The formation and reduction of the 14,15-double bond in cholesterol biosynthesis

It was shown that 100mug quantities of 4,4'-dimethyl[2-(3)H(2)]cholesta-8,14-dien-3beta-ol (IIIa), tritiated cholesta-8,14-dien-3beta-ol, 4,4'-dimethyl[2-(3)H(2)]cholesta-7,14-dien-3beta-ol, dihydro[2-(3)H(2)]lanosterol and [24-(3)H]lanosterol were converted by a 10000g supernatant of rat liver homogenate into cholesterol in 17%, 54%, 6%, 9.5% and 24% yields respectively. From an incubation of dihydro[3alpha-(3)H]lanosterol with a rat liver homogenate in the presence of a trap up to 38% of the radioactivity was found to be associated with a fraction that was unambiguously shown to be 4,4'-dimethylcholesta-8,14-dien-3beta-ol. Another related compound, 4,4'-dimethylcholesta-7,14-dien-3beta-ol was also shown to be equally effective in its ability to trap compound (IIIa) from an incubation of dihydro[3alpha-(3)H]lanosterol. The mechanism of the further conversion of the compound (IIIa) into cholesterol occurred by the reduction of the 14,15-double bond and involved the addition of a hydrogen atom from the medium to C-15 and another from the 4-position of NADPH to C-14. Two possible mechanisms for the removal of the 14alpha-methyl group in sterol biosynthesis are discussed.     

A novel olefinic rearrangement. The enzymic conversion of cholesta-7,9-dien-3β-ol into cholesta-8,14-dien-3β-ol

1. [3alpha-(3)H]Cholesta-7,9-dien-3beta-ol is converted in high yield into cholesterol by a 10000g(av.) supernatant fraction of rat liver homogenate. 2. Incubation of cholesta-7,9-dien-3beta-ol with [4-(3)H]NADPH and rat liver microsomal fractions under anaerobic conditions resulted in (3)H being incorporated into the 14alpha-position of cholest-7-en-3beta-ol. 3. Under anaerobic conditions in the absence of NADPH cholesta-7,9-dien-3beta-ol was isomerized into cholesta-8,14-dien-3beta-ol by rat liver microsomal fractions.     

The biological conversion of 7-dehydrocholesterol into cholesterol and comments on the reduction of double bonds

It is shown that the 7-dehydrocholesterol reductase-catalysed conversion of 7-dehydrocholesterol into cholesterol (II), with a 105000g microsomal pellet of rat liver in the presence of [4-(3)H(2)]NADPH, results in the transfer of radioactivity to the 7alpha-position of cholesterol. When the conversion is carried out in the presence of tritiated water the label is introduced exclusively at the 8beta-position. However, when the conversion of 7-dehydrocholesterol into cholesterol is performed with a 500g supernatant of rat liver homogenate the radioactivity is incorporated at both the 7alpha- and the 8beta-position. Evidence is provided for the presence of an enzyme system in the 500g supernatant that catalyses an equilibration of hydrogen atoms between those at the 4-position of NADPH and those of water. The work with stereospecifically labelled cofactors shows that both the equilibrating system and the 7-dehydrocholesterol reductase utilize the 4B-hydrogen atom of NADPH. In the light of these results a mechanism for the reduction of carbon-carbon double bonds is discussed.     

The metabolic sequence by which some 4,4-dimethyl sterols are converted into cholesterol

