Synthesis of polyhydroxylated indolizidines and piperidines from Garner's aldehyde: total synthesis of (−)-swainsonine, (+)-1,2-di-epi-swainsonine, (+)-8,8a-di-epi-castanospermine,pentahydroxy indolizidines, (−)-1-deoxynojirimycin, (−)-1-deoxy-altro-nojirimycin,and related diversity

Diastereoselective and diverse synthesis of polyhydroxylated indolizidines and piperidines have been described, where a common chiral intermediate 2-(hydroxymethyl) piperidine-3-ol is converted into (−)-swainsonine, (+)-1,2-di-epi-swainsonine, (+)-8,8a-di-epi-castanospermine, pentahydroxy indolizidines, (−)-1-deoxynojirimycin, (−)-1-deoxy-altro-nojirimycin, and related diversity. The key steps were hydroxy directed intramolecular aminomercuration, Mitsunobu cyclization, and diastereoselective dihydroxylation.     

The combined use of stereoelectronic control and ring closing metathesis for the synthesis of (−)-8-epi-swainsonine

A novel and efficient synthesis of (−)-8-epi-swainsonine 2 is reported. Stereocontrolled diol formation from the bicyclic alkene 3 followed by a stereoselective vinylation of the aldehyde and ring closing metathesis gave the indolizidine ring system, which was converted into (−)-8-epi-swainsonine 2.     

A formal synthesis of (−)-swainsonine from a chiral aziridine

A formal synthesis of enantiomerically pure (−)-swainsonine was successfully achieved using intramolecular cyclization of the amino alcohol 4 which was derived from a readily available 1-(R)-α-methylbenzylaziridine-2-carboxylic acid (−)-menthol ester 6.     

A concise synthesis of (−)-cytoxazone and (−)-4-epi-cytoxazone using chlorosulfonyl isocyanate

A concise synthesis of (−)-cytoxazone and its stereoisomer (−)-4-epi-cytoxazone, novel cytokine modulators, has been accomplished each in six steps from readily available p-anisaldehyde with good diastereoselectivity. Key steps in the synthesis include the regioselective and diastereoselective amination of anti- and syn-1,2-dimethyl ethers with chlorosulfonyl isocyanate and the subsequent regioselective cyclization of the diol to construct the oxazolidin-2-one core. The diastereoselectivity of amination reaction using CSI was explained by the Cieplak electronic model via S_N1 mechanism and neighboring group effect, leading to the retention of the configuration.     

Intramolecular α-acylamino radical cyclizations with acylsilanes in the preparation of polyhydroxylated alkaloids: (+)-lentiginosine, (+)-1,8a-di-epi-lentiginosine, and (+)-1,2-di-epi-swainsonine

Acylsilanes with latent α-acylamino radical functionality were prepared from different chiral templates. Radical cyclizations of these acylsilanes efficiently constructed polyhydroxylated indolizidine derivatives with excellent stereoselectivity at the bridgehead position. These cyclization products were converted to (+)-lentiginosine, (+)-1,8a-di-epi-lentiginosine, and (+)-1,2-di-epi-swainsonine.     

A facile synthesis of 1,4-dideoxy-1,4-imino-l-ribitol (LRB) and (−)-8a-epi-swainsonine from d-glutamic acid

A facile synthesis of (−)-8a-epi-swainsonine 2 and 1,4-dideoxy-1,4-imino-l-ribitol (LRB) 4 has been achieved by using the versatile building block 3, which was available from cheap d-glutamic acid. The new forming stereogenic center in synthesis of 2 was constructed by highly selective reduction of the ketone 13 with Li(t-BuO)₃AlH in THF (dr=95:5).     

Enantioselective synthesis of (R)-deoxydysibetaine and (−)-4-epi-dysibetaine

Enantioselective synthesis of (R)-deoxydysibetaine and (−)-4-epi-dysibetaine was achieved by employing a samarium iodide-promoted reductive carbon-nitrogen bond cleavage of a proline derivative, as a key reaction.     

Synthesis of (+)-agelasine C. A structural revision

An efficient synthesis of (+)-agelasine C has been achieved from ent-halimic acid. The structure and absolute configuration of the natural product (−)-agelasine C was established and a structure for epi-agelasine C, is proposed.     

