Bone collagen cross-links: an efficient one-pot synthesis of (+)-pyridinoline and (+)-dexoypyridinoline

A one-pot reaction of (2S,5R)-(−)-tert-butyl-[(2-tert-butoxycarbonyl)amino]-5-hydroxy-6-aminohexanoate 2b or (S)-(−)-tert-butyl-[(2-tert-butoxycarbonyl)amino]-6-aminohexanoate 2c with (S)-(−)-tert-butyl-6-bromo-[bis-(2-tert-butoxycarbonyl)amino]-5-oxohexanoate 5 in the presence of K₂CO₃ in MeCN–MeOH followed by hydrolysis gave bone collagen cross-links, (+)-Pyd 1b or (+)-Dpd 1c, in 42–48% yield, respectively.     

Total,asymmetric synthesis of ethyl d-ido-4-heptulosuronate derivatives starting from diethyl 4-oxopimelate

Bromination of diethyl 4-oxopimelate, followed by double elimination of HBr and ketalization provided diethyl (E,E)-4,4-(ethylidenedioxy)hepta-2,5-dienedioate 4. Sharpless asymmetric dihydroxylation of 4 produced diethyl (2S,3S)-4,4-(ethylidenedioxy)-2,3-dihydroxyhept-5-enedioate (+)-5, with 78% e.e. The corresponding tetrol could not be obtained in one step. Silylation of (+)-5 and a second asymmetric dihydroxylation, followed by silylation led to 20% of meso-diester 9 and 60% of diethyl (2S,3S,5S,6S)-2,3,5,6-tetrakis[(t-butyl)dimethylsilyloxy]-4,4-(ethylidenedioxy)heptanedioate (−)-10. Reductive desymmetrization of (−)-10 with DIBAL-H furnished, after selective oxidation, ethyl (2S,3S,5S,6S)-2,3,5,6-tetrakis-[(t-butyl)dimethylsilyloxy]-4,4-(ethylidenedioxy)-7-oxoheptanoate (+)-13 which was then converted into ethyl 1,2,3,6-O-tetraacetyl-4,4-ethylidenedioxy-α- and β-d-ido-heptapyranuronate (−)-15α,β and into the corresponding 3-(α-d-pyranosyl)propene (−)-16.     

Synthesis of versatile chiral intermediates by enantioselective conjugate addition of alkenyl Grignard reagents to enamides deriving from (R)-(−)- or (S)-(+)-2-aminobutan-1-ol

Conjugate addition of but-3-enylmagnesium bromide to the chiral crotonamide (R)-(+)- and (S)-(−)-3, followed by hydrolysis and oxidation, afforded enantiopure (R)-(+)- and (S)-(−)-3-methyladipic acids 8, respectively. Conjugate addition of vinylmagnesium chloride to the chiral crotonamide and cinnamamides (R)-(+)-3–5, followed by hydrolysis, gave the alkenoic acids (S)-12–14, respectively. Iodolactonization of the latter led to the 5-iodomethyllactones (+)-15–17, which were reduced by means of n-Bu₃SnH into the trans-disubstituted 5-methyllactones (+)-19–21, respectively. Treatment of the iodomethyllactone (+)-16 with LiMe₂Cu or n-Bu₂CuLi furnished the trans-5-alkyl-4-phenyllactones (−)-22 or (+)-23.     

Asymmetric synthesis of (S)-(−)-acromelobinic acid

A total synthesis of (S)-(−)-acromelobinic acid 2, which was isolated from clitocybe acromelalga, was achieved via an asymmetric hydrogenation protocol. Dehydroamino acid derivative 12 was prepared from 2,5-lutidine 5 and subjected to asymmetric hydrogenation using (S,S)-[Rh(Et-DuPHOS)(COD)]BF₄ to give the (S)-(+)-pyridylalanine derivative 13 in 93% yield and >96% e.e. Removal of the protecting groups in (S)-(+)-13 afforded (S)-(−)-acromelobinic acid 2.     

Enantiodivergent syntheses of cycloheptenone intermediates for guaiane sesquiterpenes

The syntheses of enantiomeric 6-isopropenyl-3-methyl-2-cycloheptenones 16 and 22 have been effected starting from (R)-(−)-carvone. In the synthesis of 16, (R)-(−)-carvone was reduced and the resulting dihydrocarvone transformed regioselectively into silyl enol ethers. Cyclopropanation with dibromocarbene and in situ rearrangement gave an α-bromo-cycloheptenone which was reduced to the (R)-(+)-cycloheptenone 16. In the synthesis of 22, (R)-(−)-carvone was cyclopropanated with a sulfur ylide, followed by reduction with LiAlH₄ and acid-catalyzed cyclopropylcarbinyl rearrangement to afford a cycloheptenol. Oxidation and double bond conjugation led to the (S)-(−)-cycloheptenone 22 in a partially racemized form. Four cycloheptenones have been obtained and are suitable intermediates for the enantiodivergent syntheses of guaiane sesquiterpenes.     

