Biochemical and Structural Studies of LjSK1, a Lotus japonicus GSK3ß/SHAGGY-like Kinase, Reveal Its Functional Role.

The crystal structure of a truncated form of the Lotus japonicus glycogen synthase kinase 3ß (GSK3ß) like kinase (LjSK190-467) has been resolved at 2.9 Å resolution, providing, for the first time, structural data for a plant GKS3ß like kinase. The 3D structure of LjSK190-467 revealed conservation at the structural level for this plant member of the GSK3ß family. However, comparative structural analysis to the human homologue revealed significant differences at the N- and C-termini, supporting the notion for an additional regulatory mechanism in plant GSK3-like kinases. Structural similarities at the catalytic site and the ATP binding site explained the similarity in the function of the human and plant protein. LjSK1 and lupeol are strongly linked to symbiotic bacterial infection and nodulation initiation. An inhibitory capacity of lupeol (IC50 = 0.77 µM) for LjSK1 was discovered, providing a biochemical explanation for the involvement of these two molecules in nodule formation, and constituted LjSK1 as a molecular target for the discovery of small molecule modulators for crop protection and development. Studies on the inhibitory capacity of two phytogenic triterpenoids (betulinic acid and hederacoside C) to LjSK1 provided their structure-activity relationship and showed that hederacoside C can be the starting point for such endeavors.

Novel diarylamides and diarylureas with N-substitution dependent activity against medulloblastoma.

Medulloblastoma - highly aggressive and heterogeneous tumours of the cerebellum - account for 15-20% of all childhood brain tumours, and are the most common high-grade childhood embryonal tumour of the central nervous system. Herein, potent in vitro anticancer activity against two established medulloblastoma cell lines of the sonic hedgehog subgroup, namely DAOY (p53 mutant) and ONS-76 (p53 wild type), has been achieved. A number of first-generation diarylamides and diarylureas were evaluated and activity is likely to be, in-part, conformation-dependent. The most active compound from this first-generation set of compounds, 1-naphthyl derivative 4b, was selected and a second-generation of compounds were optimised and tested for activity against the medulloblastoma cell lines. This process resulted in drug-like compounds with up to sixty times the activity (sub-micromolar) of the first-generation - thus providing potent new leads for further study.

Mutagenesis of a Lotus japonicus GSK3ß/Shaggy-like kinase reveals functionally conserved regulatory residues.

The glycogen synthase kinases 3 family (GSK3s/SKs; serine/threonine protein kinases) is conserved throughout eukaryotic evolution from yeast to plants and mammals. We studied a plant SK kinase from Lotus japonicus (LjSK1), previously implicated in nodule development, by enzyme kinetics and mutagenesis studies to compare it to mammalian homologues. Using a phosphorylated peptide as substrate, LjSK1 displays optimum kinase activity at pH 8.0 and 20 °C following Michaelis-Menten kinetics with Km and Vmax values of 48.2 µM and 111.6 nmol/min/mg, respectively, for ATP. Mutation of critical residues, as inferred by sequence comparison to the human homologue GSK3ß and molecular modeling, showed a conserved role for Lys167, while residues conferring substrate specificity in the human enzyme are not as significant in modulating LjSK1 substrate specificity. Mutagenesis studies also indicate a regulation mechanism for LjSK1 via proteolysis since removal of a 98 residue long N-terminal segment increases its catalytic efficiency by almost two-fold. In addition, we evaluated the alteration of LjSK1 kinase activity in planta, by overexpressing the mutant variants in hairy-roots and a phenotype in nodulation and lateral root development was verified.

The architecture of hydrogen and sulfur σ-hole interactions explain differences in the inhibitory potency of C-ß-d-glucopyranosyl thiazoles, imidazoles and an N-ß-d glucopyranosyl tetrazole for human liver glycogen phosphorylase and offer new insights to structure-based design.

C-Glucopyranosyl imidazoles, thiazoles, and an N-glucopyranosyl tetrazole were assessed in vitro and ex vivo for their inhibitory efficiency against isoforms of glycogen phosphorylase (GP; a validated pharmacological target for the development of anti-hyperglycaemic agents). Imidazoles proved to be more potent inhibitors than the corresponding thiazoles or the tetrazole. The most potent derivative has a 2-naphthyl substituent, a Ki value of 3.2 µM for hepatic glycogen phosphorylase, displaying also 60% inhibition of GP activity in HepG2 cells, compared to control vehicle treated cells, at 100 µM. X-Ray crystallography studies of the protein - inhibitor complexes revealed the importance of the architecture of inhibitor associated hydrogen bonds or sulfur σ-hole bond interactions to Asn284 OD1, offering new insights to structure-based design efforts. Moreover, while the 2-glucopyranosyl-tetrazole seems to bind differently from the corresponding 1,2,3-triazole compound, the two inhibitors are equipotent.

