Stereochemistry of the Enzymatic Conversion of a Δ<sup>4</sup>‐3‐Oxosteroid into a 3‐Oxo‐5β‐Steroid

Björkhem, Ingemar

doi:10.1111/j.1432-1033.1969.tb19625.x

Cited by 36 publications

(7 citation statements)

References 26 publications

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“…Alkaline enolization of coprostanone was carried out as described previously [a]. Conversion of coprostanone into A4-cholestenone with selenium dioxide and subsequent purification of the product were performed as described previously [12]. The removal of isotope from C-6 in the A4-cholestenone by alkaline enolization was performed as described by Rosenfeld, Hellman and Gallagher [13].…”

Section: Determination Of Isotope In Different Positions In Coprostanolmentioning

confidence: 99%

Mechanism of Microbial Transformation of Cholesterol into Coprostanol

Björkhem

Gustafsson

1971

European Journal of Biochemistry

117

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The conversion of cholesterol into coprostanol by cecal contents from rats under anaerobic conditions was studied using deuterated water, [4β‐3H,4‐14C]‐ and [3α‐3H,4‐14C]cholesterol. On the basis of the following experimental findings, it was concluded that the conversion of cholesterol into coprostanol proceeds to at least 50% by means of the intermediate formation of Δ4‐cholestenone. Conversion of [3α‐3H,4‐14C]cholesterol into coprostanol occurred with loss of 50% of the tritium. The tritium retained in coprostanol was located in the C‐3α position. However, part of the tritium retained might have been introduced in a reductive step following an initial oxidative step. Evidence for this possibility was provided by the finding that coprostanol formed from [4‐14C]cholesterol in the presence of [3α‐3H]β‐sitosterol contained significant amounts of tritium in the C‐3α position. After conversion of part of [3α‐3H,4‐14C]cholesterol into coprostanol, unchanged cholesterol had a higher 3H/14C ratio than the cholesterol added to the incubation mixture, indicating that oxidation of the 3β‐hydroxyl group is at least partly rate limiting in the over‐all conversion of cholesterol into coprostanol. After incubation of cholesterol in the presence of deuterated water, the coprostanol isolated had a deuterium content of about 1.4 atoms at C‐2, C‐3 and C‐4, about 0.5 atoms at C‐5 and about 0.1 atoms at C‐6, indicating extensive oxido‐reduction at C‐3 during or after conversion of cholesterol into coprostanol. Coprostanol isolated after incubation of [4β‐3H,4‐14C]cholesterol retained 60% of the tritium. The main part of this tritium had been transferred to the C‐6 position, showing that the conversion of cholesterol into coprostanol involves isomerization of the Δ5 double bond to a Δ4 double bond. Incubation of Δ4‐[4‐14C]cholestenone resulted in efficient formation of coprostanol.

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Section: Determination Of Isotope In Different Positions In Coprostanolmentioning

confidence: 99%

Mechanism of Microbial Transformation of Cholesterol into Coprostanol

Björkhem

Gustafsson

1971

European Journal of Biochemistry

117

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“…Dehydrogenation of 3-0x0-5a-steroids by reagents such as selenium dioxide and dichlorodicyanoquinone leads primarily to the formation of A1-3-oxosteroids, which in turn may be converted into A1~4-3-oxosteroids. Dehydrogenation with selenium dioxide and dichlorodicyanoquinone of 3-0x0-5a-steroids and 3-0x0-5B-steroids has been shown to be stereospecific [3,20,21] and it is probable that the formation of A1~4-3-oxosteroids from A'-3-oxosteroids also is stereospecific. However, considerable difficulties arose in the isolation of a A1~4-3-oxosteroid from the reaction mixture.…”

Section: Stereochemistry Of the Introduction Of Hydrogen Into The 4-pmentioning

confidence: 99%

“…The present results indicate that the saturation of the A 4 double bond in the conversion of 7cc-hydroxycholest-4-en-3-one into 7u-hydroxy-5a-choles~n-3-one also involves an ionic mechanism with transfer of a hydride ion from NADPH to the 5u-position of the steroid and addition of a proton from the medium to the 4-position. A notable difference between the Conversion of a C2,-A4-3-oxosteroid into a 3-oxo-5p-steroid [2,3] and that into a 3-0x0-5a-steroid is that in the former case the hydride ion comes from the A-side of NADPH and the addition of hydrogens is trans, whereas in the latter case the B-side of NADPH is used and the addition is cis, a t least to 5O0lO.…”

Section: Stereochemistry Of the Introduction Of Hydrogen Into The 4-pmentioning

confidence: 99%

“…7a-Hydroxycholest -4-en-3 -one, 7a -hydroxy -58-cholestan-3 -one,7a, 12a-dihydroxycholest-4-en- 3 -one, and 7a,i2a-dihydroxy-5~-cholestan-3-one have been shown to be intermediates in the major pathways for the conversion of cholesterol into the main primary 5B-cholanoic acids, chenodeoxycholic acid and cholic acid [l]. The reduction of the A 4 double bond is catalyzed by soluble A4-3-oxosteroid 5B-reductases and the mechanism and stereochemistry of this reaction have been the subject of two recent communications [Z, 31.…”

mentioning

confidence: 99%

“…[4-311,4-14C]7a-lIydroxycholest -4-en-3-one. This compound was prepared as described previously [3]. The preparation used in the experiments in vitro had a specific radioactivity of 0.5 x lo6 countslminl pmole with respect to 3H and 0.2 x lo6 countslminl pmole with respect to 14C.…”

mentioning

confidence: 99%

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Mechanism and Stereochemistry of the Enzymatic Conversion of a Delta4-3-Oxosteroid into a 3-Oxo-5alpha-Steroid

