Herstellung von 3-Oxo-17β-hydroxy-1,19-cyclo-5α-androstan. Über Steroide, 219. Mitteilung

Under the influence of radical anions generated from lithium and biphenyl, 3-oxo-17β-acetoxy-19-mesyloxy-Δ¹-5α-androstane was converted into 3-oxo-17β-acetoxy-1, 19-cyclo-5α-androstane.     

Steroids and sex hormones. The synthesis of 1-beta, 4-beta-oxido-3-aza-17-beta-hydroxy-A-homo-5-alpha-androstane

A sterically controlled transformation of 3-oxo-17β-acetoxy-Δ^1?-α-androstene ( 2 ) into 1β,4β-oxido-3-aza-17β-hydroxy-A-homo-5α-androstane ( 16 ) is described. With the exception of two conversions [ 14 → 15 (60%); 15 → 16 (50%)], the yields of the remaining seven steps are higher than 75% each. The reaction sequence will serve as a model for an analogous partial synthesis of samandarine ( 1 ).     

Substituent increments for the 1H-NMR. Chemical shifts of the 18- and 19-methyl protons of steroids. Part II: 9alpha, 10beta(normal)-steroids

In Part II of this series we report 292 substituent increments for the ¹H-NMR. chemical shifts (solvent: CDCl₃) of the 18- and 19-methyl protons of 9α,10β(normal)-steroids relative to 5α,9α,10β,-androstane. The increments were calculated by a least-squares procedure from 988 spectra of 681 different steroids.     

Substituent increments for the 1H-NMR. Chemical shifts of the 18- and 19-methyl protons of steroids. Part I: 9beta, 10alpha(retro)-steroids

This paper reports 261 substituent increments for the ¹H? NMR. chemical shifts (solvent: CDCl₃) of the 18- and 19-methyl protons of 9β, 10α(retro)-steroids relative to 5β,9β,10α,-androstane. The increments were calculated by a least-squares procedure from 1334 spectra of 759 different steroids.     

Mass spectra of 17ξ-hydroxy-5ξ-androstane C(3) ketone and C(3ξ) alcohol isomers

Positive ion electron impact mass spectral data for the four isomeric 17ξ-hydroxy-17ξ-methyl-5ξ-androstane C(3) ketones and the eight isomeric C(3ξ) alcohols are reported. In contrast to earlier reports, no general correlation was observed between the [M? H₂O]⁺˙/[M]⁺˙ ratio and the configuration at C(17). The ratios of the intensity of several fragment ions to that of the molecular ion do differentiate between the 5α- and 5β-isomers in both C(3) ketones and alcohols, the extent of fragmentation being greater for 5β-steroids. All of these fragments probably involve elimination of a water molecule at some stage in their formation. Elimination of water is also enhanced for 3α- v. 3β-hydroxysteroids, particularly in a 5β-isomer.     

Oxetane from A-nor-steroides: 2-alpha, 5-oxido-A-nor-5-alpha-cholestane, 2-beta, 5-oxido-A-nor-5-beta-cholestane and 2-alpha-ethyl-2-beta,2'-oxido-A-nor-5-alpha-cholestane

Treatment of 2β-tosyloxy-A-nor-5α-cholestane-5-ol ( 2 ) with t-butoxide in t-butanol gave 2α, 5-epoxy-A-nor-5α-cholestane ( 3 ) in quantitative yield. When A-nor-5β-cholestane-2α, 5-diol ( 4 ) was treated with tosyl chloride in pyridine 2β-chloro-A-nor-5β-cholestane-5-ol ( 7 ) and 2α-tosyloxy-A-nor-5β-cholestane-5-ol ( 8 ) were obtained. Whereas the chloride 7 was resistant to t-butoxide the tosylate 8 was transformed into an 1 : 1 mixture of 2α, 5-epoxy-5β-cholestane ( 10 ) and 2ξ-t-butoxy-A-nor-5β-cholestane-5-ol ( 11 ). In 2α-tosyloxy-A-nor-5α-cholestane-5-ol ( 12 ) substitution occurred as the only reaction. Both oxetanes 3 and 10 isomerize after heating above 50° and in polar or protic solvents to form A-nor-Δ³⁽⁵⁾-cholestene-2α-ol ( 6 ) and -2β-ol ( 14 ) respectively. Also, 2, 5-diols are encountered. 2α-Ethyl-2β, 2′-epoxy-A-nor-5α-cholestane ( 23 ) was synthesized starting from A-nor-5α-cholestane-2-one ( 17 ). The intermediates were the ester 16 , the diol 18 , the hydroxy-tosylate 19 and the chlorhydrin 20 . The spirocyclic oxetane 23 was reduced by LiAlH₄ in dioxane (not in ether). By chromatography on silica gel 23 was isomerized to the homoallylic alcohol 21 and transformed into 2-methylene-A-nor-5α-cholestane ( 24 ) by fragmentation. The IR. and NMR. spectra of the new oxetanes were compared with those of a series of known oxetanes.     

