Approaches to (R)- and (S)-1′-(1-aminoethyl)ferrocene-1-carboxylic acid derivatives

Lipase-catalyzed esterification of (±)-methyl 1′-(1-hydroxyethyl)ferrocene-1-carboxylate 4 afforded its (R)-acetate (−)-5 (ee = 99%) and (S)-(+)-4 (ee = 90%). Stereoretentive azidation/amination/acetylation of (R)-(−)-5 gave (R)-(+)-methyl 1′-(1-acetamidoethyl)ferrocene-1-carboxylate (R)-3 (ee = 98%). In a similar manner (S)-(+)-4 was converted into (S)-(−)-3 (ee = 84%). Both enantiomers of 3 were obtained in high chemical yields without a loss of enantiomeric purity. The title compounds can be coupled with natural amino acids and peptides on both C- and N-termini.     

Stereoselective synthesis of α-substituted serines from protected erythrulose oximes

The additions of organolithium reagents to the CN bond of several chiral oxime ethers derived from erythrulose afforded protected amino polyols with high diastereoselectivity. Four of the latter compounds have been converted into the α,α-disubstituted α-amino acids (R)-2-(−)-methylserine, (S)-2-(+)-methylserine, (R)-(+)-2-phenylserine and (R)-(−)-2-n-butylserine.     

New chiral 1,4-aminoalcohols derived from (+)-camphor and (−)-fenchone for the enantioselective addition of diethylzinc to aldehyde

Various optically active 1,4-aminoalcohols were synthesized from (+)-camphor and (−)-fenchone. The aminoalcohols 5 or 6-mediated enantioselective addition reactions of diethylzinc to benzaldehyde resulted in the formation of the optically active secondary alcohol in good yield. When the catalyst derived from (+)-camphor was used, the (S)-alcohol was obtained in high ee, while the (R)-alcohol was obtained in the reaction with the catalyst derived from (−)-fenchone.     

Synthesis of (S)-(−)- and (R)-(+)-O-methylbharatamine using a diastereoselective Pomeranz–Fritsch–Bobbitt methodology

Laterally lithiated (S)-(−)- and (R)-(+)-o-toluamides 6 with a chiral auxiliary derived from (S)- and (R)-phenylalaninol, respectively, were used as the building blocks and chirality inductors in the asymmetric modification of the Pomeranz–Fritsch–Bobbitt synthesis of isoquinoline alkaloids. Their addition to imine 2 proceeded with partial cyclization, giving isoquinolones (+)-7 and (−)-7 along with acyclic products, (−)-8 and (+)-8, respectively. LAH-reduction of (+)-7 and (−)-7, followed by cyclization, afforded both enantiomers of the alkaloid, (S)-(−)- and (R)-(+)-O-methylbharatamine 5, in 32% and 40% overall yield and with 88% and 73% ees, respectively.     

Stereoselective synthesis of 1-methoxyspiroindoline phytoalexins and their amino analogues

The stereoselective synthesis of the spiroindoline phytoalexin (R)-(+)-1-methoxyspirobrassinin and its unnatural (S)-(−)-enantiomer were achieved by the bromine-induced spirocyclization of 1-methoxybrassinin using chiral auxiliaries (+)- and (−)-menthol, followed by oxidation of the obtained menthyl ethers. The TFA-catalyzed methanolysis of chiral 1-methoxyspirobrassinol menthyl ethers provided (2R,3R)-(−)-1-methoxyspirobrassinol methyl ether and its other three unnatural stereoisomers. The enantiomers of the 2-amino analogues of the indole phytoalexin (2R,3R)-(−)-1-methoxyspirobrassinol methyl ether were prepared by the TFA-catalyzed replacement of the chiral alkoxy group with an amine. The synthesized compounds were tested in vitro on cancer cell lines and examined with enantiopure 2-amino analogues of the indole phytoalexin (2R,3R)-(−)-1-methoxyspirobrassinol methyl ether, which showed in most cases, lower activity than the corresponding racemates.     

Crystal and molecular structure of the levorotatory (1R,2S)-ephedrinium (S)-t-butylsulfinylacetate: a definitive proof of the absolute configuration of enantiomeric t-butyl methyl sulfoxides

The levorotatory enantiomer of t-butylsulfinylacetic acid 3 was obtained in the reaction of the α-carbanion of (+)-t-butyl methyl sulfoxide 1 with carbon dioxide. The same enantiopure form of the acid 3 was isolated from its diastereomerically pure levorotatory salt 5 with (−)-(1R,2S)-ephedrine. The structure of this salt was determined by X-ray analysis and the absolute configuration (S) at sulfur was ascribed to the t-butylsulfinylacetate anion. Consequently, the absolute configuration (S) was assigned to the acid (−)-3 and its precursor (+)-t-butyl methyl sulfoxide 1.     