Total synthesis of (+)-valienamine and (−)-1-epi-valienamine via a highly diastereoselective allylic amination of cyclic polybenzyl ether using chlorosulfonyl isocyanate

The total synthesis of (+)-valienamine and (−)-1-epi-valienamine was concisely accomplished from readily available d-glucose via a highly diastereoselective amination of chiral benzylic ether using chlorosulfonyl isocyanate, intramolecular olefin metathesis, and diastereoselective reduction of cyclic enone using l-Selectride as the key steps.     

Stereoselective synthesis of (−)-8-epi-swainsonine starting with a chiral aziridine

An efficient synthesis of (?)-8-epi-swainsonine, starting from a commercially available 1-(R)-α-methylbenzylaziridine-2-methanol, was developed. The synthetic route utilizes stereocontrolled Sharpless asymmetric dihydroxylation governed by AD-mix-β followed by an aziridine ring opening-cyclization sequence to generate the five membered N-heterocyclic ring system present in the bicyclic target. A subsequent stereoselective allylation and piperidine ring forming cyclization then produced a precursor that was converted into (?)-8-epi-swainsonine.     

Musanahol: a new aureonitol-related metabolite from a Chaetomium sp.

Two antibacterial furano-polyenes, (−)-musanahol (1) and 3-epi-aureonitol (5), and a fatty acid, linoleic acid (8) were isolated from the laboratory cultures of a Chaetomium sp. accessed from tomato fruits, and grown on YMG medium (yeast extract, glucose, malt extract and water) at pH 5.8-6.0. The structure of compound 1, a new furano-polyene, was elucidated by spectroscopic methods that include extensive 2D NMR experiments, double resonance experiments, Mosher's method and PM3 calculations. (−)-Musanahol (1) and 3-epi-aureonitol (5) were present in the culture filtrate of the fungus. 3-epi-Aureonitol (5) completely inhibited the growth of Streptococcus pyogenes at 15.63 μg/mL and Escherichia coli, Staphylococcus aureus, Salmonella choleraesuis and Corynebacterium diphtheriae at 31.25 μg/mL, whereas (−)-musanahol (1) lacked the antimicrobial potency of compound 5 in spite of the similarities in their structures. Linoleic acid (8) was isolated from the mycelia of the fungus; it inhibited the growth of S. aureus and Bacillus subtilis at a minimum concentration of 15.62 μg/mL.     

A concise route to (−)-shikimic acid and (−)-5-epi-shikimic acid, and their enantiomers via Barbier reaction and ring-closing metathesis

A simple route for the synthesis of naturally occurring (−)-shikimic acid, (−)-5-epi-shikimic acid, and their enantiomers from d-ribose-derived enantiomeric aldehydes 8a and 8b by employing Barbier reaction and ring-closing metathesis as key steps has been developed.     

A flexible enantioselective approach to 3,4-dihydroxyprolinol derivatives by SmI2-mediated reductive coupling of chiral nitrone with ketones/aldehydes

A flexible enantioselective approach to polyhydroxylated prolinol derivatives was described, which is based on the samarium diiodide-mediated reductive coupling of the chiral nitrone (3S,4R)-8, derived from d-isoascorbic acid with aldehydes/ketones. Thereby, polyhydroxyprolinol derivatives 9a–e and 9h–j were obtained from aromatic ketones and aliphatic aldehydes in good to excellent yields of 65–91%. These reductive hydroxyalkylations are highly diastereoselective in establishing the C-4 stereogenic center. By this way, the asymmetric syntheses of (?)-8a-epi-swainsonine (4) and (?)-8,8a-di-epi-swainsonine (5) have been achieved.     

Concise and divergent total synthesis of swainsonine, 7-alkyl swainsonines, and 2,8a-diepilentiginosine via a chiral heterocyclic enaminoester intermediate

The concise and divergent total syntheses of (−)-swainsonine, (−)-7-alkyl swainsonines, and (−)-2,8a-diepilentiginosine from a common chiral heterocyclic enaminoester intermediate in five-step sequences are presented. The highly efficient annulation reaction of the chiral heterocyclic enaminoester with various α,β-unsaturated carboxylates, and a straightforward carboxy inversion constituted the key features of the synthetic pathway. This work provides an example for divergent synthesis of different natural and unnatural polyhydroxylated indolizidines from a readily available platform.     

