NMR analysis of site-specific mutants of yeast phosphoglycerate kinase. An investigation of the triose-binding site

MgF3- and AlF4- transition state analogue complexes of yeast phosphoglycerate kinase

The phospho-transfer mechanism of yeast phosphoglycerate kinase (PGK) has been probed through formation of trifluoromagnesate (MgF₃^-) and tetrafluoroaluminate (AlF₄^-) transition state analogue complexes and analyzed using ¹⁹F, ¹H waterLOGSY and ¹H chemical shift perturbation NMR spectroscopy. We observed the first ¹⁹F NMR spectroscopic evidence for the formation of metal fluoride transition state analogues of yeast PGK and also observed significant changes to proton chemical shifts of PGK in the presence, but not in the absence, of fluoride upon titration of ligands, providing indirect evidence of the formation of a closed ternary transition state. WaterLOGSY NMR spectroscopy experiments using an uncompetitive model were used in an attempt to measure ligand binding affinities within the transition state analogue complexes.

Dodine as a transparent protein denaturant for circular dichroism and infrared studies

The fungicide dodine combines the cooperative denaturation properties of guanidine with the mM denaturation activity of SDS. It was previously tested only on two small model proteins. Here we show that it can be used as a chemical denaturant for phosphoglycerate kinase (PGK), a much larger two-domain enzyme. In addition to its properties as a chemical denaturant, dodine facilitates thermal denaturation of PGK, and we show for the first time that it also facilitates pressure denaturation of a protein. Much higher quality circular dichroism and amide I' infrared spectra of PGK can be obtained in dodine than in guanidine, opening the possibility for use of dodine as a denaturant when UV or IR detection is desirable. One caution is that dodine denaturation, like other detergent-based denaturants, is less reversible than guanidine denaturation.

Infrared studies reveal unique vibrations associated with the PGK-ATP-3-PG ternary complex

Phosphoglycerate kinase (PGK) catalyzes a reversible phospho-transfer reaction between ATP and 3-phosphoglycerate (3-PG) that is thought to require a hinge-bending motion in the protein that brings two separate substrate-binding domains together. We have used difference infrared spectroscopy to better understand the conformational changes that are unique to the PGK-ATP-3-PG complex. Caged nucleotides (caged-ADP and caged-ATP) were used to initiate nucleotide binding to PGK or PGK-3-PG complexes. The difference spectra include those of PGK-ATP minus PGK, PGK-3-PG-ATP minus PGK-3-PG, PGK-3-PG-ADP minus PGK-3-PG, and PGK-ADP minus PGK. The resulting spectra were compared in attempts to identify bands associated with each PGK complex. In addition, complementary activity assays were performed in the presence of caged-nucleotides. While PGK activity decreased in the presence of caged-ADP, the activity was not influenced by the addition of caged-ATP. The activity assay results suggest that the caged-ADP may interact with PGK substrate binding site(s) and inhibit phospho-transfer. Therefore, additional difference infrared nucleotide exchange experiments were used to isolate the differences between ADP and ATP binding to PGK. Difference FTIR spectra obtained on PGK-nucleotide-3-PG complexes show distinct bands that may result from amino acid side chains as well as structural changes in the hinge region and/or increased interactions such as salt bridges forming between the two domains. The infrared data obtained on the active ternary complexes show evidence of changes in alpha-helix and beta-structures as well as signals consistent with Arg, Asn, His, Lys, Asp, Glu, and additional side chains that are uniquely perturbed in the active ternary complex as compared to other PGK complexes.

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.

Molecular cloning and immunological characterization of phosphoglycerate kinase from Clonorchis sinensis

The parasite Clonorchis sinensis was determined to utilize a large amount of external glucose to carry its energy metabolism. Phosphoglycerate kinase (PGK), a glycolytic enzyme, found in many parasites, has been identified as one of the candidate molecules distinguished from human counterparts for vaccine and drug developments. A cDNA clone purified by screening a C. sinensis cDNA library using a heterologous cDNA probe encoded a putative peptide of 415 amino acids with over 60% identities with PGKs from a number of animals. The putative peptides revealed domains corresponding to 12 beta-sheets and inner loops forming a substrate-binding cleft of animal PGKs. The gene product was overexpressed in Escherichia coli and showed a PGK-like enzyme activity. A polyclonal antibody raised against the recombinant C. sinensis PGK was specific to native C. sinensis PGK and localized it to the muscular tissue and tegument of the adult flukes. The C. sinensis PGK elicited antibodies in C. sinensis-infected rabbits. Therefore, it is proposed that C. sinensis PGK could be used as an immunoreagent in the serodiagnosis for clonorchiasis.

