Regio- and Stereoselective Synthesis of 3-Selenylazaflavanones and 3-Selenylflavanones via Electrochemically Facilitated Selenylation Cascade.

Herein, an oxidant- and metal-free electrochemical selenylation reaction of chalcones with diselenides for the synthesis of 3-selenylazaflavanones and 3-selenylflavanones at room temperature was reported. The method proceeded under mild conditions, exhibited a broad substrate scope, and provided the selenylated products in moderate to excellent yields with high regio- and stereoselectivity. The reaction could also be readily scaled up with high efficiency. Detailed mechanistic studies through control experiments disclosed that a selenium-based radical might participate in this electrochemical transformation.

The electrochemically enabled α-C(sp3)-H azolation of ketones.

C-H/N-H cross-coupling has become a key technology for the selective conjugation of azole drug molecules. However, the development of new synthetic models and green chemical methods is imperative to enhance the construction of multi-functional compounds and compounds with unique functional groups. We herein reported an electrochemical synthesis of α-tetrazolyl ketones with excellent yields and broad substrate scope, encompassing electron-donating and electron-withdrawing groups of aryl ketones, heterocycles, and alkyl and various ketone drugs. It was further proved that α-iodoketone was involved in this transformation of the reaction as a critical intermediate.

Selenium-Electrocatalytic Cyclization of 2-Vinylanilides towards Indoles of Peptide Labeling.

A novel selenium-electrocatalytic intramolecular cyclization of 2-vinylanilides for synthesis of functionalized indoles and azaindoles has been developed. In contrast to the previous synthetic methods, this sustainable protocol enabled unparalleled broad substrates scope for viable indoles with highly functional and sensitive groups by employing recyclable selenium catalyst, under mild, metal- and external-oxidant-free conditions. The approach can be used to the late-stage modification of complex bioactive molecular system, thereby setting the stage for versatile syntheses of decorated indoles with peptide labeling. A plausible catalytic pathway was proposed.

Discovery of an Orally Active and Long-Acting DPP-IV Inhibitor through Property-Based Optimization with an in Silico Biotransformation Prediction Tool.

Long-acting dipeptidyl peptidase IV inhibitors have emerged as promising molecules for interventions for type 2 diabetes. Once weekly dosing brings greater patient compliance and more stable glycemic control. Starting from our previous highly potent compound with a thienoprimidine scaffold, which is unfortunately severely hit by hepatic biotransformation, a lead compound was rapidly generated by drawing on the experience of our previously discovered long-acting compounds with pyrrolopyrimidine scaffold. With the aid of an in silico biotransformation prediction tool, (R)-2-((2-(3-aminopiperidin-1-yl)-4-oxo-6-(pyridin-3-yl)thieno[3,2-d]pyrimidin-3(4H)-yl)methyl)-4-fluorobenzonitrile was eventually generated and determined to have high potency, a fine pharmacokinetic profile, and a long-acting in vivo efficacy.

Electrochemical Oxidative Phosphorylation of Aldehyde Hydrazones.

The electrochemical phosphorylation of aldehyde hydrazones has been developed under exogenous oxidant-free conditions. The strategy provides expedient access to highly functionalized α-iminophosphine oxides with ample scope and broad functional group tolerance by means of mild, user-friendly electrolysis, in an undivided cell.

Discovery of Highly Potent Pinanamine-Based Inhibitors against Amantadine- and Oseltamivir-Resistant Influenza A Viruses.

Influenza pandemic is a constant major threat to public health caused by influenza A viruses (IAVs). IAVs are subcategorized by the surface proteins hemagglutinin (HA) and neuraminidase (NA), in which they are both essential targets for drug discovery. While it is of great concern that NA inhibitor oseltamivir resistant strains are frequently identified from human or avian influenza virus, structural and functional characterization of influenza HA has raised hopes for new antiviral therapies. In this study, we explored a structure-activity relationship (SAR) of pinanamine-based antivirals and discovered a potent inhibitor M090 against amantadine-resistant viruses, including the 2009 H1N1 pandemic strains, and oseltamivir-resistant viruses. Mechanism of action studies, particularly hemolysis inhibition, indicated that M090 targets influenza HA and it occupied a highly conserved pocket of the HA2 domain and inhibited virus-mediated membrane fusion by "locking" the bending state of HA2 during the conformational rearrangement process. This work provides new binding sites within the HA protein and indicates that this pocket may be a promising target for broad-spectrum anti-influenza A drug design and development.

