Manshu Tang

High-Throughput Screening for Human Galactokinase Inhibitors

Inherited deficiency of galactose-1-phosphate uridyltransferase (GALT) can result in a potentially lethal disorder called classic galactosemia. Although the neonatal lethality associated with this disease can be prevented through early diagnosis and a galactose-restricted diet, the lack of effective therapy continues to have consequences: developmental delay, neurological disorders, and premature ovarian failure are common sequelae in childhood and adulthood. Several lines of evidence indicate that an elevated level of galactose-1-phosphate (gal-1-p), the product of galactokinase (GALK), is a major, if not sole, pathogenic mechanism in patients with classic galactosemia. The authors hypothesize that elimination of gal-1-p production by inhibiting GALK will relieve GALT-deficient cells from galactose toxicity. To test this hypothesis, they obtained human GALK using a bacterial expression system. They developed a robust, miniaturized, high-throughput GALK assay (Z′ factor = 0.91) and used this assay to screen against libraries composed of 50,000 chemical compounds with diverse structural scaffolds. They selected 150 compounds that, at an average concentration of 33.3 µM, inhibited GALK activity in vitro more than 86.5% and with a reproducibility score of at least 0.7 for a confirmatory screen under identical experimental conditions. Of these 150 compounds, 34 were chosen for further characterization. Preliminary results indicated that these 34 compounds have potential to serve as leads to the development of more effective therapy of classic galactosemia. ( Journal of Biomolecular Screening 2008:415-423)

Molecular and Biochemical Characterization of Human Galactokinase and its small molecule inhibitors

Human galactokinase (GALK) is the first enzyme in the Leloir pathway, converting α-d-galactose into galactose-1-phosphate (Gal-1-P). Recently, there is increasing interest in targeting GALK as a novel therapy to ameliorate the disease manifestations in patients with Classic Galactosemia as it would, in combination with (ga-)lactose restriction reduce accumulation of Gal-1-P, a cytotoxic agent. Previously, we identified 34 small molecule compounds that inhibited GALK in vitro using experimental high-throughput screening. In order to isolate useful lead compounds, we characterized these hits with regards to their kinase selectivity profiles, potency and capability to reduce Gal-1-P accumulation in patient cell lines, and their modes of action. We found that the majority of these compounds had IC(50)s ranging from 0.7μM to 33.3μM. When tested against other members of the GHMP kinase family, three compounds (1, 4, and 24) selectively inhibited GALK with high potency. Through alignment of GALK and mevalonate kinase (MVK) crystal structures, we identified that eight amino acid residues and an L1 loop were different within the ATP-binding pockets of these two closely related kinases. By site-directed mutagenesis experiments, we identified one amino acid residue required for the inhibitory function of two of the three selective compounds. Based on these results, we generated binding models of these two compounds using a high-precision docking program. Compounds 4 and 24 inhibited GALK in a mixed model, while compound 1 exhibited parabolic competitive inhibition. Most importantly, using cells from galactosemic patients we found that selected compounds lowered Gal-1-P concentrations.