A Concise Synthesis of Pleurotin Enabled by a Nontraditional C-H Epimerization

Synthesis and discovery of simplified pleurotin analogs bearing tricyclic core as novel thioredoxin reductase inhibitors

Pleurotin (1) is a benzoquinone meroterpenoid known for its wide-spectrum antitumor and antibiotic activities, notably acting as natural inhibitors of the thioredoxin reductase (TrxR). Pleurotin (1) has been chemically synthesized, but only in milligram quantities through at least 13 longest linear steps with 0.8 % overall yield due to its complex structure such as fused hexacyclic core with 8 contiguous stereocenters. Therefore, structural simplification strategy is applied to pleurotin natural products for their structure-activity relationship (SAR) study and further therapeutics development. Herein, we judiciously designed pleurotin analogs of tricyclic A/D/E ring core, retaining the putative pharmacophore of para-quinone moiety D and its supportive A and E rings. Thus 16 simplified analogs of pleurotin bearing tricyclic A/D/E core were readily synthesized in only 2 to 6 steps with up to 50 % overall yield from commercially available materials. Significantly, the best analog 14f with benzonitrile substituent exhibited more potent TrxR inhibitory activity with an IC50 of 3.5 μM than the positive control micheliolide (IC50 = 6.23 μM). Furthermore, the mechanism study revealed that compound 14f could induce apoptosis of tumor cells by inducing ROS generation and inhibiting TrxR activities. Our study for the first time showed that the tricyclic A/D/E ring scaffold from the natural product pleurotin (1) with proper substitution can maintain or even improve the TrxR inhibitory and antiproliferative activities, with high synthetic accessibility, affording natural product-derived lead compounds for the further development of TrxR inhibitors as anti-tumor therapeutics.

Atmosphere Effects on Arene Reduction with Lithium and Ethylenediamine in THF

Birch reductions employing lithium metal have been performed mostly under argon due to concerns about forming metal nitrides from the reduction of dinitrogen if performed under nitrogen. Although it is generally understood that inert atmospheres are standard for Birch and Birch-type (lithium, ethylenediamine, t-BuOH, THF) reductions, the atmosphere effect on Birch reduction has not been studied. Herein, we report the reduction of model substrates using lithium metal and ethylenediamine in THF under various atmospheric conditions. The reductions under argon and nitrogen atmospheres afforded essentially the same yields. Surprisingly, oxygen not only perturbed the yields in some cases but also controlled regioselectivity for a subset of naphthalenes. We propose a mechanism underlying the unexpected oxygen-dependent regioselectivity for the Birch-type reduction of naphthalenes. This work shows that the Birch-type reduction may be performed under a nitrogen atmosphere and may account for a fraction of oxygen-sensitive Birch-type reductions.

Concise Asymmetric Total Syntheses of (+)-Dihydropleurotinic Acid and (-)-Pleurotin, Enabling Rapid Late-Stage Diversification

(-)-Pleurotin (1) and (+)-dihydropleurotinic acid (2) are benzoquinone meroterpenoids isolated from fungal sources with powerful antitumor and antibiotic activities. Concise asymmetric total syntheses of the stereochemically pure (+)-dihydropleurotinic acid (2) and (-)-pleurotin (1) from the chiral pool (R)-Roche ester-derived vinyl bromide 7 have been achieved in 12 and 13 longest linear steps, respectively. The key transformations feature a Michael addition/alkylation cascade reaction to forge three contiguous stereocenters matched with the natural products, a PtO2-catalyzed stereoselective reduction of olefin to generate the correct stereocenter at C3, a palladium-catalyzed Negishi cross-coupling between triflate and zinc reagent to introduce the redox-sensitive para-quinone moiety, and a hydroboration/copper-catalyzed carboxylation sequence to incorporate the vital carboxyl group. Thus, the highly efficient and scalable preparation of pleurotin's pentacyclic skeleton enables the late-stage diversification, affording otherwise unavailable pleurotin analogs with significantly improved antiproliferative activities against the thioredoxin reductase (TrxR) overexpressed human breast cancer cell lines relative to the natural product pleurotin (1).

Early Steps of the Biosynthesis of the Anticancer Antibiotic Pleurotin

Pleurotin is a meroterpenoid specialized metabolite made by the fungus Hohenbuehelia grisea, and it is a lead anticancer molecule due to its irreversible inhibition of the thioredoxin-thioredoxin reductase system. Total synthesis of pleurotin has been achieved, including through a stereoselective route; however, its biosynthesis has not been characterized. In this study, we used isotope-labeled precursor feeding to show that the nonterpenoid quinone ring of pleurotin and its congeners is derived from phenylalanine. We sequenced the genome of H. grisea and used comparative transcriptomics to identify putative genes involved in pleurotin biosynthesis. We heterologously expressed a UbiA-like prenyltransferase from H. grisea that led to the accumulation of the first predicted pleurotin biosynthetic intermediate, 3-farnesyl-4-hydroxybenzoic acid. This work sets the foundation to fully elucidate the biosynthesis of pleurotin and its congeners, with long-term potential to optimize their production for therapeutic use and engineer the pathway toward the biosynthesis of valuable analogues.

Switchable Enantio- and Diastereoselective Michael Additions of β-Keto Amides to Nitroolefins: Crystallization-Based Inversion of Kinetic Stereocontrol

Asymmetric catalytic reactions rely on chiral catalysts that induce highly ordered transition states capable of imparting stereoselectivity in the bond-forming step(s). Productive deviations from this paradigm are rare yet hold the potential for accessing different stereoisomers using the same catalyst. Here, we present an enantio- and diastereoselective Michael addition of β-keto amides to nitroolefin electrophiles proceeding via an unusual scenario where the kinetic diastereocontrol imparted by the catalyst may be overridden by crystallization to provide the complementary stereoisomer of the product.

