Chemoenzymatic syntheses of naturally occurring β-glucosides

Enzymatic glycosidation of the various kinds of primary alcohols 5, 7, 9, 11, 13 and 15 and 4-nitrophenyl-β-d-glucopyranoside 4 using β-glucosidase from almonds gave stereoselectively β-d-glucosides 6, 8, 10, 12, 14 and 16 including the naturally occurring β-glucosides in moderate yield. Among them, the β-glucosides 6, 8 and 10 were converted to the cyanoglycosides, rhodiocyanoside A 20a, osmaronin 24a and sutherlandin 29, respectively.     

Some electrophilic reactivity studies of di-(2-indolyl)dibenzofurans and di-(2-indolyl)carbazoles

3,6-Bis-(2-indolyl)dibenzofurans 1,2, and carbazoles 3–6 underwent a range of electrophilic substitution reactions to produce formyl indoles 7–12, biindolyls 24–28 and 33–34, glyoxylamides 40–42, and amides 48.     

Schwefelheterocyclen durch dithiocarboxylierung von Benzoylacetonitril

Disodium salt 2 reacts with hydrogen peroxide to give 1,2,4-trithiolane 3, whereas treatment with methyl chloroformate yields 1,3-dithietane 4. Adding diluted NaOH to 3 leads to a mixture of an isothiazole 7 and 4. By chlorination of 2 isothiazole 8 is available. S-amination of 2 or 9 and following cyclization gives the isothiazoles 10 and 12, respectively. 3-Mercapto-acrylonitrile 14 reacts with quinones to condensed oxathioles 16 or 17.     

The synthesis of annulated pyridazines by cycloaddition of azodicarboxylates to vinyl heterocycles

Reaction between 2-vinyl pyridine and azodicarboxylates 2 or 5 gives N,N'-disubstituted tetrahydropyrido[3,2-c]pyridazines 3 and 6, and dihydro-3H-pyrido[1,2-c]triazines 4 and 7; 2-(prop-1-en-1-yl)-pyridine 8 gives hydropyridopyridazines 10 and 11 but 2-(prop-1-en-2-yl)pyridine 9 gives mainly the ‘ene’ addition product 12. From 4-vinyl-pyridine and esters 2 or 5 diesters of tetrahydropyrido[3,4-c]pyridazine-1,2-dicarboxylic acid, 25 and 26 are obtained, and from 2-methyl-5-vinylpyridine both possible cyclisation products, the tetrahydro-pyrido[2,3-c]pyridazines 33 and 36, and -pyrido[4,3-c]pyridazines 34 and 37. The di-t-butyl esters 6, 11, 26, and 37 are quantitatively decarbalkoxylated in TFA, giving tetrahydropyridopyridazines 16, 18, 27, and 41; of these, the first three were oxidized to give pyrido[2,3-c]-pyridazine 15, its 3-methyl derivative 19, and pyrido[3,4-c]pyridazine 28 respectively. A dihydropyrido[4,3-c]-pyridazine 42 was obtained from compound 41. Thieno[2,3-c]-pyridazine 48 has been similarly prepared from 2-vinylthiophen, but 2-(prop-1-en-2-yl)thiophen gave an ene addition compound 51 and a dihydrothienopyridazine 50. Reactions with other vinylpyridines, and with vinylfurans, were unsuccessful.     

Search for a simpler synthetic model system for intramolecular 1,3-dipolar cycloaddition to the 5,6-double bond of a pyrimidine nucleoside

In search for a simpler model system for the study of intramolecular thermal reactions between the base and 5'-functionalized sugar moiety in nucleosides, 1-(3-azidopropyl)uracil (2), 1-(4-azidobutyl) pyrimidines (12 and 13) and 1-(5-azidopentyl)-uracil (14) was synthesized through the corresponding ω-benzoyloxy-(6,7 and 8) and ω-hydroxyalkyl-pyrimidines (9,10 and 11). Heating 2 gave 1,N⁶-trimethylene-6-aminouracil (4), while heating 12 and 13 gave N¹-C₆ cleaved addition products. 15 and 16, respectively. 15 was regiospecifically transformed to 1,2,3-triazole derivatives, 17,18 and 19. Heating 1-(4-azidobutyl)-5-bromouracil (20) yielded 3,9-tetramethylene-8-azaxanthine (22). 9 with NBA gave 1,0⁶-tetramethylene-5-bromo-6-hydroxy-5,6-dihydrouracil (24) and the 5-brominated analog of 9 (25). The 4-functionalized butyl side chain proved to serve as a substitute for the 5'-functionalized sugar moiety in pyrimidine ribonucleosides.     