Steroidal imidazopyridines and lactam imidazopyridines

Condensation of 17β-acetoxy-2α-bromo-5α-androstan-3-one with unsubstituted and substituted amino-pyridines, gives the corresponding 17β-acetoxy-5α-androstanimidazo[1,2-a]pyridines. Treatment of 16α-bromo-3-aza-A-homo-4α-androsten-4,17-dione with 2-aminopyridine or methyl-2-aminopyridine produces the corresponding 3-aza-A-homo-4α-androsten[16,17:2′,3′]imidazo[1,2-a]pyridines. Similarly, from 2α-bromo-17β-acetamido-5α-androstan-3-one and methylaminopyridine the 17β-acetamido-5α-androstan[2,3:2′,3′]imidazo[1,2-a]methylpyridine has been obtained. The structure of the compounds was apparent from their chemical properties and spectral data (ir, uv and nmr).     

Synthesis of the 2,5-dioles of A-nor-5-alpha-cholestanes and A-nor-5-beta-cholestanes

Treatment of A-nor-Δ³⁽⁵⁾-cholestene-2-one ( 1 ) with alkaline hydrogen peroxide gave 3β,5-epoxy-A-nor-cholestane-2-one ( 2 ) and the epoxylactone 3 (BAEYER -VILLIGER reaction). LiAlH₄-reduction of 2 yielded A-nor-5β-cholestane-2β,5-diol( 4 ) (main product) and A-nor-5β-cholestane-2α,5-diol ( 5 ). LiAlH₄-reduction of 1 led mainly to A-nor-Δ³⁽⁵⁾-cholestene-2α-ol ( 8 ). Catalytic hydrogenation of 8 gave the known A-nor-5α-cholestane-2α-01 ( 10 ), A-nor-5β-cholestane-2α-01 ( 11 ) (main product), A-nor-5β-cholestane ( 9 ) and A-nor-5β-cholestane-2-one ( 12 ). By LiAlH₄-reduction of the ketones 12 and 13 the two additional alcohols 14 and 15 were obtained.     

Conformations of the Ten-membered Ring in 5, 10-Secosteroids. III: (Z)-3β- and (Z)-3α-Hydroxy-5, 10-seco-1 (10)-cholesten-5-one Esters and (Z)-5, 10-seco-1 (10)-Cholestene-3, 5-dione

(Z)-3β-Acetoxy- and (Z)-3 α-acetoxy-5, 10-seco-1 (10)-cholesten-5-one ( 6a ) and ( 7a ) were synthesized by fragmentation of 3β-acetoxy-5α-cholestan-5-ol ( 1 ) and 3α-acetoxy-5β-cholestan-5-ol ( 2 ), respectively, using in both cases the hypoiodite reaction (the lead tetraacetate/iodine version). The 3β-acetate 6a was further transformed, via the 3β-alcohol 6d to the corresponding (Z)-3β-p-bromobenzoate ester 6b and to (Z)-5, 10-seco-1 (10)-cholestene-3, 5-dione ( 8 ) (also obtainable from the 3α-acetate 7a ). The ¹H-and ¹³C-NMR. spectra showed that the (Z)-unsaturated 10-membered ring in all three compounds ( 6a , 7a and 8 ) exists in toluene, in only one conformation of type C ₁, the same as that of the (Z)-3β-p-bromobenzoate 6b in the solid state found by X-ray analysis. The unfavourable relative spatial factors (interdistance and mutual orientation) of the active centres in conformations of type C ₁ are responsible for the absence of intramolecular cyclizations in the (Z)-ketoesters 6 and 7 ( a and c ).     