Microbial reduction of 2-(6-m-methoxyphenyl-3-oxohexyl)-2,4-dimethylcyclopenta-1,3-dione with Schizosaccharomyces pombe (NRRL Y-164)

A mixture of cis- and trans-2-(6-m-methoxyphenyl-3-oxohexyl)-2,4-dimethylcyclopenta-1,3-dione (±)-10 was synthesized and incubated with Schizosaccharomyces pombe (NRRL Y-164) to give (+)-11, (+)-12, (−)-13, and (−)-14 in 19, 13, 22, and 16% yields, respectively. Chromic acid oxidation of these microbiologically reduced products gave (−)-10a, (+)-10b, (+)-10a, and (−)-10b, respectively.     

Total synthesis of optically active liverwort sesquiterpenes,trifarienols A and B,using phenylethylamine as a chiral auxiliary

The imine of (rac)-2,3-dimethylcyclohexanone 10a with (S)-(−)-phenylethylamine was reacted with methyl acrylate to yield methyl (1′S,6′R)-3-(1′,6′-dimethyl-2′-oxocyclohexyl)propanoate 4a in 26% (97% ee) after hydrolysis. When (2RS,3R)-2,3-dimethylcyclohexanone 10b was used, the same product 4b was obtained in 59% yield (>99.5% ee) after hydrolysis. When (2RS,3R)-2,3-dimethylcyclohexanone 10b and (R)-(+)-phenylethylamine were used, the reaction underwent in only 5% yield, the products being 4c, 12, 13, 14, and 15. Thus, the reaction of 3b with methyl acrylate is a matched case, while that of 3c is a mismatched case. These phenomena are explained by the nonbonded interaction of methyl acrylate with chiral phenylethylamine and the methyl group at the 6′-position of the cyclohexanone ring in the transition state. The propanoate product 4b was successfully transformed into liverwort sesquiterpene (+)-trifarienol A 1 and (−)-trifarienol B 2 in 10 steps. We have developed an HPLC method to determine the ees of 2,2-disubstituted and 2,2,3-trisubstituted cyclohexanones using the corresponding pentafluorophenyl esters.     

First stereoselective synthesis of (4aS,5R)-4,4a,5,6,7,8-hexahydro-4a,5-dimethyl-2(3H)-naphthalenone

The synthesis of enantiomerically pure (4aS,5R)-hexahydro-4a,5-dimethyl-2(3H)-naphthalenone (−)-1 is described for the first time. The synthesis starts from (R)-3-methylcyclohexanone and involves the preparation of Piers enol lactone 6 in its enantiopure form as the key intermediate. Treatment of (+)-6 with methyl lithium followed by an intramolecular aldol reaction gives the bicyclic enone (−)-1.     

Chemoenzymatic synthesis of (S)-2-cyanopiperidine,a key intermediate in the route to (S)-pipecolic acid and 2-substituted piperidine alkaloids

The preparation of (S)-2-cyanopiperidine 4 provides a new access to 2-substituted piperidines. This synthesis is based on an enantioselective (R)-oxynitrilase-catalyzed reaction for the preparation of (R)-(+)-6-bromo-2-hydroxyhexanenitrile 1 and the subsequent cyclization of this compound to yield the piperidine ring. The utilization of 4 as the starting material for the synthesis of (S)-2-aminomethylpiperidine 6, (R)-(−)-coniine 10 and (S)-(−)-pipecolic acid 13 is also described.     

Convenient access to both enantiomers of new azido- and aminoinositols via a chemoenzymatic route

1,2-diacetylconduritol E, (±)-1, through complementary use of Mucor miehei (Lipozyme^® IM) and Candida cylindracea lipases, affords (1S)-1,2-diacetylconduritol E, (+)-1, (1R)-1,2-diacetylconduritol E, (−)-1, (1S)-1,2,4-triacetylconduritol E, (+)-2, (1R)-1,2,4-triacetylconduritol E, (−)-2, with high enantiomeric excesses and chemical yields. Following two different methods, diester (+)-1 has been transformed into azidoinositol (−)-4 to give 1L-4-amino-4-deoxy-chiro-inositol, whereas triester (−)-2 furnished the azidoinositol (+)-13, easily converted into 1L-4-amino-4-deoxy-myo-inositol.     

