Synthesis of mono- and diglucosiduronates of metabolites of deoxycorticosterone and corticosterone and analysis by a new mass spectrometric technique

By condensing 3 alpha,21-dihydroxy-5 beta-pregnan-20-one, or its appropriate monoacetate, with methyl 2,3,4-tri-O-acetyl-1-bromo-1-deoxy-alpha-D-glucuronate in the Koenigs-Knorr reaction beta-D-glucosiduronates 10, 4, and 7 were obtained as polyacetate methyl esters. Alkaline hydrolysis of these substances cleaved the ester groups and gave the corresponding steroidal glucosiduronic acids 12, 6 and 8. Upon treatment with diazomethane, these acids produced the equivalent methyl esters. The C-3, the C-21 and the C-3,21 glucosiduronates of 3 alpha,21-dihydroxy-5 beta-pregnan-11,20-dione were prepared by previously reported methods and converted into the corresponding C-20 semicarbazones (14, 20 and 26). With C-20 stabilized by the semicarbazone group against reduction, it was possible to reduce the 11-oxo function in these substances to an 11 beta-hydroxyl group; after removal of the semi-carbazone moiety from these products at pH 2.0, glucosiduronic acids 18, 22 and 28 were obtained. The mass spectra of a representative group of the mono- and diglucosiduronic acids and esters were determined by utilizing fast atom bombardment and monitoring ions in both positive and negative modes of operation.     

Total synthesis of glycononaosyl ceramide with a sialyl dimeric Lex sequence

The first total synthesis of glycononaosyl ceramide with a sialyl dimeric Le^x sequence 1 is described. Regio- and stereo-selective glycosylations of sialyl donors 6,7,8 with the suitably protected Le^x trisaccharide acceptors 9,10 were performed to give the expected tetrasaccharides 15 and 21, which were converted into the corresponding donors 20 and 22. Boron trifluoride etherate-promoted glycosylation of 20 with pentasaccharide acceptor 11 afforded regioselectively the expected nonasaccharide 23. After replacing benzyl groups of 23 by acetyl groups, the anomeric acetate was transformed into the -trichloroacetimidate 27. The crucial coupling between 27 and (2S, 3R, 4E-3-O-benzoyl-2-N-tetracosanoylsphingenine 3 was executed to afford completely protected -glycoside 28. Finally, selective cleavage of the methyl ester and N,O-deprotection of 28 gave the target ganglioside 1.Dedicated to Professor Sen-itiroh Hakomori on the occasion of his 65th birthday.     

Extraction of steroidal glucosiduronic acids from aqueous solutions by anionic liquid ion-exchangers

A pilot study on the extraction of three steroidal glucosiduronic acids from water into organic solutions of liquid ion-exchangers is reported. A single extraction of a 0.5mm aqueous solution of either 11-deoxycorticosterone 21-glucosiduronic acid or cortisone 21-glucosiduronic acid with 0.1m-tetraheptylammonium chloride in chloroform took more than 99% of the conjugate into the organic phase; under the same conditions, the very polar conjugate, beta-cortol 3-glucosiduronic acid, was extracted to the extent of 43%. The presence of a small amount of chloride, acetate, or sulphate ion in the aqueous phase inhibited extraction, but making the aqueous phase 4.0m with ammonium sulphate promoted extraction strongly. An increase in the concentration of ion-exchanger in the organic phase also promoted extraction. The amount of cortisone 21-glucosiduronic acid extracted by tetraheptylammonium chloride over the pH range of 3.9 to 10.7 was essentially constant. Chloroform solutions of a tertiary, a secondary, or a primary amine hydrochloride also will extract cortisone 21-glucosiduronic acid from water. The various liquid ion exchangers will extract steroidal glucosiduronic acid methyl esters from water into chloroform, although less completely than the corresponding free acids. The extraction of the glucosiduronic acids from water by tetraheptylammonium chloride occurs by an ion-exchange process; extraction of the esters does not involve ion exchange.     

