Direct Catalytic Asymmetric Conjugate Addition of Benzofuran-3(2H)-ones to α,ß-Unsaturated Thioamides: Stereodivergent Synthesis of Rocaglaol.

Rocaglaol, a representative flavagline, has attracted significant attention because of its unique chemical structure and biological activities. This paper reports a mild and scalable copper-catalyzed enantioselective conjugate addition of benzofuran-3(2H)-one to α,ß-unsaturated thioamides. This method allows for the concise synthesis of all possible stereoisomers of a key intermediate of rocaglaol and its derivatives in a highly diastereo- and enantioselective manner using different chiral phosphine ligands. Theoretical insights into the reaction mechanism and the origin of ligand-dependent diastereodivergence were obtained using density functional theory calculations.

Asymmetric Syn-Selective Vinylogous Addition of Butenolides to Chromones via Al-Li-BINOL Catalysis.

A gram-scale syn-selective asymmetric vinylogous addition of butenolides to chromones, catalyzed by an Al-Li-BINOL (ALB) complex, was developed in this study. For various combinations of substrates, the observed diastereoselectivity approached 20:1 with 84-98% ee. This protocol is complementary to previously reported ones and improves the selectivity for several chromones. This methodology can be applied to a quinolone substrate, affording another type of heterocyclic scaffolds substituted with five-membered lactones. Computational studies support the role of ALB as a bifunctional catalyst in this reaction and provide insights into the origin of the observed stereoselectivity.

Synthesis of novobiocin derivatives and evaluation of their antigonococcal activity and pharmacokinetics.

Gonorrhea has become a serious problem because the number of infected people is increasing and the multi-drug resistance of the causative bacteria, Neisseria gonorrhoeae, is progressing. To develop novel drugs against resistant N. gonorrhoeae, we focused on the antibiotic novobiocin (1). This natural product has a different mechanism of action from existing drugs for gonorrhea, which may make it effective against resistant strains. Actually, it was applied to resistant N. gonorrhoeae, and moderate antibacterial activity was confirmed. Based on this result, we investigated the development of an antigonococcal drug with 1 as the lead compound. The pharmacophore is thought to be the noviose sugar moiety, especially around the 3'-position, so we derivatized this part in order to improve antibacterial activity. As a result, we found that 5 with an methylpyrrole ester structure have a very potent antibacterial activity. This derivative also showed excellent antigonococcal activity against resistant strains in vitro, however it has poor water solubility and pharmacokinetics because it is the acidic lipid-soluble compound. Therefore, we considered introduction of a basic substituent into the molecule would result in an amphoteric compound with improved water solubility, and we investigated further derivatization. As a result of synthesizing various derivatives, we found 47 containing imidazole with strong antigonococcal activity and greatly improved water solubility. This derivative has also improved metabolism and blood concentration in vivo, and is expected to be orally absorbed. Based on these results, we believe that 47 is a very promising anti-gonococcal lead compound and has great potential for further development.

Locking the Conformation of a Paddlewheel Rhodium Complex: Design, Synthesis, and Applications in Catalytic Nitrene Transfers.

The exponential proliferation of conformers makes it impossible to examine the entire population in most systems. Controlling conformational ensembles is thus pivotal in many areas of chemistry. Rh2 (esp)2 , a dicarboxylate-derived paddlewheel rhodium complex, is one of the most effective catalysts for nitrene chemistry. Its enormous success has led to preparing many analogous complexes. However, there has been little consideration for the conformational dynamics of the parent catalyst. Herein, we report a new ligand modification principle that prevents conformer interconversion. The resulting complex comprises two isolable conformers, whose structures have been determined by X-ray diffraction. Combined experimental and computational data has revealed similarities and dissimilarities between the conformationally confined and parent complexes. Three model cases have demonstrated the utility of conformational fixation in the development of stereoselective catalysts for nitrene transfer reactions. The design principle described in this study can be combined with other established modification strategies, serving as a springboard for further advancement of the chemistry of paddlewheel metal complexes.

Targeting the ATG5-ATG16L1 Protein-Protein Interaction with a Hydrocarbon-Stapled Peptide Derived from ATG16L1 for Autophagy Inhibition.

