Enantioselective Total Synthesis of (+)‐Plumisclerin A

The first and enantioselective total synthesis of (+)‐plumisclerin A, a novel unique complex cytotoxic marine diterpenoid, has been accomplished. Around the central cyclopentane anchorage, a sequential ring‐formation protocol was adopted to generate the characteristic tricycle[4.3.1.0^1,5]decane and trans‐fused dihyrdopyran moiety. Scalable enantioselective La^III‐catalyzed Michael reaction, palladium(0)‐catalyzed carbonylation and SmI₂‐mediated radical conjugate addition were successfully applied in the synthesis, affording multiple grams of the complex and rigid B/C/D‐ring system having six continuous stereogenic centers and two all‐carbon quaternary centers. The trans‐fused dihyrdopyran moiety with an exo side‐chain was furnished in final stage through sequential redox transformations from a lactone precursor, which overcome the largish steric strain of the dense multiring system. The reported total synthesis also confirms the absolute chemistries of natural (+)‐plumisclerin A.     

A Biomimetic Synthesis of (±)‐Basiliolide B

A highly diastereoselective and practical biomimetic total synthesis of (±)‐basiliolide B has been achieved through the study of the two proposed biosynthetic pathways (O‐methylation and O‐acylation) for the unprecedented 7‐methoxy‐4,5‐dihydro‐3H‐oxepin‐2‐one (C ring). The synthesis featured a cyclopropanation/ring opening strategy for establishing the stereogenic centers at C8 and C9, a biomimetic 2‐pyrone Diels–Alder cycloaddition for the synthesis of the ABD ring system, and finally a highly efficient biomimetic intramolecular O‐acylation for the C ring formation. This result provides an important perspective on the biosynthetic origin of the unprecedented 7‐membered acyl ketene acetal moiety of the C ring.     

Iodine‐Catalyzed Highly Diastereoselective Synthesis of trans‐2,6‐Disubstituted‐3,4‐Dihydropyrans: Application to Concise Construction of C28–C37 Bicyclic Core of (+)‐Sorangicin A

A novel iodine‐catalyzed highly diastereoselective synthesis of trans‐2,6‐disubstituted‐3,4‐dihydropyrans have been achieved from δ‐hydroxy α,β‐unsaturated aldehydes by treating with allyltrimethyl silane in THF at room temperature with good to excellent yields. This methodology has been successfully implemented for a concise asymmetric synthesis of C28–C37 dioxabicyclo[3.2.1]octane ring system of (+)‐sorangicin A in 8 steps with 21 % overall yield.     

Enantioselective Total Synthesis of (+)‐Ophiobolin A

The enantioselective total synthesis of (+)‐ophiobolin A is described. This total synthesis features the construction of the spiro CD ring of (+)‐ophiobolin A through a stereoselective intramolecular Hosomi–Sakurai cyclization reaction, the joining of the A ring to the CD ring by using a reaction reported by Utimoto, and the construction of the ophiobolin eight‐membered carbocyclic ring through ring‐closing metathesis (RCM), which was performed for the first time in this study. This successful RCM reaction required the use of a substrate that contained either a benzyloxy or a methoxymethoxy group at the C5 position and either an isopropenyl group or its hydroxylated form at the C6 position.     

Total Synthesis of Potent Antitumor Agent (−)‐Lasonolide A: A Cycloaddition‐Based Strategy

A detailed account of the enantioselective total synthesis of (?)‐lasonolide A is described. Our initial synthetic route to the top tetrahydropyran ring involved Evans asymmetric alkylation as the key step. Initially, we relied on the diastereoselective alkylation of an α‐alkoxyacetimide derivative containing an α′ stereogenic center and investigated such an asymmetric alkylation reaction. Although alkylation proceeded in good yield, the lack of diastereoselectivity prompted us to explore alternative routes. Our subsequent successful synthetic strategies involved highly diastereoselective cycloaddition routes to both tetrahydropyran rings of lasonolide A. The top tetrahydropyran ring was constructed stereoselectively by an intramolecular 1,3‐dipolar cycloaddition reaction. The overall process constructed a bicyclic isoxazoline, which was later unravelled to a functionalized tetrahydropyran ring as well as a quaternary stereocenter present in the molecule. The lower tetrahydropyran ring was assembled by a Jacobsen catalytic asymmetric hetero‐Diels–Alder reaction as the key step. The synthesis also features a Lewis acid catalyzed epoxide opening to form a substituted ether stereoselectively.     

