Magda N. Kosmopoulou

Kinetic and crystallographic studies on 2‐(β‐D‐glucopyranosyl)‐5‐methyl‐1, 3, 4‐oxadiazole, ‐benzothiazole, and ‐benzimidazole, inhibitors of muscle glycogen phosphorylase b. Evidence for a new binding site

In an attempt to identify leads that would enable the design of inhibitors with enhanced affinity for glycogen phosphorylase (GP), that might control hyperglycaemia in type 2 diabetes, three new analogs of β‐D‐glucopyranose, 2‐(β‐D‐glucopyranosyl)‐5‐methyl‐1, 3, 4‐oxadiazole, ‐benzothiazole, and ‐benzimidazole were assessed for their potency to inhibit GPb activity. The compounds showed competitive inhibition (with respect to substrate Glc‐1‐P) with Ki values of 145.2 (±11.6), 76 (±4.8), and 8.6 (±0.7) μM, respectively. In order to establish the mechanism of this inhibition, crystallographic studies were carried out and the structures of GPb in complex with the three analogs were determined at high resolution (GPb‐methyl‐oxadiazole complex, 1.92 Å; GPb‐benzothiazole, 2.10 Å; GPb‐benzimidazole, 1.93 Å). The complex structures revealed that the inhibitors can be accommodated in the catalytic site of T‐state GPb with very little change of the tertiary structure, and provide a rationalization for understanding variations in potency of the inhibitors. In addition, benzimidazole bound at the new allosteric inhibitor or indole binding site, located at the subunit interface, in the region of the central cavity, and also at a novel binding site, located at the protein surface, far removed (∼ 32 Å) from the other binding sites, that is mostly dominated by the nonpolar groups of Phe202, Tyr203, Val221, and Phe252.

Crystal Structure of an Aurora-A Mutant that Mimics Aurora-B Bound to Mln8054: Insights Into Selectivity and Drug Design.

The production of selective protein kinase inhibitors is often frustrated by the similarity of the enzyme active sites. For this reason, it is challenging to design inhibitors that discriminate between the three Aurora kinases, which are important targets in cancer drug discovery. We have used a triple-point mutant of Aurora-A (AurAx3) which mimics the active site of Aurora-B to investigate the structural basis of MLN8054 selectivity. The bias toward Aurora-A inhibition by MLN8054 is fully recapitulated by AurAx3 in vitro. X-ray crystal structures of the complex suggest that the basis for the discrimination is electrostatic repulsion due to the T217E substitution, which we have confirmed using a single-point mutant. The activation loop of Aurora-A in the AurAx3-MLN8054 complex exhibits an unusual conformation in which Asp274 and Phe275 side chains point into the interior of the protein. There is to our knowledge no documented precedent for this conformation, which we have termed DFG-up. The sequence requirements of the DFG-up conformation suggest that it might be accessible to only a fraction of kinases. MLN8054 thus circumvents the problem of highly homologous active sites. Binding of MLN8054 to Aurora-A switches the character of a pocket within the active site from polar to a hydrophobic pocket, similar to what is observed in the structure of Aurora-A bound to a compound that induces DFG-out. We propose that targeting this pocket may be a productive route in the design of selective kinase inhibitors and describe the structural basis for the rational design of these compounds.

Imidazo[4,5-b]pyridine Derivatives As Inhibitors of Aurora Kinases: Lead Optimization Studies toward the Identification of an Orally Bioavailable Preclinical Development Candidate

Lead optimization studies using 7 as the starting point led to a new class of imidazo[4,5-b]pyridine-based inhibitors of Aurora kinases that possessed the 1-benzylpiperazinyl motif at the 7-position, and displayed favorable in vitro properties. Cocrystallization of Aurora-A with 40c (CCT137444) provided a clear understanding into the interactions of this novel class of inhibitors with the Aurora kinases. Subsequent physicochemical property refinement by the incorporation of solubilizing groups led to the identification of 3-((4-(6-bromo-2-(4-(4-methylpiperazin-1-yl)phenyl)-3H-imidazo[4,5-b]pyridin-7-yl)piperazin-1-yl)methyl)-5-methylisoxazole (51, CCT137690) which is a potent inhibitor of Aurora kinases (Aurora-A IC(50) = 0.015 +/- 0.003 muM, Aurora-B IC(50) = 0.025 muM, Aurora-C IC(50) = 0.019 muM). Compound 51 is highly orally bioavailable, and in in vivo efficacy studies it inhibited the growth of SW620 colon carcinoma xenografts following oral administration with no observed toxicities as defined by body weight loss.

