Abstract
Brain hexokinase (HKI) is inhibited potently by its product glucose 6-phosphate (G6P); however, the mechanism of inhibition is unsettled. Two hypotheses have been proposed to account for product inhibition of HKI. In one, G6P binds to the active site (the C-terminal half of HKI) and competes directly with ATP, whereas in the alternative suggestion the inhibitor binds to an allosteric site (the N-terminal half of HKI), which indirectly displaces ATP from the active site. Single mutations within G6P binding pockets, as defined by crystal structures, at either the N- or C-terminal half of HKI have no significant effect on G6P inhibition. On the other hand, the corresponding mutations eliminate product inhibition in a truncated form of HKI, consisting only of the C-terminal half of the enzyme. Only through combined mutations at the active and allosteric sites, using residues for which single mutations had little effect, was product inhibition eliminated in HKI. Evidently, potent inhibition of HKI by G6P can occur from both active and allosteric binding sites. Furthermore, kinetic data reported here, in conjunction with published equilibrium binding data, are consistent with inhibitory sites of comparable affinity linked by a mechanism of negative cooperativity.
Highlights
Mammals harbor four hexokinase (ATP:D-hexose 6-phosphotransferase (2.7.1.1)) isozymes [1,2,3]
A small fraction of the potential HKI activity is used in brain tissue because of low concentrations of intracellular glucose and potent product inhibition by glucose 6-phosphate (G6P) [8, 9]
In light of these divergent conclusions, we examined the functional consequences of mutations at the G6P binding site at the C-terminal half of HKI
Summary
Materials—A full-length cDNA of human brain hexokinase cloned into an expression vector pET-11a (from Novagen) to produce pET-11aHKI and pET-11d-miniHK was available for use from a previous study [32, 33]. The transformer site-directed mutagenesis kit is from CLONTECH. T4 polynucleotide kinase and all the restriction enzymes are from Promega. Escherichia coli strain ZSC13 (DE3), which does not contain endogenous hexokinase, was a gift from the Genetic Stock Center, Yale University. Construction of Mutant Hexokinase Genes—The hexokinase gene was mutated according to the protocols of the CLONTECH transformer site-directed mutagenesis kit. The mutant plasmid was selected from wild-type plasmids by switching a unique NruI restriction site on the pET-11 vector to another unique XhoI site for the single point mutations. Wild-type HKIa Asp Alaa Gly Tyra Ser Alaa Thr232 Alaa Asp Alab Asp Glub Asp Lysb a From Ref. 31. Wild-type HKIa Asp Alaa Gly Tyra Ser Alaa Thr232 Alaa Asp Alab Asp Glub Asp Lysb a From Ref. 31. b From Ref. 37. c Enzyme not purified
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