Photocatalytic Activation of Elemental Sulfur Enables a Chemoselective Three-Component Thioesterification

Rhodium-Catalyzed Tandem Reaction of N-(Pivaloyloxy)acrylamides with 1,3-Diynes for the Synthesis of Furo[2,3-b]pyridines

We disclose a rhodium-catalyzed tandem reaction of N-(pivaloyloxy)acrylamides with 1,3-diynes for the efficient synthesis of furo[2,3-b]pyridines. This unique tandem reaction includes C-H activation, Lossen rearrangement, [4+2] annulation, and [3+2] annulation in "one pot", which features readily available substrates, broad functional group compatibility, and the ability to isolate pure products through simple filtration under ambient conditions with excellent regioselectivity, selectivity for mono- or diannulation, and intra- and intermolecular annulation selectivity. Furthermore, this synthetic protocol facilitates the rapid construction of a diverse library of blue-emitting molecules with high quantum yields, providing a valuable platform for developing advanced functional materials.

Photocatalytic C-C bond thio(seleno)esterification of 1,2-diketone-derived pro-aromatic intermediates

We report an organophotocatalyst-enabled oxidant-free C-S/C-Se bond coupling of (un)symmetrical 1,2-diketones via pro-aromatic dihydroquinazolinones/benzothiazolines, employing readily accessible disulfides/diselenides. In this scalable and redox-neutral method, various dialkyl, di(hetero)aryl, and alkyl-aryl 1,2-diketones are expediently converted to S-aryl (S-alkyl) alkyl/(hetero)aryl thioesters and Se-alkyl aryl selenoesters with broad functional group compatibility in high efficiency.

Unconventional Synthetic Approaches to Unusual Peptide Derivatives

Peptides that contain unusual motifs, such as non-proteinogenic amino acids (AAs) and/or macrocyclic substructures, have recently attracted great attention as a new modality in medium-sized-molecule drug discovery. Therefore, it is highly important to develop methods for the chemical synthesis of a wide variety of such unusual peptide derivatives, which are often difficult to prepare via conventional synthetic approaches. In this review, the development of unconventional approaches for the synthesis of unusual peptide derivatives is discussed. Specifically, a novel external-oxidant-mediated decarboxylative condensation of α-ketoacids that can be applied to the synthesis of a wide variety of unusual peptide derivatives is reported. Moreover, an organocatalytic asymmetric Mannich-type addition is discussed that provides chiral β-amino-α-ketoacids, which are required as starting materials for the decarboxylative condensation. In this reaction, the adducts corresponding to various unusual AA side chains are obtained in high yield and excellent stereoselectivity. Furthermore, the "N-chloropeptide strategy" is proposed as a new method for the chemical modification of peptides without the need for a reactive AA residue.

Visible-light-induced cascade chromone cyclization/chalcogenation to access 3-chalcogenyl-chromones using elemental sulfur/selenium

A mild and efficient visible-light-induced cascade undergoing a chromone cyclization/chalcogenation at room temperature has been developed. This three-component reaction employs user-friendly elemental S8 and Se as the chalcogenide source, providing an attractive route for the convenient synthesis of 3-chalcogenyl-chromones with a wide substrate scope and good functional group tolerance.

Photochemical Synthesis of Thioesters from Aryl Halides and Carboxylic Acids

Thioesters are important in synthesis, materials science, and biology, and their preparation traditionally relies on the use of disagreeable thiols. Here, we report a thiol-free protocol that stitches together widespread carboxylic acids and aryl halides, producing a diverse array of thioesters. Crucial to this strategy is the discovery that tetramethylthiourea can serve as both a sulfur source and, upon direct excitation by purple light, as a strong reductant, suitable for activating aryl halides via single-electron transfer. Coupling of the resulting aryl radicals provides an isothiouronium ion intermediate, which can be attacked by carboxylic acids via a polar pathway, affording the thioester products under mild conditions.

Ambient-Light-Promoted Stereospecific Synthesis of (Z)-Vinyl Thioesters under Solvent- and Catalyst-Free Conditions

An ambient-light-promoted stereospecific olefinic C(sp2)-S bond construction of thioacids and 1,1-diarylethenes has been demonstrated, affording various (Z)-vinyl thioesters in 51-85% yields under solvent- and catalyst-free conditions. Mechanistic studies indicated that the formation of thioacid-olefin complexes is responsible for generating a carbonyl thiyl radical and dioxygen in the air participates in the reaction and functions as a traceless reagent. Moreover, synthetic applications have been demonstrated by the gram scale synthesis and aggregation-induced emission property of representative compound 3i.

