Ruizgenin,a new steroidal sapogenin diol from AgaveLecheguilla

From the leaves of Agavelecheguilla Torrey, two steroidal sapogenin diols have been isolated. Mass spectral, infra-red and nuclear magnetic resonance data of these two compounds showed them to be (25R) spirost-5-ene-2α, 3β-diol (yuccagenin) and (25R)-5β-spirostane-3β,6α-diol. The latter is a new compound to which the trivial name ruizgenin has been given.     

A DNA-binding fraction of mouse kidney 3-ketosteroid reductase: Comparison with androgen receptors

Since approximately 1% of 3-ketosteroid reductase (which metabolizes dihydrotestosterone [17β-hydroxy-5α-androstan-3-one] to 5α-androstane-3α,17β-diol or 5α-androstane-3α,17β-diol) from mouse kidney cytosol adheres to DNA under conditions that allow virtually complete androgen receptor binding, these two DNA-binding activities were compared in cytosol extracts of mouse kidney and hypothalamus-preoptic area. This DNA-binding fraction of 3-ketosteroid reductase was distinguished from androgen receptor in several ways: (1) its pattern of elution from DNA-cellulose with steps of increasing NaC1 concentration differed from that for receptors from wild-type kidney; (2) it was influenced differently by the mutation Tfm, both in level and in DNA-cellulose elution pattern; (3) in mouse kidney cytosol it was relatively stable at moderate (25°C) temperatures which rapidly inactivated ligand-free androgen receptors in the same cytosols; (4) the DNA-binding was not proportional to androgen receptor levels between two wild-type tissues, the hypothalamus-preoptic area and kidney. By these criteria, a simple relationship of androgen receptors and a DNA-binding fraction of 3-ketosteroid reductase activity is unlikely.     

Steroid specificity of human placental 5-ene-3β-hydroxysteroid oxidoreductase

The properties of 5-ene-3β-hydroxysteroid oxidoreductase (3β-HSD) from human placental homogenates were studied invitro. The apparent Michaelis constants for 3β-HSD with the substrates pregnenolone (Δ⁵P) and dehydroepiandrosterone (DHA) were 170 nM and 40 nM respectively. The optimal pH for both these substrates was between 10 and 12. With NAD as the substrate, the Km for pregnenolone was 20 μM and for DHA, 17 μM. The activity of 3β-HSD was inhibited by various steroids. Competitive inhibitors (pregnenolone substrate) included: ethynylestradiol (inhibition constant Ki=7.3 nM), DHA (Ki=46 nM), estradiol-17β (Ki=46 nM), cholesterol (Ki=0.68 μM) and 16α-hydroxydehydroepiandrosterone (16αOHDHA) (Ki=2.2 μM). When the substrate was DHA, competitive inhibition occurred with the following steroids: ethynylestradiol (Ki=6.4 nM), estradiol-17β (Ki=69 nM), pregnenolone (Ki=91 μM), cholesterol (Ki=1.3 μM) and 16αOHDHA (Ki=1.9 μM). 4-Ene-3-ketosteroids such as androstenedione, progesterone (Δ⁴P), norethindrone and chlormadinone acetate acted as noncompetitive inhibitors towards both substrates.     

The effect of progesterone analogues,naturally occurring steroids,and contraceptive progestins on hypothalamic and anterior pituitary Δ4-steroid (progesterone) 5α-reductase

The effects of a number of steroids on the conversion of progesterone to 5α-dihydroprogesterone by hypothalamic and pituitary progesterone 5α-reductase have been investigated. Using enzyme preparations from female rats and ³H-progesterone as substrate, 5α-reduced products (5α-dihydroprogesterone and 3α-hydroxy-5α-pregnan-20-one) were analyzed by reverse isotopic dilution analysis. The amount of total 5α-reduced products formed was compared in the presence and absence of the test steroid. Derivatives lacking the Δ⁴ and/or the 3-keto moiety were without effect. Corticosterone had no effect. 16β-Methylprogesterone inhibited progesterone 5α-reduction in both tissues by at least 65%, while the 2α-, 6α-, and 7α-methylated derivatives had lesser effects. 3-Oxo-4-pregnene-20β-carboxaldehyde and 21-fluoroprogesterone were potent inhibitors. 17-Hydroxyprogesterone was a competitive inhibitor (substrate) with Ki's of 0.27 μM (pituitary) and 0.29 μM (hypothalamus). Medroxyprogesterone exerted little inhibitory effect. Of the 19-norsteroids examined, only norethindrone appreciably inhibited the 5α-reduction. These results suggest that some natural Δ⁴-3-ketosteroids can modify enzymatic activity. Also, inhibitory analogues may be useful for studies on the role of this 5α-reduction of progesterone.     