Selective modulation of autophagy is a promising therapeutic strategy, especially for cancer treatment. However, the lack of specific autophagy inhibitors limits this strategy. The formation of the ATG12-ATG5-ATG16L1 complex is essential for targeting the ATG12-ATG5 conjugate to proper membranes and to generate LC3-II for the progression of autophagy. Thus, targeting ATG5-ATG16L1 protein-protein interactions (PPIs) might inhibit early stage autophagy with high specificity. In this paper, we report that a stapled peptide derived from ATG16L1 exhibits potent binding affinity to ATG5, striking resistance to proteolysis, and significant autophagy inhibition activities in cells.

Synthesis and antiviral activity of formycin derivatives with anti-influenza virus activity.

In a screening using our unique natural product library, the C-nucleoside antibiotic formycin A, which exerts strong anti-influenza virus activity, was rediscovered. Aiming to develop a new type of anti-influenza virus drug, we synthesized new derivatives of formycin and evaluated its anti-influenza virus activity. Structural modifications were focused on the base moiety and sugar portion, respectively, and >40 novel formycin derivatives were synthesized. Modification of the C-7 position of the pyrazolopyrimidine ring strongly contributed to improve the activity. In particular, excellent anti-influenza virus activity was observed in the NHMe (10), SMe (12), and SeMe (15) derivatives, in which heteroatoms were introduced. In addition, in the modification of the sugar moiety, the presence of a hydroxyl group and its stereochemistry greatly affected both the expression and intensity of the activity. Furthermore, the evaluation results of the 7-SEt derivative (29) and the 2'-modified derivative (59) suggested that structural modifications may reduce cytotoxicity.

Oxygen-Fueled Iterative Hydride Transfer Driven by a Rigid Planar Architecture.

An iterative hydride reduction/oxidation process was promoted under ambient conditions by a quasi-planar iminium cation rigidified by two concatenated quinoline units. The iminium proton was fixed by hydrogen bonding from neighboring quinoline nitrogen atoms, rendering the imine highly susceptible to hydride reduction with weak reductants, e.g., 1,4-dihydropyridines. The thus-formed amine was readily oxidized by molecular oxygen to regenerate the quasi-planar iminium cation under ambient conditions. This process was exploited for catalytic oxidation of 1,4-dihydropyridines as well as 9,10-dihydroacridine to highlight an intriguing rigidity-driven catalysis.

A Missing Link in Multisubstituted Pyrrolidines: Remote Stereocontrol Forged by Rhodium-Alkyl Nitrene.

Pyrrolidines are significant N-heterocycles in medicinal chemistry and are among the top ten ring systems found in drug molecules. While simple derivatives are commercially available, densely decorated derivatives with precise stereochemical arrangements remain difficult to obtain. Methods for synthesizing multisubstituted pyrrolidines with nonadjacent stereocenters are particularly scarce. To bridge this gap, we report the stereoselective synthesis of remotely decorated, trisubstituted ß-prolines via Rh-catalyzed C-H amination. The transformation proceeds well in the presence of various functionalities with exclusive anti-selectivity. Carboxylic acids in the products serve as gateways for diverse downstream transformations. Furthermore, the combined experimental and computational study sheds lights on the origin of high diastereoselectivity.

Concise and Stereodivergent Approach to Chromanone Lactones through Copper-Catalyzed Asymmetric Vinylogous Addition of Siloxyfurans to 2-Ester-Substituted Chromones.

Vicinal oxygen-containing tetra- and tri-substituted stereocenters exist widely in chromanone lactone and tetrahydroxanthone natural products. Their enantioselective construction in a single step remains elusive and poses a formidable challenge for chemical synthesis. Here, we report the first copper(I)-catalyzed asymmetric vinylogous additions of siloxyfurans to 2-ester-substituted chromones, which enable concise and enantioselective assembly of chromanone lactones. Both syn and anti adducts can be accessed with excellent diastereo- and enantioselectivity by judicious choice of the chiral ligands. Our approach allowed for the efficient synthesis of (-)-blennolide B with precise stereochemical control, which provides a formal synthesis of secalonic acid A.

Catalytic Asymmetric Total Synthesis of Leucinostatin A.

This review describes our efforts toward achieving catalytic asymmetric total synthesis of leucinostatin A, a compound that interferes with the tumor-stroma interaction. The synthesis utilizes four catalytic asymmetric reactions, including direct-type reactions exemplified by high atom-economy, and three C-C bond forming reactions. Thorough analysis of the NMR data, HPLC profiles, and biologic activity led us to unambiguously revise the absolute configuration regarding the 6-position of the AHMOD residue side chain from S (reported) to R. Other examples of previously reported important studies on the stereoselective synthesis of HyLeu and AHMOD are also described.