Cholest-8(14)-enol is the major radioactive component of the 4-di-demethyl sterol fraction biosynthesized from 4,4-dimethyl[2-(3)H(2)]cholest-8(14)-enol by rat liver microsomal fractions, and therefore the first steps in the biosynthesis of cholesterol from the latter compound probably involve removal of the 4-methyl groups. 4,4-Dimethylcholesta-8,14-dienol therefore is not an intermediate in this process, although its presence in the incubation medium at a concentration of 0.146mm almost completely inhibits the demethylation of 4,4-dimethyl[2-(3)H(2)]cholest-8(14)-enol. Nor is cholesta-8,14-dienol an intermediate in the conversion of cholest-8(14)-enol into cholest-7-enol and cholesterol. With 4,4-dimethyl[2-(3)H(2)]cholesta-8,14-dienol as the cholesterol precursor, 4,4-dimethylcholest-8(9)-enol becomes heavily labelled and there is very little radioactivity associated with cholesta-8,14-dienol.In this case, the most heavily labelled 4-di-demethyl sterols are cholest-7-enol and cholesterol with the former predominating. There is little or no radio-activity associated with cholest-8(14)-enol. A similar labelling pattern amongst the 4-di-demethyl sterols was observed with dihydro[(14)C]lanosterol as the precursor. The first step therefore in the synthesis of cholesterol from the 4,4-dimethyl[2-(3)H(2)]dienol is reduction of the Delta(14(15)) bond and not removal of the 4alpha-methyl group. Depending on the nature of the precursor, addition of the soluble fraction of the cell to the microsomal fraction resulted in a two- to four-fold stimulation of 4-di-demethyl sterol biosynthesis from the 4,4-dimethyl sterols studied. Under these conditions, 4,4-dimethylcholesta-8,14-dienol is the most efficient precursor of cholesterol and cholest-7-enol, and dihydrolanosterol is better than 4,4-dimethylcholest-8(14)-enol.     

Studies on the mechanism and regulation of C-4 demethylation in cholesterol biosynthesis. The role of adenosine 3′:5′-cyclic monophosphate

1. An assay for demethylation has been developed based on the release of tritium from 4,4-dimethyl[3alpha-(3)H]cholest-7-en-3beta-ol (II). 2. The maximum release of (3)H from 3alpha-(3)H-labelled compound (II) in a rat liver microsomal preparation occurs in the presence of NADPH and NAD(+) under aerobic conditions. 3. Incubation of 3alpha-(3)H-labelled compound (II) with NADPH under aerobic conditions leads to the formation of a 3alpha-(3)H-labelled C-4 carboxylic acid. This compound undergoes dehydrogenation on subsequent anaerobic incubation with NAD(+). 4. The (3)H released from the steroid was located in [4-(3)H]nicotinamide and the medium. Incubation with synthetic [4-(3)H(2)]NADH gave a similar result. 5. In the presence of glutamate dehydrogenase and alpha-oxoglutarate part of the (3)H released from the steroid was transferred to glutamate. 6. A series of 3-oxo steroids were reduced equally well by [4-(3)H(2)]NADH and [4-(3)H(2)]NADPH. The reduction of 5alpha-cholest-7-en-3-one was shown to use the 4B H atom from the nucleotide. 7. 3':5'-Cyclic AMP was shown to be a competitive inhibitor of the 3beta-hydroxy dehydrogenase enzyme in the demethylation reaction.     

The pathway for the conversion of dihydroagnosterol into cholesterol in rat liver.

Dihydroagnosterol is demethylated by a rat liver homogenate to give 4,4'-dimethylcholesta 7,9-dienol and then cholesta-7,9-dienol. The cholesta-7,9-dienol is isomerized to cholesta-8,14-dienol, which is converted into cholesterol by the normal pathway.     

Compartmentation of NADPH in rat liver.

Rat liver slices were incubated with specifically ³H-labeled glucoses and [2-³H]sorbitol, and the incorporations of ³H into fatty acids and cholesterol were determined. Incorporation of ³H from [1-³H]glucose relative to that from [3-³H]glucose via NADPH formed in the pentose cycle was similar into fatty acids and cholesterol. This indicates (1) the presence of a common pool of NADPH formed via the pentose cycle, from which is derived the reductive hydrogens for fatty acid and cholesterol synthesis; (2) the absence of a major separate pool of NADPH formed from glucose by microsomal glucose dehydrogenase (EC 1.1.1.47) catalysis for use in cholesterol synthesis. ³H from [4-³H]glucose and from [2-³H]sorbitol was incorporated into cholesterol more than into fatty acids relative to the incorporations of ³H from [3-³H]glucose. Assuming that the ³H from [4-³H]glucose and from [2-³H]sorbitol were incorporated via the conversion, catalyzed by malic enzyme, of NADH to NADPH, this indicates the Compartmentation of the NADPH formed via malic enzyme catalysis from that formed via the pentose cycle. Alternatively, NADH provides reductive hydrogens for cholesterol synthesis in greater measure than in fatty acid formation or the stereochemistry of the synthetic processes are such that [A-³H]NADPH has greater excess than [B-³H]NADPH to cholesterol synthesis relative to fatty acid synthesis.     