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.

Conformational dynamics and enzyme activity

Conformational flexibility and structural fluctuations play an important role in enzyme activity. A great variety of internal motions ranging over different time scales and of different amplitudes are involved in the catalytic cycle. These different types of motions and their functional consequences are considered in the light of experimental data and theoretical analyses. The conformational changes upon substrate binding, and particularly the hinge-bending motion which occurs in enzymes made of two domains, are analyzed from several well documented examples. The conformational events accompanying the different steps of the catalytic cycle are discussed. The last section concerns the motions involved in the allosteric transition which regulates the enzyme activity.

An engineered amino-terminal domain of yeast phosphoglycerate kinase with native-like structure

Previous studies have suggested that the carboxy-terminal peptide (residues 401-415) and interdomain helix (residues 185-199) of yeast phosphoglycerate kinase, a two-domain enzyme, play a role in the folding and stability of the amino-terminal domain (residues 1-184). A deletion mutant has been created in which the carboxy-terminal peptide is attached to the amino-terminal domain (residues 1-184) plus interdomain helix (residues 185-199) through a flexible peptide linker, thus eliminating the carboxy-terminal domain entirely. CD, fluorescence, gel filtration, and NMR experiments indicated that, unlike versions described previously, this isolated N-domain is soluble, monomeric, compactly folded, native-like in structure, and capable of binding the substrate 3-phosphoglycerate with high affinity in a saturable manner. The midpoint of the guanidine-induced unfolding transition was the same as that of the native two-domain protein (Cm approximately 0.8 M). The free energy change associated with guanidine-induced unfolding was one-third that of the native enzyme, in agreement with previous studies that evaluated the intrinsic stability of the N-domain and the contribution of domain-domain interactions to the stability of PGK. These observations suggest that the C-terminal peptide and interdomain helix are sufficient for maintaining a native-like fold of the N-domain in the absence of the C-domain.

Glycolytic enzyme operon of Borrelia burgdorferi: characterization and evolutionary implications

The genes encoding three enzymes of the glycolytic pathway have been identified and sequenced completely in Borrelia burgdorferi sensu stricto and partially in B. hermsii. They are clustered on the chromosome into an operon with a single putative promoter and are arranged downstream of this promoter in the following order: gapdh (glyceraldehyde-3-phosphate dehydrogenase), pgk (phosphoglycerate kinase), and tpi (triosephosphate isomerase). gapdh and pgk are separated by 19 bp of intergenic sequence and pgk and tpi are separated by only 1 bp. Each of the three genes contains a putative RBS 6-7 bp upstream of each respective translational (ATG) start codon. The deduced protein encoded by gapdh consists of 335 amino acids (aa) with a predicted MW of 36,400, that of pgk is 393 aa (MW of 42,156) and that of tpi is 290 aa (MW of 27,683). The aa sequences of each of the three enzymes share 58.4% (GAPDH), 52.8% (PGK) and 46.1% (TPI) identity with respective enzymes from other prokaryotic organisms. Phylogenetic analyses based on these universal and conserved proteins support the hypothesis that spirochetes are an ancient and distinct eubacterial phylum.

Structure of the R65Q mutant of yeast 3-phosphoglycerate kinase complexed with Mg-AMP-PNP and 3-phospho-D-glycerate