Direct Catalytic Asymmetric Addition of Alkylnitriles to Aldehydes with Designed Nickel-Carbene Complexes.

A direct catalytic asymmetric addition of acetonitrile to aldehydes that realizes over 90 % ee is the ultimate challenge in alkylnitrile addition chemistry. Herein, we report achieving high enantioselectivity by the strategic use of a sterically demanding NiII pincer carbene complex, which afforded highly enantioenriched ß-hydroxynitriles. This highly atom-economical process paves the way for exploiting inexpensive acetonitrile as a promising C2 building block in a practical synthetic toolbox for asymmetric catalysis.

Inhibition of mitochondria ATP synthase suppresses prostate cancer growth through reduced insulin-like growth factor-1 secretion by prostate stromal cells.

Modulation of prostate stromal cells (PrSCs) within tumor tissues is gaining attention for the treatment of solid tumors. Using our original in vitro coculture system, we previously reported that leucinostatin (LCS)-A, a peptide mycotoxin, inhibited prostate cancer DU-145 cell growth through reduction of insulin-like growth factor 1 (IGF-I) expression in PrSCs. To further obtain additional bioactive compounds from LCS-A, we designed and synthesized a series of LCS-A derivatives as compounds that target PrSCs. Among the synthesized LCS-A derivatives, LCS-7 reduced IGF-I expression in PrSCs with lower toxicity to PrSCs and mice than LCS-A. As LCS-A has been suggested to interact with mitochondrial adenosine triphosphate (ATP) synthase, a docking study was performed to elucidate the mechanism of reduced IGF-I expression in the PrSCs. As expected, LCS-A and LCS-7 directly interacted with mitochondrial ATP synthase, and like LCS-A and LCS-7, other mitochondrial ATP synthase inhibitors also reduced the expression of IGF-I by PrSCs. Furthermore, LCS-A and LCS-7 significantly decreased the growth of mouse xenograft tumors. Based on these data, we propose that the mitochondrial ATP synthases-IGF-I axis of PrSCs plays a critical role on cancer cell growth and inhibition could be a potential anticancer target for prostate cancer.

Direct Catalytic Asymmetric Addition of α-Fluoronitriles to Aldehydes.

A fluorine-containing tetrasubstituted stereogenic center is a highly valued structural feature in medicinal chemistry. Herein, we describe the direct coupling of racemic α-fluoronitriles and aldehydes promoted by a chiral CuI /Barton's base catalytic system, delivering α-tetrasubstituted α-fluoro-ß-hydroxynitriles with satisfactory stereoselection. The stereochemical course was positively biased by the combined use of asymmetrical achiral thiourea as a supplementary ligand for CuI , which significantly enhanced the stereoselectivity. Both aromatic and aliphatic aldehydes were implemented to provide densely and stereoselectively functionalized chiral building blocks with aliphatic and aromatic tails.

Catalytic Asymmetric 1,3-Dipolar Cycloaddition of α,ß-Unsaturated Amide and Azomethine Imine.

α,ß-Unsaturated amides were incorporated as viable dipolarophiles in a catalytic asymmetric 1,3-dipolar cycloaddition of azomethine imines. The use of a 7-azaindoline auxiliary was essential to acquire sufficient reactivity with excellent diastereoselectivity, likely due to the chelating activation of the amide by the In(III)/bishydroxamic acid complex. Although the enantioselectivity remains unsatisfactory, this work is an important step toward the development of an asymmetric catalysis utilizing stable and low-reactive substrates.

Traceless Electrophilic Amination for the Synthesis of Unprotected Cyclic ß-Amino Acids.

Electrophilic aminations involve an umpolung of a nitrogen atom, providing an alternate, distinctive synthetic strategy. The recent advent of various designed O-substituted hydroxylamines has significantly advanced this research field. An underappreciated issue is atom economy of the transformations: The necessary activating group on the oxygen atom is left in coproduced waste. Herein, we describe Rh-catalyzed electrophilic amination of substituted isoxazolidin-5-ones for the synthesis of unprotected, cyclic ß-amino acids featuring either benzo-fused or spirocyclic scaffolds. Using the cyclic hydroxylamines allows for retaining both nitrogen and oxygen functionalities in the product. The traceless, redox neutral process proceeds on a gram scale with as little as 0.1 mol % catalyst loading. In contrast to related electrophilic aminations in the literature, a series of mechanistic experiments suggests a unique pathway involving spirocyclization, followed by the skeletal rearrangement. The insights provided herein shed light on a nuanced reactivity of the active species, Rh-nitrenoid generated from the activated hydroxylamine, and extend the knowledge on electrophilic aromatic substitutions.