Synthesis of thioesters using an electrochemical three-component reaction involving elemental sulfur

An electrochemical three-component reaction involving elemental sulfur is disclosed for achieving a metal-free, oxidant-free synthesis of thioesters in a high atom-economical, step-economical and chemoselective manner. A mechanistic investigation indicates that the use of elemental sulfur to trap acyl radical derived from radical umpolung of α-keto acid with an electrochemical design can efficiently generate a carbonyl thiyl radical, which can further be captured by diazoalkane to afford various thioesters.

Electro-oxidative three-component cascade coupling of isocyanides with elemental sulfur and amines for the synthesis of 2-aminobenzothiazoles

2-Aminobenzothiazoles are commonly encountered in various functional compounds. Herein, we disclose an electro-oxidative three-component reaction for the effective synthesis of 2-aminobenzothiazoles under mild conditions, utilizing non-toxic and abundant elemental sulfur as the sulfur source. Both aliphatic amines and aryl amines demonstrate good compatibility at room temperature, highlighting the broad functional group tolerance of this approach. Additionally, elemental selenium demonstrated reactivities comparable to those of elemental sulfur.

Multimodal Acridine Photocatalysis Enables Direct Access to Thiols from Carboxylic Acids and Elemental Sulfur

Development of photocatalytic systems that facilitate mechanistically divergent steps in complex catalytic manifolds by distinct activation modes can enable previously inaccessible synthetic transformations. However, multimodal photocatalytic systems remain understudied, impeding their implementation in catalytic methodology. We report herein a photocatalytic access to thiols that directly merges the structural diversity of carboxylic acids with the ready availability of elemental sulfur without substrate preactivation. The photocatalytic transformation provides a direct radical-mediated segue to one of the most biologically important and synthetically versatile organosulfur functionalities, whose synthetic accessibility remains largely dominated by two-electron-mediated processes based on toxic and uneconomical reagents and precursors. The two-phase radical process is facilitated by a multimodal catalytic reactivity of acridine photocatalysis that enables both the singlet excited state PCET-mediated decarboxylative carbon-sulfur bond formation and the previously unknown radical reductive disulfur bond cleavage by a photoinduced HAT process in the silane-triplet acridine system. The study points to a significant potential of multimodal photocatalytic systems in providing unexplored directions to previously inaccessible transformations.

Visible-Light-Mediated Synthesis of Thioesters Using Thiocarboxylic Acid as the Dual Reagent

We have developed a visible-light-driven method for thioester synthesis that relies on the unique dual role of thiobenzoic acids as one-electron reducing agents and reactants leading to the formation of sulfur radical species. This synthetic process offers a wide scope, accommodating various thioacid and thiol substrates without the need for a photocatalyst.

Direct Synthesis of Thioesters from Feedstock Chemicals and Elemental Sulfur

The development of a mild, atom- and step-economical catalytic strategy that effectively generates value-added molecules directly from readily available commodity chemicals is a central goal of organic synthesis. In this context, the thiol-ene click chemistry for carbon-sulfur (C-S) bond construction has found widespread applications in the synthesis of pharmaceuticals and functional materials. In contrast, the selective carbonyl thiyl radical addition to carbon-carbon multiple bonds remains underdeveloped. Herein, we report a carbonyl thiyl radical-based thioester synthesis through three-component coupling from feedstock aldehydes, alkenes, or alkynes and elemental sulfur by direct photocatalyzed hydrogen atom transfer. This method represents an orthogonal strategy to the conventional thiol-based nucleophilic substitution and exhibits a remarkably broad substrate scope ranging from simple commodity chemicals such as ethylene and acetylene to complex pharmaceutical molecules. This protocol can be easily extended to the synthesis of thiolactones, oligomer/polymers, and thioacids. Its synthetic utility has been demonstrated by a two-step synthesis of the drug esonarimod. Mechanistic studies indicate that the use of elemental sulfur to trap acyl radicals is both thermodynamically and kinetically favored, illustrating its great potential for the synthesis of sulfur-containing molecules.

Selective oxidative β-C-H bond sulfenylation of tetrahydroisoquinolines with elemental sulfur

In this article, a convenient and efficient KIO₃-promoted oxidative sulfenylation at the β-position of tetrahydroisoquinolines and subsequent aromatization in the presence of elemental S₈ is presented. The reaction proceeds with moderate to good yields via a double C-S formation process. A wide range of structurally diverse 4-sulfenylisoquinolines/3-sulfenylpiperidine were synthesized with excellent functional group tolerance and high efficiency.

Elemental sulfur as the “S” source: visible-light-mediated four-component reactions leading to thiocyanates

An eco-friendly and photocatalyst-free visible-light-promoted four-component reaction of α-diazoesters, elemental sulfur, cyclic ethers and TMSCN leading to thiocyanates is described.