The structure of a ternary complex of the R65Q mutant of yeast 3-phosphoglycerate kinase (PGK) with magnesium 5'-adenylylimidodiphosphate (Mg-AMP-PNP) and 3-phospho-D-glycerate (3-PG) has been determined by X-ray crystallography to 2.4 angstrom resolution. The structure was solved by single isomorphous replacement, anamalous scattering, and solvent flattening and has been refined to an R-factor of 0.185, with rms deviations from ideal bond distance and angles of 0.009 angstrom and 1.78 degrees, respectively. PGK consists of two domains, with the 3-PG bound to a "basic patch" of residues from the N-terminal domain and the Mg-AMP-PNP interacting with residues from the C-terminal domain. The two ligands are separated by approximately 11 angstrom across the interdomain cleft. The model of the R65Q mutant of yeast PGK is very similar to the structures of PGK isolated from horse, pig, and Bacillus stearothermophilus (rms deviations between equivalent alpha-carbons in the individual domains < 1.0 angstrom) but exhibits substantial variations with a previously reported yeast structure (rms deviations between equivalent alpha-carbons in the individual domains of 2.9-3.2 angstrom). The most significant tertiary structural differences among the yeast R65Q, equine, porcine, and B. stearothermophilus PGK structures occur in the relative orientations of the two domains. However, the relationships between the observed conformations of PGK are inconsistent with a "hinge-bending" behavior that would close the interdomain cleft. It is proposed that the available structural and biochemical data on PGK may indicate that the basic patch primarily represents the site of anion activation and not the catalytically active binding site for 3-PG.

Studies with inhibitors of the glycolytic enzyme phosphoglycerate kinase for potential treatment of cardiovascular and respiratory disorders

Inhibition of the glycolytic enzyme phosphoglycerate kinase (PGK) in erythrocyte cells could provide a method of treatment for cardiovascular and respiratory disorders. The product of the reaction catalysed by PGK, 1,3-diphosphoglycerate, is converted by another enzyme in erythrocytes to 2,3-diphosphoglycerate, which is an allosteric effector of haemoglobin. For this reason, a series of fluoro-phosphonate inhibitors have been tested for their potency in detailed inhibition kinetic experiments with yeast PGK. The results were analysed by Lineweaver-Burk and Dixon plots and Ki values obtained. Two fluorophosphonates were found to be inhibitory and both have an electron rich mid-chain functionality, which is thought to provide electrons for hydrogen bonding to residues in the triose binding site of the enzyme. It is postulated that either the fluorine or mid-chain moieties of the analogues are binding to Asp23 and Asn25 residues in the so called 'basic patch' area of the triose site. These residues are shown to bind to the D-hydroxyl moiety on the C2 of the true substrate, 3-phosphoglycerate, in the high-resolution crystal structure of pig muscle PGK co-crystallized with 3-phosphoglycerate.

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.

Site-directed mutagenesis of yeast phosphoglycerate kinase. Arginines 65, 121 and 168

In the absence of a structure of the closed form of phosphoglycerate kinase we have modified by site directed mutagenesis several of the residues which, on the basis of the open form structure, are likely to be involved in substrate binding and catalysis. Here we report on the kinetic and anion activation properties of the yeast enzyme modified at positions 65, 121 and 168. In each case an arginine, thought to be involved in the binding of the sugar substrate's non-transferable phosphate group, has been replaced by lysine (same charge) and by methionine (no charge). Km values for 3-phosphoglycerate of all six mutant enzymes are only marginally higher than that of the wild-type enzyme. Removing the charge associated with two of the three arginine residues appears to influence (as judged by the measured Km's) the binding of ATP. Although binding affinity is not necessarily coupled to turnover the substitutions which have the greatest effect on the Km's do correlate with the reduction in enzymes maximum velocity. The one exception to this generalisation is the R65K mutant which, surprisingly, has a significantly higher kcat than the wild-type enzyme. In the open form structure of the pig muscle enzyme each of the three substituted arginines residues are seen to make two hydrogen bonds to the sugar substrate's non-transferable phosphate. From this it might be expected that anion activation would be similarly affected by the substitution of any one of these three residues. Although the interpretation of such effects are complicated by the fact that one of the mutants (R65M) unfolds at low salt concentrations, this appears not to be the case. Replacing Arg121 and Arg168 with methionine reduces the anion activation whereas a lysine in either of these two positions practically destroys the effect. With the substitutions at residue 65 the opposite is observed in that the lysine mutant shows anion activation whereas the methionine mutant does not.