Stereochemical course of the methylation of the polygalacturonic acid carboxyl groups of pectin

The steric course of the methyl group transfer to polygalacturonic acid to form the methyl ester group in pectin was studied using S-adenosylmethionine (AdoMet) carrying a methyl group made chiral by labeling with ¹H, ²H, ³H, in an asymmetric arrangement. The incubation of the two diastereomers of this substrate with a particulate enzyme preparation obtained from Phaseolus aureus (mung bean) shoots gave the corresponding pectins. These were degraded in a series of stereochemically unambiguous reactions that converted the methoxy group into the methyl group of acetate, which was then analyzed for its configuration. The results indicate that the transfer of the methyl group from the sulfur of AdoMet to the oxygen of the carboxyl group proceeds with inversion of configuration of the methyl group.     

Isolation, determination of structure and synthesis of the acid-labile conjugate of aldosterone.

1. After administration of 600mg of 3H-labelled aldosterone to human volunteers, 57 mg of homogeneous acid-labile conjugate was isolated from the urine and identified as aldosterone 18 beta-D-glucosiduronic acid. 2. Esterification and acetylation of the conjugate gave a tetra-acetate methyl ester, which, by measurement of the optical rotation and nuclear-magnetic-resonance spectrum, was shown to be a beta-glucosiduronate. This tetra-acetate methyl ester was synthesized in approx. 10% yield by the Koenigs-Knorr procedure. 3. Removal of the acetyl and methyl ester groups from the tetra-acetate methyl ester with alkali was accompanied by almost complete isomerization at C-17 to give 17-isoaldosterone 18 beta-D-glucosiduronic acid. 4. To prevent inversion at C-17 during removal of the acetate and ester groups of beta-glucosiduronate (a) the 3,20-disemicarbazone was prepared, (b) the acetate and ester groups were removed from the disemicarbazone by treatment with alkali, and (c) the semicarbazone groups were removed from the product at pH 2.0, and aldosterone 18 beta-D-glucosiduronic acid was obtained in 47% overall yield. 5. In the presence of components used to synthesize beta-glucosiduronate by the Koenigs-Knorr reaction this substance is converted slowly into the alpha-glucosiduronate; this conversion is responsible, in part, for the low yield of beta-glucosiduronate. 6. Two additional conjugates were obtained in the Koenigs-Knorr reaction; a provisional structure was assigned to one substrate. The other substance is a C-18 alpha-glucosiduronate. Removal of the acetyl and ester groups from C-18 alpha-glucosiduronate gave the alpha-glucosiduronic acid in 84% yield and the 17-isoaldosterone alpha-glucosiduronic acid in 12% yield. 7. The rate at which several types of beta-glucuronidase hydrolyse the foregoing steroidal alpha- and beta-glucosiduronic acids is given.     

Synthesis and stereochemistry of C-3- and C-7-linked (O-carboxymethyl)-oximino- and hemisuccinamido derivatives of 5 alpha-dihydrotestosterone.

