Barry G. Shearer

Hepatocyte Nuclear Factor 4 Is a Transcription Factor that Constitutively Binds Fatty Acids.

The 2.7 A X-ray crystal structure of the HNF4gamma ligand binding domain (LBD) revealed the presence of a fatty acid within the pocket, with the AF2 helix in a conformation characteristic of a transcriptionally active nuclear receptor. GC/MS and NMR analysis of chloroform/methanol extracts from purified HNF4alpha and HNF4gamma LBDs identified mixtures of saturated and cis-monounsaturated C14-18 fatty acids. The purified HNF4 LBDs interacted with nuclear receptor coactivators, and both HNF4 subtypes show high constitutive activity in transient transfection assays, which was reduced by mutations designed to interfere with fatty acid binding. The endogenous fatty acids did not readily exchange with radiolabeled palmitic acid, and all attempts to displace them without denaturing the protein failed. Our results suggest that the HNF4s may be transcription factors that are constitutively bound to fatty acids.

Recent advances in peroxisome proliferator-activated receptor science.

The peroxisome proliferator-activated receptor (PPAR) family of nuclear receptors, a set of three receptor sub-types encoded by distinct genes, function as lipid sensors to regulate a broad range of genes in many metabolically active tissues. Synthetic PPAR agonists have exhibited therapeutic benefits in treating diabetes and cardiovascular diseases. The discovery of PPAR-specific ligands has led to significant advancement in our understanding of the structure of these receptor proteins and the molecular mechanism of their ligand-dependent activation. Herein, we present both recent progress in the functional analysis of these orphan receptors and the confirmation of the PPARs as molecular targets for the development of new medicines to treat human metabolic disease.

S-2-NAPHTHYLMETHYL THIOACETIMIDATE HYDROBROMIDE : A NEW ODORLESS REAGENT FOR THE MILD SYNTHESIS OF SUBSTITUTED ACETAMIDINES

Abstract The development, synthesis and use of S-2-naphthylmethyl thioacetimidate hydrobromide 7 as a highly reactive reagent for the mild conversion of amines to substituted acetamidines in a nonodorous process is described.

Discovery of a novel class of PPARδ partial agonists

Anthranilic acid GW9371 was identified as a novel class of PPARdelta partial agonist through high-throughput screening. The design and synthesis of SAR analogues is described. GSK1115 and GSK7227 show potent partial agonism of the PPARdelta target genes CPT1a and PDK4 in skeletal muscle cells.

Discovery of GSK1997132B a novel centrally penetrant benzimidazole PPARγ partial agonist

The peroxisome proliferator-activated receptor γ (PPARγ) is a ligand-activated nuclear receptor, thought to play a role in energy metabolism, glucose homeostasis and microglia-mediated neuroinflammation. A novel benzimidazole series of centrally penetrant PPARγ partial agonists has been identified. The optimization of PPARγ activity and in vivo pharmacokinetics leading to the identification of GSK1997132B a potent, metabolically stable and centrally penetrant PPARγ partial agonist, is described.

Conformationally restricted arginine analogues as inhibitors of human nitric oxide synthase

Abstract Conformationally restricted analogues of the endogenous NOS substrate l -arginine and the arginine based NOS inhibitors NG-methyl- l -arginine ( l -NMA) and Nδ-iminoethyl- l -ornithine ( l -NIO) were synthesized for evaluation as inhibitors of human NOS. Incorporation of a phenyl ring into the C4C5 backbone chain provided 2-aminophenylalanine analogues which retained potent NOS inhibition. Structurally related analogues of 3-aminophenylalanine were significantly weaker inhibitors.

Phenoxyacetic acids as PPARδ partial agonists: Synthesis, optimization, and in vivo efficacy

A series of phenoxyacetic acids as subtype selective and potent hPPARδ partial agonists is described. Many analogues were readily accessible via a single solution-phase synthetic route which resulted in the rapid identification of key structure-activity relationships (SAR), and the discovery of two potent exemplars which were further evaluated in vivo. Details of the SAR, optimization, and in vivo efficacy of this series are presented herein.

2,4-Diamino-8-quinazoline carboxamides as novel, potent inhibitors of the NAD hydrolyzing enzyme CD38: Exploration of the 2-position structure-activity relationships

Starting from 4-amino-8-quinoline carboxamide lead 1a and scaffold hopping to the chemically more tractable quinazoline, a systematic exploration of the 2-substituents of the quinazoline ring, utilizing structure activity relationships and conformational constraint, resulted in the identification of 39 novel CD38 inhibitors. Eight of these analogs were 10-100-fold more potent human CD38 inhibitors, including the single digit nanomolar inhibitor 1am. Several of these molecules also exhibited improved therapeutic indices relative to hERG activity. A representative analog 1r exhibited suitable pharmacokinetic parameters for in vivo animal studies, including moderate clearance and good oral bioavailability. These inhibitor compounds will aid in the exploration of the enzymatic functions of CD38, as well as furthering the study of the therapeutic implications of NAD enhancement in metabolic disease models.

Recent Advances in Peroxisome Proliferator- Activated Receptor Science

The peroxisome proliferator-activated receptor (PPAR) family of nuclear receptors, a set of three receptor sub-types encoded by distinct genes, function as lipid sensors to regulate a broad range of genes in many metabolically active tissues. Synthetic PPAR agonists have exhibited therapeutic benefits in treating diabetes and cardiovascular diseases. The discovery of PPAR-specific ligands has led to significant advancement in our understanding of the structure of these receptor proteins and the molecular mechanism of their ligand-dependent activation. Herein, we present both recent progress in the functional analysis of these orphan receptors and the confirmation of the PPARs as molecular targets for the development of new medicines to treat human metabolic disease.