Diastereoselective Total Synthesis of (±)‐Schindilactone A,Part 3: The Final Phase and Completion

The final phase for the total synthesis of (±)‐schindilactone A ( 1 ) is described herein. Two independent synthetic approaches were developed that featured Pd–thiourea‐catalyzed cascade carbonylative annulation reactions to construct intermediate 3 and a RCM reaction to make intermediate 4 . Other important steps that enabled the completion of the synthesis included: 1) A Ag‐mediated ring‐expansion reaction to form vinyl bromide 17 from dibromocyclopropane 30 ; 2) a Pd‐catalyzed coupling reaction of vinyl bromide 17 with a copper enolate to synthesize ketoester 16 ; 3) a RCM reaction to generate oxabicyclononenol 10 from diene 11 ; 4) a cyclopentenone fragment in substrate 8 was constructed through a Co–thiourea‐catalyzed Pauson–Khand reaction (PKR); 5) a Dieckmann‐type condensation to successfully form the A ring of schindilactone A ( 1 ). The chemistry developed for the total synthesis of schindilactone A ( 1 ) will shed light on the synthesis of other family members of schindilactone A.     

Total Synthesis of (±)‐Hippolachnin A

The first total synthesis of the marine polyketide (±)‐hippolachnin A has been achieved in nine linear steps and an overall yield of 9 %. Rapid access to the oxacyclobutapentalene core structure was secured by strategic application of an ene cyclization.     

29Si NMR Investigation of Si‐alkylsubstituted 1,3,5‐Trisilacyclohexanes

²⁹Si NMR spectra of 29 Si‐alkylsubstituted derivatives of 1,3,5‐trisilacyclohexanes have been recorded and analyzed. A systematic preparation of alkyl derivatives with mixed substituents made it possible to evaluate substituent‐induced chemical shift (SCS) values for the ring silicon atoms in α and γ position. It is found that the equatorial α‐effect increases in the order Me < Et < i‐Pr < t‐Bu. For the alkyl groups Me, Et, and i‐Pr the axial α‐effect is similar in magnitude to the α_e‐effect. Axial SCS values for the t‐Bu group are not accessible because chair conformations with an axial t‐Bu group are energetically unfavourable and escape into a twisted boat form. The observed γ‐effects exhibit the γ_gauche‐effect for axial substituents as known from compounds with a pure carbon framework.     

Diastereoselective Total Synthesis of (±)‐Schindilactone A,Part 2: Construction of the Fully Functionalized CDEFGH Ring System

The successful synthesis of the highly complex model compound ( 2 ) of the CEFGH ring system of schindilactone A ( 1 ) is described. Several synthetic methodologies were developed and applied to achieve this goal, including ring‐closing metathesis (RCM) and Co–thiourea‐catalyzed Pauson–Khand reactions. Furthermore, two independent approaches were developed for the construction of the GH ring of model compound 2 , the key steps of which included Pd–thiourea‐catalyzed carbonylative annulation, methylation, and sequential RCM/oxa‐Michael‐addition reactions. The chemistry developed herein has provided a greater understanding of the synthesis of schindilactone A ( 1 ) and its analogous compounds of the same family.     

One‐Pot Protection‐Glycosylation Reactions for Synthesis of Lipid II Analogues

(2,6‐Dichloro‐4‐methoxyphenyl)(2,4‐dichlorophenyl)methyl trichloroacetimidate ( 3 ) and its polymer‐supported reagent 4 can be successfully applied to a one‐pot protection‐glycosylation reaction to form the disaccharide derivative 7 d for the synthesis of lipid II analogues. The temporary protecting group or linker at the C‐6 position and N‐Troc protecting group of 7 d can be cleaved simultaneously through a reductive condition. Overall yields of syntheses of lipid II ( 1 ) and neryl‐lipid II N^ε‐dansylthiourea are significantly improved by using the described methods.     

Synthesis and Biophysical Studies on 35‐Deoxy Amphotericin B Methyl Ester

The use of molecular editing in the elucidation of the mechanism of action of amphotericin B is presented. A modular strategy for the synthesis of amphotericin B and its designed analogues is developed, which relies on an efficient gram‐scale synthesis of various subunits of amphotericin B. A novel method for the coupling of the mycosamine to the aglycone was identified. The implementation of the approach has enabled the preparation of 35‐deoxy amphotericin B methyl ester. Investigation of the antifungal activity and efflux‐inducing ability of this amphotericin B congener provided new clues to the role of the 35‐hydroxy group and is consistent with the involvement of double barrel ion channels in causing electrolyte efflux.     

Studies of a Diazo Cyclopropanation Strategy for the Total Synthesis of (−)‐Lundurine A

The bioactive Kopsia alkaloids lundurines A–D are the only natural products known to contain indolylcyclopropane. Achieving their syntheses can provide important insights into their biogenesis, as well as novel synthetic routes for complex natural products. Asymmetric total synthesis of (?)‐lundurine A has previously been achieved through a Simmons–Smith cyclopropanation strategy. Here, the total synthesis of (?)‐lundurine A was carried out using a metal‐catalyzed diazo cyclopropanation strategy. In order to avoid a carbene C?H insertion side reaction during cyclopropanation of α‐diazo‐ carboxylates or cyanides, a one‐pot, copper‐catalyzed Bamford–Stevens diazotization/diazo decomposition/cyclopropanation cascade was developed, involving hydrazone. This approach simultaneously generates the C/D/E ring system and the two chiral quaternary centers at C2 and C7.