Total synthesis of mycestericin A

The first total synthesis of mycestericin A (1) starting from tartrates is described. The Overman rearrangement of an allylic trichloroacetimidate generated a tetra-substituted carbon with nitrogen, and subsequent stereoselective transformations afforded the highly functionalized vinyl iodide. The cross-coupling of the vinyl iodide with a chiral organozinc species under Negishi conditions, followed by deprotection, completed the total synthesis of 1.     

Synthetic studies on antascomicin A: construction of the C18-C34 fragment

Stereoselective synthesis of the C18-C34 fragment of antascomicin A is described. Construction of the C27-C34 carbocycle moiety was achieved via catalytic Ferrier carbocylization and Johnson-Claisen rearrangement, which was converted to iodide 2 by use of asymmetric alkylation and Sharpless epoxidation as key transformations. Coupling of iodide 2 and sulfone 3 furnished the C18-C34 fragment.     

Enantioselective syntheses of poison-frog alkaloids: 219F and 221I and an epimer of 193E

Enantioselective syntheses of indolizidines (−)-219F and (−)-221I have been achieved and the relative stereochemistries of natural 219F and 221I were determined by the present synthesis. A levorotatory indolizidine, corresponding to one proposed structure for 193E, was also synthesized, but was found to differ from 193E. It seems likely that natural 193E is the 8-epimer of the synthesized indolizidine.     

New synthesis of (−)- and (+)-actinobolin from d-glucose

The total synthesis of (−)-actinobolin 2, an antipode of the natural product starting from d-glucose is described. A three-component coupling reaction of a functionalized cyclohexenone (+)-6, derived from d-glucose by way of Ferrier's carbocyclization, with vinyl cuprate and an aldehyde (R)-5 effectively constructed the carbon framework of 2 in a highly stereoselective manner. The formal synthesis of the natural enantiomer 1 from d-glucose was also achieved.     

Synthesis of (15S,16S,21R)-4-deoxyrollicosin analog

Synthesis of 4-deoxy rollicosin analog 2 was completed in nine steps, which was based on palladium-catalyzed coupling of two building blocks 3 and 4. Lactone 3 was synthesized from 5-hexyn-1-ol, and vinyl iodide 4 was accessed from l-glutamate and 1-hexyne.     

Stereoselective synthesis of a 12-acetoxyazadiradione analogue

The synthesis of the 12-acetoxy enone 15 related to the limonoid azadiradione has been achieved in 12 steps (16% overall yield) starting from tricyclic diester 1. The key steps involve intramolecular 1,3-dipolar cycloaddition of a nitrile oxide and a Stille coupling reaction of a vinyl iodide with a stannylfuran.     

Total synthesis of the proposed structure of iriomoteolide-1a

Full details of the total synthesis of the proposed structure of iriomoteolide-1a (1) are described. The key steps include (i) a Sakurai reaction between allylsilane 11 and aldehyde 10 that bears both a tertiary chiral center and vinyl iodide moiety (ii) an anti-aldol reaction to construct the C18/C19 chiral centers (iii) a B-alkyl Suzuki-Miyaura coupling reaction to assemble the C7-C23 fragment, and (iv) a macrocyclic ring-closing metathesis to complete the construction of the target molecule. Two different approaches to access penultimate precursor 2 are delineated. The NMR spectra of the synthetic iriomoteolide-1a (1) were found not to match those reported for the natural product bringing into question its true structural identity.     

Studies on the Synthesis of Reidispongiolide A: Stereoselective Synthesis of the C(22)-C(36) Fragment

A highly stereoselective synthesis of the C(22)-C(36) fragment 2 of reidispongiolide A is described. This synthesis features the highly stereoselective mismatched double asymmetric crotylboration reaction of the aldehyde derived from 5 and the new chiral reagent (S)-(E)-7 that provides 12 with >15:1 dr. Subsequent coupling of the derived vinyl iodide 3 with aldehyde 16 provided allylic alcohol 17, that was elaborated by three steps into the targeted reidispongiolide fragment 2.     

Total synthesis of actinobolin from d-glucose by way of the stereoselective three-component coupling reaction

The total synthesis of (−)-actinobolin 3, an antipode of the natural product, starting from d-glucose is described. A three-component coupling reaction of functionalized cyclohexenone (+)-6 derived from d-glucose by way of Ferrier's carbocyclization reaction, with vinyl cuprate and 2-alkoxypropanal 7 effectively constructed the carbon framework of 3 in a highly stereoselective manner. In an aldol process of the three-component coupling reaction, stereochemical control (chelation and Felkin-Anh conditions) was achieved by the choice of the protecting groups of a hydroxy function in 2-hydroxypropanal and the reaction solvents. The formal synthesis of the natural enantiomer, (+)-actinobolin 1, starting from d-glucose was also accomplished.     

