Reactions of terpene alcohols and diols with chlorine dioxide in dimethylformamide

The system chlorine dioxide–dimethylformamide in combination with or without a catalytic amount of MoCl₅, CeCl₃, ZrOCl₂, or VO(acac)₂ induces oxidative chlorination of a number of bicyclic terpene alcohols and vicinal diols. 2α-Chloropinan-3-one, 3α-chloro-10β-pinan-4-one, 5α-chloro-3α-hydroxycaran-4-one, 5β-chloro-3β-hydroxycaran-4-one, and 4α-chloro-2α-hydroxypinan-3-one were thus synthesized in good preparative yields.     

Triterpene glycosides of Hedera taurica

From the leaves of Crimean ivy we have isolated the previously known glycosides 3-O-α-L-Ara_p-28-O-[O-α-L-Rha_p-(1→4)-O-β-D-Glc_p-(1→6)-β-D-Glc_p]hederagenin, 3-O-[O-α-L-Rha_p-(1→2)-α-L-Ara_p]-28-O-[O-α-L-Rha_p-(1→4)-O-β-D-Glc_p-(1→6)-β-D-Glc_p]oleanic acid and -hederagenin, and 3-O-[O-α-L-Rha_p-(1→2)-α-L-Ara_p]-28-O-[O-β-D-Glc_p-(1→6)-β-D-Glc_p]hederagenin and a new one: tauroside H₁ — 3-O-[O-α-L-Rha_p-(1→2)-O-α-L-Ara_p]-28-O-[O-α-L-Rha_p-(1→4)-O-β-D-Glc_p-(1→6)-β-D-Glc_p]echinocystic acid.     

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.     

Nature of α,β-CCC agostic bonding in metallacyclobutanes

The α,β-CCC agostic bonding in metallacyclobutanes is examined on the basis of structural, bonding, energetics, and electron density features. The structural features such as C_α–C_β, M–C_α, and M–C_β distances and C_αC_βC_α and MC_αC_β angles of the agostic metallacyclobutanes were distinctly different from those of the corresponding non-agostic complexes. Two different orbital interactions characteristic of the agostic complex, causing the deformation of the propane-1,4-diyl unit of the metallacyclobutane were identified. The energy difference between the propane-1,4-diyl unit of metallacyclobutane in an agostic complex to that in a non-agostic complex is proposed as a good measure for the strength of α,β-CCC agostic interaction (E_agostic). E_agostic values of 37.0, 36.2, 13.7, 28.6, and 23.9 kcal/mol were obtained for the Grubb’s first generation Ru, Grubb’s second generation Ru, Ti, W, and Ta metallacyclobutane complexes and these values showed a linear correlation with the electron density at the ring CPs. The QTAIM features of the agostic complexes viz. the smaller ρ value at the C_α–C_β BCPs, larger ellipticity of the C_α–C_β BCPs, and diminished covalent character of C_α–C_β bonds as seen in their Laplacian of the electron density (∇²ρ) at the BCPs, when compared with the non-agostic systems, fully supported the agostic bonding interactions. The α,β-CCC bonding is considered as the first example of a π type orbital formed between a metal atom and a carbon atom, where there is no σ bond connectivity and this type of bonding is anticipated with all transition metals provided that the metal center is highly electron deficient.     

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 ).     

Stapelogenin,vermutliche Struktur. Glykoside und Aglykone, 276. Mitteilung

Stapelogenin, C₂₁H₃₀O₄, shows a double bond and two hydroxyl groups which can be acetylated. On the grounds of UV.-, IR.-, and NMR-spectra as well as mass spectra, the probable structure is that of a 3β, 12β-dihydroxy-(18, 20β), (14β, 20α)-diepoxy-Δ⁵-pregnene ( 1 ). The exact position of the hydroxyl group, assumed to be 12β, is particularly unsure, as it could also be situated 11α- or 12α-position.     

Bile acids LXIX. Selective K-Selectride reduction of 3,7-diketo steroids

The K-Selectride reduction at low temperature (-45°C) of 7-oxo-5α-holestan-3β-yl acetate and methyl 7-oxo-3α-hydroxy-5(β-cholanoate resulted in almost quantitative yield of the 7α-alcohol in the 5α-compound but only moderate yield of the 5β-analog. The simultaneous reduction of two carbonyl groups in the 3 and 7 positions afforded good to excellent yields of the diaxial diol in planar steroids (methyl 3,7-dioxo-5α-cholanoate, 3,7-dioxo-5α-cholestane and methyl 3,7-dioxo-5α-cholestan-27-oate) and only 14% of 3α,7α-(OH)₂ from methyl 3,7-dioxo-5β-cholanoate.     

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.     

Lewis acid-catalyzed rearrangement of steroidal oxetanes: revision of the course of solvolysis of 3β-tosyloxy-5β-cholestan-5-ol-6-one.

