Abstract
One molecule of glucose 6-phosphate inhibits brain hexokinase (HKI) with high affinity by binding to either one of two sites located in distinct halves of the enzyme. In addition to potent inhibition, glucose 6-phosphate releases HKI from the outer leaflet of mitochondria; however, the site of glucose 6-phosphate association responsible for the release of HKI is unclear. The incorporation of a C-terminal polyhistidine tag on HKI facilitates the rapid purification of recombinant enzyme from Escherichia coli. The tagged construct has N-formyl methionine as its first residue and has mitochondrial association properties comparable with native brain hexokinases. Release of wild-type and mutant hexokinases from mitochondria by glucose 6-phosphate follow equilibrium models, which explain the release phenomenon as the repartitioning of ligand-bound HKI between solution and the membrane. Mutations that block the binding of glucose 6-phosphate to the C-terminal half of HKI have little or no effect on the glucose 6-phosphate release. In contrast, mutations that block glucose 6-phosphate binding to the N-terminal half require approximately 7-fold higher concentrations of glucose 6-phosphate for the release of HKI. Results here implicate a primary role for the glucose 6-phosphate binding site at the N-terminal half of HKI in the release mechanism.
Highlights
Brain tissue relies almost exclusively on glucose as its source of energy
As the initial 10 –12 residues are absolutely crucial for mitochondrial binding [44], the purified recombinant system used in crystallography can provide no information regarding mitochondrial association and release phenomena
The mutation disrupts the coupling between Glucose 6-phosphate (Glu-6-P) binding sites of the Nand C-terminal halves, i.e. inhibition of the ␣ϩ2 construct by AnGlu6-P is competitive with ATP and noncompetitive with glucose, and as potent as AnGlu-6-P inhibition of the wild-type enzyme (TABLE ONE)
Summary
Brain tissue relies almost exclusively on glucose as its source of energy. Approximately 25% of circulating blood glucose and 20% of consumed oxygen is utilized by the brain, an organ that constitutes less than 2% of the human body mass [1]. Release of wild-type and mutant hexokinases from mitochondria by glucose 6-phosphate follow equilibrium models, which explain the release phenomenon as the repartitioning of ligand-bound HKI between solution and the membrane.
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