Chemoenzymatic synthesis of enantiopure geminally dimethylated cyclopropane-based C2- and pseudo-C2-symmetric diamines

Enantiopure (−)-(1S,3S)-2,2-dimethyl-3-(2-methylprop-1-enyl)cyclopropanecarboxamide 2 and (+)-(1R,3R)-2,2-dimethyl-3-(2-methylprop-1-enyl)cyclopropanecarboxylic acid 3 were easily obtained from a multigram scale biotransformation of racemic amide or nitrile in the presence of Rhodococcus erythropolis AJ270 whole cell catalyst under very mild conditions. Coupled with efficient and convenient chemical manipulations, comprising mainly of the Curtius rearrangement, oxidation, and reduction reactions, chiral C₂-symmetric (1S,2S)-3,3-dimethylcyclopropane-1,2-diamine 6 and ((1R,3R)-3-(aminomethyl)-2,2-dimethylcyclopropyl)methanamine 8 and pseudo-C₂-symmetric (1S,3S)-3-(aminomethyl)-2,2-dimethylcyclopropanamine 11 were prepared. These were also transformed into the corresponding chiral salen derivatives 12, 13, and 14, respectively, in almost quantitative yields.     

Lipase mediated resolution of 1,3-butanediol derivatives: chiral building blocks for pheromone enantiosynthesis. Part 3

(R,S)-1,3-Butanediol 5 was kinetically resolved by enzymatic acetylation with vinyl acetate under the presence of Chirazyme™ L-2, c–f, yielding (S)-1-O-acetyl-1,3-hydroxybutane 6 and (R)-1,3-di-O-acetyl-1,3-butanediol 7 with enantiomeric excesses of 91% (E=67.3). Compounds 6 and 7 were easily transformed into the corresponding (S)-3-O-(2-methoxyethoxymethyl)-3-hydroxybutanal 10 and (R)-3-benzyloxybutanal 19, through a protection–deprotection and functional group interchange methodology. Subsequent reaction of 10 and 19 with 3-(methoxycarbonylpropionylmethylene)triphenylphosphorane afforded methyl (E,S)-8-O-(2-methoxyethoxymethyl)-4-oxo-5-nonenoate 12 and (E,R)-8-benzyloxy-4-oxo-5-nonenoate 20. The alkenes 19 and 20 were then catalytically hydrogenated to the corresponding saturated esters 13 and 21. Treatment of 13 and 21 with 1,2-ethanedithiol/F₃B·OEt₂ afforded dithioketals 14 and 22, which were respectively reduced to (S)-1,8-dihydroxy-4-nonanone ethylidenedithioketal 15 and (R)-8-O-benzyl-1,8-dihydroxy-4-nonanone ethylidenedithioketal 23. Finally, deprotection of 15 by catalytic hydrogenation under acidic conditions gave the expected (5S,7S)-(−)-7-methyl-1,6-dioxaspiro[4.5]decane 1. The (5R,7R)-(+)-1 enantiomer was analogously prepared from 23. Both compounds were formed by this procedure with an e.e. of 91%.     

Resolution of 3-methyl-3-phospholene 1-oxides by molecular complex formation with TADDOL derivatives

The antipodes of 1-phenyl-3-methyl-3-phospholene 1-oxide 1a were separated in good yield and in high enantiomeric excess (∼99% ee) by resolution via formation of diastereomeric complexes with (4R,5R)-(−)- and (4S,5S)-(+)-4,5-bis(diphenylhydroxymethyl)-2,2-dimethyldioxolane 2 (TADDOL) or (−)-(2R,3R)-α,α,α′,α′-tetraphenyl-1,4-dioxaspiro[4.5]decan-2,3-dimethanol 3. The method was also suitable for the resolution of the 1-ethoxy-3-phospholene derivative 1b, suggesting that our novel procedure may be of general value, both for the resolution of chiral phosphine oxides and phosphinates.     

Enzymatic resolution of (±)-conduritol-B,a key intermediate for the synthesis of glycosidase inhibitors

Lipases from porcine pancreas, Candida cylindracea and Mucor miehei (adsorbed on support, Lipozyme^® IM) catalysed in t-butylmethylether the alcoholysis of rac-conduritol-B peracetate, (±)-1, by n-butanol to give enantiopure (2S,3S)-diacetoxy-(1R,4R)-dihydroxycyclohex-5-ene, (−)-3, and (1S,2R,3R,4S)-tetraacetoxy-cyclohex-5-ene, (+)-1. The enantioforms (+)- and (−)-conduritol-B, obtained after chemical hydrolysis of (−)-3 and (+)-1, respectively, may be employed to prepare both the enantiomers of conduritol-B epoxide and cyclophellitol, powerful inhibitors of glycosidases.     

