Peter F. Hall

Cytochrome P-450 C21scc : one enzyme with two actions : hydroxylase and lyase

Testis, adrenal, ovary and placenta contain a microsomal cytochrome P-450 that is capable of converting progesterone to androstenedione and pregnenolone to dehydroepiandrosterone. This conversion requires 17 alpha-hydroxylation followed by C17,20-lyase activity which are both catalyzed by this one protein. Gene cloning and Northern blotting reveal that, at least in man, the same gene is responsible for both testicular and adrenal enzymes. The enzyme was first purified from neonatal pig testis. Both the testicular and adrenal enzymes show a marked preference for the 5-ene substrate (pregnenolone) in keeping with the extensive use of the 5-ene pathway in that species. Affinity alkylation with 17 alpha-bromoacetoxyprogesterone reveals a conserved cysteine at the active site of the enzyme and confirms the conclusion that a single enzyme catalyzes both reactions. Under some circumstances the enzyme catalyzes only 17 alpha-hydroxylation to permit the formation of the C21 steroid cortisol. The regulation of lyase activity, i.e. the determination of the extent to which the second activity is expressed, results from the availability of P-450 reductase. No doubt the greater concentration of this protein in testicular as opposed to adrenal microsomes (x 3.5) is responsible for the production of androgens in the testis and cortisol in the adrenal. Testicular cytochrome b5 also specifically stimulates lyase activity and also causes the porcine enzyme to catalyze a new reaction, i.e. delta 16-synthetase, resulting in synthesis of the important pheromone androsta-4,16-dien-3-one from progesterone.

Roles of microfilaments and intermediate filaments in adrenal steroidogenesis.

The problem for the steroidogenic cell if it is to accelerate steroid synthesis in response to trophic stimulation, consists in moving cholesterol from the sites of synthesis and storage to mitochondria at an accelerated rate. The most intensely studied situation is that in which the sterol is stored as ester in lipid droplets. Cholesterol ester must be de‐esterified and transported to mitochondria where steroid synthesis begins. Since droplets and mitochondria are now known to be attached to intermediate filaments and since these structures are not contractile, it appears to be necessary to invoke the actions of other cytoskeletal elements. Actin microfilaments are involved in cholesterol transport so that it is tempting to propose that the contractile properties of actomyosin are used in this process.

Attachment of mitochondria to intermediate filaments in adrenal cells : relevance to the regulation of steroid synthesis

The rate of steroid synthesis is regulated by the rate of transport of cholesterol from lipid droplets to mitochondria. We have previously demonstrated that lipid droplets in adrenal cells are tightly attached to intermediate filaments. Here we now show that mitochondria colocalize with intermediate filaments in modified double indirect immunofluorescence and by electron microscopy of extracted adrenal cells. Direct contact between mitochondria and intermediate filaments was established by examination of stereo pairs of electron micrographs from extracted cells. The attachment of both droplets and mitochondria to intermediate filaments suggests possible mechanisms for this form of intracellular transport of cholesterol to mitochondria and hence for the regulation of steroid synthesis.

Hormonal regulation of estradiol biosynthesis, aromatase activity, and aromatase mRNA in rat ovarian follicles and corpora lutea

To determine the molecular basis for changes in aromatase (P450arom) activity in rat ovarian follicles and corpora lutea, seven clones for rat P450arom cDNA have been identified and isolated from a rat granulosa cell lambda gt11 cDNA expression library using a 62 mer deoxyoligonucleotide probe (derived from an amino acid sequence of purified human placental aromatase) and a human placental P450arom cDNA probe. One of the rat P450arom cDNA clones contained an insert 1.2 kb in size. Both the human 1.8 kb cDNA and the rat 1.2 kb cDNA probes hybridized to a single species of P450arom mRNA that was 2.6 kb in size. Northern blot analysis revealed that corpora lutea isolated on day 15 of pregnancy contained high amounts of P450arom mRNA, whereas granulosa cells of antral follicles of hormonally primed, hypophysectomized rats (i.e., those from which mRNA was isolated to construct the cDNA library) contained only low amounts of P450arom mRNA. The lower amounts of P450arom in granulosa cells of preovulatory follicles in the estradiol-follicle-stimulating hormone primed hypophysectomized rats were unexpected because follicles incubated in medium containing testosterone substrate produce more estradiol than do corpora lutea isolated on day 15 of pregnancy and incubated under similar conditions. Additional studies will determine the hormonal events responsible for the elevated amounts and constitutive maintenance of P450arom mRNA and aromatase activity in luteal cells in vivo and in vitro.

Structure-function studies of human aromatase ☆

Site-directed mutagenesis experiments have been carried out to determine the structure-function relationship of human aromatase. By sequence comparison, the region in aromatase that corresponds to the distal helix of cytochrome P-450cam has been identified to be Gln-298 to Val-313. Eight aromatase mutants with changes in this region, i.e. C299A, E302L, P308F, D309N, D309A, T310S, T310C, and S312C, have been generated using a mammalian cell stable-expression system. The results from site-directed mutagenesis studies indicate that the region containing Gln-298 to Val-313 is indeed a very important part of the active site of aromatase. The catalytic properties of P308F, D309N, and D309A have been examined in detail and are discussed. Active site-directed labeling is also an important approach to investigate the structure-function relationship of aromatase. HPLC-linked electrospray mass spectrometry is indicated as a useful technique for the characterization of active site-directed probe-modified enzyme. The mass spectral analysis of aromatase suggests that aromatase is glycosylated.

