Abstract
Fructokinase (FRK) catalyzes the first step of fructose metabolism i.e., D-fructose to D-fructose-6-phosphate (F6P), however, the mechanistic insights of this reaction are elusive yet. Here we demonstrate that the putative Vibrio cholerae fructokinase (VcFRK) exhibit strong fructose-6-kinase activity allosterically modulated by K+/Cs+. We have determined the crystal structures of apo-VcFRK and its complex with fructose, fructose-ADP-Ca2+, fructose-ADP-Ca2+-BeF3−. Collectively, we propose the catalytic mechanism and allosteric activation of VcFRK in atomistic details explaining why K+/Cs+ are better activator than Na+. Structural results suggest that apo VcFRK allows entry of fructose in the active site, sequester it through several conserved H-bonds and attains a closed form through large scale conformational changes. A double mutant (H108C/T261C-VcFRK), that arrests the closed form but unable to reopen for F6P release, is catalytically impotent highlighting the essentiality of this conformational change. Negative charge accumulation around ATP upon fructose binding, is presumed to redirect the γ-phosphate towards fructose for efficient phosphotransfer. Reduced phosphotransfer rate of the mutants E205Q and E110Q supports this view. Atomic resolution structure of VcFRK-fructose-ADP-Ca2+-BeF3−, reported first time for any sugar kinase, suggests that BeF3− moiety alongwith R176, Ca2+ and ‘anion hole’ limit the conformational space for γ-phosphate favoring in-line phospho-transfer.
Highlights
Phosphorylation of monosaccharides is a fundamental reaction in carbohydrate metabolism which traps sugar inside the cells and targets them for further utilization by specific metabolic pathways
Structural perspective of catalytic phosphotransfer has been enlivened for several pfkB family of enzymes which include RK5, Adenosine kinase (AK)6, 4-methyl-5-beta-hydroxyethylthiazole kinase (ThiK)7, 4-amino-5 -hydroxymethyl-2-methylpyrimidine phosphate kinase (HMPPK)[8] and Aminoimidazole Riboside kinase (AIRsK)[9]
Our isothermal titration calorimetry (ITC) data demonstrated that V. cholerae FRK (VcFRK) binds D-fructose while kinetic experiments confirmed strong divalent metal dependent fructokinase activity where monovalent cations as allosteric activators
Summary
The flexible lid domain, which extends from the central β-sheet core, is formed by two pairs of antiparallel β-strands β2-β3 and β6-β7 and their connecting loops They are designated as small lid sub-domain and large lid sub-domain respectively. At the centre of the dimeric interface of apo VcFRK, small lid sub-domain from each monomer interact strongly while their large lid sub-domains are projected away, forming eight stranded β-sheet arrangement β7-β6-β2-β3-β3′-β2′-β6′-β7′ (Fig. 1c). Both VcFRK and EcRK5 dimerize through lid domains their mode of dimerization is quite different. Data collection Wavelength (Å) Space group Unit cell parameters (a/b/c (Å)) Resolution range (Å)* No of reflections Rsym (%) I/σ (I) Completeness (%) Redundancy Wilson B-factor (Å2) Refinement Rwork/Rfree (%) No of atoms (protein/ligand/ solvent) Mean B value (Å2) RMS deviation (bond(Å)/angle (deg)/chiral volume (Å) Ramachandran plot (favored/ allowed (%)) PDB Code
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