Reductive inactivation of digitoxin by Eubacterium lentum cultures

The obligate anaerobe Eubacterium lentum inactivated the cardiac glycoside digitoxin by reducing the double bond in the lactone ring. This conversion was quantitative when the substrate was incubated at a concentration of 10 micrograms/ml. The reduction reaction coincided with the growth phase of the bacterium. The stereochemical configuration at C-20 of the reduction product dihydrodigitoxin was found to be R. Incubation of digitoxigenin and its mono- and bisdigitoxosides individually with E. lentum led to the formation of their respective dihydro derivatives. The configuration at C-20 of these reduced metabolites was also found to be R.     

Reduction of digoxin to 20R-dihydrodigoxin by cultures of Eubacterium lentum.

The anaerobic bacterium Eubacterium lentum, a common constituent of the intestinal microflora, inactivates digoxin by reducing the unsaturated lactone ring. Reduction of the cardiac glycoside by growing cultures of E. lentum ATCC 25559 proceeded in a stereospecific manner, with the 20R-dihydrodigoxin constituting more than 99% of the product formed. This is in contrast to the 3:1 ratio of 20R and 20S epimers formed in the chemical catalytic hydrogenation. Formation of the reduced glycosides proceeded quantitatively when an overall concentration of 10 micrograms/ml was added to the cultures. E. lentum did not hydrolyze the digitoxose sugars from C-3 of the parent glycoside. However, the synthetically prepared sugar-hydrolyzed metabolites (digoxigenin, digoxigenin monodigitoxoside, and digoxigenin bisdigitoxoside) were reduced to the corresponding dihydro metabolites. Repetition of the experiments with a feces sample from a volunteer who was known to be a converter of digoxin to dihydrodigoxin gave results identical to those obtained with pure E. lentum cultures.     

Reduction of digoxin to 20R-dihydrodigoxin by cultures of Eubacterium lentum

The anaerobic bacterium Eubacterium lentum, a common constituent of the intestinal microflora, inactivates digoxin by reducing the unsaturated lactone ring. Reduction of the cardiac glycoside by growing cultures of E. lentum ATCC 25559 proceeded in a stereospecific manner, with the 20R-dihydrodigoxin constituting more than 99% of the product formed. This is in contrast to the 3:1 ratio of 20R and 20S epimers formed in the chemical catalytic hydrogenation. Formation of the reduced glycosides proceeded quantitatively when an overall concentration of 10 micrograms/ml was added to the cultures. E. lentum did not hydrolyze the digitoxose sugars from C-3 of the parent glycoside. However, the synthetically prepared sugar-hydrolyzed metabolites (digoxigenin, digoxigenin monodigitoxoside, and digoxigenin bisdigitoxoside) were reduced to the corresponding dihydro metabolites. Repetition of the experiments with a feces sample from a volunteer who was known to be a converter of digoxin to dihydrodigoxin gave results identical to those obtained with pure E. lentum cultures.     

Stereochemistry of sodium borohydride reduction of tryptophan synthase of Escherichia coli and its amino acid Schiff's bases

Tryptophan synthase alpha 2 beta 2 complex containing [4'-3H]pyridoxal phosphate was reduced with sodium borohydride in the presence of various substrates and analogs in an attempt to trap reaction intermediates. Reduction in the presence of L-serine gave noncovalently bound radioactive material which was identified as phosphopyridoxylalanine, presumably resulting from reduction of the intermediate Schiff's base formed between pyridoxal phosphate and alpha-aminoacrylate. The tritium in this compound was located in the pro-R position at C-4', indicating that reduction of the Schiff's base double bond had occurred on the Si face at C-4'. On the other hand, analysis of phosphopyridoxyllysine obtained by hydrolysis of the reduced [3H]pyridoxal-P-alpha 2 beta 2 protein showed that the internal Schiff's base had been reduced on the C-4' Re face, suggesting a cofactor reorientation upon substrate binding. Analysis of phosphopyridoxylalanine from a reduction of unlabeled alpha 2 beta 2 complex in the presence of (2S,3R)-[2,3-2H2]serine with tritiated sodium borohydride demonstrated the presence of tritium at C-4' (50%), C-2 (20%), and C-3 (30%). According to the configuration at C-3, reduction of the phosphopyridoxal-alpha-aminoacrylate Schiff's base has occurred from the same side of the molecule at C-4' and C-3.     