Stereoselective synthesis of (R)-(+)-1-methoxyspirobrassinin, (2R,3R)-(−)-1-methoxyspirobrassinol methyl ether and their enantiomers or diastereoisomers

Stereoselective synthesis of cruciferous indole phytoalexin (R)-(+)-1-methoxyspirobrassinin and its unnatural (S)-(−)-enantiomer was achieved by spirocyclization of 1-methoxybrassinin in the presence of (+)- and (−)-menthol and subsequent oxidation of the obtained menthyl ethers. Methanolysis of menthyl ethers in the presence of TFA afforded (2R,3R)-(−)-1-methoxyspirobrassinol methyl ether as well its unnatural (2S,3S)-, (2R,3S)-, and (2S,3R)-isomers.     

Palladium-catalyzed asymmetric Diels–Alder reactions with novel chiral imino-phosphine ligands

Palladium-catalyzed asymmetric Diels–Alder reactions have been achieved with considerably high enantioselectivity by using chiral imino-phosphine ligands derived from (1S,4R)-(+)-fenchone, (1R,2R,5R)-(+)-2-hydroxy-3-pinanone derivatives, (1S,5R)-(−)-menthone, (1R,4R)-(+)-camphor, and (1S)-(+)-ketopinic acid. A mechanism for the asymmetric induction is proposed on the basis of the stereochemical outcome of the reactions.     

Synthesis of (+)-(S)-Streptenol A and Biomimetic Synthesis of (2R,4S)- and (2S,4S)-2-(Pent-3-enyl)piperidin-4-ol

(+)-(S)-Streptenol A is synthesized by coupling a 1,3-dithiane with an optically pure epoxide. The absolute configuration of (+)-(S)-streptenol A is thereby correlated with that of (S)-malic acid. Stereoselective reduction of an oxime that could easily be prepared from streptenol A gave the (3S,5R)- and (3S,5S)-aminostreptenols, and after cyclization, configurationally pure 2,4-functionalized piperidine alkaloids.     

A new asymmetric synthesis of (2S,3R,4R,5S)-trihydroxypipecolic acid

A novel four step synthesis of enantiomerically pure (2S,3R,4R,5S)-trihydroxypipecolic acid, starting from readily available materials, that is, condensation products of (R)-(−)-phenylglycinol with a mesotrihydroxylated glutaraldehyde, is described. The scope and limitations of the reaction have also been investigated.     

Racemization of (S)-(+)-10,11-dimethoxyaporphine and (S)-(+)-aporphine: efficient preparations of (R)-(−)-apomorphine and (R)-(−)-aporphine via a recycle process of resolution

Efficient preparations of (R)-(−)-apomorphine (R)-1 and (R)-(−)-aporphine (R)-2 based on a recycle process of resolution are described. In this recycle process of resolution, (RS)-(±)-10,11-dimethoxyaporphine 3 as the precursor of 1, and (RS)-(±)-aporphine 2 were successfully resolved into both enantiomers with (+)-dibenzoyltartaric acid (DBTA). The desired (R)-3 and (R)-2 were obtained and then, respectively, transformed to compound (R)-1, the hydrochloride salt of (R)-1, diacetate compound 4 and the hydrochloride salt of (R)-2; while the undesired (S)-3 and (S)-2 were racemized to obtain a racemate, which was suitable for further resolution. A method for the racemization of the undesired (S)-3 and (S)-2 was extensively studied, in order to obtain high-yielding racemization conditions. A plausible mechanism for the racemization of (S)-3 and (S)-2 was also proposed.     

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.     

Efficient preparation of (1′R)-(−)-1-(2′-hydroxy-1′-phenylethyl)piperidin-2-one: synthesis of (2′S,3R)-(+)-stenusine

An efficient oxidation of (2′R)-(−)-2′-phenyl-2′-(piperidin-1-yl)ethanol 2 with bromine to generate the corresponding piperidin-2-one 3 in 96% is described. In addition, starting from 3, (2′S,3R)-(+)-stenusine 8 was synthesized in 70% overall yield. The X-ray analysis of piperidine 6·HCl is also reported.     

Studies towards the synthesis of (1R,2S)- and (1S,2S)-1,2-epoxy-3-hydroxypropylphosphonates and (1S,2S)- and (1R,2S)-2,3-epoxy-1-hydroxypropylphosphonates