Minor and trace sterols in marine invertebrates V. isolation,structure elucidation and synthesis of 3β-hydroxy-26,27-bisnorcholest-5-en-24-one from the sponge Psammaplysilla Purpurea

The free sterol mixture of the sponge Psammaplysilla purpurea was shown to contain aplysterol as the major constituent. In addition to other sterols such as 5,7-cholestadien-3β-ol, cholesterol, 5α-cholestan-3β-ol, 24ε-methylcholesta-5,22-dien-3β-ol, 24ε-methylcholesterol, 24ε-ethylcholesta-5,22-dien-3β-ol and 24,28-dehydroaplysterol, a new minor sterol was isolated and shown by spectral analysis as well as partial synthesis to be 3β-hydroxy-26,27-bisnorcholest-5-en-24-one. The sterol mixture contains no other short side chain or 24-keto sterols except for small amounts of 3β-hydroxypregn-5-en-20-one and 3β-hydroxy-5α-pregnan-20-one.     

Synthesis of 5-Chloro-l-(2, 3-Orisopropylidene-4-keto Rhamnopyranosyl)-uracil

Abstract

Syntheses of 5-chloro-l-C2, 3, 4-tri-0-acetyl-αa-L-rhamnopyrano-syl)-uracil (1), 5-chloro-l-(a-L-rhamnopyranosyl)-uracil (2), 5-chloro-l (2, 3-Oisopropylidene-α-L-rhamnopyranosyl)-uracil (3), and 5-chloro-l-(2, 3-O-isopropylidene-4-Tceto-rhamnopyranosyl)-uracil (4 are reported. Oxidation of 3 to 4 was effected using pyridinium chlorochromate.     

The Synthesis of Novel Carbohydrates Amenable to the Synthesis of 2′,3′-Dideoxy-3′-Branched Nucleosides

Abstract

The facile synthesis of several substituted carbohydrates that are amenable for the preparation of 2′,3′-dideoxy-3′-hydroxymethyl nucleosides are reported. Elaboration of a previously reported analog, 5-O-benzoyl-3-deoxy-3-(benzyloxy)methyl-1,2-O-isopropylidene-β-D- ribofuranose (4) has provided two 2,3-dideoxy-3-branched ribose derivatives 5-O-benzoyl-2,3-dideoxy-3-(benzyloxy)methyl-1-O-methyl-β-D-ribofuranose (7) and 1.5-di-O-benzoyl-2,3-dideoxy-3-(benzyloxy)methyl-(α,β)-D-ribofuranose (10). Due to problems involved with the separation of anomeric mixtures when these carbohydrates were condensed with an heterocycle, another versatile synthon 5-O-benzoyl-3-deoxy-3-(benzyloxy)methyl-2-O-t-butyldimethylslyl-1-O- methyl-β-D-ribofuranose (12) was synthesized. The utility of this compound (12) is demonstrated in the total synthesis of 1-[3-deoxy-3-hydroxymethyl-β-D-ribofuranosyl]thymine (20).     

Studies on the Chemical Synthesis of Potential Antimetabolites. 371. Synthesis of 3-Deazaadenine Nucleosides Modified at the Sugar Moiety

Abstract

Several types of 3-deazaadenine pentofuranosides, represented by 9-(3-deoxy-β-D-glycero-pent-3-enofuranosyl)-3-deazaadenine (1), 9-(5-deoxy-β-Q-erythro-pent-4-enofuranosyl)-3-deazaadenine (2) and 9-β-D-xylo-furanosyl-3-deazaadenine (3), were prepared starting from 6-chloro-9-β-D-ribofuranosyl-3-deazaadenine (4).     

