been carried out. Antibodies against cytochrome P-450scc, adrenodoxin reductase and adrenodoxin from bovine adrenocortical mitochondria were shown to cross-react with corresponding antigens of human placental mitochondria. A highly sensitive immunochemical method for cytochrome P-450scc determination has been developed. Limited proteolysis of cytochrome P-450scc of human placental mitochondria was studied, and the products of trypsinolysis were identified using antibodies against cytochrome P-450scc and fragments of its polypeptide chain: F1, F2 and F3. Immunochemical relatedness of ferredoxins from bovine adrenocortical and human placental mitochondria allowed one to develop a fast and efficient method for cytochrome P-450scc purification from human placental mitochondria by affinity chromatography on adrenodoxin-Sepharose.     

Nestin expression in normal adrenal gland and adrenocortical tumors

Human adrenocortical cells have been shown to express cytokeratins and vimentin. Nestin is an intermediate filament protein that is mainly expressed in the developing nervous system and that has been recently reported in rat adrenal gland as well. Using immunohistochemical and biochemical approaches, the present study demonstrates that nestin is constantly expressed in situ in the cortex of normal human adrenal glands. Nestin expressing cells were prevalently located in the zona reticularis but some positive cells could be spotted in the zona fasciculata as well. Moreover, patches of nestin-positive cells have been constantly detected on sections of cortical adenomas. In contrast, adrenal carcinomas displayed a variable number of nestin-immunoreactive cells that in some cases were virtually absent. Samples of renal clear cell carcinoma metastasis in the adrenals were also examined which did not show nestin-immunoreactivity. We propose that a positive nestin-immunoreaction could be useful in differential diagnosis of clear cell tumors in adrenal glands.     

Oxidation of glycerol-3-phosphate in porcine and bovineadrenal cortex mitochondria

The capabilities of porcine adrenal cortex mitochondria to oxidize glycerol-3-phosphate (GP) were studied. In comparison with bovine adrenal cortex mitochondria, porcine mitochondria oxidized GP about three times more actively (18.9 vs 6.1 nmol O(2)/min per mg protein in the presence of ADP) and the activity of mitochondrial glycerol-3-phosphate dehydrogenase was about four times higher (33.4 vs 8.2 nmol/min per mg protein). In porcine adrenal cortex mitochondria we found similar values for succinate and GP oxidation both in the absence and presence of ADP or deoxycorticosterone (DOC). Rotenone sensitivity of DOC stimulation of GP oxidation indicated that porcine adrenal cortex mitochondria are able to oxidize GP and thus to generate NADPH from GP, presumably via reverse electron transport followed by energy-dependent NADH-NADP transhydrogenation.