Abstract
Classic galactosemia is caused by loss-of-function mutations in galactose-1-phosphate uridylyltransferase (GALT) that lead to toxic accumulation of its substrate, galactose-1-phosphate. One proposed therapy is to inhibit the biosynthesis of galactose-1-phosphate, catalyzed by galactokinase 1 (GALK1). Existing inhibitors of human GALK1 (hGALK1) are primarily ATP-competitive with limited clinical utility to date. Here, we determined crystal structures of hGALK1 bound with reported ATP-competitive inhibitors of the spiro-benzoxazole series, to reveal their binding mode in the active site. Spurred by the need for additional chemotypes of hGALK1 inhibitors, desirably targeting a nonorthosteric site, we also performed crystallography-based screening by soaking hundreds of hGALK1 crystals, already containing active site ligands, with fragments from a custom library. Two fragments were found to bind close to the ATP binding site, and a further eight were found in a hotspot distal from the active site, highlighting the strength of this method in identifying previously uncharacterized allosteric sites. To generate inhibitors of improved potency and selectivity targeting the newly identified binding hotspot, new compounds were designed by merging overlapping fragments. This yielded two micromolar inhibitors of hGALK1 that were not competitive with respect to either substrate (ATP or galactose) and demonstrated good selectivity over hGALK1 homologues, galactokinase 2 and mevalonate kinase. Our findings are therefore the first to demonstrate inhibition of hGALK1 from an allosteric site, with potential for further development of potent and selective inhibitors to provide novel therapeutics for classic galactosemia.
Highlights
The Leloir pathway is essential for the metabolism of dietary galactose,[1] generating glucose units for glycolysis and biosynthesis of glycogen, glycoproteins, and glycolipids
A series of spiro-benzoxazole inhibitors of lowmicromolar potency was previously reported for human GALK1 (hGALK1), and in silico modeling and kinetic characterization were indicative of their binding in the active site ATP pocket,[24,25,28] no experimental structures have been reported
We found that hGALK1 co-crystallized with galactose and T2 produced the required quantity and diffraction quality for the screening campaign
Summary
The Leloir pathway is essential for the metabolism of dietary galactose,[1] generating glucose units for glycolysis and biosynthesis of glycogen, glycoproteins, and glycolipids. At the hub of the Leloir pathway is galactose-1-phosphate uridylyltransferase (GALT; EC 2.7.7.12), which converts galactose-1-phosphate (Gal-1-P) and UDP-glucose (UDP-Glc) into glucose-1phosphate and UDP-galactose.[2] Inherited mutations of the GALT gene lead to the autosomal recessive disorder classic galactosemia (OMIM 230400),[3] affecting 1:16 000−60 000 live births. Classic galactosemia patients generally sicken in the neonatal period, with liver, kidney, intestinal, and central nervous system toxicity exacerbated by the high galactose content in human and formula milk.[4,5] If lactose, the primary exogenous source of galactose, is not removed from the patient’s diet, progressive liver and brain damage lead to death or severe disability. The current mainstay treatment is life-long dietary galactose restriction, which resolves acute life-threatening symptoms but fails to prevent the long-term, late-onset complications that include learning and speech difficulties, neurological impairments manifesting as ataxia, and premature ovarian insufficiency.[4]
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