The occurrence and metabolism of 20 alpha-hydroxycholesterol in bovine adrenal preparations

Tracking the subcellular fate of 20(s)-hydroxycholesterol with click chemistry reveals a transport pathway to the Golgi

Oxysterols, oxidized metabolites of cholesterol, are endogenous small molecules that regulate lipid metabolism, immune function, and developmental signaling. Although the cell biology of cholesterol has been intensively studied, fundamental questions about oxysterols, such as their subcellular distribution and trafficking pathways, remain unanswered. We have therefore developed a useful method to image intracellular 20(S)-hydroxycholesterol with both high sensitivity and spatial resolution using click chemistry and fluorescence microscopy. The metabolic labeling of cells with an alkynyl derivative of 20(S)-hydroxycholesterol has allowed us to directly visualize this oxysterol by attaching an azide fluorophore through cyclo-addition. Unexpectedly, we found that this oxysterol selectively accumulates in the Golgi membrane using a pathway that is sensitive to ATP levels, temperature, and lysosome function. Although previous models have proposed nonvesicular pathways for the rapid equilibration of oxysterols between membranes, direct imaging of oxysterols suggests that a vesicular pathway is responsible for differential accumulation of oxysterols in organelle membranes. More broadly, clickable alkynyl sterols may represent useful tools for sterol cell biology, both to investigate the functions of these important lipids and to decipher the pathways that determine their cellular itineraries.

Oxysterols are allosteric activators of the oncoprotein Smoothened

Oxysterols are a class of endogenous signaling molecules that can activate the Hedgehog pathway, which has critical roles in development, regeneration and cancer. However, it has been unclear how oxysterols influence Hedgehog signaling, including whether their effects are mediated through a protein target or indirectly through effects on membrane properties. To answer this question, we synthesized the enantiomer and an epimer of the most potent oxysterol, 20(S)-hydroxycholesterol. Using these molecules, we show that the effects of oxysterols on Hedgehog signaling are exquisitely stereoselective, consistent with the hypothesis that they function through a specific protein target. We present several lines of evidence that this protein target is the seven-pass transmembrane protein Smoothened, a major drug target in oncology. Our work suggests that these enigmatic sterols, which have multiple effects on cell physiology, may act as ligands for signaling receptors and provides a generally applicable framework for probing sterol signaling mechanisms.

Other conceivable renditions of some of the oxidative processes used in the biosynthesis of steroid hormones

The generally accepted version (GAV) of the chemical processes by which the steroid hormones are biosynthesized cannot be considered to be an inerrant description of in vivo processes. Customarily this version is derived by piecing together the results obtained from several independent artificial in vitro incubation experiments. Extrapolation of such results from in vitro to in vivo requires untested assumptions which introduce varying degrees of uncertainty. In vitro incubation experiments reveal only what is possible; not what actually prevails in situ. Presented here are hypothetical alternative renditions of some of the oxidative processes involved in steroidogenesis. These versions suggest that some cytochrome P-450's catalyze the introduction of both oxygen atoms of dioxygen into an appropriate sterol precursor. The products are conceived as oxygen free radicals (peroxy or 1,2-cyclic peroxy) which serve as the "reactive intermediates" (the precursors) for the hormones. The true intermediates are not stable, isolable, hydroxylated compounds as they are customarily portrayed in the GAV. Central to these new renditions is the hypothesis that the appropriate P-450 introduces dioxygen into the precursor yielding either: A, a 20 peroxy sterol species or B, a species oxygenated at both C-17 and C-20 or C, a species oxygenated at both C-20 and C-21. In this hypothesis, A would serve as the precursor for progesterone, B, for the C19-androgens and C18-estrogens and C, for the mineralocorticoids (corticosterone and aldosterone) and the glucocorticoid (cortisol). How this version of steroidogenesis can be used to understand the etiologies of various genetically derived enzyme deficiency diseases of the adrenal and ovaries will be discussed. If as proposed here, the various polyfunctional cytochromes (P-450(scc), P-450(c17,) P-45011B1 (P-450(cortisol)), P-45011B2 (P-450(aldo)), etc.) catalyze conversions that are different from simple hydroxylations, the labels usually given these deficiency diseases may not be appropriate. More importantly, these new conceptions may clarify the etiology of some of the characteristic symptoms of these diseases that are not now adequately explained by the GAV.