PHOTODYNAMICALLY GENERATED 3-β-HYDROXY-5α-CHOLEST-6-ENE-5-HYDROPEROXIDE: TOXIC REACTIVITY IN MEMBRANES and SUSCEPTIBILITY TO ENZYMATIC DETOXIFICATION

Singlet oxygen (¹O₂)-mediated photooxidation of cholesterol gives three hydroperoxide products: 3β-hydroxy-5α-cholest-6-ene-5-hydroperoxide (5α-OOH), 3β-hydroxycholest-4-ene-6α-hydrope-roxide (6α-OOH) and 3β-hydroxycholest-4-ene-6β-hydroperoxide (6β-OOH). These species have been compared with respect to photogeneration rate on the one hand and susceptibility to enzymatic reduction/ detoxification on the other, using the erythrocyte ghost as a cholesterol-containing test membrane and chloroaluminum phthalocyanine tetrasulfonate (AlPcS₄) as a ¹O₂ sensitizer. Peroxide analysis was accomplished by high-performance liquid chromatography with mercury cathode electrochemical detection (HPLC-EC[Hg]). The initial rate of 5α-OOH accumulation in AlPcS₄/light-treated ghosts was found to be about three times greater than that of 6α-OOH or 6β-OOH. Membranes irradiated in the presence of ascorbate and ferric-8-hydroxyquinoline (Fe[HQ]₂, a lipophilic iron complex) accumulated lesser amounts of 5α-OOH, 6α-OOH and 6β-OOH but relatively large amounts of another peroxide pair, 3β-hydroxycholest-5-ene-7α- and 7β-hydroperoxide (7α,7β-OOH), suggestive of iron-mediated free radical peroxidation. When photoperoxidized membranes containing 5α-OOH, 6α,6β-OOH and 7α,7β-OOH (arising from 5α-OOH rearrangement) were incubated with glutathione (GSH) and phospholipid hydroperoxide glutathione peroxidase (PHGPX), all hydroperoxide species underwent HPLC-EC(Hg)-detect-able reduction to alcohols, the relative first order rate constants being as follows: 1.0 (5α-OOH), 2.0 (7α,7β-OOH), 2.4 (6α-OOH) and 3.2 (6β-OOH). Relatively rapid photogeneration and slow detoxification might make 5α-OOH more cytotoxic than the other peroxide species. To begin investigating this possibility, we inserted 5α-OOH into ghosts by transferring it from 5α-OOH-containing liposomes. When exposed to Fe(HQ)₂/ascorbate, these ghosts underwent GSH/PHGPX-inhibitable chain peroxidation, as indicated by the appearance of 7α,7β-OOH, phospholipid hydroperoxides and thiobarbituric acid reactive substances. Liposomal 5α-OOH also exhibited a strong, Fe(HQ)₂-enhanced, toxicity toward LI210 leukemia cells, an effect presumably mediated by damaging chain peroxidation. This appears to be the first reported example of eukaryotic cytotoxicity attributed specifically to 5α-OOH.     

Anwendung3H-markierter Silylierungsmittel zur Bestimmung der Geschwindigkeits- und Gleichgewichtskonstanten der Silylierungsreaktionen für die massenspektrometrische Analyse von Steroidhormonen

Steroid hormones were silylated, using³H-labelled silylating agents. The trimethylsilyl ether derivatives obtained were stable products. Using HMDS and TMCS the silylation reaction of 3α-hydroxy-5α-androstane was a first order reaction.     

On the formation of homo-azasteroidal esters of N,N-bis(2-chloroethyl)aminobenzoic acid isomers and their antitumor activity

The N, N-bis(2-chloroethyl)aminobenzoate isomers and the 4-methyl-3-N, N-bis(2-chloro-ethyl)aminobenzoate of 3β-hydroxy-13α-amino-13,17-seco-5α-androstan-17-oic-13,17-lactam, 3α-hydroxy-13α-amino-13,17-seco-5α-androstan-17-oic-13,17-lactam, 3α-hydroxy-13α-amino-13,17-seco-5-androsten-17-oic-13,17-lactam and 17β-hydroxy-3-aza-A-homo-4α-androsten-4-one, have been prepared and their biological activity evaluated against P388 leukemia in vivo and Ehrlich Ascites tumor (EAT), P388 and L1210 leukemias and Baby Hamster cells (BHK) in vitro. The esters in which the alkylating congener is linked to the lactam alcohol in the axial position are inactive in vivo in P388 leukemia, while compounds 1, 4, 6, 13, 14 and the alkylating congeners 17, 18 and 20 are active. The effect of the homo-azasteroidal of N, N-bis(2-chloroethyl)aminobenzoic acid isomers and of 4-methyl-3-N, N-bis(2-chloroethyl)aminobenzoic acid on the incorporation of the radioactive precursor into the DNA of L1210, P388 leukemias, Ehrlich ascites tumor and, baby Hamster kidney cells was investigated. Higher inhibitory effects on the incorporation of the radioactive precursor was obtained with the ortho derivatives, yielding <70% inhibition of thymidine incorporation in all tumor lines tested.     