The 3-(O-carboxymethyl)oximino derivative of 17β-hydroxy-5α-androstan-3-one (5α-dihydrotestosterone) was prepared. Thin-layer chromatography of the corresponding methyl ester showed the presence of two syn (60%) and anti (40%) geometrical isomers of the oxime chain to the C-4 position, which were characterized by ¹³C nmr. The 3β-hemisuccinami-do-5α-androstan-17β-ol was obtained after selective saponification with potassium carbonate of the 17β-hemisuccinate group of the 3,17-dihemi-succinoylated derivative of the previously described 3β-amino-5α-androstan-17β-ol. This 3β-hemisuccinamide was purified as the corresponding methyl ester-17β-acetate and was regenerated after saponification. The 3,3'-ethylenedioxy-7-oxo-5α-androstan-17β-yl acetate was obtained in quantitative yield by catalytic hydrogenation over 10% palladium-oncharcoal of the Δ⁵-7-oxo precursor in a dioxane-ethanol mixture containing traces of pyridine. The exclusive 5α-configuration of this hydrogenated product was established from nmr data and was confirmed by the synthesis of methyl 3,3'-ethylenedioxy-7-oxo-5β-cholan-24-oate as 5β-H-reference compound. The preceding 5α-H-7-ketone was converted into the 7-(O-carboxymethyl)oximino derivative (syn isomer to the C-6 position, exclusively) which was esterified into the corresponding methyl ester. The selective hydrolysis of the 3-ethyleneketal group was achieved by a short treatment with a formic acid-ether 1:1 (v/v) mixture at 20°C. Saponification of the latter reaction product with ethanolic potassium hydroxide gave the 7-(O-carboxymethyl)oximino-17β-hydroxy-5α-androstan-3-one derivative, which was characterized as the corresponding methyl ester. The reduction of the oxime of the 5α-H-7-ketone with sodium in ethanol or with lithium-aluminium hydride gave respectively the 7β-amine or the 7α-amine as the major product. The 7β- and 7α-configurations were established from nmr spectra of the corresponding 7-acetamido derivatives. The 7β- and 7α-hemisuccinamido derivatives were prepared from the mixture of 7β- and 7α-amines, as described above for 3-derivatives and were isolated after thin-layer chromatography of the methyl esters, followed by saponification of the corresponding 17β-acetates.     

The linkage of 4-O-methyl-L-galactose in the sulphated polysaccharide of Aeodes ulvoidea

Methyl 2-acetamido-5,6-di-O-benzyl-2-deoxy-β-d-glucofuranoside (11) was obtained in six steps from the known methyl 3-O-allyl-2-benzamido-2-deoxy-5,6-O-isopropylidene-β-d-glucofuranoside. Mild acid hydrolysis, followed by benzylation gave the 5,6-dibenzyl ether. The benzamido group was exchanged for an acetamido group by strong alkaline hydrolysis, followed by N-acetylation, and the allyl group was isomerized into a 1-propenyl group that was hydrolyzed with mercuric chloride. Treatment of 11 with l-α-chloropropionic acid and with diazomethabe gave methyl 2-acetamido-5,6-di-O-benzyl-2-deoxy-3-O-[d-1-(methoxycarbonyl)ethyl]-β-d-glucofuranoside which formed on mercaptolysis the internal ester 16, further converted into 2-acetamido-4-O-acetyl-5,6-di-O-benzyl-2-deoxy-3-O-[d-1-(methoxycarbonyl)ethyl]-d-glucose diethyl dithioacetal (18) by alkaline treatment followed by esterification with diazomethane and acetylation. Attempts to remove the O-acetyl group of the corresponding dimethyl acetal 20 with sodium methoxide in mild conditions were not successful.     

Structure of a Peptidal Antibiotic P168 Produced by Paecilomyces lilacinus (Thom) Samson

( + )-α-Kainic acid (1) was synthesized by starting from a building block, N-Boc-3-acetoxyallylglycine ethyl ester (2). The key intermediate, a methyl 4-[(tert-butoxycarbonyl)prenylamino]-5-hydroxy-2-pentenoate derivative (9), was prepared from 2 in eight synthetic steps. After converting 10 into a methyl ester (11), intramolecular ene-carbocyclization of 11 gave a pyrrolidine derivative (12), which was converted to 1 in a moderate yield.     

Novel semicarbazones based 2,5-disubstituted-1,3,4-oxadiazoles: One more step towards establishing four binding site pharmacophoric model hypothesis for anticonvulsant activity

A series of novel N¹-{5-[(naphthalene-2-yloxy)methyl]-1,3,4-oxadiazol-2-yl}-N⁴-(4-substitutedbenzaldehyde)-semicarbazone, N¹-{5-[(naphthalene-2-yloxy)methyl]-1,3,4-oxadiazol-2-yl}-N⁴-[1-(4-substitutedphenyl)ethanone]-semicarbazone and N¹-{5-[(naphthalene-2-yloxy)methyl]-1,3,4-oxadiazol-2-yl}-N⁴-[1-(4-substitutedphenyl) (phenyl) methanone]-semicarbazone were designed and synthesized on the basis of semicarbazone based pharmacophoric model to meet the structural requirements necessary for anticonvulsant activity. The anticonvulsant activities of the compounds were investigated using maximal electroshock seizure (MES), subcutaneous pentylenetrtrazole (scPTZ) and subcutaneous strychnine (scSTY) models. Some of the selected active compounds were subjected to GABA assay to confirm their mode of action. The efforts were also made to establish structure activity relationships among synthesized compounds. The results of the present studying validated that the pharmacophoric model with four binding sites is essential for anticonvulsant activity.     