Identification, sequence analysis, and expression of a Corynebacterium glutamicum gene cluster encoding the three glycolytic enzymes glyceraldehyde-3-phosphate dehydrogenase, 3-phosphoglycerate kinase, and triosephosphate isomerase

To investigate a possible chromosomal clustering of glycolytic enzyme genes in Corynebacterium glutamicum, a 6.4-kb DNA fragment located 5' adjacent to the structural phosphoenolpyruvate carboxylase (PEPCx) gene ppc was isolated. Sequence analysis of the ppc-proximal part of this fragment identified a cluster of three glycolytic genes, namely, the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene gap, the 3-phosphoglycerate kinase (PGK) gene pgk, and the triosephosphate isomerase (TPI) gene tpi. The four genes are organized in the order gap-pgk-tpi-ppc and are separated by 215 bp (gap and pgk), 78 bp (pgk and tpi), and 185 bp (tpi and ppc). The predicted gene product of gap consists of 336 amino acids (M(r) of 36,204), that of pgk consists of 403 amino acids (M(r) of 42,654), and that of tpi consists of 259 amino acids (M(r) of 27,198). The amino acid sequences of the three enzymes show up to 62% (GAPDH), 48% (PGK), and 44% (TPI) identity in comparison with respective enzymes from other organisms. The gap, pgk, tpi, and ppc genes were cloned into the C. glutamicum-Escherichia coli shuttle vector pEK0 and introduced into C. glutamicum. Relative to the wild type, the recombinant strains showed up to 20-fold-higher specific activities of the respective enzymes. On the basis of codon usage analysis of gap, pgk, tpi, and previously sequenced genes from C. glutamicum, a codon preference profile for this organism which differs significantly from those of E. coli and Bacillus subtilis is presented.

A study of the hinge-bending mechanism of yeast 3-phosphoglycerate kinase

The hinge-bending mechanism proposed as part of the catalytic mechanism for phosphoglycerate kinase (PGK) has been investigated using yeast PGK and the site-directed mutant [H388Q]PGK, where His388 is replaced by Gln. The emission and quenching of fluorescence, supported by the aromatic CD band, show that the mutation in the waist region affects the tryptophan environment in the C-terminal domain. The mutant is also less stable to guanidine denaturation and less cooperative in its unfolding. The effect of substrates on the conformation of PGK was studied using 8-anilino-1-naphthalenesulphonic acid (ANS), a competitive inhibitor of ATP binding to the C-terminal domain, and 8-(2-[(iodoacetyl)ethyl]amino)naphthalene (I-AEDANS), attached to Cys197 on the N-terminal domain. Under the influence of substrates the novel anisotropy decay curves for ANS indicate a 1-5 degrees change in the orientation of the probe, interpreted as a small reorientation of the domains about the waist region. The experimental data are interpreted as a small swivelling of the domains about the waist region under the influence of substrate. The results with AEDANS anisotropy decay are consistent with those for ANS. The enzyme activity of PGK shows a break in the Arrhenius plot at 20 degrees C mirrored by a break in the temperature dependence of tryptophan ellipticity. This is interpreted as a change in protein dynamics associated with destabilisation of the waist region. This destabilisation is shown to have already taken place in the mutant enzyme and in the wild type at pH 5.6, both of which exhibit linear Arrhenius plots. NMR titration curves show that the pH effect must be due to a group other than histidine. The results give further support to the permissive model of hinge bending previously proposed by one of the authors, in which binding of substrate destabilises the waist region. This loosens the hinge which can then swing slightly to bring the domains closer together to make favourable interactions between the domains and the substrates, with the exclusion of water.

Structural studies by proton-NMR spectroscopy of plant horseradish peroxidase C, the wild-type recombinant protein from Escherichia coli and two protein variants, Phe41----Val and Arg38----Lys