The structures of macbecin I and II : New antitumor antibiotics

Macbecin I 1, C₃₀H₄₂N₂O₈, and macbecin II 2, C₃₀H₄₄N₂O₈, were shown to be 2,6-disubstituted benzoquinone and hydroquinone derivatives by an oxidation-reduction relationship, UV. ¹H and ¹³C NMR spectra. Alkaline methanolysis of 1 gave a 2-aminobenzoquinone derivative 5, suggesting an ansa-structure for 1, and acid hydrolysis of 1 gave decarbamoyl products 9,10 and 11, indicative of the location of carbamoyloxy group in allylic position. Spin decoupling studies on 1,3 and 5clarified the partial structures [A], [B], [C] and [D]. From their mutual disposition two structures 1a and 1b, were proposed out of which 1a has been selected for the structure of 1 on the basis of the structure of oxidative degradation product 12. X-Ray analysis of the bromoacetyl derivative of 1 confirmed the above proposed structure and determined the absolute stereochemistry of 1 and 2.     

Chemo-, stereo- and regioselective hydrogenolysis of carbohydrate benzylidene acetals. Synthesis of benzyl ethers of benzyl α-d-, methyl β-D-mannopyranosides and benzyl α-D-rhamnopyranoside by ring cleavage of benzylidene derivatives with the LiAlH4-AlCl3 reagent

Treatment of benzyl α-(1) and methyl β-d-mannopyranoside (2) with α,α-dimethoxytoluene gave the exo and endo isomers (3,5 and 4,6) of the dibenzylidene derivatives of 1 and 2. Hydrogenolysis of the exo isomers (3 and 5) with a molar equivalent of AlH₂Cl gave the 3-0-benzyl-4,6-0-benzylidene derivatives (7 and 21), whereas the endo isomers (4 and 6) gave the 2-0-benzyl-4,6-0-benzylidene compounds (8 and 22). The 2-0-allyl ether 9 of 7, the 3-0-allyl derivative (10) of 8 and compounds 21 and 22 were treated with an additional molar equivalent of AlH₂Cl at reflux and the products were the 4-0-benzyl-6-hydroxyl derivatives (11, 12, 23 and 24), whereas in the case of 22 the 6-0-benzyl-4-hydroxyl isomer (25) was also isolated. By deallylation of 11 and 12, 3,4-(13) and 2,4-di-0-benzyl (14) ethers of 1 were prepared. Tosylation of 11 and 12, and subsequent reduction of the products (15 and 16) made possible the preparation of the partially protected benzyl α-d-rhamnopyranoside derivatives (17–20). The structures of the compounds synthesized were characterized by ¹H and ¹³C NMR spectroscopic investigation and by chemical methods.     

9(11)-Secoestra-11,17-dioic acids and related compounds

While hydrogenations of 2b furnished a mixture in which the rac 14α isomer 8b predominated, the rac lactone 6 was hydrogenolyzed to give the rac 14β diacid 9a. Clemmensen reduction of 6 gave the rac 14α tetrahydro compound 7a. Another route to 8 involved conversion of the d-ketoacid 11b into 23b via the cyanolactone 20b or the amidolactone 21b. Base-catalyzed elimination at 206° yielded the Δ¹⁶ diester 27 which was hydrogenated to 8c. An analogous conversion was also carried out in the ring B reduced series 13 → 20a + 21a → 23a → 25a → 26. In the 14β series, using the same sequence of reactions, the rac ketoacid 10a was transformed into the rac lactone ester 29. In distinction from the 14α series, treatment with alkali at 206° gave only partial elimination, the double bond migrating to the 14,15 position to furnish 2. Evidence is presented that amides of the ketoacid 13a exist in the hydroxylactam form 30 and can be readily O-alkylated to furnish 22. Attempts to aromatize ring B of 13a with DDQ led to lactones 15 and 16, while reaction of the ester 13b with DDQ gave the pentaene 17 and the hexaene 18, establishing that dehydrogenation proceeded stepwise in the sequence Δ⁸, Δ¹⁴ and finally Δ⁶.     

Reaction of cholest-4-ene-3,6-dione with perbenzoic acid : Formation of novel oxetalactones

Oxidation of 1 with perbenzoic acid (p-toluene-sulphonic acid monohydrate as catalyst) provided novel oxetalactones 4 and 5 along with compounds 2 and 3. Treatment of 2 with perbenzoic acid yielded 4. A probable pathway for the formation of 4 from 1 involving the intermediacy of 2 has been suggested.     