Stereoselective syntheses of 20-epi cholanic acid derivatives from 16-dehydropregnenolone acetate

A stereoselective total synthesis of naturally occurring 20-epi cholanic acid derivatives has been realized, starting from readily available 16-dehydropregnenolone acetate. The key step of these syntheses involves an ionic hydrogenation of a C-20,22-ketene dithioacetal and deoxygenation of steroidal C-20 tert-alcohols, to set up the unnatural C(20R) configuration with 100% stereoselectivity. The unnatural C-22 aldehydes with C(20R) stereocenters thus obtained were elaborated to 20-epi cholanic acid derivatives. Two derivatives of 20-epi cholanic acid were synthesized and their structures have been confirmed by single crystal X-ray analysis. Catalytic hydrogenation of 16-dehydropregnenolone acetate and 16-dehydropregnenolone in ethanol affords C-5,C-16 tetrahydro products. Crystal structure analysis of one of these products revealed C-5α and C-17α configurations of the hydrogen atoms.     

Towards the synthesis of prevezol C: total enantioselective synthesis of (−)-2-epi-prevezol C

(−)-2-epi-Prevezol C was readily accessed from the chirons (−)- and (+)-limonene oxide in a total of nine steps and in 24% yield. This efficient enantioselective synthesis of this complex product utilises a highly stereoconvergent, substrate-controlled allylic alkylation strategy to assemble rapidly the unprecedented diterpene core.     

A diastereodivergent strategy for the asymmetric syntheses of (−)-martinellic acid and (−)-4-epi-martinellic acid

Asymmetric syntheses of (−)-martinellic acid and (−)-4-epi-martinellic acid were achieved in 20 steps from commercially available starting materials using a diastereodivergent strategy. The conjugate addition of lithium (R)-N-allyl-N-(α-methyl-p-methoxybenzyl)amide to tert-butyl (E)-3-[2′-(N,N-diallylamino)-5′-bromophenyl]propenoate and alkylation of the resultant β-amino ester with methyl bromoacetate were used as the key steps to install the C(9b) and C(3a) stereogenic centres, respectively. Subsequent cyclisation to the corresponding pyrroloquinolin-2-one and reduction of the C(4)-carbonyl group was followed by two complementary procedures for olefination and concomitant intramolecular Michael addition, which gave both C(4)-epimers of this tricyclic molecular architecture in >99:1 dr. Subsequent elaboration of these templates provided access to (−)-martinellic acid and, for the first time, (−)-4-epi-martinellic acid.     

First synthesis of naturally occurring (±)-epi-conocarpan

(±)-epi-Conocarpan 1 was synthesized via the key intermediate 5-bromo-cis-2-(4-methoxyphenyl)-3-methyl-2,3-dihydrobenzofuran 6 which was synthesized by a ruthenium(II) porphyrin-catalyzed intramolecular C-H insertion reaction using aryl tosylhydrazone salt 5 as the carbene source, starting from the commercially available 5-bromo-2-hydroxyacetophenone.     

Total synthesis of (+)-negamycin and its 5-epi-derivative

(+)-Negamycin was prepared in 13 steps in an overall yield of 31% from commercially available ethyl (R)-(+)-4-chloro-3-hydroxybutanoate. The key step in the reaction sequence was a highly stereoselective asymmetric Michael addition of chiral amine (−)-21 [(1S,2R)-(−)-2-methoxybornyl-10-benzylamine] into the α,β-unsaturated carbonyl moiety of key intermediate 8, thus establishing the second chiral center in (+)-negamycin. 5-epi-Negamycin was also prepared in a similar fashion.     

Highly stereoselective and stereospecific syntheses of a variety of quercitols from d-(−)-quinic acid

The highly stereoselective synthesis of (−)-epi-, (−)-allo- and neo-quercitols as well as stereospecific synthesis of (−)-talo- and (+)-gala-quercitols have been achieved. The general strategy is employing dihydroxylation of the isolated double bond of various kinds of protected chiral (1,4,5)-cyclohex-2-ene-triols, which are derived from d-(−)-quinic acid. The choosing of protecting groups from either BBA (butane 2,3-bisacetal) or acetyl groups will result in the various degrees of stereoselectivity of dihydroxylation. On the other hand, the cyclohexylidene acetal moiety is attributed to the stereospecificity during dihydroxylation to afford the request molecules.