Elucidation of the Concise Biosynthetic Pathway of the Communesin Indole Alkaloids

The communesins are a prominent class of indole alkaloids isolated from Penicillium species. Owing to their daunting structural framework and potential as pharmaceuticals, communesins have inspired numerous synthetic studies. However, the genetic and biochemical basis of communesin biosynthesis has remained unexplored. Herein, we report the identification and characterization of the communesin (cns) biosynthetic gene cluster from Penicillium expansum. We confirmed that communesin is biosynthesized by the coupling of tryptamine and aurantioclavine, two building blocks derived from L ‐tryptophan. The postmodification steps were mapped by targeted‐gene‐deletion experiments and the structural elucidation of intermediates and new analogues. Our studies set the stage for the biochemical characterization of communesin biosynthesis. This knowledge will aid our understanding of how nature generates remarkable structural complexity from simple precursors.     

Exploration of the interrupted Fischer indolization reaction

A convergent method to access the fused indoline ring system present in a multitude of bioactive molecules has been developed. The strategy involves the condensation of hydrazines with latent aldehydes to ultimately deliver indoline-containing products by way of an interrupted Fischer indolization sequence. The method is convergent, mild, operationally simple, broad in scope, and can be used to access enantioenriched products. In addition, our approach is amenable to the synthesis of furoindoline and pyrrolidinoindoline natural products as demonstrated by the concise formal total syntheses of physovenine and debromoflustramine B. The strategy will likely enable the synthesis of more complex targets such as the communesin alkaloids.     

Concise Total Synthesis of Dehaloperophoramidine

Perophoramidine, dehaloperophoramidine, and communesin F are structurally related alkaloids having intriguing polycyclic structures. A strategy for the synthesis of dehaloperophoramidine has been developed. In this synthesis all skeletal atoms and all functional groups required to reach the target molecule are incorporated early in the sequence. This approach led to the discovery of two novel substrate‐specific domino processes, one encompassing four steps and the other comprising five steps, thus resulting in an eight‐step synthesis of dehaloperophoramidine.     

Asymmetric Brønsted Acid Catalyzed Synthesis of Triarylmethanes—Construction of Communesin and Spiroindoline Scaffolds

Aza‐ortho‐quinone methides allow the straightforward asymmetric synthesis of natural‐product‐inspired indole scaffolds possessing a quaternary stereocenter. Our approach provides access to diverse communesin and spiroindoline derivatives with high enantioselectivity under mild reaction conditions. Predictable substitution patterns are found to be the key to our regiodivergent protocols.     

Asymmetric Total Syntheses of Communesin F and a Putative Member of the Communesin Family

Here we report asymmetric total syntheses of communesin F and a putative member of the communesin family of bis‐aminal alkaloid natural products. The successful strategy featured the invention of an asymmetric organocatalytic reaction to unify two oxindole subunits, a Ti(OⁱPr)₄‐mediated dehydrative skeletal rearrangement, and a late‐stage Pd(OAc)₂‐catalyzed directed CH‐alkenylation reaction. Collectively, the synthetic technologies disclosed herein enabled the preparation of a late‐stage polycyclic intermediate catered for the synthesis of both naturally occurring and designed communesins. More importantly, speculated and yet to be discovered member(s) of the communesin family can now be accessed to facilitate a better understanding of the communesin biosynthetic network.     

Interrupted Fischer Indolization Approach toward the Communesin Alkaloids and Perophoramidine

A concise approach toward the total synthesis of the communesin alkaloids and perophoramidine is reported. The strategy relies on the use of the interrupted Fischer indolization to build the tetracyclic indoline core of the natural products. Studies to probe the scope and limitations of this plan are presented. Although the methodology does not tolerate a C8-allyl substituent en route to the challenging vicinal quaternary stereocenters, variation at C7 and on the C ring is permitted.     

Total Syntheses of Aurachins A and B

Aurachins A and B are alkaloids having 3‐hydroxyquinoline N‐oxide cores. An efficient method for the synthesis of 3‐hydroxyquinoline N‐oxides was established and is amenable to the total syntheses of aurachins A and B. Alkylation of 1‐(2‐nitrophenyl)butan‐2‐one with farnesyl bromide took place selectively at the benzylic position, and subsequent treatment of the alkylated product with sodium tert‐butoxide in dimethyl sulfoxide gave aurachin B. Alkylation of 1‐(2‐nitrophenyl)butan‐2‐one with an epoxy iodide derived from farnesol was used to access aurachin A.     