High-resolution crystal structures of ribonuclease A complexed with adenylic and uridylic nucleotide inhibitors. Implications for structure-based design of ribonucleolytic inhibitors

The crystal structures of bovine pancreatic ribonuclease A (RNase A) in complex with 3′,5′‐ADP, 2′,5′‐ADP, 5′‐ADP, U‐2′‐p and U‐3′‐p have been determined at high resolution. The structures reveal that each inhibitor binds differently in the RNase A active site by anchoring a phosphate group in subsite P1. The most potent inhibitor of all five, 5′‐ADP (Ki = 1.2 μM), adopts a syn conformation (in contrast to 3′,5′‐ADP and 2′,5′‐ADP, which adopt an anti), and it is the β‐ rather than the α‐phosphate group that binds to P1. 3′,5′‐ADP binds with the 5′‐phosphate group in P1 and the adenosine in the B2 pocket. Two different binding modes are observed in the two RNase A molecules of the asymmetric unit for 2′,5′‐ADP. This inhibitor binds with either the 3′ or the 5′ phosphate groups in subsite P1, and in each case, the adenosine binds in two different positions within the B2 subsite. The two uridilyl inhibitors bind similarly with the uridine moiety in the B1 subsite but the placement of a different phosphate group in P1 (2′ versus 3′) has significant implications on their potency against RNase A. Comparative structural analysis of the RNase A, eosinophil‐derived neurotoxin (EDN), eosinophil cationic protein (ECP), and human angiogenin (Ang) complexes with these and other phosphonucleotide inhibitors provides a wealth of information for structure‐based design of inhibitors specific for each RNase. These inhibitors could be developed to therapeutic agents that could control the biological activities of EDN, ECP, and ANG, which play key roles in human pathologies.

Aurora Isoform Selectivity: Design and Synthesis of Imidazo[4,5-B]Pyridine Derivatives as Highly Selective Inhibitors of Aurora-A Kinase in Cells.

Aurora-A differs from Aurora-B/C at three positions in the ATP-binding pocket (L215, T217, and R220). Exploiting these differences, crystal structures of ligand–Aurora protein interactions formed the basis of a design principle for imidazo[4,5-b]pyridine-derived Aurora-A-selective inhibitors. Guided by a computational modeling approach, appropriate C7-imidazo[4,5-b]pyridine derivatization led to the discovery of highly selective inhibitors, such as compound 28c, of Aurora-A over Aurora-B. In HCT116 human colon carcinoma cells, 28c and 40f inhibited the Aurora-A L215R and R220K mutants with IC50 values similar to those seen for the Aurora-A wild type. However, the Aurora-A T217E mutant was significantly less sensitive to inhibition by 28c and 40f compared to the Aurora-A wild type, suggesting that the T217 residue plays a critical role in governing the observed isoform selectivity for Aurora-A inhibition. These compounds are useful small-molecule chemical tools to further explore the function of Aurora-A in cells.

Optimization of Imidazo[4,5-B]Pyridine-Based Kinase Inhibitors: Identification of a Dual Flt3/Aurora Kinase Inhibitor as an Orally Bioavailable Preclinical Development Candidate for the Treatment of Acute Myeloid Leukemia.

Optimization of the imidazo[4,5-b]pyridine-based series of Aurora kinase inhibitors led to the identification of 6-chloro-7-(4-(4-chlorobenzyl)piperazin-1-yl)-2-(1,3-dimethyl-1H-pyrazol-4-yl)-3H-imidazo[4,5-b]pyridine (27e), a potent inhibitor of Aurora kinases (Aurora-A Kd = 7.5 nM, Aurora-B Kd = 48 nM), FLT3 kinase (Kd = 6.2 nM), and FLT3 mutants including FLT3-ITD (Kd = 38 nM) and FLT3(D835Y) (Kd = 14 nM). FLT3-ITD causes constitutive FLT3 kinase activation and is detected in 20–35% of adults and 15% of children with acute myeloid leukemia (AML), conferring a poor prognosis in both age groups. In an in vivo setting, 27e strongly inhibited the growth of a FLT3-ITD-positive AML human tumor xenograft (MV4–11) following oral administration, with in vivo biomarker modulation and plasma free drug exposures consistent with dual FLT3 and Aurora kinase inhibition. Compound 27e, an orally bioavailable dual FLT3 and Aurora kinase inhibitor, was selected as a preclinical development candidate for the treatment of human malignancies, in particular AML, in adults and children.