Preparation, properties and metabolism of 5,6-monoepoxyretinoic acid

1. Methyl retinoate has been converted into methyl 5,6-monoepoxyretinoate by reaction with monoperphthalic acid. The epoxy acid ester on alkaline hydrolysis gave 5,6-monoepoxyretinoic acid. 2. Treatment of the 5,6-monoepoxy compounds with ethanolic hydrochloric acid gave the corresponding 5,8-epoxy (furanoid) compounds. 3. With lithium aluminium hydride, the acid and the ester groups were selectively reduced to primary alcohols. 4. Administration of methyl 5,6-monoepoxyretinoate intraperitoneally and subcutaneously had good growth response in vitamin A-deficient rats. 5. 5,6-Monoepoxyretinoic acid, when given intraperitoneally as the sodium salt, was 157% as active as all-trans-retinyl acetate. 6. Methyl 5,6-monoepoxyretinoate was hydrolysed to the epoxy acid by rat-liver homogenate. It had 35% of the biological activity of all-trans-retinyl acetate in the rat when given orally.     

Autotrophic synthesis of activated acetic acid from two CO2 in Methanobacterium thermoautotrophicum

In a previous study with Methanobacterium thermoautotrophicum evidence was presented that methanogenesis and autotrophic synthesis of activated acetic acid from CO₂ are linked processes. In this study one-carbon metabolism was investigated with growing cultures and in vitro.Serine was shown to be converted into glycine and activated formaldehyde, but only traces of label from [¹⁴C-3] of serine appeared in biosynthetic one-carbon positions. This seeming discrepancy could be explained if the same activated formaldehyde is an intermediate in biosynthesis and in methanogenesis from CO₂. This hypothesis was supported by demonstrating that [¹⁴C-3] of serine and [¹⁴C] formaldehyde were rapidly converted into methane, but a small portion of the label was also specifically incorporated into the methyl group of acetate. Methane and acetate synthesis in vitro were similarly stimulated by various compounds. These experiments indicate that the methyl of acetate and methane share common one-carbon precursor(s), i.e. methylene tetrahydromethanopterin, which can also be formed enzymatically from C-3 of serine or chemically from formaldehyde.Propyl iodide 20–40 M) and methyl iodide (1–3 M) completely inhibited growth in the dark. This effect was abolished by light. Methane formation was hardly affected. When ¹⁴CH₃I was applied at an only slightly inhibitory concentration, ¹⁴C was incorporated into the methyl of acetate. In vitro, similar effects on [¹⁴C] acetate formation from ¹⁴CO₂ or from [¹⁴C-3] of serine were observed, except that methyl iodide did not inhibit, but even stimulated acetate synthesis. These experiments indicate that a corrinoid is involved in acetate synthesis and probably not in methanogenesis from CO₂; the metal is light-reversibly alkylated and functions in methyl transfer to the acetate methyl.     

Nucleophilic Substitution on 4-Nitro- and 4-Methoxy-3-pyridinecarboxylic Acid-1-oxides

1-Oxides of 4-nitro-3-pyridinecarboxylic acid (3) and methyl 4-methoxy-3-pyridinecarboxylate (5) were converted to 4-(diphenylmethyl)amino (7), 4-phenylthio (8), 4-phenylamino (9) and 4-(2-methylpropyl)-amino (6) derivatives by reaction with the corresponding nucleophiles. The 4-phenylamino derivative 9 was alkylated with bromoethane to form the corresponding ethyl ester of the 1-ethoxypyridinium salt 10.     

