Judit Szabó

Transition State Analogue Structures of Human Phosphoglycerate Kinase Establish the Importance of Charge Balance in Catalysis.

Transition state analogue (TSA) complexes formed by phosphoglycerate kinase (PGK) have been used to test the hypothesis that balancing of charge within the transition state dominates enzyme-catalyzed phosphoryl transfer. High-resolution structures of trifluoromagnesate (MgF(3)(-)) and tetrafluoroaluminate (AlF(4)(-)) complexes of PGK have been determined using X-ray crystallography and (19)F-based NMR methods, revealing the nature of the catalytically relevant state of this archetypal metabolic kinase. Importantly, the side chain of K219, which coordinates the alpha-phosphate group in previous ground state structures, is sequestered into coordinating the metal fluoride, thereby creating a charge environment complementary to the transferring phosphoryl group. In line with the dominance of charge balance in transition state organization, the substitution K219A induces a corresponding reduction in charge in the bound aluminum fluoride species, which changes to a trifluoroaluminate (AlF(3)(0)) complex. The AlF(3)(0) moiety retains the octahedral geometry observed within AlF(4)(-) TSA complexes, which endorses the proposal that some of the widely reported trigonal AlF(3)(0) complexes of phosphoryl transfer enzymes may have been misassigned and in reality contain MgF(3)(-).

Highly potent dUTPase inhibition by a bacterial repressor protein reveals a novel mechanism for gene expression control

Transfer of phage-related pathogenicity islands of Staphylococcus aureus (SaPI-s) was recently reported to be activated by helper phage dUTPases. This is a novel function for dUTPases otherwise involved in preservation of genomic integrity by sanitizing the dNTP pool. Here we investigated the molecular mechanism of the dUTPase-induced gene expression control using direct techniques. The expression of SaPI transfer initiating proteins is repressed by proteins called Stl. We found that Φ11 helper phage dUTPase eliminates SaPIbov1 Stl binding to its cognate DNA by binding tightly to Stl protein. We also show that dUTPase enzymatic activity is strongly inhibited in the dUTPase:Stl complex and that the dUTPase:dUTP complex is inaccessible to the Stl repressor. Our results disprove the previously proposed G-protein-like mechanism of SaPI transfer activation. We propose that the transfer only occurs if dUTP is cleared from the nucleotide pool, a condition promoting genomic stability of the virulence elements.

Substrate-induced double sided H-bond network as a means of domain closure in 3-phosphoglycerate kinase

Closure of the two domains of 3‐phosphoglycerate kinase, upon substrate binding, is essential for the enzyme function. The available crystal structures cannot provide sufficient information about the mechanism of substrate assisted domain closure and about the requirement of only one or both substrates, since lattice forces may hinder the large scale domain movements. In this study the known X‐ray data, obtained for the open and closed conformations, were probed by solution small‐angle X‐ray scattering experiments. The results prove that binding of both substrates is essential for domain closure. Molecular graphical analysis, indeed, reveals formation of a double‐sided H‐bond network, which affects substantially the shape of the main molecular hinge at β‐strand L, under the concerted action of both substrates.

Nucleotide pyrophosphatase employs a P-loop-like motif to enhance catalytic power and NDP/NTP discrimination

We investigated the potential (d)NDP/(d)NTP discrimination mechanisms in nucleotide pyrophosphatases. Here, we report that dUTPase, an essential nucleotide pyrophosphatase, uses a C-terminal P-loop-like sequence in a unique mechanism for substrate discrimination and efficient hydrolysis. Our spectroscopy and transient kinetics results on human dUTPase mutants combined with previous structural studies indicate that (i) H-bond interactions between the γ-phosphate and the P-loop-like motif V promote the catalytically competent conformation of the reaction center at the α-phosphate group; (ii) these interactions accelerate the chemical step of the kinetic cycle and that (iii) hydrolysis occurs very slowly or not at all in the absence of the γ-phosphate—motif V interactions, i.e., in dUDP, dUDP.BeFx, or in the motif V-deleted mutant. The physiological role of dUTPase is to set cellular dUTP∶dTTP ratios and prevent injurious uracil incorporation into DNA. Based upon comparison with related pyrophosphate generating (d)NTPases, we propose that the unusual use of a P-loop-like motif enables dUTPases to achieve efficient catalysis of dUTP hydrolysis and efficient discrimination against dUDP at the same time. These specifics might have been advantageous on the appearance of uracil-DNA repair. The similarities and differences between dUTPase motif V and the P-loop (or Walker A sequence) commonly featured by ATP- and GTPases offer insight into functional adaptation to various nucleotide hydrolysis tasks.