Thio-acids—V : Some reactions of 3-oxo-1,2-dithioles

Diphenyldiazomethane with compound (1) gave dibenzoyl, while 2 and 3 gave the corresponding 3-oxo(2H)thiophenes 5. With copper-bronze 1 gave 2,2′-di-(thiobenzoate) (4), while 2 gave 2,7-diphenylthiepin (6a) and 2,5-diphenylthiophene (7a), but 3 gave only 2,5-di-(p-methoxyphenyl)thiophene (7b). With Grignard reagents 1 gave the corresponding methanol derivative 14, while 2 gave the thiobenzoylethylenes 13a and b, but 3 gave 2,7-di-(p - methoxyphenyl) - 4,4,5,5- tetraphenyl(4H)thiepin (15). The reaction mechanisms are discussed.     

Studies on organophosphorus compounds: Thiation of 3,1-benzoxathian-4-ones. New routes to 1,2-benzisothiazole-3(2H)-thiones and 3H-1,2-benzodithiol-3-imines

3,1-Benzoxathian-4-ones, 2, when heated with 2,4-bis(4-methoxyphenyl)-1,3,2,4-dithiadiphosphetane-2, 4-disulfide, 1, or with P₄S₁₀ give one or more of the following products 3,1-benzoxathian-4-thione, 3, 1,3-benzodithian-4-one, 4, 1,3-benzodithian-4-thione, 5, and 3H-1,2-benzodithiole-3-thione, 6. Compounds 2, when heated with primary and secondary amines and with hydrazines, give 2-mercaptobenzamides, 7, and 2-mercaptobenzohydrazides, 8, or their corresponding disulfides, 7' and 8'. 3H-1, 2-Benzodithiol-3-immes, which are in equilibrium with 1,2-benzisothiazole-3(2H)-thiones, (9A ? 9B), are prepared by two new routes (a) by allowing 3 or 5 to react with primary amines or hydrazines, (b) by allowing 7, 8, 7' or 8' to react with 1.     

Enantioselective hydrolyses with Yarrowia lipolytica: a versatile strain for esters,enol esters,epoxides, and lactones

Racemic secondary esters 1–3, γ-lactones 8–9, and styrene oxide 7 are kinetically resolved via hydrolysis with Yarrowia lipolytica YL2 strain. The enantioselective hydrolysis of prochiral enol esters 4–6 to the corresponding homochiral carbonyl compounds 13–15 is also described. Subsequent reduction of the ketone 13 and of the aldehyde 15 can be avoided using lyophilised cells.     

Selektive doppelbindungsisomerisierungen an a-nor-pregnadienen

The reaction sequence 9→11→ 20→23 was carried out as model investigation for the total synthesis of 20-methyl-pregn-4-en-3-on (23) via 9 obtainable by cyclization of tetraen-ol 1. A-nor-steroid-3(5),8(14) diene 9 together with isomers 10–12 was prepared by HBr induced rearrangement of the cyclosteroids 6/7, obtained from ergosterin. 10 and 12 were isomerized on palladium charcoal to 9 or 11 respectively; 9 could be isomerized by HBr to 11. Regioselective hydrogenation of 11 yielded the mono-en 20 which was converted to 23.     

A regioselective synthesis of daunomycinone and related anthracyclinones

The phthalic anhydrides 4a and 4b are attacked by the Grignard reagents 15 and 33 in tetrahydrofuran/tetramethylethylene diamine almost exclusively at the carbonyl group, which is situated in the meta position of the methoxy substituent(s). This highly regioselective reaction (minimum: 95:5) is used as the key step in a short synthesis of daunomycinone (2a), 2-methoxy-7-deoxycarminomycinone (22b),γ-rhodomycinone (8), and 10-dexoy-γ-rhodomycinone (9). The products of the addition of 15 to 4a and 4b, the pseudoacids 16 are converted via the olefins 17 and the epoxides 18 into the ketones 19, which lead by application of known reactions to the anthracyclinones 2a, 22a, and 9. The product, formed by addition of 33 to 4a, is converted to γ-rhodomycinone (8) via the quinone 27. The precursors of the Grignard reagents 15 and 33, the bromides 14 and 32, can be prepared easily and in large scale from the carboxylic acid 10, which is readily available from the cheap chemicals hydroquinone and succinic anhydride.     

Remote halogenation: Some model studies and specific degradation of the cholesterol,sitosterol, and campesterol side chain

1) Two high-yield procedures for the conversion of 1 to 4 are reported. 2) 11 was degraded to 34 in good overall yield via 17, 20, 26, 31, 29, and 30. Similarly, 34 was obtained from 12 and 13.     