Synthesis of homoursodeoxycholic acid and [11,12-3H]homoursodeoxycholic acid

Homoursodeoxycholic acid and [11,12-³H]homoursodeoxycholic acid were synthesized from ursodeoxycholic acid and homocholic acid, respectively. Ursodeoxycholic acid (Ia) was converted to 3α,7β-diformoxy-5β-cholan-24-oic acid (Ib) using formic acid. Reaction of the diformoxy derivative (Ib) with thionyl chloride yielded the acid chloride (II) which was treated with diazomethane to produce 3α,7β-diformoxy-25-diazo-25-homo-5β-cholan-24-one (III). Homoursodeoxycholic acid (IV) was formed from the diazoketone (III) by means of the Wolff rearrangement of the Arndt-Eistert synthesis.N-Bromosuccinimide oxidation of homocholic acid (V), which was prepared from cholic acid by the same procedure described above, afforded 3α,12α-dihydroxy-7-oxo-25-homo-5β-cholan-25-oic acid (VI). Reduction of the 7-ketohomodeoxycholic acid (VI) with sodium in 1-propanol gave 3α,7β,12α-trihydroxy-25-homo-5β-cholan-25-oic acid (VII). The methyl ester of 7-epihomocholic acid (VII) was partially acetylated to give methyl 3α,7β-diacetoxy-12α-hydroxy-25-homo-5β-cholan-25-oate (VIII) using a mixture of acetic anhydride, pyridine and benzene. Dehydration of the diacetoxy derivative (VIII) with phosphorus oxychloride yielded methyl 3α,7β-diacetoxy-25-homo-5β-chol-11-en-25-oate (IX). Reduction of the unsaturated ester (IX) with tritium gas in the presence of platinum oxide catalyst followed by alkaline hydrolysis gave [11,12-³H]homoursodeoxycholic acid.     

Ecdysone metabolism in Pieris brassicae during the feeding last larval instar

Ecdysone metabolism in Pieris brassicae during the feeding last larval stage was investigated by using ³H-labeled ecdysteroid injections followed by high-performance liquid chromatographic (HPLC

1 Abbreviations: 3DE = 3-dehydroecdysone; 3D20E = 3-dehydro-20-hydroxyecdysone; 2026E = 20,26-dihydroxyecdysone; E = ecdysone; Eoic = ecdysonoic acid; 2026E′ = 3-epi-20,26-dihydroxyecdysone; E′ = 3-epiecdysone; E′oic = 3-epiecdysonoic acid; E′8P = 3-epiecdysone 3-phosphate; 20E′ = 3-epi-20-hydroxyecdysone; 20E′3P = 3-epi-20-hydroxyecdysone 3-phosphate; FT = Fourier transform; HPLC = high-performance liquid chromatography; 20E = 20-hydroxyecdysone; 20Eoic = 20-hydroxyecdysonoic acid; NMR = nuclear magnetic resonance; NP-HPLC = normal phase HPLC; RP-HPLC = reverse phase HPLC; TFA = trifluoroacetic acid; Tris = tris(hydroxymethyl)-aminomethane.

) analysis of metabolites. Metabolites were generally identified by comigration with available references in different HPLC systems. Analysis of compounds for which no reference was available required a large-scale preparation and purification for their identification by ¹H nuclear magnetic resonance spectrometry. The metabolic reactions affect the ecdysone molecule at C-3, C-20, and C-26, leading to molecules which are modified at one, two, or three of these positions. At C-20, hydroxylation leads to 20-hydroxyecdysteroids. At C-26, hydroxylation leads to 26-hydroxyecdysteroids which can be further converted into 26-oic derivatives (ecdysonoic acids) by oxidation. At C-3, there are several possibilities: there may be oxidation into 3-dehydroecdysteroids, or epimerization possibly followed by phosphate conjugation. Thus, injected 20-hydroxyecdysone was converted principally into 20-hydroxyecdysonoic acid, 3-dehydro-20-hydroxyecdysone, and 3-epi-20-hydroxyecdysone 3-phosphate. Labelled ecdysone mainly gave the same metabolites doubled by a homologous series lacking the 20-hydroxyl group.     