The detection of 20S-hydroxycholesterol in extracts of rat brains and human placenta by a gas chromatograph/mass spectrometry technique

The presence of 20(S)-hydroxycholesterol in rat brains and human placenta has been established using the gas chromatography/mass spectrometry (GC/MS) select ion monitoring (SIM) technique. Identification was ensured by three criteria: the specific retention time when the compound emerges from the gas chromatogram and the two m/z ions (201 and 461amu) which are characteristic of its mass spectrum. The possible role of 20(S)-hydroxycholesterol in steroid hormone biosynthesis and in other biological processes is discussed.

17-Hydroxylase: an evaluation of the present view of its catalytic role in steroidogenesis

This survey analyses the evidence that has led to the belief that the catalytic role of 17-hydroxylase in the biosynthesis of cortisol, estradiol, testosterone and dehydroepiandrosterone is confined to two chemical reactions: pregnenolone-->17-hydroxypregnenolone-->dehydroepiandrosterone. This analysis suggests that the evidence supporting this view is not compelling enough to accept it unquestioningly. Different interpretations of the data can suggest other catalytic roles for 17-hydroxylase that are worthy of consideration. One such alternative is proposed.

Reflections on sterol sidechain cleavage process catalyzed by cytochrome P450(scc)

The essay examines the evidence upon which the presently accepted version of the mechanism of the cytochrome P450(scc)-catalyzed-cleavage of the sidechain of cholesterol is based. This analysis indicates that the generally held view of the process (two consecutive hydroxylations, followed by cleavage of the resulting glycol) most likely does not describe the true mechanism. The available evidence can not be used to support this traditional notion. Two alternative hypotheses are proposed.

Enhanced susceptibility of cholesteryl sulfate-enriched low density lipoproteins to copper-mediated oxidation

Cholesteryl sulfate (CS) is a minor component of cell membranes, also present in lipoproteins, and its exact function is unknown. Since oxidation of low density lipoproteins (LDL) is thought to be an important determinant of atherogenesis, we investigated the influence of CS enrichment on copper-mediated oxidation of LDL. CS was found to act as a pro-oxidant, as measured by lipid oxidation parameters. The results also suggest that these effects were dependent on the sulfate group since pure cholesterol or cholesteryl acetate did not promote Cu(2+)-mediated oxidation. Our findings imply that CS may affect the oxidizability and hence the potential atherogenicity of LDL.

Precursors of the neurosteroids

In addition to the neurosteroids pregnenolone and dehydroepiandrosterone, organic solvent extracts of rat brains contain related compounds that react with various reagents to yield additional amounts of these ketosteroids. Among the chemicals producing these increments are triethylamine, HCl, FeCl3, and Pb(OAc)4. Most revealing is the action of FeSO4 on these extracts. This reducing agent also converts components of the extract into the two neurosteroids, suggesting the presence of sterol hydroperoxides or peroxides in brain. The clues provided by this study indicate that the chemical nature of the steroidal constituents existing in extracts of mammalian brains remains to be determined. It is likely that their association with neurological functions will be better understood when the structures of these substances are established.

Steroidogenic potential of lyophilized mitochondria from bovine adrenocortical tissue

When incubated with [3H]cholesterol, a bovine adrenocortical mitochondrial pellet obtained by centrifugation at 12,000 x g yielded, as expected, only the C21O2 metabolites progesterone and pregnenolone. However, the steroidogenic potential of the 12,000 x g pellet fraction was augmented significantly by lyophilization. After lyophilization, the 12,000 x g pellet converted the sterol into C19 androgens and corticosteroids, in addition to C21O2 pregnane derivatives. Leaching the lyophilized mitochondrial fraction with either hexane or acetone increased substantially the yields of the metabolites. It did not change qualitatively the array of metabolites formed during in vitro incubation, but 5 alpha-reductase activity was unmasked by the washings, particularly with acetone. Thus, the fraction sedimented at 12,000 x g contains the complete complement of steroidogenic enzymes required for the biosynthesis of the aforementioned adrenal hormones. These results cast doubt upon the widely held belief that the various enzymes required for adrenocortical steroidogenesis are distributed between two different subcellular compartments, the mitochondrion and the endoplasmic reticulum.