Synthetic Nucleosides and Nucleotides. XX1. Synthesis of Various 1-β-D-Xylofuranosyl-5-Alkyluracils and Related Nucleosides

Abstract

Treatment of D-xylose (1) with 0.5% methanolic hydrogen chloride under controlled conditions followed by benzoylation and acetolysis afforded crystalline 1-O-acetyl-2, 3, 5-tri-O-benzoyl-α-D-xylofuranose (4) in good yield. Coupling of 4 with 2, 4-bis-trimethylsilyl derivatives of 5-alkyluracils (methyl, ethyl, propyl and butyl) (5a-5d), 5-fluorouracil (5e) and uracil (5f) in acetonitrile in the presence of stannic chloride gave 1-(2,3,5-tri-O-benzoyl-β-D-xylofuranosyl)-nucleosides (6a-6f). Saponification of 6 with sodium methoxide afforded 1-β-D-xylofuranosyl-5-substituted uracils (7a-7f). Condensation of 4 with free adenine in similar fashion and deblocking gave carcinostatic 9-β-D-xylofuranosyladenine (7g).     

The synthesis of 2α,3α-isopropylidenedioxy-6,6-ethylenedioxy-5α-androst-15-en-17-one and its 2β,3β-isomer

Androstane and Δ¹⁵-androstane analogues of brassinosteroids were synthesized from dehydroepiandrosterone. The key stage, hydroxylation of 17β-acetoxyandrost-2-en-6-one double bond with OsO₄, yielded the corresponding 2α,3α-and 2β,3β-diols. The target 2α,3α-isopropylidenedioxy-6,6-ethylenedioxy-5α-androst-15-en-17-one and its 2β,3β-isomer were obtained by dehydrosilylation of the corresponding silylenol ethers with palladium acetate.     

Studies Towards the Large Scale Chemical Synthesis of the Precursors of Ribonucleosides-3′,4′,5′,5″- 2H 4 and -2′,3′,4′,5′,5″- 2H 5

Abstract

A summary delineating the large scale synthetic studies to prepare labeled precursors of ribonucleosides-3′,4′,5′,5″- ²H ₄ and -2′,3′,4′,5′,5″- ²H ₅ from D-glucose is presented. The recycling of deuterium-labeled by-products has been devised to give a high overall yield of the intermediates and an expedient protocol has been elaborated for the conversion of 3-O-benzyl-α,β-D-allofuranose-3,4-d ₂ 6 to 1-O-methyl-3-O-benzyl-2-O-t-butyldimethylsilyl-α,β-D-ribofuranose-3,4,5,5′-d ₄ 16 (precursor of ribonucleosides-3′,4′,5′,5″- ²H ₄ ) or to 1-O-methyl-3,5-di-O-benzyl-α,β-D-ribofuranose-3,4,5,5′-d ₄ 18 (precursor of ribonucleosides-3′,4′,5′,5″- ²H ₄ ).     

Proton magnetic resonance spectra of 17ξ-Hydroxy-17ξ-methyl-5ξ-androstane C-3 ketone and c-3ξ alcohol isomers in chloroform-d and pyridine-d5

17α-Hydroxy-17β-methyl-5β-androstan-3-one, 17μ-methyl-5α-androstane-3α, 17α-diol, 17β-methyl-5α-androstane-3β, 17α-diol, 17α-methyl-5β-androstane-3β, 17β-diol, 17β-methyl-5β-androstane-3α, 17α-diol and 17β-methy1–5β-androstane-3β, 17α-diol were synthesized for the first time. ¹H NMR spectra of all four 17ξ-hydroxy/17ξ-methyl C-3 ketones and all eight C-3 alcohols were recorded in chloroform-d and pyridine-d₅. Pyridine-induced chemical shifts are discussed. Thin-layer Chromatographic data are given.     

Epimerisation of 3β-ol to 3α-ol steroid alkaloids by Nocardia restrictus

(22S,25S)-5α-tomatanin-3β-ol, N-acetyl-(22S,25S)-5α-tomatanin-3β-ol, (22R,25R)-5α-tomatanin-3β-ol and (22R,25S)-22,26-epimino-5α-cholestane-3β,16β-diol are transformed by Nocardia restrictus into corresponding 3α-ol compounds with yields from 70 to 5%.     