Highly stereoselective synthesis of para-substituted (E)-N-styrylcarbazoles via sequential silylative coupling-Hiyama coupling reaction

A series of new para-substituted (E)-(N)-styrylcarbazoles, i.e., eight (E)-9-[2-(aryl)ethenyl]-9H-carbazoles (5-12) and 1,4-bis[(E)-2-(9H-carbazol-9-yl)vinyl]benzene (13), have been synthesized in high yield and stereoselectively by a sequential silylative coupling-Hiyama coupling reaction, i.e., coupling of commercially available 9-vinylcarbazole with vinyltriethoxysilane or divinyltetramethyldisiloxane in the presence of [RuHCl(CO)(PCy₃)₂] (I), followed by Pd (II) catalyzed cross-coupling with para-substituted iodobenzenes.The tandem procedure has facilitated the synthesis of 13. X-ray structures of the intermediate silylvinylcarbazole (4), as well as products 12 and 13 have been obtained.     

Adenine-based urea receptors in fluorescent recognition of iodide

Adenine-based receptors 1 and 2 are designed and synthesized for selective sensing of iodide over the other halides and carboxylate anions. Both the receptors 1 and 2 use the urea motif for binding carboxylates and halides. Emissions of the naphthalene and the anthracene in 1 and 2, respectively, are monitored in CHCl₃ in detecting the anions. While carboxylates, fluoride, chloride, and bromide increase the emissions of naphthalene and anthracene in both the receptors 1 and 2 during complexation, iodide quenches the emission. Such selective quenching allows iodide to be discriminated from other halides and carboxylate anions.     

Reinvestigation of the stereochemistry of kulokekahilide-2

An attempt to carry out a total synthesis of kulokekahilide-2 (1) by macrolactonization of a seco acid prepared from a suitably protected hexapeptide and a dioxy acid moiety unexpectedly resulted in the formation of the 43-epimer (1a) of the cytotoxic depsipeptide, for which structure 1b has previously been proposed. A second attempt involving macrolactamization of the corresponding amino acid gave the target product, 1b, but the spectral data of the product did not match those of natural 1. Furthermore, neither 1a nor 1b showed any cytotoxicity, from which it is concluded that the structure of natural 1 is incorrect and should be re-examined.     

Formal total synthesis of aspergillide A

The formal total synthesis of aspergillide A 1 is described. The cross-metathesis of enone 6 with 6-hepten-2-ol derivative 5 provided E-olefin 15 corresponding to the C₄-C₁₄ backbone of 1. The CBS asymmetric reduction of 15 gave allyl alcohol 16, which was transformed into β-alkoxyacrylate 4 which had a formyl group. SmI₂-induced reductive cyclization of 4 gave a 2,6-syn-2,3-trans THP derivative 3 in good yield. After methoxymethylation of 3, the resulting compound 19 was submitted to desilylation and hydrolysis, to afford Fuwa’s key intermediate 2 for the total synthesis of 1.     

Total synthesis of (+)-ambruticin S

A convergent total synthesis of the novel antifungal agent ambruticin S (1) has been completed from the assembly of intermediates 18, 33 and 52 that served as the respective A-, B-, and C-ring precursors. The first generation approach to a potential A-ring intermediate eventuated in the synthesis of 9a via a route that featured oxidation of the dihydroxy furan 2 and elaboration of the dihydropyranone 3 derived therefrom. Although 9a served as a precursor of 31E to complete a formal synthesis of 1, there were several inefficiencies associated with the preparation of 9a. A more expedient and efficient route to an A-ring subunit was devised that commenced with the carbohydrate-derived bisacetonide aldehyde 10 and produced 18 in five steps and 46% overall yield. The synthesis of the cyclopropyl sulfone 33 was initiated with the enantioselective cyclopropanation of 19 catalyzed by Rh₂[5(S)-MEPY]₄. Ring opening of the resultant lactone 20 followed by a series of refunctionalizations gave 33 in a total of seven steps and 46% yield from 19. Coupling of the A- and B-ring precursors 18 and 33 was then achieved via a modified Julia coupling followed by deprotection and oxidation to furnish the key intermediate 35. The dihydropyran core of the C-ring subunit precursor 49 was formed from the ring closing metathesis of the diene 48, which was prepared in three steps from the known epoxide 45, followed by oxidation. A chelation-controlled addition to the methyl ketone 49 set the stage for a stereoselective [2,3]-Wittig rearrangement that delivered the alcohol 51 that was then transformed in two steps to the sulfone 52. A traditional Julia coupling of 52 and 35 proceeded with excellent stereoselectivity, and subsequent removal of the various protecting groups gave ambruticin S (1). The longest linear sequence was 13 steps and proceeded in 4.3% overall yield.     

Synthesis of seco-psymberin/irciniastatin A: the discovery of a novel PhI(OAc)2 mediated cascade cyclization reaction

The psymberin unsaturated ‘psymberate’ side chain 7 was synthesized in 7 steps (36% yield) with good diastereoselectivity using commercially available starting material to control the stereochemistry at C₄ and C₅. The synthesis of seco-psymberin was completed in an efficient manner based on a CuI mediated coupling reaction between vinyl iodide 8 and ‘psymberamide’ 7. In an attempt to synthesize natural psymberin from the seco-intermediate, a novel PhI(OAc)₂ mediated cascade ring closing reaction was discovered. A possible mechanistic pathway for the formation of the ring closing product was presented.     