Synthesis of (−)-(1′S,4aS,8aR)- and (+)-(1′S,4aR,8aS)-4a-ethyl-1-(1′-phenylethyl)-octahydroquinolin-7-ones

A synthesis of the enamine (−)-(1′S)-5-ethyl-1-(1′-phenylethyl)-1,2,3,4-tetrahydropyridine 4 and its application in a synthesis of (−)-(1′S,4aS,8aR)- and (+)-(1′S,4aR,8aS)-4a-ethyl-1-(1′-phenylethyl)-octahydroquinolin-7-ones 5 and 6 is described. In addition, an X-ray study of 6 is reported. Finally, the preparation of (+)-(4aS,8aR)-4a-ethyl-octahydroquinolin-7-one 7 is described.     

Synthesis of enantiopure C1 symmetric diphosphines and phosphino-phosphonites with ortho-phenylene backbones

Reaction of 2-(diphenylphosphino)phenylphosphonous acid tetramethyldiamide 1 with (+)-menthol, (1S,2S,3S,5R)-isopinocampheol and (1R,2R)-trans-cyclohexanediol affords enantiopure phosphino-phosphonite ligands 3–5. The X-ray structures of 1 (space group P2₁/n) and 3 (space group P2₁) have been determined. The reaction of 1 with (1R,2R,3S,5R)-(−)-pinanediol proceeds diastereoselectively to afford a novel type of enantiopure phosphino-phosphonite ligand 6 with an asymmetric substituted P atom. On reaction of (+)-cedryl alcohol with 1 the adduct 7 of the phosphonous acid 2-Ph₂PC₆H₄P(O)(H)OH 9 and its dimethylammonium salt is formed through elimination of water and subsequent hydrolysis. The structure of 7 (space group P1̄) was elucidated by X-ray structural analysis. Reduction of the chlorophosphine 8 with LiAlH₄ yields the novel primary–tertiary phosphine 10, which is a valuable starting material for the synthesis of the enantiopure C₁ symmetric bidentate phospholane ligands 11 and 12.     

A general strategy for the formal synthesis of (−)-trans-kumausyne and total synthesis of (5R)-Hagen’s gland lactones from diacetone-d-glucose

A general strategy for the formal synthesis of (−)-trans-kumausyne 1 via the bicyclic lactone (3aR,5R,6aR)-4 and total synthesis of (5R)-Hagen’s gland lactones 2 and 3 via bicyclic lactone (3aR,5S,6aR)-5 starting from diacetone-d-glucose 6 is described. Syntheses of 4 and 5 were achieved by Wittig olefination–lactonization–Michael addition of the corresponding lactols 16 and 17, respectively.     

New methodology for the synthesis of enantiopure (3R,2aR)-(−)-3-phenyl-hexahydro-oxazolo[3,2-a]-pyridin-5-one: a synthesis of (S)-(+)-coniine

A new and efficient methodology for the enantiopure synthesis of (3R,2aR)-(−)-3-phenyl-hexahydro-oxazolo[3,2-a]pyridin-5-one 3 starting from (1′R)-(−)-1-(2′-hydroxy-1′-phenyl-ethyl)-(1H)-pyridin-2-one 1 is described. In addition, the enantiospecific synthesis of (S)-(+)-coniine hydrochloride 6 in good yield from 3 is reported.     

Hydroboration of (1R)-(+)-α-pinene and (1S)-(−)-β-pinene with B10H12(SMe2)2: a straightforward approach to the preparation of optically active 6-(alkyl)-nido-B10H13 derivatives

In separate three-step, one-pot procedures, the known polyhedral boron hydride arachno-6,9-(Me₂S)₂B₁₀H₁₂ is combined with α- or β-pinene to produce the optically active boranes (−)-6-(α-pinanyl)–B₁₀H₁₃ (1) and (−)-6-(β-pinanyl)–B₁₀H₁₃ (2), respectively, as crystalline solids in good yields.     

Further enantioselective syntheses of α-arylalkanamines via intermediate addition of Grignard reagents to a chiral hydrazone derived from (R)-(−)-2-aminobutan-1-ol

Reaction of various aromatic aldehydes with the chiral hydrazine (R)-(−)-2, derived from 2-aminobutan-1-ol (R)-(−)-1, gave the corresponding hydrazones 5–12. Enantioselective addition of EtMgBr or n-BuMgBr to 5–8 gave the trisubstituted hydrazines 13a–f (d.e.s=100%). Catalytic hydrogenolysis (6 bar/Pd–C/110°C/5 h) of the N–N bond of the latter afforded the enantiomerically enriched α-arylalkanamines (R)-(+)-14a–f (e.e.s=90–93%).