The pathway for the removal of the 15α-methyl group of lanosterol : The role of Lanost-8-ene-3β,32-diol in cholesterol biosynthesis

[19α-³H]Lanost-7-ene-3β-ol is synthesized and is shown to be demethylated by a rat liver homogenate to give 4,4′-dimethylcholesta-7,14-dien-3β-ol. [32-³H]Lanost-8-ene-3β,32-diol is synthesized and is shown to be demethylated by a rat liver microsomal preparation to give 4,4′-dimethylcholesta-8,14-dien-3β-ol with the release of C-32 as formic acid.     

Role of cytosolic superoxide dismutase as a stimulator in anthranilamide hydroxylation by a microsomal monooxygenase system in rat liver

We have isolated a protein factor from rat liver which stimulates anthranilamide hydroxylation by the microsomes in the presence of NADPH and oxygen and showed this factor to contain Cu and Zn and to have superoxide dismutase activity [Biochim. Biophys. Acta 365, 148-157 (1974)]. In the present study, this protein factor was confirmed to be a superoxide dismutase (SOD) by comparison of the recovery of SOD activity with that of anthranilamide hydroxylation-stimulating activity at each step of its purification, by inhibition of SOD activity with NaCN and hydrogen peroxide (H2O2), and by recovery of the SOD activity of the protein factor after reconstitution with Cu2+ and/or Zn2+. At a given SOD activity level, there was no difference among the rat liver SOD, Cu,Zn-SOD from bovine erythrocytes, and Mn-SOD from Serratia marcescens in their ability to stimulate anthranilamide hydroxylation not only by rat liver microsomes, but also by the reconstituted cytochrome P-450-containing monooxygenase system. Rat liver SOD stimulated anthranilamide hydroxylation by the reconstituted system in proportion to its amount below a protein concentration of 1 microgram/ml. In anthranilamide hydroxylation by the reconstituted system without SOD, only a slight hydroxylase activity was found at the initial stage of the reaction and a marked increase in the amounts of NADPH oxidized and H2O2 formed was observed after a lag time. In the presence of rat liver SOD, however, the hydroxylase activity was markedly and continuously increased almost proportionally to reaction time with a concomitant decrease in the amounts of NADPH oxidized and H2O2 formed. In addition, a trace of 3-OH anthranilamide, one of the products, not only stimulated NADPH-dependent H2O2 formation in the reconstituted system, but also inhibited the apparent reduction of cytochrome P-450 by NADPH in the reconstituted system. These effects of 3-OH anthranilamide were diminished by rat liver SOD. When a trace of 3-OH anthranilamide were added to a system composed of NADPH-cytochrome c (P-450) reductase and NADPH, H2O2 formation and NADPH oxidation were markedly stimulated. However, on addition of 3-OH anthranilamide to the system containing rat liver SOD, no stimulation on either H2O2 formation or NADPH oxidation was found.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cholesterol 7α-hydroxylase in rat liver microsomal preparations

Subcellular fractions containing microsomes prepared from rat livers homogenized in the absence of EDTA catalysed the oxidation of cholesterol to 7alpha-hydroxycholesterol, 7-oxocholesterol, 7beta-hydroxycholesterol and 5alpha-cholestane-3beta,5,6beta-triol. These reactions required native protein, molecular oxygen and NADPH. It is suggested that these compounds are formed by a peroxidation analogous to the peroxidation of fatty acids catalysed by liver microsomal preparations. Incubations of [4-(14)C]cholesterol with microsomal preparations from rat liver homogenized in the presence of EDTA gave 7alpha-hydroxy[(14)C]cholesterol as the main product. This reaction required molecular oxygen and NADPH, and was inhibited by CO. The mass of 7alpha-hydroxycholesterol formed during the incubation was measured by a double-isotope-derivative dilution procedure. This procedure was used to assay the activity of cholesterol 7alpha-hydroxylase and to measure low concentrations of endogenous 7alpha-hydroxycholesterol in liver.     

Rat-liver cholesterol 7 alpha-hydroxylase. 1. Development of a new assay based on the enzymic exchange of the tritium located on the 7 alpha position of the substrate.