Synthesis of 1-(4-Keto-2, 3-O-isopropylidene-α-L-rhamnopyranosyl) uracil

Abstract

Synthesis of 1-(2, 3, 4-tri-0-acetyl-α-L-rhamnopyranosyl) uracil (3), 1-(α-L-rhamnopyranosyl) uracil (4), 1-(2, 3-0-isopropylidene-α-L-rhamnosyl) uracil (5), and 1-(2, 3-0-isopropylidene-4-keto-α-L-rhamnopyranosyl) uracil (6) are reported. Oxidation of (5) to (6) was effected using pyridinium chlorochromate in presence of molecular sieves.     

Synthesis of Certain 4-Substituted-1-β-D-Ribofuranosyl-3-Hydroxypyrazoles Structurally Related to the Antibiotic Pyrazofurin

Abstract

Several 4-substituted-1-β-D-ribofuranosyl-3-hydroxypyrazoles were prepared as structural analogs of pyrazofurin. Glycosylation of the TMS derivative of ethyl 3(5)-hydroxypyrazole-4-carboxylate (3) with 1-0-acetyl-2,3,5-tri-0-benzoyl-D-ribofuranose in the presence of TMS-triflate gave predominantly ethyl 3-hydroxy-1-(2,3,5-tri-0-benzoyl-β-D-ribofuranosyl)pyrazole-4-carboxylate (4a), which on subsequent ammonolysis furnished 3-hydroxy-1-β-D-ribofuranosylpyrazole-4-carboxamide (5). Benzylation of 4a with benzyl bromide and further ammonolysis gave 3-benzyloxy-1-β-D-ribofuranosylpyrazole-4-carboxamide (8a). Catalytic (Pd/C) hydrogenation of 8a afforded yet another high yield route to 5. Saponification of the ester function of ethyl 3-benzyloxy-1-β-D-ribofuranosylpyrazole-4-carboxylate (7b) gave the corresponding 4-carboxylic acid (6a). Phosphorylation of 8a and subsequent debenzylation of the intermediate 11a gave 3-hydroxy-1-β-D-ribofuranosylpyrazole-4-carboxamide 5′-phosphate (11b). Dehydration of 3-benzyloxy-1-(2,3,5-tri-0-acetyl-β-D-ribofuranosyl)pyrazole-4-carboxamide (8b) with POCl₃ provided the corresponding 4-carbonitrile derivative (10a), which on debenzylation with Cl₃SiI gave 3-hydroxy-1-(2,3,5-tri-0-acetyl-β-D-ribofuranosyl)pyrazole-4-carbonitrile (13). Reaction of 13 with H₂S/pyridine and subsequent deacetylation gave 3-hydroxy-1-β-D-ribofuranosylpyrazole-4-thiocarboxamide (12b). Similarly, treatment of 13 with NH₂OH afforded 3-hydroxy-1-β-D-ribofuranosylpyrazole-4-carboxamidoxime (14a), which on catalytic (Pd/C) hydrogenation gave the corresponding 4-carboxamidine derivative (14b). The structural assignment of these pyrazole ribonucleosides was made by single-crystal X-ray analysis of 6a. None of these compounds exhibited any significant antitumor or antiviral activity in cell culture.     

Synthesis of metabolic intermediates of diethylstilbestrol

This report details the synthesis of 1) 3,4,4′-trihydroxy-α,α′-diethyl-trans-stilbene; 2) 3,4-bis-(p-hydroxyphenyl)-trans-3-hexenol; 3) 3,4-bis-(p-hydroxyphenyl)-2,4-cis,cis-hexadienol; 4) 3,4-bis-(3′-methoxy-4′-hydroxyphenyl)-trans-3-hexene; 5) 3,4-bis-(3′, 4′-dimethoxyphenyl)-trans-3-hexene. These compounds are suspected metabolites of diethylstilbestrol.     