The BF₃-catalysed rearrangement of 6β-acetoxy-3α,5-epoxy-5α-cholestane gave the 3α,5β-diol, the 3α,10α-epoxide, and the 2α,5α-epoxide, and the product of solvolysis of 3β-tosyloxy-5β-cholestan-5-ol-6-one was identified as 3α,5-epoxy-A-homo-B-nor-5α-cholestan-4a-one.     

Tordanone,un stéroïde replié avec une jonction de cycle A/B β-cis (5β) et B/C α-cis(8α)

Tordanone, a Twice Bent Steroid Structure with Ring A/B β-cis(5β)- and Ring B/C α-cis(8α)-Fused The 3β, 14α, 25-trihydroxy-5β, 8α-cholestan-6-one ( = tordanone; 4 ) has been prepared by stereospecific hydrogenation of 3β, 14α, 25-trihydroxy-5β-cholesta-7,22ξ-dien-6-one ( 5 ). This is the first stereospecific synthesis of a B/C cis-fused steroid belonging to the 5β, 8α -cholestane group with a H-atom at positions 5β (A/B cis-fused) and 8α. The resulting twice bent structure shows a particularly strong steric hindrance of the β-face where CH₃(18) at the C/D ring junction and H_β? C(7) of the B ring are very close to each other. Structural features and mechanistic aspects of the hydrogenation are discussed.     

The application of chemical effects in high resolution X-ray spectrometry

Chemical effects on Mn K_α Mn K_β, Cr K_β and Sn L_β2 were investigated with a high resolution two-crystal X-ray spectrometer. The width of Mn K_α1 and the energy shifts of Mn K_β, Cr K_β and Sn L_β2 were found to be dependent on the chemical state, especially on the oxidation number of X-ray emitting atoms. The changes in the Mn K_α1 width and in the Mn K_β, Cr K_β and Sn L_β2, energy shifts were large enough to be used for identification of the oxidation states of these elements in various compounds. The phenomena were applied to the chemical state analysis of manganese and chromium in inorganic pigments, chromium and tin in glass, and tin in organic catalysts.     

Palladium-catalyzed arylation of α,α-difluoro-allylic-β-hydroxyester

The aryl-substituted α,α-difluoro-allylic-β-hydroxyesters and aryl-substituted α,α-difluoroketones were obtained via the coupling reaction of aryl iodides with α,α-difluoro-allylic-β-hydroxyester in the presence of Pd(OAc)₂ as the catalyst and Et₃N as the base.     

Synthese von tri- und tetrasaccharid-einheiten des O-antigens aus Aeromonas salmonicida

The following oligosaccharide sequences containing the repeating unit of the O-specific chain of lipopolysaccharides from aeromonas salmonicida have been synthesized: α-D-Glcp-(1→3)-α-L-Rhap-(1 →3)-β-D-ManpNAcO(CH₂)₈CO₂Me, α-D-Glcp-(1 →4)-α-D-Glcp-(1→3)-α-L-Rhap-(1→3)-β-D-ManpNAcO(CH₂)₈CO₂Me and α-D-Glcp(1→4)-α-D-Glcp-(1→3)-[β-D-ManpNAc(1→4)]-L-Rha.     

Synthese von 3-Oxacholestanen

Successive treatment of 5α-cholestan-3-one ( 1 ) with O₂ under basic conditions and then NaBH₄ led to 5α-3-oxa-cholestan-2-one ( 5 ). Analogous reactions with 5β-cholestan-3-one ( 6 ) yielded 5α-4-oxa-cholestan-3-one ( 7 ) and 5 ξ-3-oxa-cholestan-4-one ( 8 ). 4-Cholesten-2-one ( 10 ), which was prepared starting from 4-cholesten-3-one, was isomerized by methanolic KOH to give a mixture of 5α-cholest-3-en-2-one ( 11 ) and 5β-cholest-3-en-2-one ( 12 ). 5β-Cholestane-2,3-dione ( 17 ) was synthesized from 4β-bromo-5β-cholestan-3-one ( 13 ). Ozonolysis of the dione 17 and subsequent NaBH₄ reduction of the oxidation product gave both 5β-2-oxa-cholestan-3-one ( 18 ) and 5β-3-oxa-cholestan-2-one ( 19 ).     