Rapid generation of a novel DPP-4 inhibitor with long-acting properties: SAR study and PK/PD evaluation.

Drug compliance is critical for patients with chronic diseases such as diabetes. In our continuous effort to find better glucose-lowering agents, an exploration for long-acting DPP-4 inhibitors had been launched. Based on our previously reported compounds bearing a pyrrolopyrimidine scaffold, the lead compound 4a (IC50 = 2.3 nM, t1/2(rat) = 5.46 h) with pharmacokinetic superiority was rapidly determined. Further SAR study indicated that the pyrrole ring was generally tolerable for variation, in which a ß-substitution gave a better DPP-4 affinity. In depth evaluation of the pyrrole ring ß position identified a highly potent compound 12a (IC50 = 0.76 nM, t1/2(rat) = 7.89 h). In vivo pharmacodynamics tests demonstrated similar or even slightly better sustained DPP-4 inhibition for compounds 4a and 12a compared with the first marketed once-weekly drug trelagliptin in this category, indicating that improvements to DPP-4 inhibitory activity or pharmacokinetic profile might be feasible ways to rapidly generate long-acting DPP-4 inhibitors.

Microglia-Based Phenotypic Screening Identifies a Novel Inhibitor of Neuroinflammation Effective in Alzheimer's Disease Models.

Currently, anti-AD drug discovery using target-based approaches is extremely challenging due to unclear etiology of AD and absence of validated therapeutic protein targets. Neuronal death, regardless of causes, plays a key role in AD progression, and it is directly linked to neuroinflammation. Meanwhile, phenotypic screening is making a resurgence in drug discovery process as an alternative to target-focused approaches. Herein, we employed microglia-based phenotypic screenings to search for small molecules that modulate the release of detrimental proinflammatory cytokines. The identified novel pharmacological inhibitor of neuroinflammation (named GIBH-130) was validated to alter phenotypes of neuroinflammation in AD brains. Notably, this molecule exhibited comparable in vivo efficacy of cognitive impairment relief to donepezil and memantine respectively in both ß amyloid-induced and APP/PS1 double transgenic Alzheimer's murine models at a substantially lower dose (0.25 mg/kg). Therefore, GIBH-130 constitutes a unique chemical probe for pathogenesis research and drug development of AD, and it also suggests microglia-based phenotypic screenings that target neuroinflammation as an effective and feasible strategy to identify novel anti-AD agents.

[A novel dipeptidyl peptidase IV inhibitors developed through scaffold hopping and drug splicing strategy].

Though all the marketed drugs of dipeptidyl peptidase IV inhibitors are structurally different, their inherent correlation is worthy of further investigation. Herein we rapidly discovered a novel DPP-IV inhibitor 8g (IC50 = 4.9 nmol.L-1) which exhibits as good activity and selectivity as the market drugs through scaffold hopping and drug splicing strategies based on alogliptin and linagliptin. This study demonstrated that the employment of classic medicinal chemistry strategy to the marketed drugs with specific target is an efficient approach to discover novel bioactive molecules.

Highly potent dipeptidyl peptidase IV inhibitors derived from Alogliptin through pharmacophore hybridization and lead optimization.

The superposition of the DPP-IV complex revealed that the butynyl group of Linagliptin can be freely switched with the cyanobenzyl group of Alogliptin. Thus, a pharmacophore hybridization of Alogliptin was initiated and led to a novel DPP-IV inhibitor, 11a. Although it did not exhibit the desired activity (IC50=0.2 µM), compound 11a acts as a lead compound, which triggered a resulting structural optimization and the formation of compound 11m. A novel series of potent DPP-IV inhibitors represented by compound 11m (IC50=0.4 nM) was ultimately obtained with a robust pharmacokinetic profile and superior in vitro and in vivo efficacy compared to Alogliptin.

