The roles of ADP2- and Mg2+ in control steps of phosphoglycerate kinase

Substrate-assisted movement of the catalytic Lys 215 during domain closure: site-directed mutagenesis studies of human 3-phosphoglycerate kinase

3-Phosphoglycerate kinase (PGK) is a two-domain hinge-bending enzyme. It is still unclear how the geometry of the active site is formed during domain closure and how the catalytic residues are brought into the optimal position for the reaction. Comparison of the three-dimensional structures in various open and closed conformations suggests a large (10 A) movement of Lys 215 during domain closure. This change would be required for direct participation of this side chain in both the catalyzed phospho transfer and the special anion-caused activation. To test the multiple roles of Lys 215, two mutants (K215A and K215R) were constructed from human PGK and characterized in enzyme kinetic and substrate binding studies. For comparison, mutants (R38A and R38K) of the known essential residue, Arg 38, were also produced. Drastic decreases (1500- and 500-fold, respectively), as in the case of R38A, were observed in the kcat values of mutants K215A and K215R, approving the essential catalytic role of Lys 215. In contrast, the R38K mutation caused an only 1.5-fold decrease in activity. This emphasizes the importance of a very precise positioning of Lys 215 in the active site, in addition to its positive charge. The side chain of Lys 215 is also responsible for the substrate and anion-dependent activation, since these properties are abolished upon mutation. Among the kinetic constants mainly the Km values of MgATP and 1,3-BPG are increased (approximately 20- and approximately 8-fold, respectively) in the case of the neutral K215A mutant, evidence of the interaction of Lys 215 with the transferring phospho group in the functioning complex. Weakening of MgATP binding (a moderate increase in Kd), but not of MgADP binding, upon mutation indicates an initial weak interaction of Lys 215 with the gamma-phosphate already in the nonfunctioning open conformation. Thus, during domain closure, Lys 215 possibly moves together with the transferring phosphate; meanwhile, this group is being positioned properly for catalysis.

Role of phosphate chain mobility of MgATP in completing the 3-phosphoglycerate kinase catalytic site: binding, kinetic, and crystallographic studies with ATP and MgATP

The complexes of pig muscle 3-phosphoglycerate kinase with the substrate MgATP and with the nonsubstrate Mg(2+)-free ATP have been characterized by binding, kinetic, and crystallographic studies. Comparative experiments with ADP and MgADP have also been carried out. In contrast to the less specific and largely ionic binding of Mg(2+)-free ATP and ADP, specific occupation of the adenosine binding pocket by MgATP and MgADP has been revealed by displacement experiments with adenosine and anions, as well as supported by isothermal calorimetric titrations. The Mg(2+)-free nucleotides similarly stabilize the overall protein structure and restrict the conformational flexibility around the reactive thiol groups of helix 13, as observed by differential scanning microcalorimetry and thiol reactivity studies, respectively. The metal complexes, however, behave differently. MgADP, but not MgATP, further increases the conformational stability with respect to its Mg(2+)-free form, which indicates their different modes of binding to the enzyme. Crystal structures of the binary complexes of the enzyme with MgATP and with ATP (2.1 and 1.9 A resolution, respectively) have shown that the orientation and interaction of phosphates of MgATP largely differ not only from those of ATP but also from the previously determined ones of either MgADP [Davies, G. J., Gamblin, S. J., Littlechild, J. A., Dauter, Z., Wilson, K. S., and Watson, H. C. (1994) Acta Crystallogr. D50, 202-209] or the metal complexes of AMP-PNP [May, A., Vas, M., Harlos, K., and Blake, C. C. F. (1996) Proteins 24, 292-303; Auerbach, G., Huber, R., Grattinger, M., Zaiss, K., Schurig, H., Jaenicke, R., and Jacob, U. (1997) Structure 5, 1475-1483] and are more similar to the interactions formed with MgAMP-PCP [Kovári, Z., Flachner, B., Náray-Szabó, G., and Vas, M. (2002) Biochemistry 41, 8796-8806]. Mg(2+) is liganded to both beta- and gamma-phosphates of ATP, while beta-phosphate is linked to the conserved Asp218, i.e., to the N-terminus of helix 8, through a water molecule; the known interactions of either MgADP or the metal complexes of AMP-PNP with the N-terminus of helix 13 and with Asn336 of beta-strand J are absent in the case of MgATP. Fluctuation of MgATP phosphates between two alternative sites has been proposed to facilitate the correct positioning of the mobile side chain of Lys215, and the catalytically competent active site is thereby completed.