The trans-configured fosfomycin analogue, diethyl (1S,2S)-1,2-epoxy-3-hydroxypropylphosphonate, was synthesised by the intramolecular Williamson reaction of diethyl (1S,2R)-1,3-dihydroxy-2-mesyloxypropylphosphonate. The cis-analogue was obtained as O-ethyl or O,O-diethyl (1R,2S)-1,2-epoxy-3-hydroxypropylphosphonates, when (1R,2R)-1,3-dihydroxy-2-mesyloxypropylphosphonate or its 3-O-trityl derivative were used as starting materials, respectively. The intramolecular Williamson cyclisations of diethyl (1S,2R)- and (1R,2S)-1-benzyloxy-3-hydroxy-2-mesyloxypropylphosphonates led to diethyl (1S,2S)- and (1R,2S)-2,3-epoxy-1-benzyloxypropylphosphonates, respectively, with the concomitant formation of diethyl (E)-1-benzyloxy-3-hydroxyprop-1-en-1-phosphonate. From diethyl (1S,2S)- and (1R,2S)-2,3-epoxy-1-benzyloxypropylphosphonates, enantiomerically pure diethyl (1S,2S)- and (1R,2S)-1,2-dihydroxypropylphosphonates were obtained by catalytic hydrogenation, while diethyl (1S,2S)- and (1R,2S)-3-acetamido-1,2-dihydroxypropylphosphonates were produced after epoxide ring opening with dibenzylamine, acetylation and hydrogenolysis.     

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.     

Synthesis of (1S,4R)-4-isopropyl-1-methyl-2-cyclohexen-1-ol,the aggregation pheromone of the ambrosia beetle Platypus quercivorus,its racemate, (1R,4R)- and (1S,4S)-isomers

(S)-Perillyl alcohol was converted to (R)-cryptone (91.5–93% ee) in six steps, which was then treated with methyllithium to give (1S,4R)-4-isopropyl-1-methyl-2-cyclohexen-1-ol, the aggregation pheromone of the ambrosia beetle Platypus quercivorus. The racemic pheromone was also prepared by methylation of (±)-cryptone. Both (1R,4R)- and (1S,4S)-isomers (98% ee) of the pheromone were synthesized from the enantiomers of dihydrolimonene oxide.     

(+)-(1S, 3S, 6S, 8S)-und (−)-(1R, 3R, 6R, 8R)-4, 9-Twistadien: Synthese und Bestimmung der absoluten Konfiguration

(+)-(1S, 3S, 6S, 8S)-and (?)-(1R, 3R, 6R, 8R)-4, 9-Twistadiene: Synthesis and Absolute Configuration A synthesis and the determination of the absolute configuration of (+)-(1S, 3S, 6S, 8S)- and (?)-(1R, 3R, 6R, 8R)-4, 9-twistadiene ((+)- and (?)- 4 , respectively) is described. Their chiroptical properties are compared with those of saturated twistane ((+)- and (?)- 5 ) as well as with those of the unsaturated and saturated 2, 7-dioxatwistane analogs (+)- and (?)- 9 , and (+)- and (?)- 10 , respectively, which also are compounds of known absolute configurations.     

Convergent and enantioselective syntheses of both enantiomers of (5Z)-tetradecen-4-olide,scarab beetle pheromones

Japonilure and its enantiomer, that is, (R)-(−)- and (S)-(+)-(5Z)-tetradecen-4-olide, have been synthesised in satisfactory overall yields using a highly convergent procedure. In situ prepared 1-decynylethylzinc was enantioselectively coupled to isopropyl 4-oxobutanoate in the presence of (S)- or (R)-BINOL. The alkoxy-ester intermediates obtained were cyclised to the corresponding substituted γ-lactones, carrying a triple bond in the side chain. Lindlar-hydrogenation of the latter yielded the target compounds.     

Prostaglandin chemistry—V : Synthesis of new prostaglandin synthons; 4(R)-(+)- and 4(S)-(−)-t-butyldimethylsiloxycyclopent-2-en-1-one

Optically active prostaglandin intermediates, 4(R)-(+)- and 4(S)-(?)-hydroxycyclopent-2-en-1-one derivatives, were synthesized from 3(R),5(R)-diacetoxycyclopent-1-ene, 3(R)-acetoxy-5(R)-hydroxycyclopent-1-ene and 3(S),5(S)-dihydroxycyclopent-1-ene obtained by microbiological hydrolysis of 3,5-diacetoxycyclopent-1-ene. The absolute configurations of all these compounds were determined by the exciton chirality method and the induced CD method. The optical purities were determined by NMR measurements of the diastereomeric esters of a versatile optically pure acid, (+)-α-methoxy-α-trifluoromethylphenylacetic acid.     

Total synthesis of (4R,5S,6E,14S)- and (4R,5S,6E,14R)-cystothiazoles F

Total synthesis of (4R,5S,6E,14S)- and (4R,5S,6E,14R)-cystothiazoles F 3 was achieved from the chiral bithiazole-type primary alcohols [(S)- and (R)-4-ethoxycarbonyl-2′-(1-hydroxymethylethyl)-2,4′-bithiazoles 8], which were obtained based on the enzymatic resolution of racemic alcohol 8 and its acetate 9. From a direct comparison by means of chiral HPLC between natural cystothiazole F 3 and synthetic compounds [(4R,5S,6E,14S)- and (4R,5S,6E,14R)-cystothiazoles 3], natural cystothiazole F 3 was found to be a 33:67 diastereomeric mixture [(4R,5S,6E,14S)-3:(4R,5S,6E,14R)-3 = 33:67].