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.     

Diastereoselective Total Synthesis of (±)‐Schindilactone A,Part 1: Construction of the ABC and FGH Ring Systems and Initial Attempts to Construct the CDEF Ring System

First‐generation synthetic strategies for the diastereoselective total synthesis of schindilactone A ( 1 ) are presented and methods for the synthesis of the ABC, FGH, and CDEF moieties are explored. We have established a method for the synthesis of the ABC moiety, which included both a Diels–Alder reaction and a ring‐closing metathesis as the key steps. We have also developed a method for the synthesis of the FGH moiety, which involved the use of a Pauson–Khand reaction and a carbonylative annulation reaction as the key steps. Furthermore, we have achieved the construction of the central 7–8 bicyclic ring system by using a [3,3]‐rearrangement as the key step. However, unfortunately, when this rearrangement reaction was applied to the construction of the more advanced CDEF moiety, the anticipated annulation reaction did not occur and the development of an alternative synthetic strategy would be required for the construction of this central core.     

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.     

Asymmetric Total Synthesis of Propindilactone G,Part 2: Enantioselective Construction of the Fully Functionalized BCDE Ring System

The enantioselective synthesis of the fully functionalized BCDE tetracyclic ring system of propindilactone G ( A ) is reported. Several synthetic methods were developed and applied to achieve this goal, including: 1) an asymmetric Diels–Alder reaction in the presence of Hayashi′s catalyst for the synthesis of optically pure key intermediate 3 ; 2) an intramolecular Pauson–Khand reaction (PKR) for the stereoselective synthesis of the BCDE ring with an all‐carbon chiral quaternary center at the C13 position by using the TMS‐substituted acetylene as the substrate; and 3) Pd‐catalyzed reductive hydrogenolysis for the stereoselective synthesis of the fully functionalized BCDE tetracyclic ring system. The chemistry developed herein provided a greater understanding of the total synthesis propindilactone G ( A ) and its analogues.     

Asymmetric Total Synthesis of Propindilactone G,Part 1: Initial Attempts towards the Synthesis of Schiartanes

Our first‐generation synthetic study towards the total synthesis of propindilactone G ( 1 ) and its analogues is reported. The key synthetic steps were an intramolecular Pauson–Khand reaction (PKR) and a vinylogous Mukaiyama reaction (VMAR). The stereoselective synthesis of the CDE ring moiety with an all‐carbon quaternary center through a PKR was difficult, whilst a VMAR afforded a product with the opposite stereochemistry at the C20 position on the side chain. These results led us to redesign our synthetic strategy for the total synthesis of compound 1 .     

Biomimetic Total Synthesis of (±)‐Pallavicinolide A

Piecing it together : The first total synthesis of naturally occurring diterpene pallavicinolide A was achieved. Notable features are highlighted by three key biomimetic transformations: a base‐promoted Grob fragmentation, a singlet oxygen oxidation, and an intramolecular Diels–Alder cycloaddition.

     

Enantiocontrolled Total Synthesis of (−)‐Mersicarpine

A racemic synthesis of mersicarpine ( 1 ) was achieved by the Mizoroki–Heck reaction and a DIBALH‐mediated reductive ring‐expansion reaction. Based on a first‐generation synthesis, a second‐generation enantiocontrolled total synthesis of (?)‐mersicarpine ( 1 ) was achieved by an 8‐pot/11‐step sequence in 21 % overall yield from commercially available 2‐ethylcyclohexanone. Subjection of a ketoester, which was prepared by an asymmetric Michael addition (according to the protocol by d’Angelo and Desmaële), and phenylhydrazine to modified Fischer indole conditions provided a six‐membered tricyclic indole. Benzylic oxidation and subsequent oxime formation provided a ketoxime, which was treated with diisobutylaluminum hydride (DIBALH) to construct the characteristic azepinoindole skeleton in good yield. In the DIBALH‐mediated reductive ring‐expansion reaction, gradually increasing the reaction temperature and in situ‐protection of the nitrogen in an oxygen‐sensitive azepinoindole with a benzyloxycarbonyl (Cbz) group were crucial for the high‐yielding process. With these methodologies, the short‐step and efficient synthesis of (?)‐mersicarpine was accomplished. Several synthetic efforts are also described.     

Total Synthesis of (±)‐Alstoscholarisine A

The first total synthesis of the neuroactive indole alkaloid (±)‐alstoscholarisine A is reported. The key step of the concise synthesis is an efficient domino sequence that was used to assemble the 2,8‐diazabicyclo[3.3.1]nonane core through the formation of two C?N bonds and one C?C bond in a single step.     

Diastereoselective Total Syntheses of (±)‐Caseabalansin A and (±)‐18‐Epicaseabalansin A via Intramolecular Robinson‐type Annulation

Highly diastereoselective total syntheses of (±)‐caseabalansin A ( 1 ) and (±)‐18‐epicaseabalansin A ( 2 ) are described in this paper. We revealed that the intramolecular Robinson‐type annulation of an alkynone was effective in the stereocontrolled construction of the bicyclic skeleton of 1 and 2 . Further transformation of the resulting enone, including diastereoselective reduction by LiAlH(OtBu)₃, hydroxy‐group‐directed hydrogenation, cyclization to form the cyclic acetal moiety, and introduction of a side chain by a C(sp³)?C(sp³) Stille coupling reaction, resulted in the total syntheses of (±)‐ 1 and (±)‐ 2 .     

Total Synthesis of (+)‐ and (±)‐Hosieine A

Described herein is a concise total synthesis of the highly potent nicotinic acetylcholine receptor ligand hosieine A in racemic and enantioenriched forms. The synthesis requires only seven steps and features a telescoped reaction sequence initiated by a gold‐catalyzed Rautenstrauch reaction.     

Total Synthesis of (±)‐Phomoidride D

Described herein is a synthetic strategy for the total synthesis of (±)‐phomoidride D. This highly efficient and stereoselective approach provides rapid assembly of the carbocyclic core by way of a tandem phenolic oxidation/intramolecular Diels–Alder cycloaddition. A subsequent SmI₂‐mediated cyclization cascade delivers an isotwistane intermediate poised for a Wharton fragmentation that unveils the requisite bicyclo[4.3.1]decene skeleton and sets the stage for synthesis completion.     

Total Synthesis of (±)‐Aspidophylline A

A total synthesis of aspidophylline A, a pentacyclic akuammiline‐type monoterpene indole alkaloid, is described. The synthesis features: 1) rapid access to a fully functionalized dihydrocarbazole through the desymmetrization of readily available 2‐allyl‐2‐(o‐nitrophenyl)cyclohexane‐1,3‐dione; 2) an intramolecular azidoalkoxylation of an enecarbamate to install both the furoindoline ring and the azido functionality; and 3) an intramolecular Michael addition for the construction of the 2‐azabicyclo[3.3.1]nonane ring system.