Synthesis of 2,4-dimethyl-cyclohex-3-ene carboxaldehyde derivatives with olfactory properties

Oxidation of the starting aldehyde 1 led to the acid 6 which was esterified in neutral conditions to give the esters 7–11. A Wittig reaction with 1 and various phosphoranes led to compounds 12–15 bearing a functionalized unsaturated side chain. Acidic hydrolysis of 15 gave the aldehyde 16 homologue of 1. Ketone 19 was obtained by Grignard reaction between 1 and the bromoacetal 17 followed by oxidation of the alcohol 18. Intramolecular cyclization of 18 and 19 gave the lactone 22 and the pentenone 20, respectively. Analysis of the olfactory properties of all these compounds revealed that esters 7, 9, ether 15 and aldehyde 16 could be used in the formulation of flowery or fruity compositions.     

Simple and condensed β-lactams-I : The application of diketene in β-lactam synthesis. The synthesis and functional group manipulations of diethyl 3-acetyl-4-oxoazetidine-2,2-dicarboxylates

Acylation of the N-substituted diethyl aminomalonates 3a–3d with diketene furnished the ring tautomers 6a–6d of the expected acetoacetyl derivatives 5. By treatment with iodine and sodium ethoxide compounds 6a–6d are smoothly converted into the β-lactam derivatives 2a–2d. Deethoxycarbonylation of the ethylene ketals 7a–7d of the latter furnishes mixtures of the corresponding diastereomeric monoesters 8 and10. The ethoxycarbonyl groups of the trans esters 8 are more reactive than those of the cis isomers 10. This permits, under appropriate conditions, selective alkaline hydrolysis and NaBH₄ reduction of the trans esters 8 in the presence of the cis esters 10. Reduction of the cis ester 10c under more forceful conditions furnishes the trans hydroxymethyl derivative 11c.     

Sesterterpenes and phenolic alkenes from the Thai sponge Hyrtios erectus

Sesterterpene, erectusolide A (1), six phenolic alkenes, erectuseneols A?F (2–7) and nine known compounds, luffalactone (8), luffariolide E (9), (6E)- and (6Z)-neomanoalide 24,25-diacetates (10 and 11), 6,6-dimethylundecane-2,5,10-trione (12), threo- and erythro-cavernosines (13 and 14), (4E,6E)-dehydromanoalide (15), echinoclerodane A (16), were isolated from the marine sponge Hyrtios erectus. Compound 13 was isolated for the first time from a natural source. The structures of these compounds were elucidated on the basis of spectroscopic analysis. The phenolic alkenes 3 and 7, the sesterterpenes 8–11 and 15, and compounds 12–14 were evaluated for cytotoxic activities against six cancer cell lines, MOLT-3, HepG2, HeLa, HuCCA-1, A549, and MDA-MB-231.     

A highly efficient and straightforward stereoselective synthesis of novel chiral α-acetylenic ketones

A very efficient and straightforward synthesis of novel chiral α-acetylenic ketones of type 3 has been developed. Starting from commercially available l-(−)-serine 4, and through the Garner's aldehyde 5, ethynyloxazolidine 2 was formed in good overall yield. Condensation of the corresponding lithium acetylide 7 with different aliphatic and aromatic aldehydes 5 and 8a–h at low temperatures yielded the respective propargylic alcohols 9a–i. Subsequent mild oxidation of 9a–i with 10-I-4-iodinane oxide (IBX) 12 afforded chiral α-acetylenic ketones 3a–i almost quantitatively.     

Synthesis, photophysical properties and sugar-dependent in vitro photocytotoxicity of pyrrolidine-fused chlorins bearing S-glycosides

Eight S-glycosylated 5,10,15,20-tetrakis(tetrafluorophenyl)porphyrins (1a′, 1b′, 1a and 1b (a: S-glucosylated, b: S-galactosylated)) and their 1,3-dipolar cycloadducts, i.e. chlorins 2a′, 2b′, 2a and 2b were prepared by nucleophilic substitution of the pentafluorophenyl groups with S-glycoside. These photosensitizers were characterized by ¹H, ¹³C and ¹⁹F NMR spectroscopies and elemental analysis. The photocytotoxicity of the S-glycosylated photosensitizers and the parent porphyrin (1) and chlorin (2) was examined in HeLa cells. Photosensitizers 1, 2, 1a′, 1b′, 2a′ and 2b′ showed no significant photocytotoxicity at the concentration of 0.5 μM, while the deprotected photosensitizers 1a, 1b, 2a and 2b were photocytotoxic. The strong inhibition by sodium azide of the photocytotoxicity of these photosensitizers suggested that ¹O₂ is the main mediator. The S-glucosylated photosensitizers 1a and 2a showed higher photocytotoxicity than S-galactosylated 1b and 2b, respectively. The cellular uptake of 1a and 2a increased up to 24 h, while that of 1b and 2b was saturated by 12 h.