A new assay is described to measure the activity of cholesterol 7alpha-hydroxylase and compared to the conventional 14C method used by other investigators. This method is based on the mechanism of the enzymic hydroxylation, i.e. a direct and stereospecific substitution of the 7alpha-hydrogen by a hydroxyl group. [7alpha-3H]Cholesterol is incubated at 37 degrees C and in the presence of molecular O2, in a medium buffered by postassium phosphate at pH 7.4 and containing liver microsomes (or 9000 X g supernatant), NADPH, MgCl2 and cysteamine. Tween-80 (1.5 mg/ml) is used to introduce enough substrate (300 muM) in the incubation mixture to saturate the enzyme (Km = 100 muM). Under these conditions the tritiated water released into the incubation medium reflects accurately the enzymic activity. The results obtained with this method are similar to the one obtained with a [4-14C]cholesterol technique (r = 0.96; P less than 0.001). The main advantage of the [7alpha-3H]cholesterol method is a complete independence from further metabolism of the first enzymic product, the 7alpha-hydroxycholesterol, the tritiated water representing the entire cholesterol 7alpha-hydroxylase activity.     

The effect of sodium butyrate on acetylation in vitro of chromosomal proteins in three classes of liver nuclei from different ages of rats

The optimum conditions of in vitro incorporation of sodium [³H]acetate into sliced rat liver were studied. The incubations with sliced liver from three different ages of rats were performed in the presence of sodium n-butyrate. It was found that butyrate decreases the incorporation of sodium [³H]acetate into the homogenate, isolated nuclei, non-histone chromosomal proteins and histones for all age groups. The acetylations of non-histone chromosomal proteins and histones increase with age upto 2-months and decrease in 4-month-old rats both in the absence and presence of butyrate. Liver nuclei were fractionated by the simple method of zonal centrifugation into three classes, namely diploid stromal, diploid parenchymal and tetraploid parenchymal nuclei. The acetylations of non-histone chromosomal proteins and histones in three classes of nuclei of three ages of rats were studied in the presence and absence of butyrate. Butyrate can decrease the overall acetylations of non-histone chromosomal proteins and histones but increase the amount of polyacetylated histone H4 in all classes of nuclei of the three ages.     

Biosynthesis of acaterin: mechanism of the reaction catalyzed by dehydroacaterin reductase

Dehydroacaterin reductase is an enzyme which catalyzes the final step of acaterin biosynthesis, that is, the reduction of the C-4/C-5 double bond of dehydroacaterin. The mechanism of the reduction was investigated with a cell-free preparation obtained from the acaterin-producing microorganism, Pseudomonas sp. A 92. Incubation of dehydroacaterin in the presence of [4,4- 2H2]NADPH or D2O followed by 2H NMR analysis of the resulting acaterin revealed that the deuterium atom from NADPH was incorporated into the C-5 position of acaterin, while the deuterium atom from D2O was introduced into the C-4 position. It was further demonstrated that the pro-R hydrogen at C-4 of NADPH was stereospecifically utilized in this reduction.     

Sterol synthesis by the ocular lens of the rat during postnatal development

Great amounts of plasma membranes are formed during early postnatal development of the ocular lens as lens epithelial cells differentiate into fiber cells. Little information is available on the source of the lipids, and particularly cholesterol, required for formation of these plasma membranes. The present study measured the capacity of the lens of the rat to synthesize cholesterol during this dynamic period of growth. Incorporation by lens of (3)H(2)O into total fatty acids was also examined. Absolute rates of cholesterol synthesis per whole lens were estimated in vitro from incorporation of (3)H from (3)H(2)O into digitonide precipitable sterols (DPS) by intact lenses of 6- to 30-day old rats. Rates of cholesterol synthesis were calculated which were adequate to furnish from either 50-100% or 20-40% of the cholesterol required by the lens for growth, depending upon the animal's age and upon whether one considered NADPH to be generated by the pentose phosphate pathway or by oxidative enzymatic processes (NADPH from the pentose pathway is not labeled from (3)H(2)O). Generation of the NADPH necessary for cholesterol synthesis principally by the pentose pathway would support the higher percent contribution of synthesis to the total growth requirement. The pentose pathway was clearly active in the young rat lens, since between 7.5 to 9.0 times more [1-(14)C]glucose than [6-(14)C]glucose was oxidized in vitro to (14)CO(2) by 6- and 22-day old lenses. Incorporation of (3)H(2)O into DPS decreases sharply after 2 weeks of age in spite of a constant rate of cholesterol accumulation by the lens. These results indicate that the ocular lens of the rat can furnish most if not all of its cholesterol requirements by synthesis de novo during the first 2 weeks of life, and imply a contribution from another source at older ages. Whether lipoproteins can supply cholesterol to the lens is still unclear, although neither HDL nor LDL altered the incorporation in vitro of [U-(14)C]glucose into DPS by lens.-Cenedella, R. J. Sterol synthesis by the ocular lens of the rat during postnatal development.     