Neighboring Protonation Unveils Lewis Acidity in the B3NO2 Heterocycle.

Boron serves a distinctive role in a broad range of chemistry disciplines. The utility of the element lies in its Lewis acidity, and thus, it is crucial to understand the properties of the boron atom in chemically different contexts. Herein, a combination of experiments and computations reveals the nuanced nature of boron in direct amidation reactions catalyzed by recently disclosed 1,3-dioxa-5-aza-2,4,6-triborinanes (DATBs). The most active DATB catalyst has been shown to bear an azaborine ring in its structure, thus having four boron atoms in a single molecule. Three chemically distinct boron atoms in the catalyst framework have been shown to serve different roles in the catalytic cycle, depending on their innate Lewis acidity. More specifically, the most Lewis acidic boron interacts with the amine, whereas the two boron atoms in the B-N-B substructure acquire Lewis acidity only upon protonation of the center nitrogen atom. Furthermore, although the least acidic boron atom in the azaborine ring did not act as a Lewis acid, it still plays an important role in the catalytic cycle by forming a hydrogen bond between carboxylic acid and the B-OH moiety. The mechanistic insights obtained from this study not only extend the knowledge on catalytic direct amidation but also provide a guiding principle for the further exploration of multi-boron compounds.

All Non-Carbon B3 NO2 Exotic Heterocycles: Synthesis, Dynamics, and Catalysis.

The B3 NO2 six-membered heterocycle (1,3-dioxa-5-aza-2,4,6-triborinane=DATB), comprising three different non-carbon period 2 elements, has been recently demonstrated to be a powerful catalyst for dehydrative condensation of carboxylic acids and amines. The tedious synthesis of DATB, however, has significantly diminished its utility as a catalyst, and thus the inherent chemical properties of the ring system have remained virtually unexplored. Here, a general and facile synthetic strategy that harnesses a pyrimidine-containing scaffold for the reliable installation of boron atoms is disclosed, giving rise to a series of Pym-DATBs from inexpensive materials in a modular fashion. The identification of a soluble Pym-DATB derivative allowed for the investigation of the dynamic nature of the B3 NO2 ring system, revealing differential ring-closing and -opening behaviors depending on the medium. Readily accessible Pym-DATBs proved their utility as efficient catalysts for dehydrative amidation with broad substrate scope and functional-group tolerance, offering a general and practical catalytic alternative to reagent-driven amidation.

A C4N4 Diaminopyrimidine Fluorophore.

A new scaffold for producing efficient organic fluorescent materials was identified: 2,5-diamino-4,6-diarylpyrimidine featuring a C4N4 elemental composition. Single-step installation of two aryl groups at the 4,6-positions of the pyrimidine core delivered fluorescent organic materials in a modular fashion. A range of fluorescent compounds with distinct absorption/emission properties was readily accessed by changing the aromatic attachments. A generally high absorption coefficient and quantum yield were observed, including C4N4 derivatives that could fluoresce even in the solid state. The two amino groups at the 2,5-positions of the pyrimidine were essential for intense fluorescence with a large Stokes shift, which was corroborated by structural relaxation to a p-iminoquinone-like structure in the excited state. Besides live-cell imaging capabilities, fluorescent labeling of a protein involved in autophagy elucidated a new protein-protein interaction, supporting potential utility in bioimaging applications.

A fluorogenic C4N4 probe for azide-based labelling.

The design, synthesis and photophysical properties of a new fluorogenic probe are described. The structure is based on the recently identified 2,5-diaminopyrimidine (C4N4) fluorophore. The strain-promoted [3 + 2] cycloaddition of the azido-C4N4 probe furnished a triazole that exhibited more than 30-fold enhancement in fluorescence intensity as compared to the azide.

On the Nitrogen Inversion of Isoxazolidin-5-ones.

The nitrogen inversion energies of a series of N-substituted isoxazolidin-5-ones were studied by density functional theory. The transition state energy was found to strongly correlate with the s-character of the lone pair of electrons on the nitrogen in the ground state. Although the activation energy trends for isxazolidin-5-ones and isoxazolidines are similar, their conformational equilibria are slightly different and the isoxazolidin-5-one inversion energies are generally higher.