The sugar cube: Network control and emergence in stereoediting reactions

Stereochemical editing strategies have recently enabled the transformation of readily accessible substrates into rare and valuable products. Typically, site selectivity is achieved by minimizing kinetic complexity by using protecting groups to suppress reactivity at undesired sites (substrate control) or by using catalysts with tailored shapes to drive reactivity at the desired site (catalyst control). We propose "network control," a contrasting paradigm that exploits hidden interactions between rate constants to greatly amplify modest intrinsic biases and enable precise multisite editing. When network control is applied to the photochemical isomerization of hexoses, six of the eight possible diastereomers can be selectively obtained. The amplification effect can be viewed as a mesoscale phenomenon between the limiting regimes of kinetic control in simple chemical systems and metabolic regulation in complex biological systems.

A Unified Synthetic Approach to the Pleurotin Natural Products

The asymmetric total syntheses of four pleurotin natural products, namely, (-)-pleurotin, (+)-leucopleurotin, (+)-leucopleurotinic acid, and (+)-dihydropleurotinic acid, were described in a concise manner. Key transformations feature a Johnson-Claisen rearrangement, a diastereo-controlled sequential hydroboration-oxidation, a SOMO/photoredox activated aldehyde α-alkylation, and oxidative cyclizations.

Development of a Divergent Synthesis of Pleurotinoid Natural Products

Herein, we describe the evolution of our syntheses of the pleurotinoid natural products pleurotin (1), pleurogrisein (3), and 4-hydroxypleurogrisein (4). An approach based on a proximity-induced intramolecular Diels-Alder cycloaddition of a transient ortho-quinone dimethide (e.g., 6, Scheme 1) was inferior to an alternative construction featuring Gao's titanium(IV)-mediated photoenolization Diels-Alder coupling of ortho-tolualdehyde 20 with functionalized hydrindenone 22. While this pairing exhibited the desired stereoface selectivity and produced cis-fused hydrindanone 23, the successful realization of our syntheses of 1, 3, and 4 required a post-Diels-Alder epimerization of the unactivated stereocenter at C-5 in compound 23. Ultimately, it was possible to generate a reactive oxygen-centered radical via a reductive homolytic cleavage of the N-O bond in 23 and capitalize on its ability to break the C5-H bond in an intramolecular 1,5-hydrogen atom transfer (HAT). The carbon radical arising from this pivotal 1,5-HAT was subsequently trapped in situ by an exogenous thiol in a kinetically controlled HAT reaction to establish the natural configuration at C-5. The successful flipping of the cis-hydrindane in 23 to the challenging trans configuration in 24 provided a firm foundation for a formal synthesis of pleurotin (1), as well as syntheses of pleurogrisein (3) and 4-hydroxypleurogrisein (4).

Structural Design of Single-Atom Catalysts for Enhancing Petrochemical Catalytic Reaction Process

Petroleum, as the "lifeblood" of industrial development, is the important energy source and raw material. The selective transformation of petroleum into high-end chemicals is of great significance, but still exists enormous challenges. Single-atom catalysts (SACs) with 100% atom utilization and homogeneous active sites, promise a broad application in petrochemical processes. Herein, the research systematically summarizes the recent research progress of SACs in petrochemical catalytic reaction, proposes the role of structural design of SACs in enhancing catalytic performance, elucidates the catalytic reaction mechanisms of SACs in the conversion of petrochemical processes, and reveals the high activity origins of SACs at the atomic scale. Finally, the key challenges are summarized and an outlook on the design, identification of active sites, and the appropriate application of artificial intelligence technology is provided for achieving scale-up application of SACs in petrochemical process.

Radical Redox Annulations: A General Light-Driven Method for the Synthesis of Saturated Heterocycles

We introduce here a two-component annulation strategy that provides access to a diverse collection of five- and six-membered saturated heterocycles from aryl alkenes and a family of redox-active radical precursors bearing tethered nucleophiles. This transformation is mediated by a combination of an Ir(III) photocatalyst and a Brønsted acid under visible-light irradiation. A reductive proton-coupled electron transfer generates a reactive radical which undergoes addition to an alkene. Then, an oxidative radical-polar crossover step leading to carbocation formation is followed by ring closure through cyclization of the tethered nucleophile. A wide range of heterocycles are easily accessible, including pyrrolidines, piperidines, tetrahydrofurans, morpholines, δ-valerolactones, and dioxanones. We demonstrate the scope of this approach through broad structural variation of both reaction components. This method is amenable to gram-scale preparation and to complex fragment coupling.

Stereochemical editing logic powered by the epimerization of unactivated tertiary stereocenters

The stereoselective synthesis of complex targets requires the precise orchestration of chemical transformations that simultaneously establish the connectivity and spatial orientation of desired bonds. In this work, we describe a complementary paradigm for the synthesis of chiral molecules and their isomers, which tunes the three-dimensional structure of a molecule at a late stage. Key to the success of this strategy is the development of a mild and highly general photocatalytic method composed of decatungstate polyanion and disulfide cocatalysts, which enable the interconversion of unactivated tertiary stereogenic centers that were previously configurationally fixed. We showcase the versatility of this method-and the implementation of stereoediting logic-by the rapid construction of chiral scaffolds that would be challenging to access using existing tools and by the late-stage stereoediting of complex targets.