Some biological activities of a series of 9a-homo-9,11-epoxy prostanoic acid analogues

A number of stereochemical variants at C-8, C-12 and C-15 of 9a-homo-9,11-epoxy prostaglandins (PGs) have been examined for in vivo activity on blood pressure, bronchial resistance, tracheal segment pressure, heart rate and on intestinal and uterine contractility in artificially respired anaesthetised guinea-pigs; and on blood pressure and blood platelet aggregation in rats (using the extra-corporeal filter-aorta loop technique). In vitro tests for smooth muscle activity were carried out on the isolated rat fundus strip, the guinea-pig tracheal chain and the rat uterus. The following was found: 1. In the guinea-pig, in vivo, all the homo-epoxy PGs were vasopressor and bronchoconstrictor following bolus injections of 250 micrograms i.v. The effects on heart rate, and intestinal and uterine contractility were equivocal. The configurations at the chiral centres, C-8, C-12 and C-15 play an important role in determining potency. The 15-(S)-hydroxy derivatives were the most potent in stimulating vascular and respiratory muscle. The 8-iso configuration appeared to enhance potency amongst the 15-(S)-hydroxy compounds. The 15-(R)-hydroxy configuration markedly reduced constrictor potency. The same pattern of activity was seen on rat blood pressure, in vivo. The 15-(S)-hydroxy configuration combined with the 8-iso configuration had the most potent constrictor activity, while the 15-(R)-hydroxy group negated this and even led, in the case of the natural configuration at C-8 and C-12, to vasodepression. 2. In vitro, the activity on the rat fundus and guinea-pig tracheal chain followed the same pattern. The 15-(S)-hydroxy derivatives were very much more potent than the 15-(R)-hydroxy derivatives at contracting the smooth muscle preparations. Uterine muscle appeared to be relaxed by the PGs with the natural configuration at C-8 and C-12, with the 15-(R)-hydroxy compound exhibiting greater activity. 3. Inhibition of ADP-induced rat blood platelet aggregation after "intra-arterial" administration was shown only by the derivatives with a single change in the natural configuration either at C-8 or at C-15. Additional changes either resulted in inactivity or, in the case of the 8,12-di-iso-15-(S)-hydroxy compound, even reversed the effect to aggregation. The inhibition of aggregation was long lasting with both the 8-iso-15-(S)-hydroxy derivative and the 8,12-nat-15-(R)-hydroxy derivative. In the case of the latter compound, GBR-30731, activity increased during the 30 min after administration. GBR-30731 deserves further investigation as a platelet aggregation inhibitor because of its relatively low smooth muscle stimulant (sometimes even relaxant effects) and its long lasting platelet aggregation inhibiting activity.     

Some biological activities of a series of 9a-homo-9,11-epoxy prostanoic acid analogues

A number of stereochemical variants at C-8, C-12 and C-15 of 9a-homo-9,11-epoxy prostaglandins (PGs) have been examined for in vivo activity on blood pressure, bronchial resistance, tracheal segment pressure, heart rate and on intestinal and uterine contractility in artificially respired anaesthetised guinea-pigs; and on blood pressure and blood platelet aggregation in rats (using the extra-corporeal filter-aorta loop technique). In vitro tests for smooth muscle activity were carried out on the isolated rat fundus strip, the guinea-pig tracheal chain and the rat uterus. The following was found:

1. In the guinea-pig, in vivo, all the homo-epoxy PGs were vasopressor and bronchoconstrictor following bolus injections of 250 μg i.v. The effects on heart rate, and intestinal and uterine contractility were equivocal. The configurations at the chiral centres, C-8, C-12 and C-15 play an important role in determining potency. The 15-(S)-hydroxy derivatives were the most potent in stimulating vascular and respiratory muscle. The 8-iso configuration appeared to enhance potency amongst the 15-(S)-hydroxy compounds. The 15-(R)-hydroxy configuration markedly reduced constrictor potency. The same pattern of activity was seen on rat blood pressure, in vivo. The 15-(S)-hydroxy configuration combined with the 8-iso configuration had the most potent constrictor activity, while the 15-(R)-hydroxy group negated this and even led, in the case of the natural configuration at C-8 and C-12, to vasodepression.

2. In vitro, the activity on the rat fundus and guinea-pig tracheal chain followed the same pattern. The 15-(S)-hydroxy derivatives were very much more potent than the 15-(R)-hydroxy derivatives at contracting the smooth muscle preparations. Uterine muscle appeared to be relaxed by the PGs with the natural configuration at C-8 and C-12, with the 15-(R)-hydroxy compound exhibiting greater activity.