Communication between the nucleotide site and the main molecular hinge of 3-phosphoglycerate kinase

3-Phosphoglycerate kinase is a hinge-bending enzyme with substrate-assisted domain closure. However, the closure mechanism has not been described in terms of structural details. Here we present experimental evidence of the participation of individual substrate binding side chains in the operation of the main hinge which is distant from the substrate binding sites. The combined mutational, kinetic, and structural (DSC and SAXS) data for human 3-phosphoglycerate kinase have shown that catalytic residue R38, which also binds the substrate 3-phosphoglycerate, is essential in inducing domain closure. Similarly, residues K219, N336, and E343 which interact with the nucleotide substrates are involved in the process of domain closure. The other catalytic residue, K215, covers a large distance during catalysis but has no direct role in domain closure. The transmission path of the nucleotide effect toward the main hinge of PGK is described for the first time at the level of interactions existing in the tertiary structure.

Structure and enzymatic mechanism of a moonlighting dUTPase

Genome integrity requires well controlled cellular pools of nucleotides. dUTPases are responsible for regulating cellular dUTP levels and providing dUMP for dTTP biosynthesis. In Staphylococcus, phage dUTPases are also suggested to be involved in a moonlighting function regulating the expression of pathogenicity-island genes. Staphylococcal phage trimeric dUTPase sequences include a specific insertion that is not found in other organisms. Here, a 2.1 Å resolution three-dimensional structure of a ϕ11 phage dUTPase trimer with complete localization of the phage-specific insert, which folds into a small β-pleated mini-domain reaching out from the dUTPase core surface, is presented. The insert mini-domains jointly coordinate a single Mg2+ ion per trimer at the entrance to the threefold inner channel. Structural results provide an explanation for the role of Asp95, which is suggested to have functional significance in the moonlighting activity, as the metal-ion-coordinating moiety potentially involved in correct positioning of the insert. Enzyme-kinetics studies of wild-type and mutant constructs show that the insert has no major role in dUTP binding or cleavage and provide a description of the elementary steps (fast binding of substrate and release of products). In conclusion, the structural and kinetic data allow insights into both the phage-specific characteristics and the generally conserved traits of ϕ11 phage dUTPase.

Thermodynamic analysis of substrate induced domain closure of 3-phosphoglycerate kinase

The energetic changes accompanying domain closure of 3‐phosphoglycerate kinase, a typical hinge‐bending enzyme, were assessed. Calorimetric titrations of the enzyme with each substrate, both in the absence and presence of the other one, provide information not only about the energetics of substrate binding, but of the associated conformational changes, including domain closure. Our results suggest that conformational rearrangements in the hinge generated by binding of both substrates provide the main driving force for domain closure overcoming the slightly unfavourable contact interactions between the domains.

Reproduction of shortage in the Hungarian car market

The basic question considered in this chapter is: what are the shortage phenomena that appear in the car market, and what are the factors that account for the perpetuation of shortage in this market? Using the general theoretical ideas and analytical apparatus previously developed by one of the authors (Kornai, 1980), we try to discover whether there are any regularities that are theoretically important in the development of demand and supply, in the behaviour of buyer and seller and in the changes that occur in the market situation.

Role of side-chains in the operation of the main molecular hinge of 3-phosphoglycerate kinase

The single mutants (F165A, E192A, F196A, S392A, T393A) at and near the main hinge (β‐strand L) of human 3‐phosphoglycerate kinase (hPGK) exhibit variously reduced enzyme activity, indicating the cumulative effects of these residues in regulating domain movements. The residues F165 and E192 are also essential in maintaining the conformational integrity of the whole molecule, including the hinge‐region. Shortening of βL by deleting T393 has led to a dramatic activity loss and the concomitant absence of domain closure (as detected by small angle X‐ray scattering), demonstrating the role of βL in functioning of hPGK. The role of each residue in the conformational transmission is described.

Direct kinetic evidence that lysine 215 is involved in the phospho-transfer step of human 3-phosphoglycerate kinase

3-Phosphoglycerate kinase (PGK) is a promising candidate for the activation of nucleotide analogues used in antiviral and anticancer therapies. PGK is a key enzyme in glycolysis; it catalyzes the reversible reaction 1,3-bisphosphoglycerate + ADP <--> 3-phosphoglycerate + ATP. Here we explored the catalytic role in human PGK of the highly conserved Lys 215 that has been proposed to be essential for PGK function by a transient and equilibrium kinetic study with the active site mutant K215A. By the stopped-flow method we show that the kinetics of substrate binding and the associated protein isomerization steps are fast and identical for the wild-type PGK and mutant K215A. By the use of a chemical sampling method (rapid quench flow) under multiple and single turnover conditions and in both directions of the reaction, we show that the rate-limiting step with wild-type PGK follows product formation (presumably product release), whereas with the mutant it is the phospho-transfer step itself that is rate-limiting. Mutant K215A has a low inherent phosphotransferase activity, and to explain this, we carried out a molecular modeling study. This suggests that with the mutant the conserved Arg 65 replaces the missing Lys 215 by helping to position the transferable phospho group during the reaction. Molecular dynamics simulations suggest that in the mutant the closed conformation of the enzyme is stabilized by a salt bridge between Asp 218 and Arg 170 rather than Arg 65 in the wild-type PGK.