Wild-type recombinant horseradish peroxidase isoenzyme C and two protein variants, Phe41----Val and Arg38----Lys, have been characterised using both one- and two-dimensional NMR spectroscopy. Proton NMR spectra recorded in both resting and cyanide-ligated states of the proteins were compared with those of the corresponding plant peroxidase. The latter contains 18% carbohydrate in eight N-linked oligosaccharide side chains whereas the recombinant proteins are expressed in nonglycosylated form. The spectra of the plant enzyme and refolded recombinant protein are essentially identical with the exception of carbohydrate-linked resonances in the former, indicating that their solution structures are highly similar. This comparison also identifies classes of carbohydrate resonances in the plant enzyme which provides new information on the local environment and mobility of the oligosaccharide side chains. Comparison of the spectra of the cyanide-ligated states of the two variants and those of plant horseradish peroxidase C indicated that there were significant differences with respect to haem and haem-linked resonances. These could not be rationalised simply on the basis of the local perturbation expected from a single-site substitution. The two substitutions made to residues on the distal side of the haem apparently influenced the degree of imidazolate character of the proximal His170 imidazole ring thus perturbing the magnetic environment of the haem group. Inspection of the spectra of the Phe41----Val variant also showed that the resonances of a phenylalanine residue in the haem pocket had been incorrectly assigned to Phe41 in a previous study. A new assignment, based on additional information from two-dimensional nuclear Overhauser enhancement spectroscopy, was made to Phe152. The assignments made for the Phe41----Val variant were also used as a basis to investigate the structure of the complex formed with the aromatic donor molecule, benzhydroxamic acid.

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.

Characterization of the structure and properties of the His 62-->Ala and Arg 38-->Ala mutants of yeast phosphoglycerate kinase: an investigation of the catalytic and activatory sites by site-directed mutagenesis and NMR

The role of two "basic patch" residues, Arg-38 and His-62, in the catalytic function and anion-dependent activation of yeast 3-phosphoglycerate kinase (PGK) was investigated by site-directed mutagenesis. Steady-state kinetics and NMR experiments were conducted to characterize the functional properties and structural integrity of the R38A and H62A mutants. The results of these studies, in combination with earlier mutagenesis experiments, suggest that Arg-38 is the only catalytically essential residue among the conserved histidines and arginines of the basic patch. It appears that, similar to the remaining basic patch residues, His-62 is important for anion-dependent activation but not for enzyme activity. Cumulative evidence from this study and from previous mutagenesis experiments suggests that the basic patch region is in effect an extended anion binding site that encompasses both the catalytic and the general anion-binding site. It is proposed that substitution of any one of the basic patch residues results in an increased localization of the catalytic site. Substrate and product may still bind to this site, but a simultaneous binding of activatory anions, required for activation, has been impaired. NMR experiments suggest that the conformational changes observed upon binding of 3-PG to wild-type PGK are necessary for anion- and substrate-dependent activation.

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.

Crystal structure of the binary complex of pig muscle phosphoglycerate kinase and its substrate 3-phospho-D-glycerate

Pig muscle phosphoglycerate kinase has been crystallized from polyethyleneglycol in the presence of its substrate 3-phospho-D-glycerate (3-PG) and the structure has been determined at 2.0 A resolution. The structure was solved using the known structure of the substrate-free horse muscle enzyme and has been refined to a crystallographic R-factor of 21.5%. 3-Phospho-D-glycerate is bound to the N-domain of the enzyme through a network of hydrogen bonds to a cluster of basic amino acid residues and by electrostatic interactions between the negatively charged phosphate and these basic protein side chains. This binding site is in good agreement with earlier proposals [Banks et al., Nature (London) 279:773-777, 1979]. The phosphate oxygen atoms are hydrogen bonded to His-62, Arg-65, Arg-122, and Arg-170. The 2-hydroxyl group, which defines the D-isomer of 3PG, is hydrogen bonded to Asp-23 and Asn-25. The carboxyl group of 3-PG points away from the N-domain towards the C-domain and is hydrogen bonded via a water molecule to main chain nitrogen atoms of helix-14. The present structure of the 3-PG-bound pig muscle enzyme is compared with the structure of the substrate-free horse enzyme. Major changes include an ordering of helix-13 and a domain movement, which brings the N-domain closer to the ATP-binding C-domain. This domain movement consists of a 7.7 degree rotation, which is less than previously estimated for the ternary complex. Local changes close to the 3-PG binding site include an ordering of Arg-65 and a shift of helix-5.