Probing the ß-pocket of the active site of human liver glycogen phosphorylase with 3-(C-ß-d-glucopyranosyl)-5-(4-substituted-phenyl)-1, 2, 4-triazole inhibitors.

Human liver glycogen phosphorylase (hlGP), a key enzyme in glycogen metabolism, is a valid pharmaceutical target for the development of new anti-hyperglycaemic agents for type 2 diabetes. Inhibitor discovery studies have focused on the active site and in particular on glucopyranose based compounds with a ß-1 substituent long enough to exploit interactions with a cavity adjacent to the active site, termed the ß-pocket. Recently, C-ß-d-glucopyranosyl imidazoles and 1, 2, 4-triazoles proved to be the best known glucose derived inhibitors of hlGP. Here we probe the ß-pocket by studying the inhibitory effect of six different groups at the para position of 3-(ß-d-glucopyranosyl phenyl)-5-phenyl-, 1, 2, 4-triazoles in hlGP by kinetics and X-ray crystallography. The most bioactive compound was the one with an amine substituent to show a Ki value of 0.43 µM. Structural studies have revealed the physicochemical diversity of the ß-pocket providing information for future rational inhibitor design studies.

Affinity Crystallography Reveals the Bioactive Compounds of Industrial Juicing Byproducts of Punica granatum for Glycogen Phosphorylase.

BACKGROUND: Glycogen phosphorylase (GP) is a pharmaceutical target for the discovery of new antihyperglycaemic agents. Punica granatum is a well-known plant for its potent antioxidant and antimicrobial activities but so far has not been examined for antihyperglycaemic activity. OBJECTIVE: The aim was to examine the inhibitory potency of eighteen polyphenolic extracts obtained from Punica granatum fruits and industrial juicing byproducts against GP and discover their most bioactive ingredients. METHOD: Kinetic experiments were conducted to measure the IC50 values of the extracts while affinity crystallography was used to identify the most bioactive ingredient. The inhibitory effect of one of the polyphenolic extracts was also verified ex vivo, in HepG2 cells. RESULTS: All extracts exhibited significant in vitro inhibitory potency (IC50 values in the range of low µg/mL). Affinity crystallography revealed that the most bioactive ingredients of the extracts were chlorogenic and ellagic acids, found bound in the active and the inhibitor site of GP, respectively.While ellagic acid is an established GP inhibitor, the inhibition of chlorogenic acid is reported for the first time. Kinetic analysis indicated that chlorogenic acid is an inhibitor with Ki=2.5 x 10-3Mthat acts synergistically with ellagic acid. CONCLUSION: Our study provides the first evidence for a potential antidiabetic usage of Punica granatum extracts as antidiabetic food supplements. Although, more in vivo studies have to be performed before these extracts reach the stage of antidiabetic food supplements, our study provides a first positive step towards this process.

Nanomolar Inhibitors of Glycogen Phosphorylase Based on ß-d-Glucosaminyl Heterocycles: A Combined Synthetic, Enzyme Kinetic, and Protein Crystallography Study.

Aryl substituted 1-(ß-d-glucosaminyl)-1,2,3-triazoles as well as C-ß-d-glucosaminyl 1,2,4-triazoles and imidazoles were synthesized and tested as inhibitors against muscle and liver isoforms of glycogen phosphorylase (GP). While the N-ß-d-glucosaminyl 1,2,3-triazoles showed weak or no inhibition, the C-ß-d-glucosaminyl derivatives had potent activity, and the best inhibitor was the 2-(ß-d-glucosaminyl)-4(5)-(2-naphthyl)-imidazole with a Ki value of 143 nM against human liver GPa. An X-ray crystallography study of the rabbit muscle GPb inhibitor complexes revealed structural features of the strong binding and offered an explanation for the differences in inhibitory potency between glucosyl and glucosaminyl derivatives and also for the differences between imidazole and 1,2,4-triazole analogues.

van der Waals interactions govern C-ß-d-glucopyranosyl triazoles' nM inhibitory potency in human liver glycogen phosphorylase.

3-(C-Glucopyranosyl)-5aryl-1,2,4-triazoles with an aryl moiety larger than phenyl have been shown to have strong inhibitory potency (Ki values in the range of upper nM) for human liver glycogen phosphorylase (hlGP), a pharmacologically relevant target for diabetes type 2. In this study we investigate in a comparative manner the inhibitory effect of the above triazoles and their respective imidazoles on hlGPa. Kinetic studies show that the imidazole derivatives are 6-8 times more potent than their corresponding triazoles. We also seek to answer how the type of the aryl moiety affects the potency in hlGPa, and by determination of the crystal structure of rmGPb in complex with the triazole derivatives the structural basis of their inhibitory efficacy is also elucidated. Our studies revealed that the van der Waals interactions between the aryl moiety and residues in a hydrophobic pocket within the active site are mainly responsible for the variations in the potency of these inhibitors.