Temperature dependence of vibrational modes of CH3?CC(ads) and I(ads) coadsorbed on Ag(111): Ab initio molecular dynamics approach

Ab initio molecular dynamics simulations accompanied by a Fourier transform of the dipole moment (aligned perpendicular to the surface) autocorrelation function are implemented to investigate the temperature‐dependent infrared (IR) active vibrational modes of CH₃? C_(β)?C_(α)(ads) and I_(ads) when coadsorbed on an Ag(111) surface at 200 and 400 K, respectively. The analytic scheme of the Fourier transform of a structural coordinate autocorrelation function is used to identify two distinguishable IR active peaks of C_(β)?C_(α) stretching, which are characterized by two types of dynamic motion of adsorbed CH₃? C_(β)?C_(α)(ads) at 200 K, namely, the motion of the tilted ? C? C_(β)?C_(α)? axis and the motion of the stand‐up ? C? C_(β)?C_(α)? axis. These two recognisable IR active peaks of C_(β)?C_(α) stretching are gradually merged into one peak as a result of the dominant motion of the stand‐up ? C? C_(β)?C_(α)? axis as the temperature increases from 200 to 400 K. The calculated intensities of the IR active peaks of the asymmetrical deformation mode of CH₃ and the asymmetrical stretching mode of CH₃, with their dynamic dipole moments nearly perpendicular to the ? C? C_(β)?C_(α)? axis, become relatively weak; however, the symmetrical deformation mode of CH₃ and the symmetrical stretching mode of CH₃, with their dynamic dipole moments randomly directed away from the ? C? C_(β)?C_(α)? axis, will not have direct correspondence between the intensities of their IR active peaks and the angle between the Ag(111) surface and the ? C? C_(β)?C_(α)? axis as the temperature increases from 200 to 400 K. Finally, the increased flipping from the motion of the tilted ? C? C_(β)?C_(α)? axis to the motion of the stand‐up ? C? C_(β)?C_(α)? axis followed by its diffusion, resulting from the increasing temperature from 200 to 400 K or even higher, seems to be the initial event that initiates the alkyne self‐coupling reaction that leads to the final production of H₃C? C?C? C?C? CH₃. © 2012 Wiley Periodicals, Inc.     

Synthesis of haloconduritols from an endo-cycloadduct of furan and vinylene carbonate

A method for preparing haloconduritols having a conduritol-A construction is described. A mixture of endo- and exo-cycloadduct derivatives prepared from the Diels-Alder reaction of furan and vinylene carbonate was converted into diacetate derivatives by hydrolysis (K₂CO₃/MeOH) followed by acetylation (Ac₂O/pyridine). Boron trihalide (BBr₃ or BCl₃)-assisted ring-opening of the endo-diacetate in CH₂Cl₂ at −78°C gave (1α,2α,3β,6β)-6-halogeno-4-cyclohexene-1,2,3-triol 1,2-diacetate from which the corresponding triacetate was prepared by acetylation (AcCl). trans-Esterification of the triacetate (MeOH/HCl) afforded (1α,2α,3β,6β)-6-halogeno-4-cyclohexene-1,2,3-triol (X=Br or Cl). BF₃-Assisted ring-opening of the endo-diacetate in CH₂Cl₂ gave (1α,2α,3β,6β)-6-chloro-4-cyclohexene-1,2,3-triol 1,2-diacetate by means of halogen exchange.     

Culcitosides C2 and C3 from the starfishCulcita novaeguineae

Two steroid glycosides not previously described have been isolated from the digestive system of the starfishCulcite novaeguiniae, and these have been called culcitosides C₂ and C₃. With the aid of chemical and spectral methods, the chemical structure of C₂ has been established as 24ξ-methyl-5α-cholestane-3β,4β,6α,8,15β,16β,28-heptaol 28-O-[O-(2,4-di-O-methyl-β-D-xylopyranosyl)-(1 → 2)-α-L-arabinofuranoside, and that of C₃ as its 4-deoxy analogue.     

Alkaloide aus Cortex Condurango

From the CH₂Cl₂ extract of the bark of Marsdenia cundurango Reichenb. fil. (Cortex Condurango) a mixture of basic compounds could be isolated. Repeated thin layer and column chromatography yealded two alkaloids in pure form. For Kondurangamin A, which would be the mayor alkaloid with a content of 0.0007%, the structure was determined as 3β, 14β,20-trihydroxy-11 α-nicotinoyloxy-12β-acetoxy-5α,14β-pregnane and for Kondurangamin B as 3β,11α,12β,14β-tetrahydroxy-20-nicotinoyloxy-5α,14β-pregnane.     

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 .     

Drüsenfarbstoffe aus Labiaten: Die polaren Diterpenoide aus Plectranthus argentatus S. T. BLAKE

Polar Diterpenoids from Leaf-Glands of Plectranthus argentatus S. T. B_LAKE From the red leaf-glands of the Australian Plectranthus argentatus the following novel diterpenoids were isolated: coleon-U-quinone ( 1 ), 8α,9α-epoxycoleon-U-quinone ( 3 ), 6β-formyloxy-7α-hydroxyroyleanone ( 7 ), and 5,6-dihydrocoleon U ( 10 ), besides the already known compounds 6β, 7α-dihydroxyroyleanone ( 4 ), 7α-acetoxy-6β-hydroxyroyleanone ( 5 ), and 7α-formyloxy-6β-hydroxyroyleanone ( 6 ). Epoxydation of 1 by perborate led in 32% yield to the epoxyquinone 3 .