3. Inhibition of ADP-induced rat blood platelet aggregation after “intra-arterial” administration was shown only by the derivatives with a single change in the natural configuration either at C-8 or at C-15. Additional changes either resulted in inactivity or, in the case of the 8,12-di-iso-15-(S)-hydroxy compound, even reversed the effect to aggregation.

The inhibition of aggregation was long lasting with both the 8-iso-15-(S)-hydroxy derivative and the 8,12-nat-15-(R)-hydroxy derivative. In the case of the latter compound, GBR-30731, activity increased during the 30 min after administration. GBR-30731 deserves further investigation as a platelet aggregation inhibitor because of its relatively low smooth muscle stimulant (sometimes even relaxant effects) and its long lasting platelet aggregation inhibiting activity./lt     

X-ray structure determination of mexiprostil, a new gastroprotective 16-methoxy-16-methyl-PGE1 analogue

Mexiprostil is a new gastroprotective 16-methoxy-16-methyl-PGE1 methyl ester. To assign the absolute configuration at C-15, a crystalline high-melting C-1 ester analog 5 11,15-dihydroxy-16-methoxy-16-methyl-9-oxoprost-13-en-1-oic acid 4-(4-bromobenzamide)phenyl ester (15R, 16R) was prepared and submitted to single crystal X-ray analysis. Since C-8, C-11, C-12 and C-16 are shown to have R configurations, the X-ray diffraction results established that the configuration at C-15 is also R.     

Biosynthesis of lasalocid A: biochemical mechanism for assembly of the carbon framework

Labeling experiments on the biosynthesis of the polyether antibiotic lasalocid A (1) using carboxylic acid precursors bearing 13C, 2H, and 3H labels at various positions established the following: (1) 2H or 3H at C-2 of propionate or 2H at C-2 of butyrate was partially retained at C-12 and C-14 of 1, respectively. (2) 2H at C-2 of propionate or at C-2 and C-3 of succinate did not label C-10. These and earlier data [Hutchinson, C. R., Sherman, M. M., Vederas, J. C., & Nakashima, T. T. (1981) J. Am. Chem. Soc. 103, 5953; Hutchinson, C. R., Sherman, M. M., McInnes, A. G., Walter, J. A., & Vederas, J. C. (1981) J. Am. Chem. Soc. 103, 5956] are consistent with a hypothesis for the stereochemical control of lasalocid A biosynthesis, whose main tenets are that the configuration of C-12 and C-14 is determined by the stereoselectivity of the carbon chain forming condensation between acyl thio ester and 2-carboxyacyl thio ester intermediates and that the configuration of C-11 and C-15 results from the reduction of 2-keto thio ester intermediates with opposing stereospecificities.     

C-25 epimeric 26-haloponasterone A: synthesis, absolute configuration and moulting activity

A convenient synthesis of inokosterone has been accomplished. Inokosterone exists as two C-25 epimers, which could be separated from each other through their diacetonide derivatives. The absolute configuration of these compounds was determined. Two C-25 epimers of 26-chloroponasterone A were synthesized from the respective C-25 epimeric inokosterone. Two epimeric 26-bromo and 26-iodoponasterone A compounds were also synthesized. Moulting activity of these compounds was evaluated using the Musca bioassay, and it was found that the (25S)-26-halo analogues were more active than the corresponding (25R)-26-halo analogues. Among the 25S series, an increase in activity with an increase in size of the halogen atom was observed, indicating that the steric factor was more important than the electronic factor in binding of these ecdysteroid analogues to the receptor. On the other hand, a decrease in activity with an increase in size of the halogen atom was noted in the 25R series, suggesting that the steric factor was less important than the electronic factor. The results indicated that the configuration at C-25 and the substituent at C-26 have significant influences on the interaction of ecdysteroids with their receptor.     

5-Substituted-2,3-diphenyltetrahydrofurans: a new class of moderately selective COX-2 inhibitors

The nature of C-5 substituent and the configuration at C-5 carbon of 2,3-diphenyltetrahydrofurans, with chiral centres at C-2, C-3 and C-5, show a remarkable influence on their COX-2 inhibition and selectivity. Out of the eight compounds investigated here, 1b with COOH group and R* configuration at C-5, and 2d with CH2SCH2CH3 group and S* configuration at C-5 have been identified as lead molecules for further studies on COX-2 inhibition.     