Incorporation of [2-14C,(5R)-5-3H1]mevalonic acid into cholesterol by a rat liver homogenate and into β-sitosterol and 28-isofucosterol by Larix decidua leaves

1. Incubation of a rat liver homogenate with 3R-[2-(14)C,(5R)-5-(3)H(1)]mevalonic acid gave cholesterol with (3)H/(14)C atomic ratio 6:5. 2. Conversion of the labelled cholesterol into 3beta-acetoxy-6-nitrocholest-5-ene or cholest-4-ene-3,6-dione resulted in the loss of one tritium atom from C-6. 3. These results show that during cholesterol biosynthesis the 6alpha-hydrogen atom of a precursor sterol is eliminated during formation of the C-5-C-6 double bond. 4. Incorporation of 3R-[2-(14)C,(5R)-5-(3)H(1)]mevalonic acid into the sterols of larch (Larix decidua) leaves gave labelled cycloartenol and beta-sitosterol with (3)H/(14)C atomic ratios 6:6 and 6:5 respectively. 5. One tritium atom was lost from C-6 on conversion of the labelled beta-sitosterol into either 3beta-acetoxy-6-nitrostigmast-5-ene or stigmast-4-ene-3,6-dione, demonstrating that formation of the C-5-C-6 double bond of phytosterols also involves the elimination of the 6alpha-hydrogen atom of a precursor sterol. 6. The 3R-[2-(14)C,(5R)-5-(3)H(1)]mevalonic acid was also incorporated by larch (L. decidua) leaves into a sterol that co-chromatographed with 28-isofucosterol. Confirmation that the radioactivity was associated with 28-isofucosterol was obtained by co-crystallization with carrier 28-isofucosterol and ozonolysis of the acetate to give radioactively labelled 24-oxocholesteryl acetate. 7. The significance of these results to phytosterol biosynthesis is discussed.     

Catechol estrogen adducts

Reaction of estrone-3,4-o-quinone with ethanethiol and glutathione leads to the formation of 4-hydroxyestrone-2-thioethers. Incubations of [1-3H]hydroxyestrone with rat liver microsomes and NADPH in the presence of glutathione results in the formation of 4-hydroxyestrone-S-glutathione with no release of tritium in the water indicating GSH addition to C-2 of 4-hydroxyestrone.     

In vitro inhibition of rat liver cholest-5en-3 beta-ol (cholesterol) biosynthesis by non-mercurial sulfhydryl reagents.

In vitro conversion of 2-14C-mevalonate to cholest-5en-3 beta-ol (cholesterol) in rat liver homogenates is inhibited by arsenite, beta-mercaptoethanol, dithiothreitol and ethanethiol. Two sterols containing 20 carbon atoms accumulate under these conditions. One of these is identified as 4,4 dimethyl-5alpha-cholest-8en-3beta-ol and the other tentatively identified as 4,4 dimethyl-5alpha-cholest-8,24-dien-3beta-ol. Based on these observations, these non-mercurial sulfhydryl reagents do not inhibit 5alpha-lanosta-8,24-dien-3beta-ol 14alpha demethylase.     

Tetrahydrobiopterin biosynthesis. Studies with specifically labeled (2H)NAD(P)H and 2H2O and of the enzymes involved