Highly potent bisphosphonate ligands for phosphoglycerate kinase

We have synthesized a series of novel analogs of 1, 3-bisphospho-D-glyceric acid, 1,3-BPG,3 and evaluated their binding to phosphoglycerate kinase, PGK (EC 2.7.2.3). Nonscissile methanephosphonic acids replace the two phosphate monoesters of 1, 3-BPG and lead to several stable, tight-binding mimics of this intermediate species in glycolysis. Multiple fluorine substitution for hydrogen in the alpha-methylene groups of the phosphonic acid 1, 3-BPG analogs markedly improves their binding to PGK as determined by NMR analysis. The best ligands bind some 50-100 times more strongly than does the substrate 3-phospho-D-glyceric acid and show a requirement for pKa3 to be generally below 6.0, while the presence of a beta-carbonyl group seems to be of secondary importance.

Anion activation of 3-phosphoglycerate kinase requires domain closure

3-Phosphoglycerate kinase is a typical two-domain "hinge-bending" enzyme, which is known to be regulated by multivalent anions. Here a relationship between this regulation and the hinge-bending domain closure is proposed on the basis of enzyme kinetic analysis and molecular modeling. Activation of the pig muscle enzyme at low concentrations and inhibition at high concentrations of various anionic analogues of the substrate 3-phosphoglycerate or of the nonsubstrate metal-free ATP are described by a two-site model assuming separate sites for activation and inhibition, respectively. Kinetic experiments with various pairs of analogues suggest the presence of a common site for activation by all effectors, separate from the catalytic site for 3-phosphoglycerate; and a common site for inhibition, except for metal-free ATP, identical with the catalytic site of 3-phosphoglycerate. An additional inhibiting site for all of the anions investigated, including metal-free ATP, is also proposed. A similar two-site model can describe activation of the enzyme by a large excess of each substrate; here the ligand binds to the catalytic site as a substrate and to the regulatory site as an activator. Activation is exerted not only by the physiological substrate, 3-phophoglycerate, but also by a synthetic weak substrate. The activity in the reaction with 3-phosphoglycerate and MgATP is greatly enhanced by the simultaneous presence of the weak substrate. This finding clearly proves the existence of a regulatory site, separate from the catalytic site. This regulatory site, however, may only exist in the catalytically competent closed conformation of the enzyme, as indicated by molecular modeling. Docking of the regulator anions into the known X-ray structures of the enzyme revealed the appearance of an anion binding site between the two domains, including the invariant residues of Lys-215 (C-domain) and of Arg-65 among other residues of the basic cluster (N-domain), as a consequence of the large-scale substrate-induced conformational change that leads to domain closure.

Synergistic effects of substrate-induced conformational changes in phosphoglycerate kinase activation

Phosphoglycerate kinase (PGK), a key enzyme in glycolysis, catalyses the transfer of a phosphoryl-group from 1,3-bisphosphoglycerate to ADP to form 3-phosphoglycerate and ATP. Despite extensive kinetic and structural investigations over more than two decades, the conformation assumed by this enzyme during catalysis remained unknown. Here we present the 2.8 A crystal structure of a ternary complex of PGK from Trypanosoma brucei, the causative agent of sleeping sickness. This structure determination relied on a procedure in which fragments containing less than 10% of the scattering mass were successively positioned in the unit cell to obtain phases. The PGK ternary complex exhibits a dramatic closing of the large cleft between the two domains seen in all previous studies, thereby bringing the two ligands, 3-phosphoglycerate and ADP into close proximity. Our results demonstrate that PGK is a hinge-bending enzyme, reveal a novel mechanism in which substrate-induced effects combine synergistically to induce major conformational changes and, to our knowledge, afford the first observation of the PGK active site in a catalytic conformation.