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

1H-NMR measurements were made of solutions of yeast phosphoglycerate kinase containing the nucleotide, ADP, and Mg2+ in varying concentrations in order to investigate the affect that the metal ion has on the mode of ADP binding to the enzyme. A preliminary study of adenosine binding to phosphoglycerate kinase was made in order to be sure of the nature of the adenine site. From the change in chemical shifts of the 'basic patch' histidine resonances (His62, 167 and 170), the nucleotide C8-H, C2-H and C1'-H resonances and resonances 40 and 41 (assigned to Thr373 and Thr375 in the hydrophobic, i.e. catalytic, site), it is apparent that there are at least two ADP binding sites on the enzyme: one at the hydrophobic (catalytic) site and one at the electrostatic site. A comparison of the results for ADP and ATP reveals differences due to the differential binding of the phosphate groups. The presence of Mg2+ results in further differences being observed. The data suggest that the primary binding site of ADP, in the absence of Mg2+, involves electrostatic interactions between the diphosphate chain of the substrate and the 'basic patch' region of the N-terminal domain. In the presence of greater than or equal to 1:1 ratio of Mg2+/ADP, however, the primary binding site involves predominantly hydrophobic interactions between the adenosine moiety and the catalytic site, with secondary binding occurring at the electrostatic site. Addition of Mg2+, therefore, tends to reduce the affinity of the electrostatic site (presumably by competing for ADP). It is suggested that alpha-helix XII, including residues 372, 373 and 375, moves differentially on binding ADP, Mg ADP, ATP or Mg . ATP, consistent with Mg2+ assisting the transfer of the gamma-phosphate of ATP to 3-phosphoglycerate during catalysis.

Conformational changes in yeast phosphoglycerate kinase upon ligand binding: fluorescence of a linked probe and chemical reactivity of genetically introduced cysteinyl residues

The effects of ligands on the conformation of yeast phosphoglycerate kinase were explored by introducing cysteinyl residues at different positions in the molecule by site-directed mutagenesis. Thus several mutants were constructed, each containing a unique cysteinyl residue. Neither the conformation nor the enzyme activity was affected by the substitutions. The reactivity of the thiol groups and the fluorescence of N-acetyl-N'-(5-sulfo-1-naphthyl)ethylene-diamine covalently linked to these thiols were used to monitor the conformational changes induced upon ligand binding. It was found that the observed changes mainly involve the part of the protein located in the cleft, particularly the environment of residues 35 and 183. No alteration was observed on the external side of the protein. Only 3-Phosphoglycerate induced these conformational changes. However, when the fluorescent probe was attached to residue 377, the binding of the two substrates was required to induce a modification in the fluorescence of the probe. These results indicate that the substrates separately or together induce discrete molecular motions in phosphoglycerate kinase.

Glycolytic pathway of the human malaria parasite Plasmodium falciparum: primary sequence analysis of the gene encoding 3-phosphoglycerate kinase and chromosomal mapping studies

We have isolated and characterised the gene (PGK) encoding the glycolytic enzyme 3-phosphoglycerate kinase (PGK) from the human malaria parasite Plasmodium falciparum. This was achieved using the polymerase chain reaction (PCR) to amplify genomic DNA with primers constructed on the basis of conserved regions identified within PGK molecules of other organisms, and using the PCR product to isolate genomic clones. The gene is present in a single copy, encoding a protein of 416 amino acids (aa). The predicted aa sequence (45.5 kDa) displays approx. 60% identity to both human and yeast PGK molecules, and of the three P. falciparum glycolytic enzymes reported to date, has the greatest sequence identity to the host homologue. All aa residues implicated in substrate and cofactor binding and catalysis are conserved in the malarial PGK molecule, but there are major differences in overall composition, with implications for enzyme stability. In asexual blood-stage parasites, a single mRNA transcript of approx. 2.1 kb is observed. We have mapped the PGK gene to chromosome 9 of the parasite, and a further gene encoding a glycolytic enzyme, aldolase, to chromosome 14.

A proton-NMR study of a site-directed mutation (His388----Glu) in the interdomain region of yeast phosphoglycerate kinase. Implications for domain movement

Proton NMR has been used to study a site-directed mutant of yeast phosphoglycerate kinase in which the interdomain residue His388 has been replaced by a glutamine residue. Using 1H-NMR spectroscopy, it was found that 3-phosphoglycerate binding to the mutant protein induces different conformational effects to those observed for the wild-type enzyme. These differences are not only located at the 3-phosphoglycerate binding site but are also seen as long-range effects at the surface of the protein. Measurements of the Kd for 3-phosphoglycerate from the NMR experiments show that the mutant enzyme has a 30-times reduced affinity for this substrate as compared with the wild-type enzyme. These data are consistent with the suggestion that an aromatic residue at position 388 plays an important role in the proposed hinge-bending mechanism.