Biotransformation of ent-13-epi-manoyl oxides difunctionalized at C-3 and C-12 by filamentous fungi

Biotransformation of ent-3beta,12alpha-dihydroxy-13-epi-manoyl oxide with Fusarium moniliforme gave the regioselective oxidation of the hydroxyl group at C-3 and the ent-7beta-hydroxylation. The action of Gliocladium roseum in the 3,12-diketoderivative originated monohydroxylations at C-1 and C-7, both by the ent-beta face, while Rhizopus nigricans produced hydroxylation at C-7 or C-18, epoxidation of the double bond, reduction of the keto group at C-3, and combined actions as biohydroxylation at C-2/epoxidation of the double bond and hydroxylation at C-7/reduction of the keto group at C-3. In the ent-3-hydroxy-12-keto epimers, G. roseum originated monohydroxylations at C-1 and C-7 and R. nigricans originated the oxidation at C-3 as a major transformation, epoxidation of double bond and hydroxylation at C-2. Finally, in the ent-3beta-hydroxy epimer R. nigricans also originated minor hydroxylations at C-1, C-6, C-7 and C-20 and F. moniliforme produced an hydroxylation at C-7 and a dihydroxylation at C-7/C-11.     

Assigning stereodiversity of the 27-Me group of furostane-type steroidal saponins via NMR chemical shifts

Applicability of (13)C and (1)H NMR chemical shifts for the assignment of the 25R/25S configuration of the 27-methyl group in the case of furostane-type steroidal saponins has been investigated. A comparative study of (13)C NMR data suggest that chemical shift values for C-20, C-21, C-22, C-23, C-24, C-25, C-26 and C-27 resonances were not much influenced by R/S configuration of the 27-Me group, thus reflecting limited application of (13)C NMR chemical shifts for such stereochemical determinations. In contrast, (1)H NMR chemical shifts (delta(a), delta(b)) for geminal protons of glycosyloxy methylene (H(2)-26) exhibit pronounced dependence and the difference (Delta(ab)=delta(a)-delta(b)) among their chemical shifts [Delta(ab)= or <0.48 for 25R; Delta(ab)= or >0.57 for 25S] seems to be of general applicability for ascertaining 25R/25S orientation of the 27-methyl group of furostane-type steroidal saponins.     

Stereoselective reactions of (20R)-3,20-dihydroxy-(3',4'-dihydro-2'H-pyranyl)-5-pregnene derivatives form 27-nor-3,20,23,26-tetrahydroxy-cholesten-22-ones and related bromo ketones

The previously reported analog of pregnenolone having a 3,4-dihydro-2H-pyran attached via a Cz.sbnd;C bond to the C-20 position (1), stereoselectively reacts with m-chloroperoxybenzoic acid in methanol at -5 degrees C. Acid-catalyzed hydrolysis of the isolated intermediates gives good yields of mostly a new 27-norcholesterol analog: (20R,23R)-3,20,23,26-tetrahydroxy-27-norcholest-5-en-22-one-3-acetate (2a, and a smaller amount of its 23S enantiomer 2b). Three different conditions of epoxidation and methanolysis followed by acid-catalyzed hydrolysis typically produce approximately 2:1 ratios of the 23R:23S diastereoisomers with a C-23 hydroxy group at the new asymmetric center. Bromine also reacts stereoselectively with (20R)-3,20-dihydroxy-(3',4'-dihydro-2'H-pyranyl)-5-pregnene (4) giving mostly (20R,23R)-23-bromo-3,20,26-trihydroxy-27-norcholest-5-en-22-one (7a). Thus both major steroidal products 2a and 7a have the same C-23R configuration. Assignment of molecular structures and the absolute configurations to 1 and 2a were based on elemental analysis, mass spectra, nuclear magnetic resonance, FTIR infrared spectroscopic analysis and X-ray crystallography. Mechanisms are discussed for stereochemical selectivity during epoxidation and bromination of the 3,4-dihydro-2H-pyranyl ring in 1 and 4.     

Isotope effects in 3-dehydroquinate synthase and dehydratase. Mechanistic implications.

