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 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.     

The synthesis of (−)-varitriol and (−)-3′-epi-varitriol via a Ramberg-Bäcklund route

A concise route to the anti-tumour natural product (−)-varitriol, together with its novel isomer (−)-3′-epi-varitriol, is described using a Horner-Wadsworth-Emmons (HWE)/conjugate addition/Ramberg-Bäcklund sequence as the cornerstone. The flexibility of the synthetic route has been demonstrated by the preparation of novel varitriol analogues.     

Enantiodivergent synthesis of cytotoxic styryl lactones from d-xylose. The first total synthesis of (+)- and (−)-crassalactone C

Enantiodivergent total syntheses of both (+)- and (−)-enantiomers of goniofufurone, 7-epi-goniofufurone and crassalactone C have been accomplished starting from d-xylose. The key steps of the synthesis of 7-epi-(+)-goniofufurone were a stereo-selective addition of phenyl magnesium bromide to a protected dialdose, and a stereospecific furano-lactone ring formation by reaction of a related hemiacetal derivative with Meldrum's acid. Synthesis of both (+)-goniofufurone and (+)-crassalactone C required a configurational inversion at C-5 in the common intermediate that was efficiently achieved under the standard Mitsunobu conditions, or alternatively through a sequential oxidation of the benzylic hydroxyl group followed by a stereo-selective reduction with borohydride. A similar approach was then applied to the synthesis of the unnatural (−)-enantiomers of goniofufurone, 7-epi-goniofufurone and crassalactone C, as well as two novel, conformationally constrained analogues of both (+)- and (−)-goniofufurone. Their in vitro antiproliferative activities against a number of human tumour cell lines were recorded and compared with those observed for the parent natural products.     

Asymmetric synthesis of (−)-(S,S)-homaline

The asymmetric synthesis of (−)-(S,S)-homaline was achieved in 8 steps from commercially available starting materials using the diastereoselective conjugate addition of the novel lithium amide reagent lithium (R)-N-(3-chloropropyl)-N-(α-methyl-p-methoxybenzyl)amide to methyl cinnamate to install the correct stereochemistry. Subsequent functional group manipulation of the resultant β-amino ester and Sb(OEt)₃-mediated macrolactamisation was followed by homodimerisation to give (−)-(S,S)-homaline in 18% overall yield, representing the first asymmetric, and by far the most efficient synthesis of this natural product reported to date.     

Asymmetric synthesis of (2S,3R)-(−)-epi-CP-99,994 using sulfinimine-derived anti-2,3-diamino esters

A differentially protected C-3 N-sulfinyl, C-2 N,N-(diphenylmethylene) 2,3-diamino ester was employed in the synthesis of the amino piperidine (2S,3R)-(−)-epi-CP-99,994. Key steps in the synthesis included the chemoselective hydrolysis of the C-2 N,N-(diphenylmethylene) group and its reprotection as a dibenzylamino group.     

An efficient and stereoselective synthesis of (3S,4R)-(−)-trans-4-(4′-fluorophenyl)-3-hydroxymethyl-N-methylpiperidine

An asymmetric conjugate addition reaction between a chiral α,β-unsaturated amido ester and ethyl-N-methylmalonamide has been used as a key step in the synthesis of (3S,4R)-(−)-trans-4-(4′-fluorophenyl)-3-hydroxymethyl-N-methylpiperidine, a key intermediate for (−)-paroxetine.     

Organocatalytic Michael addition, a convenient tool in total synthesis. First asymmetric synthesis of (−)-botryodiplodin

The asymmetric Michael addition of propionaldehyde to (2E)-(3-nitro-but-2-enyloxymethyl)-benzene 8, catalyzed by the chiral diamine (S,S)-N-iPr-2,2′-bipyrrolidine, afforded, with 93% ee, a precursor 9 of (−)-botryodiplodin. The nitro functionality of 9 was converted to a ketone via a Nef reaction to give, after a few steps, the enantiomerically enriched (−)-botryodiplodin.     

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.     

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.     

Flexible approach for the asymmetric synthesis of (−)-hyacinthacine A1 and its 7a-epimer

The diastereoselective nucleophilic addition of organic boronic ester to 3-hydroxy-2-substituted N-acyliminium ions 9 led to the formation of 2,5-cis-pyrrolidine 10, from which a convenient synthesis of (−)-7a-epi-1 was developed. In addition, an efficient asymmetric synthesis of (−)-hyacinthacine A1 1 was achieved through the reduction/ring-opening process.     