Cloning and sequencing the gene encoding 3-phosphoglycerate kinase from mesophilic Methanobacterium bryantii and thermophilic Methanothermus fervidus

The nucleotide sequences of the gene (pgk) encoding 3-phosphoglycerate kinase (PGK) from the mesophilic archaebacterium, Methanobacterium bryantii, and from the closely related thermophile, Methanothermus fervidus, were determined. The deduced amino acid (aa) sequences show 61% identity with each other and 32-36% identity with the enzyme homologues from eubacteria and eukaryotes. As found for glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and L-malate dehydrogenase, the relatedness between the archaebacterial aa sequences on the one hand and the eubacterial or eukaryotic sequences on the other is lower than that between the latter ones. Comparison of the aa sequence of PGK from mesophilic and thermophilic archaebacteria indicates an increase of the overall hydrophobicity and a decrease of the chain flexibility in the thermophilic enzyme, as already deduced from respective comparisons between GAPDH aa sequences of the same organisms. In addition, glycine residues are strikingly discriminated in the thermophilic PGK, which was also observed for GAPDH. Contrary to GAPDH, however, Lys and Arg residues are preferred in the thermophilic PGK. Lys to Arg substitutions are the most frequent cold-to-hot changes in PGK, whereas in GAPDH from the same organisms these changes do not occur.

The roles of ATP4- and Mg2+ in control steps of phosphoglycerate kinase

1H-NMR measurements were made of solutions of yeast phosphoglycerate kinase containing the nucleotide substrate, ATP, and Mg2+ in varying concentrations in order to investigate the affect that the metal ion has on the mode of ATP binding to the enzyme. From the change in the chemical shifts of the 'basic-patch' histidine resonances (His62, His167 and His170) and the nucleotide C8H, C2H and C1'H resonances it is apparent that there are at least two ATP-binding sites on the enzyme. Downfield shifts observed for the above histidine resonances at low nucleotide/enzyme molar ratios indicates that the primary binding site involves electrostatic interactions between the nucleotide triphosphate chain and the basic-patch region of the N-terminal domain. The secondary binding site is shown to involve predominantly hydrophobic interactions between the adenosine moiety and the protein. Evidence from previous two-dimensional NMR experiments [Fairbrother et al. (1990) Eur. J. Biochem. 190, 161-169] suggests that the secondary site is equivalent to the crystallographically observed catalytic site. The affinity of the catalytic site is increased relative to the primary electrostatic site with increasing Mg2+ concentration. The possible importance of these observations in the regulation of this enzyme in vivo are discussed.

An NMR study of anion binding to yeast phosphoglycerate kinase

Anion binding to yeast phosphoglycerate kinase has been investigated using 1H-NMR spectroscopy. The use of anionic paramagnetic probes. [Cr(CN)6]3- and [Fe(CN)6]3-, has enabled the location of the primary anion binding site in the 'basic-patch' region of the amino-terminal domain. The anions interact most closely with Arg-65 and Arg-168. The binding of these and a variety of other anions to this site is directly competitive with the binding of the substrate, 3-phosphoglycerate. Binding of 3-phosphoglycerate and 1.3-bisphosphoglycerate is, however, stronger than expected on the basis of anionic charge and causes conformational changes in the protein not seen with any of the other simple spherical anions investigated. This must be part, at least, of the substrate specificity. Evidence for a secondary anion binding site involving the side chains of surface lysine residues is also presented. It is suggested that the primary anion site is responsible for the observed activation by anions at low concentrations while the secondary site leads to inhibition at higher anion concentrations. The kinetics fit these deductions and a scheme for kinase activity is presented.

