Christopher M. Tegley

Discovery of novel hydroxy-thiazoles as HIF-α prolyl hydroxylase inhibitors : SAR, synthesis, and modeling evaluation

Inhibition of the PHD2 enzyme has been associated with increased red blood cell levels. From a screening hit, a series of novel hydroxyl-thiazoles were developed as potent PHD2 inhibitors.

Kinetic characterization and identification of a novel inhibitor of hypoxia-inducible factor prolyl hydroxylase 2 using a time-resolved fluorescence resonance energy transfer-based assay technology.

The human hypoxia-inducible factor prolyl hydroxylases 1, 2, and 3 (HIF-PHD1, -2, and -3) are thought to act as proximal sensors of cellular hypoxia by virtue of their mechanism-based dependence on molecular oxygen. These 2-oxoglutarate (2-OG) and non-heme iron-dependent oxygenases constitutively hydroxylate HIF, resulting in high-affinity binding to Von Hippel-Lindau protein (pVHL). Some reported affinities for the HIF-PHDs for 2-OG and iron approach the estimated physiological concentrations for these cofactors, suggesting that the system as described is not catalytically optimal. Here we report the enzymatic characterization of full-length recombinant human HIF-PHD2 using a novel and sensitive catalytic assay. We demonstrated submicromolar affinities for 2-OG and ferrous iron and HIF-PHD2 Km values for oxygen that are greater than atmospheric oxygen levels, suggesting that molecular oxygen is indeed the key regulator of this pathway. In addition, we observed enhancement of HIF-PHD2 catalytic activity in the presence of ascorbic acid with only minor modifications of HIF-PHD2 requirements for 2-OG, and a detailed pH study demonstrated optimal HIF-PHD2 catalytic activity at pH 6.0. Lastly, we used this sensitive and facile assay to rapidly perform a large high-throughput screen of a chemical library to successfully identify and characterize novel 2-OG competitive inhibitors of HIF-PHD2.

Different Modes of Inhibitor Binding to Prolyl Hydroxylase by Combined Use of X-ray Crystallography and NMR Spectroscopy of Paramagnetic Complexes

In aqueous solution, azaquinolone inhibitors bind to prolyl 4-hydroxylase in two different orientations, as first detected by (19)F spectroscopy. This contrasts with the crystallographic structure where only one orientation has been determined. Dissection of the metal binding properties of the enzyme allowed structures of both complexes to be obtained in solution from (19)F and (13)C dipolar shifts in a labeled ligand.

Discovery of Ligands for Nurr1 by Combined Use of NMR Screening with Different Isotopic and Spin-Labeling Strategies

A comprehensive approach to target screening, hit validation, and binding site determination by nuclear magnetic resonance (NMR) spectroscopy is presented. NMR 19F signal perturbation was used to screen a small compound library and identify candidate ligands to the target of interest. Ligand dissociation constants were measured using a pegylated form of the protein, which resulted in a 2-fold increase in the strength of the saturation transfer difference signal. The initial small-molecule hits were further optimized by combining a residue-specific labeling strategy, to identify the specific sites of interaction with the protein, with a second site screening approach based on relaxation enhancement using a paramagnetic probe. The advantages of this combination strategy in the identification and optimization of weak binding chemical entities early in a program are illustrated with the discovery of a low micromolar ligand (Kd = 20 µM) for Nurr1 and identification of the binding site location through residue-specific 15N isotope labeling and derivatization of Cys residues with 2-mercaptoethanol-1-13C. (Journal of Biomolecular Screening 2007:301-311)

Discovery of 2-methylpyridine-based biaryl amides as γ-secretase modulators for the treatment of Alzheimer's disease.

γ-Secretase modulators (GSMs) are potentially disease-modifying treatments for Alzheimers disease. They selectively lower pathogenic Aβ42 levels by shifting the enzyme cleavage sites without inhibiting γ-secretase activity, possibly avoiding known adverse effects observed with complete inhibition of the enzyme complex. A cell-based HTS effort identified the sulfonamide 1 as a GSM lead. Lead optimization studies identified compound 25 with improved cell potency, PKDM properties, and it lowered Aβ42 levels in the cerebrospinal fluid (CSF) of Sprague-Dawley rats following oral administration. Further optimization of 25 to improve cellular potency is described.

Engineering Antibody Reactivity for Efficient Derivatization to Generate NaV1.7 Inhibitory GpTx-1 Peptide–Antibody Conjugates

The voltage-gated sodium channel NaV1.7 is a genetically validated pain target under investigation for the development of analgesics. A therapeutic with a less frequent dosing regimen would be of value for treating chronic pain; however functional NaV1.7 targeting antibodies are not known. In this report, we describe NaV1.7 inhibitory peptide-antibody conjugates as an alternate construct for potential prolonged channel blockade through chemical derivatization of engineered antibodies. We previously identified NaV1.7 inhibitory peptide GpTx-1 from tarantula venom and optimized its potency and selectivity. Tethering GpTx-1 peptides to antibodies bifunctionally couples FcRn-based antibody recycling attributes to the NaV1.7 targeting function of the peptide warhead. Herein, we conjugated a GpTx-1 peptide to specific engineered cysteines in a carrier anti-2,4-dinitrophenol monoclonal antibody using polyethylene glycol linkers. The reactivity of 13 potential cysteine conjugation sites in the antibody scaffold was tuned using a model alkylating agent. Subsequent reactions with the peptide identified cysteine locations with the highest conversion to desired conjugates, which blocked NaV1.7 currents in whole cell electrophysiology. Variations in attachment site, linker, and peptide loading established design parameters for potency optimization. Antibody conjugation led to in vivo half-life extension by 130-fold relative to a nonconjugated GpTx-1 peptide and differential biodistribution to nerve fibers in wild-type but not NaV1.7 knockout mice. This study describes the optimization and application of antibody derivatization technology to functionally inhibit NaV1.7 in engineered and neuronal cells.