Terpenoids—LXXI: Chemical studies of marine invertebrates—XIV. Four representatives of a novel sesquiterpene class—the capnellane skeleton

The isolation and complete structure determination of four marine sesquiterpenoids: Δ⁹⁽¹²⁾-capnellene-8β,10α-diol (1), Δ⁹⁽¹²⁾-capnellene-3β,8β,10α-triol (3), Δ⁹⁽¹²⁾-capnellene-5α,8β,10α-triol (5), Δ⁹⁽¹²⁾-capnellene-2ξ,8β,10α-triol (7) from the soft coral Capnella imbricata is described. These alcohols are the first members of a fundamentally new sesquiterpene class consisting of three 5-membered fused rings which we have named capnellane (A).     

Synthesis of optically active seven-membered 1,5-anhydrocarbasugars and 1,4,5-tribenzoyloxy-2-ethoxy cycloheptanes via [5+2] cycloaddition

[5+2] Cycloaddition followed by asymmetric dihydroxylation procedure have been utilized to prepare novel cyclitols. Accordingly, rac-2α-hydroxy-6α-ethoxy-1,5-anhydro cyclohept-3-ene, 10 derived from [5+2] cycloaddition of 3-oxidopyrylium ylide and vinyl ether has been recognized as a seven-membered carbasugar equivalent and elaborated to 1,4,5-tribenzoyloxy-2-ethoxy cycloheptanes through a flexible, regio- and stereoselective strategy involving Sharpless asymmetric dihydroxylation conditions to resolve the compounds obtained. The structures and relative configurations of newly synthesized (+)-2α-acetoxy-6α-ethoxy-3β,4β-dihydroxy-1,5-anhydro cycloheptane ((+)-12)); (−)-1β,4β,5β-tribenzoyloxy-6α-ethoxy cycloheptane ((−)-17) and (+)-1α,4α,5α-tribenzoyloxy-6β-ethoxy cycloheptane ((+)-17) are unambiguously established by single crystal X-ray analysis and duly supported by ¹H and ¹³C NMR spectroscopy data.     

Fourier transform 13C nuclear magnetic resonance studies of steroids—II : Derivatives of 17β-(2,5-dihydro-5-oxo-3-furyl)-3β,5α,6-trihydroxyandrostane

The natural abundance ¹³C NMR spectra of derivatives of 17β-(2,5-dihydro-5-oxo-3-furyl)-3β,5α,6-trihydroxy androstane have been measured and completely assigned. The substituent chemical shifts (S.C.S's) for 11α- and 17α-OH substitution are evaluated. The magnitude and sign of the S.C.S.'s are discussed and compared with previous results from the literature.     

Ab initio calculations on 5α-androstane

The electronic structure of 5α-androstane, the parent hydrocarbon of the hormonal steroids, has been computed by ab initio SCF methods in an STO -3G basis. The results are compared with existing MNDO computations and are used to discuss long-range electronic interactions between distant substituents that might be appended to rings A and D of 5α-androstane. It is thought that these interactions are mediated by the ribbonlike MO 'S of the parent molecule.     

3β-methoxy-5α-cholestane-4β,5-diol and related compounds

The major product of acid-catalysed hydrolysis of 4α,5-epoxy-3β-methoxy-5α-cholestane (5) has been shown to be the allylic alcohol 9 (R = H) and not diol 10 as previously reported. A preparation of the latter compound, and of a number of cholestane derivatives with oxygen substituents in rings A and B, is described.     

Dissimilar behaviour of 3β, 16α-dihydroxy-5α-androstan-17-one Diacetate under Basic and Acidic Conditions

The base-catalysed rearrangement of 3β, 16α-dihydroxy-5α-androstan-17-one diacetate ( 1 ) in (D₆)benzene/ CD₃OD to 3β, 17β-dihydroxy-5α-androstan-16-one ( 3 ) is followed by ¹³C-NMR spectroscopy. By the same procedure, it is determined that in (D₆)benzene/CD₃OD, but under acid catalysis, 1 does not rearrange to 3 but yields the intermediate product 3β, 16α-dihydroxy-5α -androstan-17-one 17α -methyl hemiacetal ( 5 ).     