The mechanism of 3-dehydroquinate synthase was explored by incubating partially purified enzyme with mixtures of [1-14C]3-deoxy-D-arabino-heptulosonic acid 7-phosphate (DAHP) and one of the specifically tritiated substrates [4-3H]DAHP, [5-3H]DAHP, [6-3H]DAHP, (7RS)-[7-3H]DAHP, (7R)-[7-3H]DAHP, or (7S)-[7-3H]DAHP. Kinetic and secondary 3H isotope effects were calculated from 3H:14C ratios obtained in unreacted DAHP, 3-dehydroquinate, and 3-dehydroshikimate. 3H was not incorporated from the medium into 3-dehydroquinate, indicating that a carbanion (or methyl group) at C-7 is not formed. A kinetic isotope effect kH/k3H of 1.7 was observed at C-5, and afforded support for a mechanism involving oxidation of C-5 with NAD. A similar kinetic isotope effect was found at C-6 owing to removal of a proton in elimination of phosphate, which is reasonably assumed to be the next step in 3-dehydroquinate synthase. Hydrogen at C-7 of DAHP was not lost in the cyclization step of the reaction, indicating that the enol formed in phosphate elimination participated directly in an aldolase-type reaction with the carbonyl at C-2. In the dehydration of 3-dehydroquinate to 3-dehydroshikimate the (7R) proton from (7RS)- or (7R)-[7-3H]DAHP is lost, indicating that the 7R proton occupies the 2R position in dehydroquinate. Hence the cyclization step occurs with inversion of configuration at C-7. A kinetic isotope effect kH/k3H = 2.3 was observed in the conversion of (2R)-[2-3H]dehydroquinate to dehydroshikimate. Hence loss of a proton from the enzyme-dehydroquinate imine contributed to rate limitation in the reaction.     

Steric effects at C-20 and C-24 on the metabolism of sterols by Tetrahymena pyriformis

Cultures of Tetrahymena pyriformis were incubated with various sterols and the extent of dehydrogenation at C-7 and C-22 was determined. The sterols incubated were desmosterol, 22-dehydrodesmosterol, 24-methyldesmosterol, 24 alpha-methylcholesterol (campesterol), 24-methylene-cholesterol, isohalosterol (26,27-bisnorcampesterol, also known as 24,24-dimethylchol-5-en-e beta-ol, a naturally occurring C26-sterol), and 20-isohalosterol. 20-Isohalosterol was not metabolized, while products with delta 7- and delta 22-bonds were formed from isohalosterol and all of the other sterols studied. This confirms an earlier conclusion, based on results with 20-isocholesterol and cholesterol, that inversion of the configuration from 20(R) to 20(S) completely prevents metabolism both in the nucleus and the side chain. On the other hand, changes in the electronics or stereochemistry at C-24 had a direct affect only on metabolism in the side chain. The presence of a methyl group at C-24 reduced the yield of metabolites with a delta 22-bond relative to those with a delta 7-bond producing an accumulation of 7-dehydro metabolite. A double bond at position-24 counteracted this steric effect, presumably by enhancing the rate of dehydrogenation, and a delta 24(28)-bond was more effect than was a delta 24(25)-bond.     

New markers for Eubacterium lentum.

Of 37 strains of Eubacterium lentum and phenotypically similar organisms, 26 (70%) synthesized a corticoid 21-dehydroxylase and/or a 3 alpha-hydroxysteroid dehydrogenase. It appeared that the corticoid 3 alpha-hydroxysteroid dehydrogenase was identical to the bile acid 3 alpha-hydroxysteroid dehydrogenase. Steroid-metabolizing enzymes were found both in E. lentum and in phenotypically similar organisms. E. lentum is characterized by nitrate reduction and enhanced growth in the presence of arginine. Many phenotypically similar organisms possess either one or the other of the two markers. In contrast, using the steroid-metabolizing enzymes as markers, a "steroid-active" and a "steroid-inactive" group were established with minimal overlapping of metabolic characteristics. Synthesis of the steroid enzymes was positively correlated with production of gas from H2O2 and formation of H2S. A simple method for the detection of corticoid 21-dehydroxylase and 3 alpha-hydroxysteroid dehydrogenase, one or both of which were present in 92% of the steroid-active group, is described.     

1,5-Hydride shift in Wolff-Kishner reduction of (20R)-3beta,20, 26-trihydroxy-27-norcholest-5-en-22-one: synthetic, quantum chemical, and NMR studies.