The effects of ligands on the conformation of phosphoglycerate kinase: fluorescence anisotropy decay and theoretical interpretation

Horse muscle phosphoglycerate kinase (PGK) is a monomer folded into two widely distant domains. In the glycolytic pathway, this enzyme catalyzes the first reaction that produces ATP. It was suggested, by analogy with yeast hexokinase, that a hinge-bending motion may be induced by the binding of specific substrates to the protein. To analyze such a motion, or any structural changes induced by ligand binding, fluorescence anisotropy decay of tryptophan residues in free and liganded PGK was studied. At 293 K, for the free protein and the binary complex with 3-phosphoglycerate, a single correlation time of 26 ns was observed, corresponding to the rotation of the overall protein, whereas upon addition of MgADP, this correlation time decreased to 10 ns. Such a decrease cannot be merely due to a change of the protein's shape and volume. To explain this, it was suggested that the fluorescence anisotropy decay of the PGK-MgADP complex corresponded to the rotation of the only buried tryptophan (Trp 335). The rotational paths of this tryptophan, in the presence and absence of the nucleotide, were established by potential energy minimization calculations. The results indicated that MgADP induces a displacement of helix alpha-13 that decreases the rotational energy barrier of Trp 335 from 16 kcal/mol in the free protein to 8 kcal/mol in the complex.

Site-directed mutagenesis of histidine 62 in the 'basic patch' region of yeast phosphoglycerate kinase

Site-directed mutagenesis has been used to produce a mutant form of yeast phosphoglycerate kinase (PGK) in which the 'basic patch' residue His 62 has been replaced by a glutamine residue. Using 1H-NMR spectroscopy, it was found that 3-phosphoglycerate (3-PG) binding to the mutant protein induces the same conformational effects as for wild-type PGK, although the affinity was reduced by 2- to 3-fold. Kinetic studies show both Km for 3-PG and Vmax to be increased by approximately 2-fold relative to the wild-type enzyme. These data are consistent with the suggestion that His 62 assists in the binding of the substrate to the enzyme.

One- and two-dimensional NMR studies of yeast phosphoglycerate kinase

One- and two-dimensional proton NMR studies have been carried out on yeast phosphoglycerate kinase (Mr approximately 45,000) in order to identify amino-acid spin systems and obtain sequence-specific assignments. A number of sequence-specific assignments have been made using a combination of structural information contained in nuclear Overhauser effect spectra and X-ray crystallographic data. The results of substrate binding studies (both 3-phosphoglycerate and Mg.ATP), which indicate mutual reorientation of certain assigned aromatic residues in the inter-domain region of the protein, are discussed.

An NMR analysis of the binding of inhibitors to yeast phosphoglycerate kinase

The binding of a series of inhibitors to the enzyme phosphoglycerate kinase has been studied using NMR to uncover the binding sites and the effects of binding on the protein conformation. The very effective inhibitor, Suramin, causes the most pronounced changes. The design of inhibitors for mobile proteins is discussed.

Site-directed mutagenesis of yeast phosphoglycerate kinase. The 'basic-patch' residue arginine 168

There is evidence, some of it of questionable authenticity, which suggests that phosphoglycerate kinase takes up a more compact form following the binding of substrates. Using this evidence it has been assumed that a conformational rearrangement is required for phosphoryl transfer to occur and that this is brought about by moving the enzyme's two domains towards each other. In order to test this hypothesis we have modified, by site-directed mutagenesis, an arginine residue thought to be involved in stabilising the transition-state intermediate. Although some 1.3 nm away from the site of phosphoryl transfer, as seen in the crystallographically determined structure, the substitution of arginine 168 by lysine (R168K) more than halves the specific activity of the enzyme. Substituting the arginine with a methionine (R168M) reduces activity further, but not completely, thus proving that the charge associated with this residue is not essential for catalytic activity. Both mutations raise the Michaelis constants (Km) for ATP and glycerate 3-phosphate. The largest change is observed with the triose substrate and the methionine mutant, suggesting that the primary function of arginine 168 is to influence the environment of this substrate. The effect on activity of adding sulphate to R168K and R168M mutant enzyme has also been investigated. The sulphate activation effect at low substrate concentrations is reduced for the methionine substitution but almost abolished for the lysine substitution. The most reasonable explanation of all these findings is that, in the wild-type enzyme, the guanidinium group of arginine 168 forms a hydrogen bond with one of the triose substrate's C1 oxygens. This steric arrangement would not be possible in the 'open form' of this enzyme as observed in the crystal structure.