Radioimmunoassay for pmol-quantities of indole-3-acetic acid for use with highly stable [125I]- and [3H]IAA derivatives as radiotracers

A radioimmunoassay for the detection of as little as 0.5–1 pmol indole-3-acetic acid (IAA) in unpurified or partially purified plant extracts is described. The assay makes use of either IAA[¹²⁵I]tyrosine methyl ester or [³H]IAA methyl ester as radioactive antigens and IAA methyl ester as the assay standard (measuring range: 1–200 pmol). Levels of extractable IAA in a number of biological samples have been estimated.Abbreviations BSA bovine serum albumin - 2,4-D 2,4-dichlorophenoxy acetic acid - DMF dimethyl formamide - GC-MS gas chromatography-mass spectroscopy - IAA indole-3-acetic acid - RIA radioimmunoassay - SICM selected ion current monitoring - TLC thin layer chromatography - TME tyrosine methyl ester Part 18 in the series: Use of immunoassay in plant science     

The synthesis of d-ribofuranosyl derivatives of methyl propiolate and a study of the activating influence of the ester group in cylcoaddition reactions

2,3,5-Tri-O-benzyl-D-ribofuranosyl bromide (17) has been converted into methyl 3-(2,3,5-tri-O-benzyl-β-d-ribofuranosyl)propiolate (8) and its α anomer 10 in 21 and 42% yields, respectively, by reaction with the silver salt of methyl propiolate. Attemps to prepare 8 from (β-d-ribofuranosyl)ethyne (1) by standard methods were unsuccesful. The reactions of the esters 8 and 10 and the ethyne 1 with several 1,3-dipoles have been examined. With diazomethene, 8 and 10 gave the pyrazole esters 20 and 28, respectively, whereas the ethyne 1 reacted more slowly to give a mixture of 23 (37%) and 26(31%). The ester 10 was converted into the triazoles 32 (51%) and 36 (34%) by reaction with benzyl azide. Treatment of the ester 10 with phenylhydrazine gave the pyrazolone 38 in 71% yield. A number of the products of dipolar addition have been converted into new d-ribofuranosyl-pyrazoles and -triazoles by hydrogenolysis.     

Biosynthetic relations between protoberberine-, benzo(C)phenanthridine- and B-secoprotoberberine type alkaloids in Corydalis incisa

The biosynthetic relations between protoberberine-, benzo[C]phenanthridine- and B-secoprotoberberine type alkaloids were demonstrated by use of (±)-tetrahydrocoptisine-[8,14-³H HCl, (±)-tetrahydrocorysamine-[8,14-³H]HCl and corynoline-[6-³H]HCl in Corydalis incisa, and the following results were presented. (±)-Tetrahydrocoptisine was converted to corynoline, corydalic acid methyl ester and corydamine hydrochloride. (±)-Tetrahydrocorysamine was converted to corynoline and corydalic acid methyl ester. Evidence that N-methyl-3-[6′-(3′,4′-methylenedioxyphenethylalcohol)]-4-methyl-7,8-methylenedioxy-1,2,3,4-tetrahydroisoquinoline-[α-³H] HCl was incorporated into corynoline-[11-³H] indicates the occurrence of the ring fission at C₆-N followed by linking ofthe C₆ and C₁₃ positions in (±)-tetrahydrocoptisine and (±)-tetrahydrocorysamine, and suggests the participation of one of two possible intermediates in the biosynthesis of these alkaloids.     