Björkhem

1969

Eur J Biochem

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The conversion of 7a-hydroxycholest-4-en-3-one into 7a-hydroxy-5a-cholestan-3-one and 5a-cholestane-3/?,7a-diol has been studied in a microsomal system. When [4-14C]7a-hydroxycholest-4-en-3-one was incubated with female rat liver microsomes in the presence of NADPH labeled with 3H in the 4A-or the 4B-position of the nicotinamide ring, 3H was incorporated into the 5a-position of 7a-hydroxy-5a-cholestan-3-one. The incorporation was five times greater with [4B-3H]NADPH than with [4A-3H]NADPH. I n the presence of microsomal fraction fortified with NADPH and NADH [4-3H,4-14C]7a-hydroxycholest-4-en-3-one was converted into 5a-cholestane-3B,7a-diol with retention of the main part of the 3H. The [4-3H,4-14C]5a-cholestane-3/,7a-diol formed was converted chemically into 3~-acetoxycholest-5-en-7-one and 3B-benzoyloxycholest-5-en-7-one. These two compounds were transformed into cholest-3,5-dien-7-one by respectively ionic trans elimination and pyrolytic cis elimination of the 4-hydrogen. On the basis of the content of 3H in the cholest-3,5-dien-7-one prepared by the two methods it was concluded that at least half of the original 3H in the enzymatically formed [4-SH,4-14C]5a-cholestane-3B,7a-diol was located in the 4/?-position. Thus, during the conversion of 7a-hydroxycholest-4-en-3-one into 7a-hydroxy-5a-cholestan-3-one a t least half of the hydrogen entering the 4-position is introduced into the 4a-position. The results indicate that saturation of the double bond involves either a cis addition of hydrogens or a non-stereospecfic addition rather than a trans addition.7a-Hydroxycholest -4-en-3 -one, 7a -hydroxy -58-cholestan-3 -one,7a, 12a-dihydroxycholest-4-en-3 -one, and 7a,i2a-dihydroxy-5~-cholestan-3-one have been shown to be intermediates in the major pathways for the conversion of cholesterol into the main primary 5B-cholanoic acids, chenodeoxycholic acid and cholic acid [l]. The reduction of the A 4 double bond is catalyzed by soluble A4-3-oxosteroid 5B-reductases and the mechanism and stereochemistry of this reaction have been the subject of two recent communications [Z, 31. I n addition to 5B-cholanoic acids, 5a-cholanoic acids can be present in small amounts in bile of mammals. The sequence of reactions in the formation of 5a-cholanoic acids has not been studied in detail. Karavolas et al. [a] have shown that in the rat 5a-cholestan-3/?-01 is converted into 3a,7a,12a-trihydroxy-5a-cholanoic acid (allocholic acid) and into an acid tentatively identifled as 3a,7a-dihydroxy5a-cholanoic acid (allochenodeoxycholic acid). From [6] it is apparent that the same pathway is present in the rabbit. A recent investigation in this laboratory indicates that 7a-hydroxycholest-4-en%one and 7a,l2a-dihydroxycholest-4-en-3-one may be intermediates in alternative pathways for the formation of 5a-cholanoic acids [7]. I n the presence of NADPH and the microsomal fraction of homogenate of rat liver, preferably from female rats, 7a-hydroxycholest-4-en-3-one and 7a,l2a-dihydroxycholest-4-en-3-one were converted into the corresponding 3-0x...

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Mechanisms of Bile Acid Biosynthesis

Danielsson

1973

The Bile Acids, Chemistry, Physiology, and Metabolism

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In this chapter, an attempt is made to summarize present knowledge concerning the mechanisms of the conversion of cholesterol into the primary bile acids. In addition, a section on the formation of bile salts in "primitive" animals is included. Emphasis in discussion and documentation of references will be placed on more recent developments. The early work will be briefly reviewed in the introductory section.

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Stereochemistry of the Enzymatic Conversion of a Δ⁴‐3‐Oxosteroid into a 3‐Oxo‐5β‐Steroid

Cited by 36 publications

References 26 publications

Mechanism of Microbial Transformation of Cholesterol into Coprostanol

Mechanism of Microbial Transformation of Cholesterol into Coprostanol

Mechanism and Stereochemistry of the Enzymatic Conversion of a Delta4-3-Oxosteroid into a 3-Oxo-5alpha-Steroid

Mechanisms of Bile Acid Biosynthesis

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Stereochemistry of the Enzymatic Conversion of a Δ4‐3‐Oxosteroid into a 3‐Oxo‐5β‐Steroid

Cited by 36 publications

References 26 publications

Mechanism of Microbial Transformation of Cholesterol into Coprostanol

Mechanism of Microbial Transformation of Cholesterol into Coprostanol

Mechanism and Stereochemistry of the Enzymatic Conversion of a Delta4-3-Oxosteroid into a 3-Oxo-5alpha-Steroid

Mechanisms of Bile Acid Biosynthesis

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Stereochemistry of the Enzymatic Conversion of a Δ⁴‐3‐Oxosteroid into a 3‐Oxo‐5β‐Steroid