Substrate-induced conformational changes in yeast 3-phosphoglycerate kinase monitored by fluorescence of single tryptophan probes

3-Phosphoglycerate kinase (PGK) catalyzes the reversible conversion of 3-phosphoglycerate (3-PG) and ATP to 1,3-diphosphoglycerate (1,3-diPG) and ADP in the presence of magnesium ions. PGK is a single polypeptide chain arranged in two domains, with an active site located in the interdomain cleft. The large distance between the binding sites for 3-PG and ATP, deduced from the crystallographic structures of the binary complexes, gave rise to the hypothesis that this enzyme undergoes a hinge-bending domain motion from open to closed conformation during catalysis. However, no direct experimental evidence exists for the "closed" conformation in the presence of both substrates. In this study, several PGK mutants with single tryptophans placed in various location were used as intrinsic fluorescent probes to examine the extent and delocalization of conformational changes induced by the binding of 3-PG, 1,3-diPG, ADP, ATP, and PNP-AMP (nonhydrolyzable analogue of ATP), and by 3-PG and PNP-AMP together. The results showed that only the probes situated in the hinge and in parts of each domain close to the hinge reflect substrate-induced conformational changes. Binding of substrates to one domain was found to induce spectral perturbation of the probes in the opposite domain, indicating a transmission of conformational changes between the domains. A combination of both substrates generated much larger fluorescence changes than the individual substrates. The binding constants were determined for each substrate using probes situated in different locations.

Conformational changes in yeast phosphoglycerate kinase upon substrate binding

Small-angle neutron scattering (SANS) was used to measure the radius of gyration (Rg) of solutions of phosphoglycerate kinase (PGK) in a variety of substrate environments in D2O. The Rg of 24.0 A was measured for native PGK. A decrease in Rg was observed for the following: 23.7 A for PGK+sulphate; 23.5 A for PGK+ beta, gamma-bidentate Cr(H2O)4ATP (CrATP); 23.3 A for PGK + 3-phospho-D-glycerate (PGA)+CrATP; 22.9 A for PGK+CrATP+sulphate; 22.6 A for PGK+PGA+CrATP+sulphate. The statistical error was about +/- 0.3 A, which is less than systematic effects in this system. These results are consistent with catalysis by a hinge-bending motion of the enzyme. Since CrATP is not hydrolyzed, these results represent the conformational states of the bound substrates in the catalytically relevant ternary complex in the absence of product formation. The second virial coefficient is also measured for this system and this is consistent with that calculated from the protein volume only.

Mg2+ affects the binding of ADP but not ATP to 3-phosphoglycerate kinase. Correlation between equilibrium dialysis binding and enzyme kinetic data

The role of Mg2+ in the binding of ADP and ATP to pig muscle and yeast 3-phosphoglycerate kinases has been studied by equilibrium dialysis. Whereas the Kd of ATP binding varies between 0.17 and 0.23 mM (S.E.M. 0.03 mM) for both enzymes, independently of the presence of Mg2+, the Kd values for ADP and MgADP binding are in the range 0.18-0.27 mM (S.E.M. 0.04 mM) and 0.05-0.06 mM (S.E.M. 0.01 mM) respectively. Thus Mg2+ exclusively tightens the interaction of ADP, but not of ATP, with the protein molecule. Although the equilibrium dialysis data are consistent with a model possessing a single site for nucleotides, the existence of a much weaker secondary site (with a Kd value at least two orders of magnitude larger) cannot be excluded. The binding of AMP and adenosine to pig muscle 3-phosphoglycerate kinase is weaker than binding of MgATP; the respective Kd values are 0.36 +/- 0.05 mM and 0.65 +/- 0.05 mM. Thus, in addition to the interaction of the alpha-phosphate that is detectable by crystallography [Banks, Blake, Evans, Haser, Rice, Hardy, Merrett and Phillips (1979) Nature (London) 279, 773-777], the beta- and/or gamma-phosphate(s) of MgATP may also interact with the enzyme molecule. The fact that MgADP binds more tightly than ADP is consistent with its stronger inhibition of the reaction catalysed by the enzyme between 3-phosphoglycerate and MgATP. MgADP is a product of this reaction, and inhibits it competitively with both substrates; as an inhibitor its KI is comparable with the Kd found in binding studies. At the same time, the Km value for MgADP in the reverse reaction (0.18 +/- 0.05 mM; mean +/- S.E.M.) is higher than these constants; this may be due either to a different kinetic mechanism in this direction of the enzymic reaction, or to different binding modes of MgADP as inhibitor and as substrate. The reason why inhibition by MgADP is competitive with 3-phosphoglycerate may be that its binding prevents the specific change in conformation that the enzyme undergoes [Harlos, Vas and Blake (1992) Proteins 12, 133-144] when it binds 3-phosphoglycerate.