It all began with an error: the nomofungin/communesin story

The communesin/nomofungin/perophoramidine story is an impressive example of how biogenetic considerations can lead to the correction of structural misassignments and inspire synthetic chemists with new, fruitful ideas. Intensive studies by a number of research groups culminated in the total synthesis of perophoramidine by the Funk research group in 2004. In 2007, Qin and co-workers completed the first total synthesis of a communesin.     

Enantioselective,Protecting‐Group‐Free Total Synthesis of Sarpagine Alkaloids—A Generalized Approach

A generalized synthetic access to sarpagine alkaloids through a joint synthetic sequence has been accomplished. Its applicability is showcased by the enantioselective total syntheses of vellosimine ( 1 ), N‐methylvellosimine ( 3 ), and 10‐methoxyvellosimine ( 8 ). The synthetic sequence is concise (eight steps) from known compound 13 , and requires no protecting groups. The indole heterocycle was introduced in the last step. This strategy allows access to sarpagine alkaloids through a shared synthetic route leading to precursor 10 , which we term “privileged intermediate”. Starting from this intermediate, all sarpagine alkaloids can be synthesized using phenylhydrazines with different substitution patterns ( 15 – 17 ). Our approach brings about the advantage, that synthesis optimization only needs to be performed once for many natural products. The key features of the synthesis are a [5+2]‐cycloaddition and a ring enlargement.     

Molybdenum-catalyzed asymmetric allylic alkylation of 3-alkyloxindoles: reaction development and applications

We report a full account of our work towards the development of Mo‐catalyzed asymmetric allylic alkylation reactions with 3‐alkyloxindoles as nucleophiles. The reaction is complementary to the Pd‐catalyzed reaction with regard to the scope of oxindole nucleophiles. A number of 3‐alkyloxindoles were alkylated successfully under mild conditions to give products with excellent yields and good‐to‐excellent enantioselectivities. Applications of this method to the preparation of indoline alkaloids such as (?)‐physostigmine, ent‐(?)‐debromoflustramine B, and the indolinoquinoline rings of communesin B are reported.     

A Divergent Synthetic Route to the Vallesamidine and Schizozygine Alkaloids: Total Synthesis of (+)‐Vallesamidine and (+)‐14,15‐Dehydrostrempeliopine

The total synthesis of representative members of the schizozygine alkaloids, (+)‐vallesamidine and (+)‐14,15‐dehydrostrempeliopine, were completed from a late‐stage divergent intermediate. The synthesis took advantage of efficient nitro‐group reactions with the A/B/C ring skeleton constructed concisely on a gram scale through an asymmetric Michael addition, nitro‐Mannich/lactamisation, Tsuji–Trost allylation, and intramolecular C?N coupling reaction. Other key features of the synthesis are a novel [1,4] hydride transfer/Mannich‐type cyclisation to build ring E and a diastereoselective ring‐closing metathesis reaction to construct ring D. This approach gave access to a late‐stage C14,C15 alkene divergent intermediate that could be simply transformed into (+)‐vallesamidine, (+)‐14,15‐dehydrostrempeliopine, and potentially other schizozygine alkaloids and unnatural derivatives.     

Synthetic strategies directed to the antitumour alkaloids sesbanimide A and manzamine A

Synthons derived from nature's chiral pool have been utilized in developing strategies aimed at the syntheses of the alkaloids sesbanimide A and manzamine A. The route designed for sesbanimide A has provided the naturally occurring alkaloid and a facile access to several analogues for structure-activity relationship studies. The approach to the synthesis of manzamine A has led to a strategically functionalized chiral tricyclic intermediate possessing the absolute stereochemistry of the natural product. Recent results on the synthesis of sesbanimide analogues and the progress towards the total synthesis of manzamine A is described.     

Highly Efficient Formal [2+2+2] Strategy for the Rapid Construction of Polycyclic Spiroindolines: A Concise Synthesis of 11‐Demethoxy‐16‐epi‐myrtoidine

A novel formal [2+2+2] strategy for the stereoselective elaboration of polycyclic indole alkaloids is described. Upon treatment with the catalyst InCl₃ (5 mol %), tryptamine‐derived enamides reacted readily with methylene malonate, thus enabling rapid and gram‐scale access to versatile tetracyclic spiroindolines with excellent diastereoselectivity (21 examples, up to 95 % yield, up to d.r.>95:5). This strategy provides a concise approach to alkaloids isolated from Strychnos myrtoides, as demonstrated by a short synthesis of 11‐demethoxy‐16‐epi‐myrtoidine.     