The biosynthesis of tetrahydrobiopterin from either dihydroneopterin triphosphate, sepiapterin, dihydrosepiapterin or dihydrobiopterin was investigated using extracts from human liver, dihydrofolate reductase and purified sepiapterin reductase from human liver and rat erythrocytes. The incorporation of hydrogen in tetrahydrobiopterin was studied in either 2H2O or in H2O using unlabeled NAD(P)H or (R)-(4-2H)NAD(P)H or (S)-(4-2H)NAD(P)H. Dihydrofolate reductase catalyzed the transfer of the pro-R hydrogen of NAD(P)H during the reduction of 7,8-dihydrobiopterin to tetrahydrobiopterin. Sepiapterin reductase catalyzed the transfer of the pro-S hydrogen of NADPH during the reduction of sepiapterin to 7,8-dihydrobiopterin. In the presence of partially purified human liver extracts one hydrogen from the solvent is introduced at position C(6) and the 4-pro-S hydrogen from NADPH is incorporated at each of the C(1') and C(2') position of BH4. Label from the solvent is also introduced into position C(3'). These results suggest that dihydrofolate reductase is not involved in the biosynthesis of tetrahydrobiopterin from dihydroneopterin triphosphate. They are consistent with the assumption of the occurrence of a 6-pyruvoyl-tetrahydropterin intermediate, which is proposed to be formed upon triphosphate elimination from dihyroneopterin triphosphate, and via an intramolecular redox reaction. Our results suggest that the reduction of 6-pyruvoyl-tetrahydropterin might be catalyzed by sepiapterin reductase.     

Chemical and enzymic studies on the characterization of intermediates during the removal of the 14alpha-methyl group in cholesterol biosynthesis. The use of 32-functionalized lanostane derivatives.

By using cell-free preparations of rat liver it was shown that the removal of the 14alpha-methyl group (C-32) of steroids containing either a delta7(8) or a delta8(9) double bond is attended exclusively by the formation of the corresponding 7,14- and 8,14-dienes respectively (structures of types III and VIII). Cumulative evidence from a variety of experimental approaches had led to the deduction that delta8(14)-steroids are not involved as intermediates on the major pathway of cholesterol biosynthesis. The metabolism of [32-3H]lanost-7-ene-3beta,32-diol (structure of type I) results in the formation of radioactive formic acid, no labelled formaldehyde being formed. By using appropriately labelled species of the compound (I) it was found that the release of formic acid and the formation of 4,4-dimethylcholesta-7,14-dien-3beta-ol (strurcture of type III) were closely linked processes, and that in the conversion of compound (I) into compound (III), 3-beta-hydroxylanost-7-en-32-al (II) is an obligatory intermediate. Both the conversion of lanost-7-ene-3beta,32-diol (I) into 3beta-hydroxylanost-7-en-32-al (II) and the further metabolism of the latter (II) to 4,4-dimethylcholesta-7,14-dien-3beta-ol (III) exhibited a requirement for NADPH and O2. This suggests that the oxidation of the 32-hydroxy group of compound (I) to the aldehyde group of compound (II) does not occur by the conventional alcohol dehydrogenase type of reaction, but may proceed by a novel mechanism involving the intermediacy of a gem-diol. A detailed overall pathway for the 14alpha-demethylation in cholesterol biosynthesis is considered, and proposals about the mechanism of individual steps in the pathway are made.     

Activation and irreversible binding of regiospecifically labeled catechol estrogen by rat liver microsomes: evidence for differential cytochrome P-450 catalyzed oxidations

Estradiol and 2-hydroxyestradiol labeled with 3H at different positions in rings A or B were incubated with male rat liver microsomes, and their oxidative transformation was followed by the transfer of 3H into 3H2O. 14C-labeled estrogen or catechol estrogen was used to determine the fraction that becomes bound covalently to microsomal protein. The further metabolism of 2-hydroxyestradiol involves activation of the steroid at C-4 and, to a much lesser extent at C-1, by a cytochrome P-450 mediated reaction as indicated by the effects of NADPH, spermine, SKF-525A, and CO in the microsomal system. Glutathione promoted the loss of 3H from C-4 of either estradiol or 2-hydroxyestradiol but had less effect on this reaction at C-1 and inhibited it at C-6,7. It also abolished the irreversible binding of 14C-labeled estradiol and 2-hydroxyestradiol to microsomal protein. NADPH was needed specifically for glutathione to exert its effect both on the transfer of 3H into 3H2O and on the formation of water-soluble products from catechol estrogen by rat liver microsomes. It could not be replaced by NADP, NAD, or NADH. Ascorbic acid inhibited these enzymatic reactions but did not affect significantly the initial 2-hydroxylation of estradiol. Evidence is also provided for the further hydroxylation of 2-hydroxyestradiol at C-6 (or C-7). These results indicate that cytochrome P-450 activates catechol estrogens by an electron abstraction process.