Synthesis of 2,5-anhydro-(beta-d-glucopyranosyluronate)- and (alpha-l-idopyranosyluronate)-d-mannitol hexa-O-sulfonate hepta sodium salt

Glycosidation of 2,5-anhydro-1,6-di-O-benzoyl-D-mannitol with methyl(2,3,4-tri-O-acetyl-alpha-d-glucopyranosyl-1-O-trichloroacetimidate)uronate in the presence of trimethylsilyl triflate afforded the corresponding 3-O-beta-glycoside, which after deprotection was converted into its hexa-O-sulfate with DMF x SO3 to give after treatment with sodium acetate and subsequent saponification of the methyl ester with sodium hydroxide the hepta sodium salt of 2,5-anhydro-3-O-(beta-d-glucopyranosyl uronate)-D-mannitol hexa-O-sulfate. Glycosidation of the same acceptor with the alpha-thiophenylglycoside of methyl 2,4-di-O-acetyl-3-O-benzyl-L-idopyranosyl uronate in the presence of NIS/TfOH afforded the corresponding 3-O-alpha-glycoside in very low yield, therefore the alpha-thiophenylglycoside of 2-O-acetyl-2,4-O-benzylidene-3-O-benzyl-L-idopyranose was used as donor. The terminal hydroxymethyl group of the obtained disaccharide was subsequently oxidised with NaOCl/TEMPO and the obtained iduronic acid derivative was converted into the hepta sodium salt of 2,5-anhydro-3-O-(-alpha-L-idopyranosyluronate)-D-mannitol hexa-O-sulfonate with DMF x SO3 and subsequent treatment with sodium acetate.     

The use of homologous and hetebologous 125 I-radioligands in the radioimmunoassay of progesterone

Eight homologous and heterologous¹²⁵ I-radioligand systems for the radioimmunoassay of progesterone were examined. Using an antiserum raised to 11α-hydroxyprogesterone 11-succinyl-bovine serum albumin, standard curves were set up with the homologous radioligands, 11α-hydroxyprogesterone 11-succinyl-[¹²⁵I]-iodotyramine, -[¹²⁵I]-iodohistamine and -[¹²⁵I]-iodotyrosine methyl ester. Heterologous bridge systems were represented by progesterone-11α-oxycarbonyl-[¹²⁵I]-iodotyrosine methyl ester and 11α-hydroxyprogesterone 11-phthalyl-[¹²⁵I]-iodotyrosine methyl ester, and heterologous site systems by progesterone-3-(O-carboxymethyl)oxime-[¹²⁵I]-iodotyramine, progesterone-12-(O-carboxymethyl) oxime-[¹²⁵ I]-iodotyramine, and progesterone-20-(O-carboxymethyl) oxime-[¹²⁵I]-iodohistamine. The preparation of the steroid derivatives and iodination by a two-phase method are described. The curves obtained from the homologous radioligands were relatively insensitive compared with a tritiated system, with the tyrosine methyl ester derivative providing a more sensitive assay than the corresponding tyramine or histamine analogues. The heterologous bridge systems gave more sensitive curves than the homologous tracers whilst the 3- and 12-(O-carboxymethyl) oxime derivatives of progesterone furnished curves as sensitive as the tritiated reference. Progesterone-20-(O-carboxymethyl)oxime-[¹²⁵I]-iodohistamine was not bound by the antibody.     

C-Glycosylation of Substituted Heterocycles Under Friedel-Crafts Conditions (II): Ribosylation of Multi-Functionalized Thiophenes and Furans for the Synthesis of Purine-Like C-Nucleosides

Abstract

In our continuing studies of the Friedel-Crafts glycosylation of preformed heterocycles, we have observed that while the SnCl₄ catalyzed glycosylation of methyl 4-(formylamino)thiophene-3-carboxylate (5) gives readily the C-nucleosides 7b and 7a, the corresponding Et₂AlCl catalyzed reaction gives exclusively the N-nucleoside 11. These nucleosides can be further elaborated into the bicyclic thieno[3,4-d]-pyrimidine system. Similarly, methyl 4-(formylamino)furan-3-carboxylate (19) gave the expected C-nucleosides 2Ob and 2Oa upon glycosylation in the presence of SnCl₄. However, these nucleosides could not be converted into the furo[3,4-d]pyrimidine system. Interestingly, several of the N-formamido compounds exhibit pronounced rotational isomerism, which was demonstrated by ¹H NMR spectroscopy