Chiral N-benzyl-N-methyl-1-(naphthalen-1-yl)ethanamines and their in vitro antifungal activity against Cryptococcus neoformans, Trichophyton mentagrophytes and Trichophyton rubrum

The discovery of novel antifungal phenylpyridines derivatives based on CYP53 binding model

Benzoates as toxic intermediate are naturally produced by fungal intracellular metabolism, and CYP53 can specific transform the substrates. In the study, we constructed the CYP53 homology model and analyzed the corresponding active region. At the same time, the molecular docking and the structure-based pharmacophore model (SBP) were performed to explore the bind mode of representative CYP53 inhibitors. On the basis, a series of phenylpyridines derivatives were designed as novel CYP53 inhibitors, and their molecular structures were synthesized and evaluated. Compared with the positive control groups, their antifungal activity showed the obvious upward trend. In particular, target compounds (13a, 15b) possessed the excellent biological activity against pathogenic fungi and drug-resistant fungi in vivo and in vitro. The preliminary action mechanism has confirmed that target compounds could inhibit CYP53 activity, and block the metabolism of toxic intermediates (Benzoates). This further induced the accumulation of reactive oxygen species (ROS) through the pattern of mitochondrial depolarization, which eventually caused fungal lysis and death. In summary, the study provided the reasonable computational models, and effectively guided the generation of novel CYP53 antifungal inhibitors.

Dynamic Kinetic Resolution-Enabled Highly Stereoselective Nucleophilic Fluoroalkylation to Access Chiral β-Fluoro Amines

β-Fluorinated amine is highly desirable for biological and pharmaceutical science, because replacing a C-H bond with a C-F bond can change the physical and chemical properties of the parent molecule to a large extent but not significantly alter its overall geometry. Herein, the highly stereoselective nucleophilic monofluoromethylation of imines have been developed. It is proposed that the chelated transition state enables the chiral induction by the dynamic kinetic resolution of the chiral α-fluoro carbanions.

A tandem reduction of primary amines, carbonyl compounds, CO2, and boranes catalyzed by in situ formed frustrated Lewis pairs

A catalytic system combining 2-aminothiazole and borane efficiently catalyzes a four-component tandem reductive coupling of primary amines, carbonyl compounds, boranes, and CO2 (1 atm) and a broad range of functionalized tertiary N-methylamines are synthesized.

Direct electrochemical hydrodefluorination of trifluoromethylketones enabled by non-protic conditions

CF₂H groups are unique due to the combination of their lipophilic and hydrogen bonding properties. The strength of H-bonding is determined by the group to which it is appended. Several functional groups have been explored in this context including O, S, SO and SO₂ to tune the intermolecular interaction. Difluoromethyl ketones are under-studied in this context, without a broadly accessible method for their preparation. Herein, we describe the development of an electrochemical hydrodefluorination of readily accessible trifluoromethylketones. The single-step reaction at deeply reductive potentials is uniquely amenable to challenging electron-rich substrates and reductively sensitive functionality. Key to this success is the use of non-protic conditions enabled by an ammonium salt that serves as a reductively stable, masked proton source. Analysis of their H-bonding has revealed difluoromethyl ketones to be potentially highly useful dual H-bond donor/acceptor moieties.

The electrochemical hydrodefluorination of trifluoromethylketones under non-protic conditions make this single-step reaction at deeply reductive potentials uniquely amenable to challenging electron-rich substrates and reductively sensitive functionalities.

Butenafine and analogues: An expeditious synthesis and cytotoxicity and antifungal activities

The incidence of fungal infections is considered a serious public health problem worldwide. The limited number of antimycotic drugs available to treat human and animal mycosis, the undesirable side effects and toxicities of the currently available drugs, and the emergence of fungal resistance emphasizes the urgent need for more effective antimycotic medicines. In this paper, we describe a rapid, simple, and efficient synthetic route for preparation of the antifungal agent butenafine on a multigram scale. This novel synthetic route also facilitated the preparation of 17 butenafine analogues using Schiff bases as precursors in three steps or less. All the synthesized compounds were evaluated against the yeast, Cryptococcus neoformans/C. gattii species complexes and the filamentous fungi Trichophyton rubrum and Microsporum gypseum. Amine 4bd, a demethylated analogue of butenafine, and its corresponding hydrochloride salt showed low toxicity in vitro and in vivo while maintaining inhibitory activity against filamentous fungi.

Construction of highly functionalized naphthalenes using an in situ ene–allene strategy

Construction of highly functionalized naphthalene derivatives remains a challenging task for organic chemists because of the effect of the substituent.