Candice Hacker scite author profile

Glucagon is a 29-amino acid peptide that is an important counter-regulatory hormone in the control of glucose homeostasis (1). Glucagon secretion from the endocrine pancreas induces an increase in hepatic glycogenolysis and gluconeogenesis, and it attenuates the ability of insulin to inhibit these processes. As such, the overall rates of hepatic glucose synthesis and glycogen metabolism are controlled by the systemic ratio of insulin and glucagon (2, 3). Therefore, glucagon antagonists have the potential to improve hepatic insulin sensitivity and to be effective hypoglycemic agents.Peptidyl glucagon antagonists and their hypoglycemic activity were first described over 15 years ago, and an extensive exploration of the structure/activity relationships of these glucagon analogs has been reported (4 -6). The hepatic receptor for glucagon was cloned recently (7,8), confirming that it is a member of the seven-transmembrane domain, G-protein-coupled receptor superfamily. This receptor superfamily has a binding pocket for small-molecule ligands within the transmembrane domain that has made it possible to identify nonpeptidyl antagonists for many receptor families in which the endogenous ligands are small peptides or proteins (9). Thus, we initiated an effort to identify non-peptidyl, orally active antagonists for the human glucagon receptor.Collins et al. (10) have described a dichloroquinoxaline glucagon antagonist with weak affinity (IC 50 ϭ 4 M) for the rat glucagon receptor. However, there have been no subsequent reports in the patent or scientific literature describing the development of potent antagonists from this series. Our initial screening efforts identified a series of triarylimidazole and triarylpyrrole compounds with significant binding affinity for the human glucagon receptor, and efforts to evaluate the structure-activity relationships of this series have lead to the identification of potent glucagon antagonists (11). In the present article, we describe the identification and characterization of a potent glucagon antagonist from this series. MATERIALS AND METHODSCharacterization of Binding Affinity and Functional Activity-Stable CHO 1 cell lines or COS cells transiently expressing the human glucagon receptor were prepared as described previously (8, 12). Antagonist binding affinity was assessed by measuring inhibition of radiolabeled glucagon binding to CHO cell membranes. Briefly, 125 I-glucagon (58 pM) binding to the membrane preparation was measured in 20 mM Tris, pH 7.4, containing 1 mM dithiothreitol, 5 g/ml leupeptin, 10 g/ml benzamidine, 40 g/ml bacitracin, 5 g/ml soybean trypsin inhibitor, and 3 M o-phenanthroline Ϯ 1 M glucagon for 1 h at room temperature. Bound cpm were recovered by filtration using a Tomtec harvester and quantified in a ␥-scintillation counter.The ability of compound to inhibit glucagon-stimulated adenylyl cyclase was assessed as described previously (12). Briefly, cells were harvested from monolayers with enzyme-free cell dissociation solution (Specialty Media, Inc.) and were...

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Potent, orally absorbed glucagon receptor antagonists

Laszlo

Hacker

et al. 1999

Bioorganic & Medicinal Chemistry Letters

168

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Molecular Basis for p38 Protein Kinase Inhibitor Specificity

Lisnock¹,

Tebben²,

Frantz³

et al. 1998

Biochemistry

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p38 is a member of the mitogen-activated protein (MAP) kinase family and is a critical enzyme in the proinflammatory cytokine pathway. Other MAP kinase group members that share both structural and functional homology to p38 include the c-Jun NH2-terminal kinases (JNKs or SAPKs) and the extracellular-regulated protein kinases (ERKs). In this study, we determined the molecular basis for p38alpha inhibitor specificity exhibited by five compounds in the diarylimidazole, triarylimidazole, and triarylpyrrole classes of protein kinase inhibitors. These compounds are significantly more potent inhibitors of p38 compared to the JNKs and ERKs. Three active site ATP-binding domain residues in p38, T106, M109, and A157, selected based on primary sequence alignment, molecular modeling, and X-ray crystal structure data, were mutated to assess their role in inhibitor binding and enzymatic catalysis. All mutants, with the exception of T106M, had kinase activity within 3-fold of wild-type p38. Mutation of T106 to glutamine, the residue present at the corresponding position in ERK-2, or methionine, the corresponding residue in p38gamma, p38delta, and the JNKs, rendered all five inhibitors ineffective. The diarylimidazoles had approximately a 6-fold decrease in potency toward M109A p38. For the mutant A157V, all diarylimidazoles and triarylimidazoles tested were 5-10-fold more potent compared with wild-type p38. In contrast, two triarylpyrroles were 15-40-fold less potent versus A157V p38. These results showed that the molecular basis for the specificity of the p38 inhibitors was attributed largely to threonine 106 in p38 and that methionine 109 contributes to increased binding affinity for imidazole based inhibitors.

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Pyrroles and other heterocycles as inhibitors of P38 kinase

Laszlo

Visco

Agarwal

et al. 1998

Bioorganic & Medicinal Chemistry Letters

119

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Molecular Basis for p38 Protein Kinase Inhibitor Specificity

Lisnock¹,

Tebben²,

Frantz³

et al. 1999

Biochemistry

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Candice Hacker

Characterization of a Novel, Non-peptidyl Antagonist of the Human Glucagon Receptor

Potent, orally absorbed glucagon receptor antagonists

Molecular Basis for p38 Protein Kinase Inhibitor Specificity

Pyrroles and other heterocycles as inhibitors of P38 kinase

Molecular Basis for p38 Protein Kinase Inhibitor Specificity

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