Discovery and Optimization of a Novel Series of Competitive and Central Nervous System-Penetrant Protease-Activated Receptor 4 (PAR4) Inhibitors.

The detailed pharmacology and therapeutic potential of the central PAR4 receptors are poorly understood due to a lack of potent, selective, and brain-penetrant tool compounds. Despite this, robust data with biochemical and genetic tools show the therapeutic potential of PAR4 antagonists in traumatic brain injury, Alzheimer's disease, Parkinson's disease, and other neurodegenerative disorders with a neuroinflammatory component. Thus, we performed a functional HTS campaign, identified a fundamentally new PAR4 competitive inhibitor chemotype, optimized this new series (increased potency >45-fold), discovered enantiospecific activity (though opposing preference for human versus mouse PAR4), and engendered high central nervous system penetration (rat Kp's of 0.52 to 4.2 and Kp,uu's of 0.52 to 1.2).

Lead optimization of the VU0486321 series of mGlu1 PAMs. Part 4: SAR reveals positive cooperativity across multiple mGlu receptor subtypes leading to subtype unselective PAMs.

Further optimization of the VU0486321 series of highly selective and CNS-penetrant mGlu1 PAMs identified unique 'molecular switches' on the central aromatic ring that engendered positive cooperativity with multiple mGlu subtypes across the receptor family, resulting in compounds with comparable activity at Group I (mGlu1/5) and Group III (mGlu4/6/7/8) mGlu receptors, receptors. These exciting data suggests this PAM chemotype appears to bind to multiple mGlu receptors, and that subtype selectivity is dictated by the degree of cooperativity, not a subtype selective, unique allosteric binding site. Moreover, there is interesting therapeutic potential for mGlu1/4/7/8 PAMs, as well as the first report of a GPCR allosteric 'privileged structure'.

Natural product-inspired aryl isonitriles as a new class of antimalarial compounds against drug-resistant parasites.

Malaria is a prevalent and deadly disease. The fast emergence of drug-resistant malaria parasites makes the situation even worse. Thus, developing new chemical entities, preferably with novel mechanisms of action, is urgent and important. Inspired by the complex and scarce isonitrile-containing terpene natural products, we evaluated a collection of easily prepared synthetic mono- and bis-isonitrile compounds, most of which feature a simple, but rigid stilbene backbone. From this collection, potent antimalarial lead compounds with EC50 value ranging from 27 to 88 nM against the Dd2 strain using a blood stage proliferation assay were identified. Preliminary SAR information showed that the isonitrile group is essential for the observed activity against the Dd2 strain and the bis-isonitrile compounds in general perform better than the corresponding mono-isonitrile compounds.

Preparation of 1,5-Dihydropyrazolo[3',4':5,6]pyrano[3,4- b]pyridines via a Microwave-Assisted, Palladium-Catalyzed Regioselective C-H Heteroarylation of Electron-Rich Pyrazoles.

Here we report the first synthesis of a family of novel heterocyclic compounds based on a 5-dihydropyrazolo[3',4':5,6]pyrano[3,4- b]pyridine core. In the course of our drug discovery programs, we had need to access the previously unknown 5-dihydropyrazolo[3',4':5,6]pyrano[3,4- b]pyridine core. Initial attempts required long reaction times, which led to degradation and side products. Reaction optimization identified a Pd-catalyzed, microwave-assisted C-H heteroarylation protocol for the rapid, general, and high yielding synthesis of this tricyclic core (as well as related analogs) suitable to drive optimization efforts.

Total Synthesis, Biological Evaluation, and Target Identification of Rare Abies Sesquiterpenoids.

Abiespiroside A (1), beshanzuenone C (2), and beshanzuenone D (3) belong to the Abies sesquiterpenoid family. Beshanzuenones C (2) and D (3) are isolated from the critically endangered Chinese fir tree species Abies beshanzuensis and demonstrated weak inhibiting activity against protein tyrosine phosphatase 1B (PTP1B). We describe herein the first total syntheses of these Abies sesquiterpenoids relying on the sustainable and inexpensive chiral pool molecule (+)-carvone. The syntheses feature a palladium-catalyzed hydrocarbonylative lactonization to install the 6,6-fused bicyclic ring system and a Dreiding-Schmidt reaction to build the oxaspirolactone moiety of these target molecules. Our chemical total syntheses of these Abies sesquiterpenoids have enabled (i) the validation of beshanzuenone C's weak PTP1B inhibiting potency, (ii) identification of new synthetic analogs with promising and selective protein tyrosine phosphatase SHP2 inhibiting potency, and (iii) preparation of azide-tagged probe molecules for target identification via a chemoproteomic approach. The latter has resulted in the identification and evaluation of DNA polymerase epsilon subunit 3 (POLE3) as one of the novel cellular targets of these Abies sesquiterpenoids and their analogs. More importantly, via POLE3 inactivation by probe molecule 29 and knockdown experiment, we further demonstrated that targeting POLE3 with small molecules may be a novel strategy for chemosensitization to DNA damaging drugs such as etoposide in cancer.