Synthesis of Pyrazolo[3, 4-d]Pyrimidine Ribonucleoside 3′, 5′-Cyclic Phosphates Related to cAMP,cIMP and cGMP1

Abstract

The synthesis of pyrazolo[3,4-d]pyrimidine ribonucleoside 3′, 5′-cyclic phosphates related to cAMP, cIMP and cGMP has been achieved for the first time. Phosphorylation of 4-amino-6-methylthio-1-β-D-ribo-furanosylpyrazolo[3,4-d]pyrimidine (1) with POCl₃ in trimethyl phosphate gave the corresponding 5′-phosphate (2a). DCC mediated intramolecular cyclization of 2a gave the corresponding 3′, 5′-cyclic phosphate (3a), which on subsequent dethiation provided the cAMP analog 4-amino-1-β-D-ribofuranosylpyrazolo[3, 4-d]pyrimidine 3′, 5′-cyclic phosphate (3b). A similar phosphorylation of 6-methylthio-1-β-D-ribofuranosylpyrazolo[3, 4-d]pyrimidin-4(5H)-one (5), followed by cyclization with DCC gave the 3′, 5′-cyclic phosphate of 5 (9a). Dethiation of 9a with Raney nickel gave the cIMP analog 1-β-D-ribofuranosylpyrazolo[3, 4-d]pyrimidin-4(5H)-one 3′, 5′-cyclic phosphate (9b). Oxidation of 9a with m-chloroperoxy benzoic acid, followed by ammonolysis provided the cGMP analog 6-amino-1-β-D-ribofuranosylpyrazolo [3, 4-d] pyrimidin-4(5H)-one 3′, 5′-cyclic phosphate (7). The structural assignment of these cyclic nucleotides was made by UV and H NMR spectroscopic studies.     

Synthesis and Biological Evaluation of 3-Deazacytidine and 3-Deazauridine Derivatives

Abstract

The synthesis of new 5-and 6- subsituted 3-deazapyrimidine ribonucleosides has been performed by reacting the silylated bases and 1-0-acetyl-2, 3, 5-tri-O-benzoyl-β-D-ribofuranose in dichloroethane in the presence of stannic chloride.

None of these compounds exhibited any antiviral activity in vitro against HSV1 and RV31.     

Synthesis of 2′,3′-Dideoxyribavirin

Abstract

A synthesis of 1-(2,3-dideoxy-β-D-ribofuranosyl)-1,2,4-triazole-3-carboxamide (2′,3′-dideoxyribavirin, ddR) is described. Glycosylation of the sodium salt of 1,2,4-triazole-3-carbonitrile (5) with 1-chloro-2-deoxy-3,5-di-0-p-toluoyl-α-D-erythro-pentofuranose (1) gave exclusively the corresponding N-1 glycosyl derivative with β-anomeric configuration (6), which on ammonolysis provided a convenient synthesis of 2′-deoxyribavirin (7). Similar glycosylation of the sodium salt of methyl 1,2,4-triazole-3-carboxylate (2) with 1 gave a mixture of corresponding N-1 and N-2 glycosyl derivatives (3) and (4), respectively. Ammonolysis of 3 furnished yet another route to 7. A four-step deoxygenation procedure using imidazolylthiocarbonylation of the 3′-hydroxy group of 5′-0-toluoyl derivative (9a) gave ddR (11). The structure of 11 was proven by single crystal X-ray studies. In a preliminary in vitro study ddR was found to be inactive against HIV retrovirus.     

omega-Hydroxylase for 5beta-cholestane-3alpha,7alpha-diol in the biosynthesis of chenodeoxycholic acid.

The 5β-cholestane-3α,7α-diol 26-hydroxylase system, which is involved in the conversion of cholesterol to chenodeoxycholic acid, was studied in rat liver mitochondria. 26-Hydroxylase of 5β-cholestane-3α,7α-diol showed the following characteristics. (i) 5β-Cholestane-3α,7α-diol 26-hydroxylase requires electron donors similar to those required for 5β-cholestane-3α,7α,12α-triol 26-hydroxylase. (ii) Both enzyme activities are inhibited by similar inhibitors such as carbon monoxide and phenylisocyanide, but not by respiratory inhibitors such as rotenone, amytal, antimycin A, and cyanide. (iii) The presence of 5β-cholestane-3α,7α-12α-triol in the incubation mixture for 5β-cholestane-3α,7α-diol inhibits the latter activity in a competitive manner. (iv) The distribution patterns of both enzyme activities in submitochondrial fractions are similar. (v) The reconstituted enzyme system composed of partially purified cytochrome P-450 from rat liver mitochondrial inner membrane, NADPH-adrenodoxin reductase and adrenodoxin (both purified from bovine adrenocortical mitochondria), and NADPH showed 26-hydroxylation activity not only for 5β-cholestane-3α,7α-diol but also for 5β-cholestane-3α,7α,12α-triol; both activities were comparable.