Total synthesis of cyclopiamide A and speradine E

Described is a total synthesis of the related alkaloids, cyclopiamide A and speradine E, via a unified strategy that also delivers the natural product aspergilline A. Key steps include metal-free conversion of a malonyl chloride and propargylamine to an intermediate pyrrolinone and a palladium catalyzed decarboxylation/aromatization sequence that delivers the requisite tetracyclic core.     

Total synthesis of amphidinolide E

A convergent and highly stereocontrolled synthesis of amphidinolide E (1) has been accomplished. The synthesis features a highly diastereoselective (>20:1) BF3.Et2O promoted [3+2] annulation reaction between aldehyde 3 and allylsilane 4 to afford substituted tetrahydrofuran 2.     

Total synthesis of isoroquefortine E and phenylahistin

Isoroquefortine E and phenylahistin were synthesized using the Horner–Wadsworth–Emmons reaction as the key step to build the dehydroamino acid moiety. The syntheses provided the materials for the biological studies of the roquefortine–phenylahistin molecules.     

Total synthesis of (+)-thiazinotrienomycin E

[formula: see text] The first total synthesis of (+)-thiazinotrienomycin E (1), member of a novel class of cytotoxic ansamycin antibiotics, has been achieved. The synthesis features a highly efficient construction of the aromatic fragment 3 incorporating TBS protection of the aniline, a significantly improved synthesis of (-)-19, an intermediate employed in our trienomycins A and F total syntheses, application of the Kocienski modified Julia protocol to elaborate the E,E,E-triene subunit, an efficient union of 3 and (+)-4, and Mukaiyama macrolactamization to access the thiazinotrienomycin macrolide.     

Total synthesis of resolvin E2

Resolvin E2 (2) was synthesized stereoselectively using the C1-8 and C15-20 aldehydes 6 and 9, which were connected to the C9-14 fragment by using Wittig reactions. The aldehyde 6 was prepared from the γ-silyl alcohol (S)-20 by a sequence of reactions involving ozonolysis, oxidation with NaIO₄, and the Wittig reaction of the resulting aldehyde with Ph₃PCHCHO, whereas the aldehyde 9 was synthesized from the corresponding γ-silyl alcohol through epoxidation, reaction with Et₂AlCN, and reduction with DIBAL-H.     

Total synthesis of Resolvin E1

The enantioselective total synthesis of Resolvin E1 (RvE1), a naturally occurring small molecule mediator of inflammation resolution, is reported. Two routes are presented, both modular and convergent in nature, with an excellent control of all stereocenters. The C12- and C18-hydroxy groups are derived from (S)-glycidol while the C5-hydroxy group is installed via enantioselective reduction of a ketone precursor. Both the cis-alkenes are introduced with excellent control by the reduction of a late-stage bis-alkyne intermediate. The synthetic disconnections are very amenable to analog preparation, and further modifications to the chemistry have allowed for scale-up and First in Man testing of this novel pro-resolution molecule.     

Total synthesis of resolvin E1

Resolvin E1 (RvE1), which is an endogenous mediator to resolve inflammation, was synthesized by Wittig reaction between the C15-C20 aldehyde and the C10-C14 phosphonium salt possessing the vinyl iodo moiety followed by Suzuki-Miyaura coupling of the resulting vinyl iodide with the vinyl borane of the C1-C9 part, which was derived from the corresponding acetylene by hydroboration. The C5 and C18 chiral centers in these parts were created by the kinetic resolution of the racemic γ-TMS allylic alcohols using the asymmetric epoxidation, while that of the C10-C14 part was constructed by the asymmetric hydrogen transfer reaction of the corresponding γ-TMS acetylene ketone.     

Total synthesis and absolute stereochemistry of plakortone E

The absolute stereochemistry of plakortone E, a cytotoxic metabolite of the Caribbean sponge, was established to be 1, by the synthesis of the racemic C-8 epimer (±)-2 and then of (−)-1 itself, which was identical with the natural compound.     

Total synthesis of plakortide E and biomimetic synthesis of plakortone B

The total synthesis of plakortide E (1a) is reported. A novel palladium-catalyzed approach towards 1,2-dioxolanes as well as an alternative substrate-controlled route leading exclusively to cis-highly substituted 1,2-dioxolanes have been developed. A lipase-catalyzed kinetic resolution was employed to provide optically pure 1,2-dioxolane central cores. Coupling of the central cores and side chains was achieved by a modified Negishi reaction. All four isomeric structures of plakortide E methyl ester, namely, 26a-d were synthesized. One of the structures, 26d, was shown to be identical with the natural plakortide E methyl ester on the basis of (1)H, (13)C NMR spectra and specific rotation comparisons. With the plakortide E methyl ester (4S,6R,10R)-(-)-cis-26d and its other three isomers in hand, we successfully converted them into (3S,4S,6R,10R)-plakortone B (2a), and its isomers ent-2a, 2b and ent-2b via an intramolecular oxa-Michael addition/lactonization cascade reaction. Finally, saponification converted 1,2-dioxolane 26d into plakortide E (1a) whose absolute configuration (4S,6R,10R) was confirmed by comparison of spectral and physical data with those reported.     

Total synthesis of naturally occurring cephalosporolides E/F

A modular total synthesis of cephalosporolides E/F featuring sequential epoxide–alkyne coupling and subsequent highly regioselective gold catalyzed alkynolcycloisomerization of the resulting alkynetetrol to construct the central spiroketal core has been documented.     

Total synthesis of (−)-petrosiol E

(−)-Petrosiol E, a metabolite of sponge Petrosia strongylata, has been synthesized in 32% overall yield from cheap natural d-xylose in 10 steps. Our strategy provides an efficient way for the total synthesis of other petrosiol members, featuring the three contiguous stereogenic centers are easily constructed from d-xylose chiral template.     

Total synthesis of the ansamycin antibiotic (+)-thiazinotrienomycin E

The first total synthesis of (+)-thiazinotrienomycin E (1), member of a novel class of cytotoxic ansamycin antibiotics, has been achieved. Key features of the synthetic strategy include (a) the efficient construction of sulfone 7 incorporating TBS protection of the aniline, (b) an improved synthesis of allyl chloride (-)-6, the advanced intermediate employed in our trienomycins A and F total syntheses, (c) application of the Kocienski modified Julia protocol to elaborate the E,E,E-triene subunit in a stereo-controlled fashion, (d) an efficient union of sulfone 7 with advanced iodide 62, and (e) Mukaiyama macrolactamization to access the thiazinotrienomycin macrocyclic ring.