Characterisation of yeast phosphoglycerate kinase modified by mutagenesis at residue 21

Site-directed mutagenesis has been used to produce mutant forms of yeast phosphoglycerate kinase in which the conserved active-site residue, Arg21, has been replaced by a methionine or a lysine. Kinetic results obtained using these mutant enzymes show that their Km for both 3-phospho-D-glycerate and ATP are significantly different from those recorded for the wild-type enzyme. The Vmax for the lysine mutant is reduced by a factor of two from that of the wild-type enzyme whereas the Vmax for the methionine mutant is reduced more than sevenfold. A very clean electron-density-difference map shows little, if any, evidence of a structural change associated with the C-terminal domain, although resonances in the NMR spectra associated with the ATP-binding site (C-terminal domain) are also affected by the mutation as one might expect from the kinetic results. The NMR data show that binding at both the 3-phospho-D-glycerate and the non-productive ATP-binding site (associated with the N-terminal domain) are affected in the mutant in a way which is different to that associated with the wild-type enzyme. These results, taken together with the X-ray and kinetic data, indicate that the non-productive ATP-binding site and the activating anion-binding site are both associated with the basic patch region of yeast phosphoglycerate kinase.

An investigation of large inhibitors binding to phosphoglycerate kinase and their effect on anion activation

This study extends, to a series of larger anions, our earlier investigation of the interaction of the trypanocidal drug suramin and other small negatively charged molecules with yeast phosphoglycerate kinase. 1H-NMR structural studies of phosphoglycerate kinase in the presence of varying concentrations of these large molecules (designed to mimic, at one end, the anionic charge distribution in the substrate 3-phosphoglycerate, while possibly being able to interact across the cleft of the enzyme) including inositol 1,4,5-triphosphate, 4-amino-6-trichloroethenyl-1,3- benzenedisulphonamide, gallic acid and sulphasalazine are described. The anion activation and/or inhibition of the enzyme by these molecules are also reported. Evidence that binding to the general anion site in the 'basic patch' region of the protein may be responsible for either the activating or inhibiting effects, while binding at the hydrophobic (catalytic) site leads to inhibition only is presented. A reaction scheme which explains these observations is given.

Investigating interdomain region mutants Phe194----Leu and Phe194----Trp of yeast phosphoglycerate kinase by 1H-NMR spectroscopy

Site-directed mutagenesis has been used to produce two mutant forms of yeast phosphoglycerate kinase in which the interdomain residue Phe194 has been replaced by a leucine or tryptophan residue. Using 1H-NMR spectroscopy, it was found that the mutations at position 194 induce both local and long-range conformational changes in the protein. It was also found that 3-phosphoglycerate binding to the mutant proteins induces somewhat different conformational effects to those observed for wild-type phosphoglycerate kinase. The affinity of mutant Phe194----Trp for 3-phosphoglycerate was found by NMR studies to be unaffected, while the affinity of Phe194----Leu mutant is reduced by about threefold relative to the wild-type enzyme. The binding of ATP at the electrostatic site of the mutant proteins is also seen to be about three times weaker for the Phe194----Leu mutant when compared to wild-type or Phe194----Leu mutant. These results are discussed in the light of the kinetic studies on the mutants which show that for Phe194----Leu mutant the Km values for both 3-phosphoglycerate and ATP, as well as the Vmax, are decreased relative to the wild-type enzyme, while for mutant Phe194----Trp, the Km values for 3-phosphoglycerate and ATP are unaffected and the Vmax is decreased when compared to wild-type enzyme. Kinetic studies in the presence of sulphate reveal that the anion activation is greater for mutant Phe194----Trp and less for mutant Phe194----Leu, relative to that observed for wild-type phosphoglycerate kinase. The NMR data, taken together with the kinetic data, are consistent with the on and off rates of 3-phosphoglycerate being affected by the mutations at position 194. It is suggested that Phe194 is important for the mobility of the interdomain region and the relative movement of the 3-phosphoglycerate binding site which allows the optimum conformation for catalysis to be attained. Apparently Trp194 reduces the mobility of the interdomain region of the protein, while Leu194 increases it.