A Concise Total Synthesis of (−)‐Himalensine A

The daphniphyllum alkaloids are a structurally fascinating and remarkably diverse family of natural products. General strategies for the chemical synthesis of their challenging architectures are highly desirable for efficiently accessing these intriguing alkaloids and addressing their pharmaceutical potential. Herein, a concise strategy designed to provide general and diversifiable access to various daphniphyllum alkaloids is described and utilized in the asymmetric synthesis of (?)‐himalensine A, which was accomplished in 14 steps. Key features of this strategy include a Cu‐catalyzed nitrile hydration, a Heck reaction to construct the challenging 2‐azabicyclo[3.3.1]nonane motif, a Meinwald rearrangement reaction, six, pot‐economic reactions, and the minimal use of protecting groups, which significantly improved the overall synthetic efficiency.     

An Indoxyl‐Based Strategy for the Synthesis of Indolines and Indolenines

An indoxyl‐based strategy for the synthesis of indolines and indolenines via unprecedented aza‐pinacol and aza‐semipinacol rearrangements was developed. This method provides direct access to the core structures of several classes of indole alkaloids. The synthetic utility was demonstrated by the divergent synthesis of an array of functionalized polycyclic structures from a common intermediate and the formal total synthesis of the indoline natural product minfiensine. The reversed reactivity of indoxyl as a building block compared to that of indole offers a conceptually distinct disconnection strategy for indoline‐ and indolenine‐containing heterocycles and natural products.     

A Concise and Versatile Synthesis of Alkaloids from Kopsia tenuis: Total Synthesis of (±)‐Lundurine A and B

A total synthesis of (±)‐lundurines A and B is described. These natural products have a unique hexacyclic skeleton which includes a cyclopropane‐fused indoline. A stereospecific construction of the pentasubstituted cyclopropane core was achieved, by radical cyclization using SmI₂, with perfect stereoselectivity. Cyclizations to give seven‐ and five‐membered heterocycles, under palladium and ruthenium catalysis, respectively, accomplished the total syntheses. The late‐stage construction of the F ring by ring‐closing metathesis enabled access to the title compounds from a spiroindoline intermediate which is a common structure of other kopsia alkaloids.     

Total Synthesis of (+)‐Minfiensine: Construction of the Tetracyclic Core Structure by an Asymmetric Cascade Cyclization

A new method for one‐step construction of the tetracyclic core structure of the indole alkaloid (+)‐minfiensine was developed utilizing a palladium‐catalyzed asymmetric indole dearomatization/iminium cyclization cascade. An efficient total synthesis of (+)‐minfiensine was realized using this strategy. The present method enables access to the common core structure of a series of monoterpene indole alkaloids, such as vincorine, echitamine, and aspidosphylline A.     

Xylochemistry—Making Natural Products Entirely from Wood

The first total synthesis of the dimeric berberine alkaloid ilicifoline (ilicifoline B) is reported. Its carbon skeleton is constructed from ferulic acid, veratrole, and methanol. The synthesis reported herein employs starting materials solely derived from wood. The natural product is thus constructed entirely from renewable resources. The same strategy is applied to a formal total synthesis of morphinan alkaloids. The use of wood‐derived building blocks (xylochemicals) instead of the conventional petrochemicals represents a sustainable alternative to classical synthetic approaches.     

Total Synthesis of (+)‐Madangamine D

Madangamines are a group of bioactive marine sponge alkaloids, embodying an unprecedented diazapentacyclic skeletal type. The enantioselective total synthesis of madangamine D has been accomplished, and represents the first total synthesis of an alkaloid of the madangamine group. It involves the stereoselective construction of the diazatricyclic ABC core using a phenylglycinol‐derived lactam as the starting enantiomeric scaffold and the subsequent assembly of the peripheral macrocyclic rings. The synthesis provides, for the first time, a pure sample of madangamine D and confirms the absolute configuration of this alkaloid family.     

Fawcettimine‐Type Lycopodium Alkaloids as a Driving Force for Discoveries in Organic Synthesis

Ever since the pioneering synthetic work reported by both Inubushi and Heathcock back in 1980s, the fawcettimine‐type Lycopodium alkaloids have continuously served as a driving force for discoveries in organic synthesis. In this personal account, we summarized our recent synthetic efforts towards the total synthesis of fawcettimine‐type Lycopodium alkaloids, along with a brief summary of relevant syntheses reported by others. Our discussions focus mainly on the key reactions applied during the synthesis of fawcettimine‐type Lycopodium alkaloids.