Structure-Based Design of Imidazo[1,2-A]Pyrazine Derivatives as Selective Inhibitors of Aurora-A Kinase in Cells.

Co-crystallisation of the imidazo[1,2-a]pyrazine derivative 15 (3-chloro-N-(4-morpholinophenyl)-6-(pyridin-3-yl)imidazo[1,2-a]pyrazin-8-amine) with Aurora-A provided an insight into the interactions of this class of compound with Aurora kinases. This led to the design and synthesis of potent Aurora-A inhibitors demonstrating up to 70-fold selectivity in cell-based Aurora kinase pharmacodynamic biomarker assays.

Crystallographic Studies on α- and β-D-glucopyranosyl Formamide Analogues, Inhibitors of Glycogen Phosphorylase

Abstract The catalytic site of glycogen phosphorylase (GP) is currently under investigation as a target for inhibition of hepatic glycogenolysis under high glucose conditions. Three D-glucopyranosyl analogues, C-(1-azido-α-D-glucopyranosyl) formamide, C-(1-acetamido-α-D-glucopyranosyl) formamide, and C-(1-hydroxy-β-D-glucopyranosyl) formamide, were recognised as moderate competitive inhibitors of muscle glycogen phosphorylase b (GPb) [with respect to α-D-glucose 1-phosphate (Glc-1-P)] with Ki values of 1.80 (±0.2) mM, 0.31 (±0.01) mM, and 0.88 (±0.04) mM, respectively. In order to elucidate the structural basis of inhibition, we determined the structure of muscle GPb complexed with the three compounds at 2.1, 2.06 and 2.0 Å resolution, respectively. The complex structures revealed that the inhibitors can be accommodated in the catalytic site of T-state GPb with very little change of the tertiary structure, and provide a rationalisation for understanding potency of the inhibitors. The glucopyranose moiety makes the standard hydrogen bonds and van der Waals contacts as observed in the GPb-glucose complex, while the substituent groups in the α- and β-position of the C1 atom make additional hydrogen bonding and van der Walls interactions to the protein.

Crystal structure of rabbit muscle glycogen phosphorylase a in complex with a potential hypoglycaemic drug at 2.0 A resolution

CP320626 has been identified as a potent inhibitor, synergistic with glucose, of human liver glycogen phosphorylase a (LGPa), a possible target for type 2 diabetes therapy. CP320626 is also a potent inhibitor of human muscle GPa. In order to elucidate the structural basis of the mechanism of CP320626 inhibition, the structures of T state rabbit muscle GPa (MGPa) in complex with glucose and in complex with both glucose and CP320626 were determined at 2.0 A resolution, and refined to crystallographic R values of 0.179 (R(free)=0.218) and 0.207 (R(free)=0.235), respectively. CP320626 binds at the new allosteric site, some 33 A from the catalytic site, where glucose binds. The binding of CP320626 to MGPa does not promote extensive conformational changes except for small shifts of the side chain atoms of residues R60, V64, and K191. Both CP320626 and glucose promote the less active T state, while structural comparisons of MGPa-glucose-CP320626 complex with LGPa complexed with a related compound (CP403700) and a glucose analogue inhibitor indicate that the residues of the new allosteric site, conserved in the two isozymes, show no significant differences in their positions.

Crystallographic studies on acyl ureas, a new class of glycogen phosphorylase inhibitors, as potential antidiabetic drugs

Acyl ureas were discovered as a novel class of inhibitors for glycogen phosphorylase, a molecular target to control hyperglycemia in type 2 diabetics. This series is exemplified by 6‐{2,6‐Dichloro‐ 4‐[3‐(2‐chloro‐benzoyl)‐ureido]‐phenoxy}‐hexanoic acid, which inhibits human liver glycogen phosphorylase a with an IC50 of 2.0 μM. Here we analyze four crystal structures of acyl urea derivatives in complex with rabbit muscle glycogen phosphorylase b to elucidate the mechanism of inhibition of these inhibitors. The structures were determined and refined to 2.26Å resolution and demonstrate that the inhibitors bind at the allosteric activator site, where the physiological activator AMP binds. Acyl ureas induce conformational changes in the vicinity of the allosteric site. Our findings suggest that acyl ureas inhibit glycogen phosphorylase by direct inhibition of AMP binding and by indirect inhibition of substrate binding through stabilization of the T′ state.