4,7-Diaryl indole-based fluorescent chemosensor for iodide ions

Simple and selective indole based fluorescent sensors for iodide anions are reported. A series of 4,7-diaryl indole derivatives (DAIs) are designed and synthesized using Suzuki coupling. These DAIs shows significant changes in UV-vis and fluorescent intensity only with addition of iodides and not with other anions. The ability of these DAIs to function as selective iodide chemosensor is reported.     

Syntheses of aza and fluorine-substituted 3-(piperidin-4-yl)-4,5-dihydro-1H-benzo[d][1,3]diazepin-2(3H)-ones

A practical and expedient synthesis of the title compounds is described. They were prepared by Stille reaction of nitro halopyridines 4 or nitro fluro-halobenzenes 10, followed by Michael addition of tert-butyl 4-aminopiperidine-1-carboxylate to the resulting activated vinyl compounds 5 and 11, hydrogenation (-NO₂→-NH₂), cyclic urea formation, Boc removal, and HCl salt formation. However, N3 and F1 analogs could not be made by this general strategy. Activated vinyl compounds 5a and 5d when reacted with tert-butyl 4-aminopiperidine-1-carboxylate did not stop at the desired Michael addition stage; but proceeded to produce azaindolines 8 and 9. Michael addition did not occur to compound 11d; instead, the fluorine atom was displaced.     

Photochromism of dihydroindolizines. Part 12: synthesis and photochromism of novel π-conjugated rigid dihydroindolizines as potential molecular electronic devices

Novel carbon-rich photochromic dihydroindolizine DHI derivatives and new spirocyclopropenes have been synthesized. Three alternative synthetic pathways for the synthesis of DHI 10 have been established. Different Sonogashira-mediated coupling reactions have been applied to optimize the reaction conditions and to obtain the best yields. Palladium-mediated Sonogashira coupling of DHIs with 4-(thioacetyl)iodobenzene 13 and iodobenzene 17 yielded coupling products, which have potential applications in molecular electronics. Irradiation of photochromic DHIs 10a-f, 12a-f, 14a-f, 16a-f and 18a-f with polychromatic light leads to betaines 9a-f, 13a-f, 15a-f, 17a-f and 19a-f. The coloured betaine forms are obvious in CH₂Cl₂ solution with concentration of 1×10⁻⁵ mol/L at room temperature because of their slower 1,5-electrocyclization. All the absorption maxima of the coloured betaines were found to be in the visible region and lie between 524 (betaine 9a) and 639 nm (betaine 15f). The kinetics of the thermal 1,5-electrocyclization was studied using multichannel UV-vis spectrophotometry. The kinetic measurements showed that the half-lives of the coloured betaines are in the second domain and lie between 112 and 1379 s. A highly pronounced increase in the half-lives of betaines bearing dimethyl substituted pyridazine compared with non-substituted pyridazine betaines was monitored. A large increase in the photostability of both DHIs and betaines under investigation compared with the standard DHI was observed. The charged zwitterionic betaine structures were stabilized by increasing the solvent polarity due to the electrostatic interactions between them. The tuning of the absorption maxima and the kinetic properties by changing the substitution in the fluorene part (region A) and pyridazine part (region C) will help these compounds to find their applications.     

Large-scale synthesis of 1,1,3,3,6-pentamethyl-1,3-disilaindan-5-ol via a CoBr2/Zn-catalyzed [2+2+2] cycloaddition reaction

1,1,3,3,6-Pentamethyl-1,3-disilaindan-5-ol (2) is a key intermediate in the synthesis of new sila-substituted gonadotropin releasing hormone receptor antagonists, such as 1. In order to produce sufficient quantities of 1 for pharmacological and toxicological evaluation, an efficient synthesis of 2 has been developed. (1,1,3,3,6-Pentamethyl-1,3-disilaindan-5-yl)methanal (11) was synthesized in a one-pot procedure. CoBr₂/Zn-catalyzed [2+2+2] cycloaddition of diyne 3 with the commercially available monoalkyne 15 was achieved through a slow addition of 3 and CoBr₂ to a mixture of 15 and zinc powder in refluxing acetonitrile, giving rise to 5-(diethoxymethyl)-1,1,3,3,6-pentamethyl-1,3-disilaindane (14). In-situ aqueous acidification yielded 11. Conversion to 2 was then achieved via a Baeyer-Villiger oxidation followed by hydrolysis under basic condition. This novel methodology is useful, not only for the rapid, large-scale synthesis of 2, but also for the synthesis and development of new sila-substituted drugs derived from 11.     

Two-directional total synthesis of efomycine M and formal total synthesis of elaiolide

The anti-inflammatory agent efomycine M (1) has been synthesized from macrodilactone 38 and vinyliodide 42 by a two-directional total synthesis in 17 steps over the longest linear sequence with an overall yield of 7%. The C₂-symmetric macrodiolide 38 has been prepared by Yamaguchi macrolactonization of seco-acid 26. The central stereopentad of 1 was obtained by a highly efficient anti-aldol reaction followed by a diastereoselective ketone reduction. Additionally, we have completed a formal total synthesis of elaiolide (3) by converting macrodiolide 37 into Paterson's methylketone 13.