Investigation of aryl isonitrile compounds with potent, broad-spectrum antifungal activity.

Invasive fungal infections present a formidable global public health challenge due to the limited number of approved antifungal agents and the emergence of resistance to the frontline treatment options, such as fluconazole. Three fungal pathogens of significant concern are Candida, Cryptococcus, and Aspergillus given their propensity to cause opportunistic infections in immunocompromised individuals. New antifungal agents composed of unique chemical scaffolds are needed to address this public health challenge. The present study examines the structure-activity relationship of a set of aryl isonitrile compounds that possess broad-spectrum antifungal activity primarily against species of Candida and Cryptococcus. The most potent derivatives are capable of inhibiting growth of these key pathogens at concentrations as low as 0.5µM. Remarkably, the most active compounds exhibit an excellent safety profile and are non-toxic to mammalian cells even at concentrations up to 256µM. The present study lays the foundation for further investigation of aryl isonitrile compounds as a new class of antifungal agents.

Natural Product Synthesis via Palladium-Catalyzed Carbonylation.

Carbon monoxide is an important one-carbon source and can be incorporated in complex molecules via various transition-metal-catalyzed carbonylation reactions. In particular, palladium-catalyzed carbonylation reactions have found broad application in total synthesis of natural products. Examples are presented in this Synopsis to highlight recent progress in this area, including our own work in macrolide and spirocyclic molecule synthesis. In these selected cases, carbon monoxide functions as a one-carbon linchpin to facilitate building structural complexity and improving synthetic efficiency.

Radical Cyclopropanol Ring Opening Initiated Tandem Cyclizations for Efficient Synthesis of Phenanthridines and Oxindoles.

ß-Keto radicals can be readily generated from single-electron oxidation and ring opening of cyclopropanols. Herein, we report new ways of trapping ß-keto radicals derived from Mn(III)-mediated oxidative cyclopropanol ring opening with biaryl isonitriles and N-aryl acrylamides derived from anilines. Through tandem radical cyclization processes, substituted phenanthridines and oxindoles can be synthesized in one step and good to excellent yield. These new synthetic methods feature broad substrate scope and mild reaction conditions, efficiently form two carbon-carbon bonds, and use cheap and commercially available manganese salts as oxidants. Concomitant installation of ketone functionality in the final products provides a handle for further functionalization of these important and biologically relevant scaffolds.

Catalytic Carbonylative Spirolactonization of Hydroxycyclopropanols.

A palladium-catalyzed cascade carbonylative spirolactonization of hydroxycyclopropanols has been developed to efficiently synthesize oxaspirolactones common to many complex natural products of important therapeutic value. The mild reaction conditions, high atom economy, broad substrate scope, and scalability of this new method were highlighted in expedient total syntheses of the Turkish tobacco natural products α-levantanolide and α-levantenolide in two and four steps, respectively. The hydroxycyclopropanol substrates are readily available in one step via a Kulinkovich reaction of the corresponding lactones. Mechanistic studies utilizing high-resolution electrospray ionization mass spectrometry (ESI-MS) identified several key intermediates in the catalytic cycle, as well as those related to catalyst decomposition and competitive pathways.

Discovery and characterization of aryl isonitriles as a new class of compounds versus methicillin- and vancomycin-resistant Staphylococcus aureus.

Methicillin- and vancomycin-resistant Staphylococcus aureus (MRSA and VRSA) have emerged as a global health concern. A new class of compounds featuring an aryl isonitrile moiety has been discovered that exhibits potent inhibitory activity against several clinically-relevant MRSA and VRSA isolates. Structure-activity relationship studies have been conducted to identify the aryl isonitrile group as the key functional group responsible for the observed antibacterial activity. The most potent antibacterial aryl isonitrile analogs (MIC 2 µM) did not show any toxicity against mammalian cells up to a concentration of 64 µM.

Synthesis of tetrahydropyran/tetrahydrofuran-containing macrolides by palladium-catalyzed alkoxycarbonylative macrolactonizations.

A novel Pd-catalyzed cascade alkoxycarbonylative macrolactonization to construct tetrahydropyran/tetrahydrofuran-containing bridged macrolactones in one step from alkendiols is described. Products with various ring sizes and substituents were obtained. Challenging macrolactones involving tertiary alcohols were synthesized smoothly as well. Mechanistically, experimental evidence to support a trans-oxypalladation step has been provided. The method was applied to the synthesis of potent anticancer compound 9-demethylneopeltolide.