Enantioselective syntheses of carbocyclic nuleosides 5'-homocarbovir, epi-4'-homocarbovir and their cyclopropylamine analogs using facially selective Pd-mediated allylations

Carbocyclic nucleosides (−)-5′-homocarbovir and (+)-epi-4′-homocarbovir were prepared from an acylnitroso-derived hetero Diels-Alder cycloadduct. A kinetic enzymatic resolution generated an enantiopure aminocyclopentenol and Pd(0)-mediated decarboxylative allylations of allyl 2,2,2-trifluoroethyl malonates were used to install the 4′-hydroxyethyl groups. Late stage derivatization gave access to the cyclopropylamine analogs, (−)-5′-homoabacavir, and (+)-epi-4′-homoabacavir. All carbonucleoside target molecules were evaluated for antiviral activity.     

Asymmetric syntheses of (−)-isoretronecanol and (−)-trachelantamidine

Short and concise total asymmetric syntheses of (−)-isoretronecanol and (−)-trachelantamidine are reported. Oxidative cleavage of tert-butyl (S,S,S,Z)-7-[N-benzyl-N-(α-methylbenzyl)amino]cyclohept-3-ene-1-carboxylate, followed by hydrogenolysis promoted in situ cyclisation/reduction, which provided rapid access to the bicyclic core within (−)-isoretronecanol. Analogous treatment of the C(1)-epimer gave (−)-trachelantamidine. Overall, the syntheses of (−)-isoretronecanol and (−)-trachelantamidine were completed in eight and seven steps and 20 and 9.5% yield, respectively, from commercially available starting materials.     

Asymmetric synthesis of the marine alkaloid (−)-(S)-nakinadine C

The first asymmetric synthesis of the marine alkaloid (−)-(S)-nakinadine C is described. This synthesis employs the conjugate addition of lithium dibenzylamide to an N-α-phenylacryloyl SuperQuat derivative followed by diastereoselective protonation of the intermediate enolate using 2-pyridone as the key step to introduce the stereochemistry. (−)-(S)-Nakinadine C was isolated in 13% yield over 9 steps from commercially available atropic acid, 98:2 dr [(Z):(E) ratio] and >99% ee.     

A concise diastereoselective approach to (+)-dexoxadrol, (−)-epi-dexoxadrol, (−)-conhydrine and (+)-lentiginosine from (−)-pipecolinic acid

A new diastereoselective pathway for the total synthesis of (+)-dexoxadrol, first asymmetric synthesis of (−)-epi-dexoxadrol and formal synthesis of conhydrine and (+)-lentiginosine is presented using commercially available (−)-pipecolinic acid. The key reactions utilized are Sharpless asymmetric dihydroxylation and Wittig reaction. The paper further describes the study of effect of protecting groups on dihydroxylation of a terminal olefin in piperidine ring system.     

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.     

Syntheses of (−)-gabosine A, (+)-4-epi-gabosine A, (−)-gabosine E, and (+)-4-epi-gabosine E

(+)-4-epi-Gabosine A 1 and (−)-gabosine A 2 have been synthesized starting from methyl α,d-glucopyranoside and methyl α,d-mannopyranoside, respectively, by utilizing Pd(0) catalyzed Stille coupling as the key step. On the other hand, syntheses of (+)-4-epi-gabosine E 3 and (−)-gabosine E 4 have been accomplished from methyl α,d-glucopyranoside and from methyl α,d-mannopyranoside, respectively, by utilizing DMAP catalyzed Morita-Baylis-Hillman reaction as the key step. Presence of acetyl group at C-6 position of sugar derived cyclic enone prevented the aromatization of MBH adduct. A plausible mechanism is also described.     

First total synthesis and absolute configuration of naturally occurring (−)-hyacinthacine A7 and its (−)-1-epi-isomer

A convergent synthesis of the naturally occurring alkaloid (−)-hyacinthacine A₇, a glycosidase inhibitor of the pyrrolizidine class, is described. The homochiral starting material was tri-orthogonally protected DMDP 10, derived from d-fructose. Key steps of the synthesis were the carbon-chain lengthening at C(5′) in 10 to the α,β-unsaturated pyrrolidine ketone 12 and the one-pot construction of the bicyclic pyrrolizidine system of 13 and 14. Another key step was the partial inversion of the configuration at C(1) in 13 which led, after total deprotection, not only to the naturally occurring target molecule 9 but also to its (−)-1-epi-isomer 19.     

Synthetic study of (−)-lasubine II via sequential cyclization process

A new synthetic pathway to lythraceae alkaloid lasubine II has been developed. In this approach, we designed a sequential cyclization pathway for the formation of quinolizidine ring. For the preparation of the requisite precursor, a known chiral β-amino ester has been used as a starting intermediate. Upon deprotection of Cbz group on nitrogen, endo-type Michael addition and the following S_N2 reaction were assumed to proceed to provide (−)-2-epi lasubine II.     

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.