Inhibition of mitochondrial cholesterol side-chain cleavage by structural analogs of cholesterol sulfate

Cholesterol sulfate inhibits cholesterol side-chain cleavage in adrenal mitochondria. In this study, analogs of cholesterol sulfate were evaluated for their ability to inhibit steroidogenesis. Structural requirements for inhibitory activity included a planar A-B ring junction, an intact side chain, and a 3 beta-ester group containing a single negative charge. This structural specificity argues against cholesterol sulfate acting solely as a membrane perturbing agent or a detergent, and also differs in some features from the specificity for binding to cytochrome P-450scc.

Stereochemistry of the incorporation of valine methyl groups into methylene groups in cephalosporin C

'Chiral methyl valines', i.e. samples of valine labelled stereospecifically in the methyl groups with 2H and 3H, were incorporated into cephalosporin C by a suspension of washed cells of Cephalosporium acremonium. Analysis by 3H n.m.r. of the cephalosporin C produced showed that the conversion of the 3-pro-S-methyl group of valine into the acetoxymethyl side-chain was a highly stereospecific process. By contrast, conversion of the 3-pro-R-methyl group into the endocyclic methylene group of the dihydrothiazine ring was shown to proceed by a non-stereospecific process.

Detection in bovine adrenal cortex of a lipoidal substance that yields pregnenolone upon treatment with alkali

Bovine adrenal cortical tissue contains a lipoidal derivative of pregnenolone (3beta-hydroxy-pregn-5-en-20-one) from which the free steroid can be liberated by treatment with alkali. Evidence for the presence of such an entity comes from examination of a nonpolar extract of tissue from which pregnenolone and its sulfate had been removed by chromatography. Treatment of the nonpolar fraction with alkali followed by exhaustive chromatographic analysis led to the detection of pregnenolone. The steroid was identified by both gas chromatography/mass spectrometry and double isotope procedures. Quantitative analysis indicated that the three forms of pregnenolone are present in bovine adrenal cortical tissue in the following amounts (mug/kg): lipoidal derivative, 290; free steroid, 435; and sulfate, 65. Because the only known metabolic function of pregnenolone is to serve as a precursor of the steroid hormones, these findings have far-reaching implications for steroid hormone biochemistry.

Biosynthesis of steroid sulfates by the boar testes

The steroidogenic enzymes present in boar testicular tissue have been shown to use steroid sulfates as substrates. Pregnenolone sulfate, doubly labeled with 3H in the nucleus and 35S, was incubated with the microsomal fraction of boar testicular tissue and a reduced triphosphopyridine nucleotide generating system and 17-hydroxypregnenolone sulfate as well as dehydroisoandrosterone sulfate were isolated. These products had the same 3H to 35S ratio as the substrate demonstrating that the conversions had taken place with the sulfate group intact. Thus testicular 17-hydroxylase and C-17,20-desmolase can convert delta5-3beta-yl sulfates into products which still contain the sulfate group at C-3. An unusual steroid sulfate, doubly labeled 5,16-androstadien-3beta-yl sulfate, was also isolated demonstrating that such an olefin can be biosynthetized via steroid sulfate pathways. In a second experiment small amounts of [3H]-21-hydroxypregnenolone sulfate were isolated from the incubation of [3H]pregnenolone sulfate with microsomes from boar testes. The isolation of the 21-hydroxylated steroid sulfate is taken as support for the hypothesis that delta16 steroids are biosynthesized from their C21 precursors by events that are initiated by oxygenation at C-21.