20, 21-Azirdin-Steroide: Reaktion von Derivaten der Oxime von 5-Pregnen-20-on,9β,10α-5-Pregnen-20-on und 9β,10α-5,7-Pregnadien-20-on mit Lithiumaluminiumhydrid und von 3β-Hydroxy-5-pregnen-20-on-oxim mit Grignard-Verbindungen

20, 21-Aziridine Steroids: Reaction of Derivatives of the Oximes of 5-Pregnen-20-one, 9β, 10α-5-Pregnen-20-one and 9β, 10α-5,7-Pregnadiene-20-one with Lithium Aluminium Hydride, and of 3β-Hydroxy-5-pregnen-20-one Oxime with Grignard Reagents. Reduction of 3β-hydroxy-5-pregnen-20-one oxime ( 2 ) with LiAlH₄ in tetrahydrofuran yielded 20α-amino-5-pregnen-3β-ol ( 1 ), 20β-amino-5-pregnen-3β-ol ( 3 ), 20β, 21-imino-5-pregnen-3β-ol ( 6 ) and 20β, 21-imino-5-pregnen-3β-ol ( 9 ). The aziridines 6 and 9 were separated via the acetyl derivatives 7 and 10 . The reaction of 6 and 9 with CS₂ gave 5-(3β-hydroxy-5-androsten-17β-yl)-thiazolidine-2-thione ( 8 ). Treatment of the 20-oximes 12 and 15 of the corresponding 9β,10α(retro)-pregnane derivatives with LiAlH₄ gave the aziridines 13 and 16 , respectively. Their deamination led to the diene 14 and triene 17 , respectively. Reduction of isobutyl methyl ketone-oxime with LiAlH₄ in tetrahydrofuran yielded 2-amino-4-methyl-pentane ( 19 ) as main product, 1, 2-imino-4-methyl-pentane ( 22 ) as second product and the epimeric 2,3-imino-4-methyl-pentanes 20 and 21 as minor products. – 3β-Hydroxy-5-pregnen-20-one oxime ( 2 ) was transformed by methylmagnesium iodide in toluene to 20α, 21-imino-20-methyl-5-pregnen-3β-ol ( 23 ) and 20β, 21-imino-20-methyl-5-pregnen-3β-ol ( 26 ). Acetylation of these aziridines was accompanied by elimination reactions leading to 3β-acetoxy-20-methylidene-21-N-acetylamino-5-pregnene ( 30 ) and 3β-acetoxy-20-methyl-21-N-acetylamino-5,17-pregnadiene ( 32 ). The reaction of oxime 2 with ethylmagnesium bromide in toluene gave 20α, 21-imino-20-ethyl-5-pregnen-3β-ol ( 24 ) and 20α,21-imino-20-ethyl-5-pregnen-3β-ol ( 27 ). Acetylation of 24 and 27 led to 3β-acetoxy-20-ethylidene-21-N-acetylamino-5-pregnene ( 31 ), 3β-acetoxy-20-ethyl-21-N-acetylamino-5,17-pregnadiene 33 and 3β, 20-diacetoxy-20-ethyl-21-N-acetylamino-5-pregnene ( 37 ). With phenylmagnesium bromide in toluene the oxime 2 was transformed to 20β, 21-imino-20-phenyl-5-pregnen-3β-ol ( 25 ) and 20β,21-imino-20-phenyl-5-pregnen-3β-ol ( 28 ). Acetylation of 25 and 28 yielded 3β-acetoxy-20-phenyl-21-N-acetylamino-5, 17-pregnadiene ( 34 ) and 3β,20-diacetoxy-20-phenyl-21-N-acetylamino-5-pregnene ( 39 ). LiAlH₄-reduction of 39 gave 3β, 20-dihydroxy-20-phenyl-21-N-ethylamino-5-pregnene ( 41 ). – The 20, 21-aziridines are stable to LiAlH₄. Consequently they are no intermediates in the formation of the 20-amino derivatives obtained from the oxime 2 .     

Improved Aldehyde Synthesis: Preparation of 3α, 7α, 12α-Triacetoxy-5β-Cholan-23-al with Ruthenium Tetroxide in Neutral Medium

In relation to our studies on the metabolism of neutral sterols² we have prepared several substituted 24-norcholanic acids. Ruthenium tetroxide was selected as the oxidizing agent^3,4 in the formation of 24-norcholic acid^5,6 from the olefin, 3α, 7α, 12α-triacetoxy-24, 24-diphenyl-5β-chol-23-ene (II), (Fig. 1) since CrO₃ provided multiple products⁵.