Heating (20R)-3beta,20,26-trihydroxy-27-norcholest-5-en-22-one (1) with hydrazine and KOH at 160 degrees C completely converted the steroid to a diastereoisomeric mixture of the new (20R,22RS)-27-norcholest-5-ene-3beta,20,22-triols (2). Exclusive formation of 2 suggests that the expected Wolff-Kishner reduction to a methylene group at the C-22 ketone in 1 was diverted to the C-26 position by a 1,5-hydride shift. All attempts under acid conditions failed to produce a C-22 phenyl hydrazone from 1. However, reaction of 1 was reacted with phenylhydrazine in hot KOH, gave the C-26 phenylhydrazone 4 as the sole product. Evidently, under alkaline conditions, first a hydride ion undergoes an intramolecular transfer from the C-26 CH(2)OH group to the C-22 ketone in 1, and then the phenylhydrazine traps the newly formed aldehyde. To examine this hypothesis, we constructed computer-simulated transition state models from quantum chemical calculations and then compared data from these models with NMR measurements of the reaction mixtures containing 2. The NMR data showed that the C-22 diastereoisomers of 2 are formed in a nearly 1:1 ratio exactly as predicted from the energy-optimized transition states, which were calculated for intramolecular 1,5-hydride shifts that produced each of the two C-22 diastereoisomers. Accordingly, these results support the hypothesis that an intramolecular 1,5-hydride shift mechanism promotes complete conversion of 1 to 2 under classical Wolff-Kishner reduction conditions.     

New markers for Eubacterium lentum.

Of 37 strains of Eubacterium lentum and phenotypically similar organisms, 26 (70%) synthesized a corticoid 21-dehydroxylase and/or a 3 alpha-hydroxysteroid dehydrogenase. It appeared that the corticoid 3 alpha-hydroxysteroid dehydrogenase was identical to the bile acid 3 alpha-hydroxysteroid dehydrogenase. Steroid-metabolizing enzymes were found both in E. lentum and in phenotypically similar organisms. E. lentum is characterized by nitrate reduction and enhanced growth in the presence of arginine. Many phenotypically similar organisms possess either one or the other of the two markers. In contrast, using the steroid-metabolizing enzymes as markers, a "steroid-active" and a "steroid-inactive" group were established with minimal overlapping of metabolic characteristics. Synthesis of the steroid enzymes was positively correlated with production of gas from H2O2 and formation of H2S. A simple method for the detection of corticoid 21-dehydroxylase and 3 alpha-hydroxysteroid dehydrogenase, one or both of which were present in 92% of the steroid-active group, is described.     

Specific 5-Hydroxylation of Piperlongumine by Beauveria bassiana ATCC 7159

A new hydroxylated derivative was efficiently prepared by transforming the natural anti-cancer product, piperlongumine, with Beauveria bassiana ATCC 7159. Its structure was determined to be 5-hydroxylpiperlongumine on the basis of the spectroscopic data. The absolute configuration at C-5 was established as R by Mosher's method.     

Mass spectrometric study of the enzymatic conversion of cholesterol to (22R)-22-hydroxycholesterol, (20R,22R)-20,22-dihydroxycholesterol, and pregnenolone, and of (22R)-22-hydroxycholesterol to the lgycol and pregnenolone in bovine adrenocortical preparations. Mode of oxygen incorporation.

Incubation of cholesterol with a bovine adrenocortical mitochondrial acetone-dried powder preparation yielded (22R)-22-hydroxycholesterol (I), (20R,22R)-20,22-dihydroxycholesterol(II), and pregnenolone (III) which were conclusively identified by combined gas chromatography-mass spectrometry. Incubations with [4-14C]cholesterol yielded I, II, and III with specific activities (determined from partial mass-spectral scans) not significantly different from those of the used substrate or the cholesterol reisolated after the incubation, demonstrating that the isolated compounds arose mostly, if not entirely, from the substrate cholesterol. Incubations in an 18O-enriched atmosphere yielded I, II, and III with 18O at position C-22, C-20 and C-22, and C-20, respectively, providing evidence that the hydroxyl groups of the side chain of I and II and the C-20 oxygen atom of III originated from molecular oxygen. The distribution of the oxygen atoms in II after incubation with 18O2 and 16O2 (devoid of 16O18O) proved that the hydroxyl groups of the side chain of II were introduced from two different molecules of oxygen, consistent with a sequential hydroxylation of cholesterol. No (20S)-20-hydroxycholesterol was found. Incubation of I in an 18O-enriched atmosphere afforded II and III with 18O at C-20.