Discovery of potent dipeptidyl peptidase IV inhibitors through pharmacophore hybridization and hit-to-lead optimization.

A novel dipeptidyl peptidase IV inhibitor hit (5, IC50=0.86 µM) was structurally derived from our recently disclosed preclinical candidate 4 by replacing the cyanobenzyl with a butynyl based on pharmacophore hybridization. A hit-to-lead optimization effort was then initiated to improve its potency. Most N-substituted analogs exhibited good in vitro activity, and compound 18o (IC50=1.55 nM) was identified to be a potent dipeptidyl peptidase IV inhibitor with a significantly improved pharmacokinetic properties (bioavailablity: 41% vs 82.9%; T1/2: 2h vs 4.9h).

Design and synthesis of pinanamine derivatives as anti-influenza A M2 ion channel inhibitors.

The adamantanes are a class of anti-influenza drugs that inhibit the M2 ion channel of the influenza A virus. However recently, the clinical effectiveness of these drugs has been called into question due to the emergence of adamantane-insensitive A/M2 mutants. Although we previously reported (1R,2R,3R,5S)-3-pinanamine 3 as a novel inhibitor of the wild type influenza A virus M2 protein (WT A/M2), limited inhibition was found for adamantane-resistant M2 mutants. In this study, we explored whether newly synthesized pinanamine derivatives were capable of inhibiting WT A/M2 and selected adamantane-resistant M2 mutants. Several imidazole and guanazole derivatives of pinanamine were found to inhibit WT A/M2 to a comparable degree as amantadine and one of these compounds 12 exhibits weak inhibition of A/M2-S31N mutant and it is marginally more effective in inhibiting S31NM2 than amantadine. This study provides a new insight into the structural nature of drugs required to inhibit WT A/M2 and its mutants.

Novel pyrrolopyrimidine analogues as potent dipeptidyl peptidase IV inhibitors based on pharmacokinetic property-driven optimization.

We previously reported a highly potent DPP-IV inhibitor 6 with low in vivo efficacy. While trying to maintain consistent in vitro and in vivo biological activity, we initiated a pharmacokinetic property-driven optimization to improve the metabolic stability and permeability of inhibitor 6. A simple scaffold replacement of thienopyrimidine with pyrrolopyrimidine (21a) led to significantly improved metabolic stability (4% vs. 65% remaining). Further modification of the pyrrolopyrimidine scaffold to produce compound 21j resulted in much better oral bioavailability than 6. Importantly, compound 21j exhibits greater in vivo efficacy than does 6 and Alogliptin and is worthy of further development.

Identification of aminopyridazine-derived antineuroinflammatory agents effective in an Alzheimer's mouse model.

Targeting neuroinflammation may be a new strategy to combat Alzheimer's disease. An aminopyridazine 1b previously reported as a novel antineuroinflammatory agent was considered to have a potential therapeutic effect for Alzheimer's disease. In this study, we further explored the chemical space to identify more potent antineuroinflammatory agents and validate their in vivo efficacy in an animal model. Compound 14 was finally identified as an effective agent with comparable in vivo efficacy to the marketed drug donepezil in counteracting spatial learning and working memory impairment in an Aß-induced Alzheimer's mouse model.

Discovery of highly potent agents against influenza A virus.

We previously reported several new M2 inhibitors as active as amantadine against influenza A virus and validated by three types of in vitro assays. Herein, we further modified one of the most potent hits in a viral inhibition assay and conducted structure-activity relationship studies on this scaffold. As a result, compound 8e was identified to be the most potent inhibitor against wild-type influenza A virus, being nearly 240-fold more active than amantadine.

Identification of hits as matrix-2 protein inhibitors through the focused screening of a small primary amine library.

Although amantadine derivatives are the only M2 drugs for influenza virus A, their use is limited in the U.S. because of drug resistance. Here we report the identification of multiple M2 inhibitors that were rapidly generated through focused screening of a small primary amine library that was designed using a scaffold-hopping strategy based on amantadine. These compounds are as active as amantadine and might be hits for further lead generation processes.