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.

The roles of microfilaments and intermediate filaments in the regulation of steroid synthesis

Much of the cholesterol used in steroid synthesis is stored in lipid droplets in the cytoplasm of steroid-forming cells. The cholesterol ester in these droplets is transported to the inner mitochondrial membrane where it enters the pathway to steroid hormones as free cholesterol--the substrate for the first enzyme, namely P450scc. It has been shown that this transport process governs the rate of steroid synthesis and is specifically stimulated by ACTH and its second messenger. The stimulating influence of ACTH on cholesterol transport is inhibited by cytochalasins, by monospecific anti-actin and by DNase I demonstrating that the steroidogenic cell must possess a pool of monomeric actin available for polymerization to F actin if it is to respond to ACTH and cyclic AMP. It has been shown that the two structures involved in cholesterol transport (droplets and mitochondria) are both bound to vimentin intermediate filaments in adrenal and Leydig cells. In addition these filaments are closely associated with the circumferential actomyosin ring in which they are crosslinked by actin microfilaments. In permeabilized adrenal cells Ca2+/calmodulin phosphorylates vimentin and this change is known to disrupt intermediate filaments and to cause contraction of actomyosin by phosphorylating myosin light chain kinase. Ca2+/calmodulin stimulated cholesterol transport and steroid synthesis and causes rounding of the responding cells by contraction of the actomyosin, if ATP is also added at the same time. Other agents that disrupt intermediate filaments include anti-vimentin plus ATP in permeabilized cells which also results in rounding of the cell. Acrylamide exerts a similar effect in intact adrenal cells and in addition causes rounding of the cells and increase in steroid synthesis without increase in cyclic AMP. It is also known that if adrenal cells are grown on surfaces treated with poly(HEMA), the cells grow in rounded form and steroid synthesis is increased in proportion to the degree of rounding (r = 0.92). This response does not involve increase in cellular levels of cyclic AMP. It is proposed that in vivo where the cell is always round and cannot show more than strictly limited change in shape, ACTH activates Ca2+/calmodulin possibly by redistributing cellular Ca2+. Ca2+/calmodulin in turn promotes phosphorylation of vimentin and myosin light chain. The first of these phosphorylations shortens intermediate filaments and the second promotes contraction of the actomyosin ring with internal shortening and approximation of lipid droplets and mitochondria. Details of the earlier events (activation of Ca2+/calmodulin) and later changes (transfer of cholesterol to the inner membrane) remain to be elucidated. It is clear however that the action of ACTH requires increase in cellular cyclic AMP. These experimental responses bypass this step in the response to ACTH.

Conversion of 11-deoxycorticosterone and corticosterone to aldosterone by cytochrome P-450 11β-/18-hydroxylase from porcine adrenal

Highly purified cytochrome P-450 11 beta-/18-hydroxylase and the electron carriers adrenodoxin and adrenodoxin reductase were prepared from porcine adrenal. When the enzyme was incubated with the electron carriers, 11-deoxycorticosterone (DOC) and NADPH, the following products were isolated and measured by HPLC: corticosterone, 18-hydroxy-11-deoxycorticosterone (18-hydroxyDOC), 18-hydroxycorticosterone and aldosterone. All of the DOC consumed by the enzyme can be accounted for by the formation of these four steroids. Aldosterone was identified by mass spectroscopy and by preparing [3H]aldosterone from [3H]corticosterone followed by recrystallization at constant specific activity after addition of authentic aldosterone. Corticosterone and 18-hydroxycorticosterone were also converted to aldosterone. Conversion of corticosterone and 18-hydroxycorticosterone to aldosterone required P-450, both electron carriers, NADPH and substrate. The reaction is inhibited by CO and metyrapone. Moreover, all three activities of the purified enzyme decline at the same rate when the enzyme is kept at room temperature for various periods of time and when the enzyme is treated with increasing concentrations of anti-11 beta-hydroxylase (IgG) before assay. It is concluded that cytochrome P-450 11 beta-/18-hydroxylase can convert DOC to aldosterone via corticosterone and 18-hydroxycorticosterone. The stoichiometry of this conversion was found to be 3 moles of NADPH, 3 moles of H+ and 3 moles of oxygen per mole of aldosterone produced.

Indirect immunofluorescence modified to display two antigens with one light filter

SummaryWe present a modification of double indirect immunofluorescence in which we used four antibodies raised in three species to visualize two different antigens. The procedure, which relies on dual recognition of a secondary antibody, requires that one primary antibody and one of the secondary antibodies be raised in the same species. As the two secondary antibodies are conjugated to two different fluorochromes, both of the antigens studied are visualized with one light filter while only one antigen is displayed with another filter. This, in turn, allows more efficient comparison of the distribution of the two antigens in a single field or photograph than is possible by comparing two fields or photographs by conventional double staining. The method is especially useful for determining possible co-localization of two cellular structures. We illustrate the method in adrenal cells in which mitochondria and intermediate filaments are seen to be co-localized.

CYTOCHROMES P-450 IN STEROIDOGENESIS: ARE THESE ENZYMES MORE SPECIFIC THAN THOSE OF DRUG METABOLISM?

1. In contrast to drug‐metabolizing cytochromes P‐450, the corresponding ster‐oidogenic enzymes appear to be highly specific with respect to substrates, reactions catalysed, and the sites in the substrate molecule that are attacked.