Your search keyword '"Baxter NJ"' showing total 6 results

1. 1 H, 15 N, 13 C backbone resonance assignments of human phosphoglycerate kinase in a transition state analogue complex with ADP, 3-phosphoglycerate and magnesium trifluoride.

Author

Serimbetov Z, Baxter NJ, Cliff MJ, and Waltho JP

Subjects

Humans, Models, Molecular, Protein Binding, Protein Conformation, alpha-Helical, Adenosine Diphosphate metabolism, Fluorides metabolism, Glyceraldehyde 3-Phosphate metabolism, Magnesium Compounds metabolism, Nuclear Magnetic Resonance, Biomolecular, Phosphoglycerate Kinase chemistry, Phosphoglycerate Kinase metabolism

Abstract

Human phosphoglycerate kinase (PGK) is an energy generating glycolytic enzyme that catalyses the transfer of a phosphoryl group from 1,3-bisphosphoglycerate (BPG) to ADP producing 3-phosphoglycerate (3PG) and ATP. PGK is composed of two α/β Rossmann-fold domains linked by a central α-helix and the active site is located in the cleft formed between the N-domain which binds BPG or 3PG, and the C-domain which binds the nucleotides ADP or ATP. Domain closure is required to bring the two substrates into close proximity for phosphoryl transfer to occur, however previous structural studies involving a range of native substrates and substrate analogues only yielded open or partly closed PGK complexes. X-ray crystallography using magnesium trifluoride (MgF 3 - ) as a isoelectronic and near-isosteric mimic of the transferring phosphoryl group (PO 3 - ), together with 3PG and ADP has been successful in trapping human PGK in a fully closed transition state analogue (TSA) complex. In this work we report the 1 H, 15 N and 13 C backbone resonance assignments of human PGK in the solution conformation of the fully closed PGK:3PG:MgF 3 :ADP TSA complex. Assignments were obtained by heteronuclear multidimensional NMR spectroscopy. In total, 97% of all backbone resonances were assigned in the complex, with 385 out of a possible 399 residues assigned in the 1 H- 15 N TROSY spectrum. Prediction of solution secondary structure from a chemical shift analysis using the TALOS-N webserver is in good agreement with the published X-ray crystal structure of this complex.

Published

2017

2. Atomic details of near-transition state conformers for enzyme phosphoryl transfer revealed by MgF-3 rather than by phosphoranes.

Author

Baxter NJ, Bowler MW, Alizadeh T, Cliff MJ, Hounslow AM, Wu B, Berkowitz DB, Williams NH, Blackburn GM, and Waltho JP

Subjects

Catalytic Domain, Crystallography, X-Ray, Fluorides metabolism, Glucosephosphates chemistry, Glucosephosphates metabolism, Hydrogen Bonding, Magnesium Compounds metabolism, Magnetic Resonance Spectroscopy, Models, Molecular, Molecular Conformation, Molecular Structure, Phosphates chemistry, Phosphates metabolism, Phosphoglucomutase metabolism, Phosphoranes metabolism, Protein Binding, Protein Conformation, Fluorides chemistry, Magnesium Compounds chemistry, Phosphoglucomutase chemistry, Phosphoranes chemistry

Abstract

Prior evidence supporting the direct observation of phosphorane intermediates in enzymatic phosphoryl transfer reactions was based on the interpretation of electron density corresponding to trigonal species bridging the donor and acceptor atoms. Close examination of the crystalline state of beta-phosphoglucomutase, the archetypal phosphorane intermediate-containing enzyme, reveals that the trigonal species is not PO-3 , but is MgF-3 (trifluoromagnesate). Although MgF-3 complexes are transition state analogues rather than phosphoryl group transfer reaction intermediates, the presence of fluorine nuclei in near-transition state conformations offers new opportunities to explore the nature of the interactions, in particular the independent measures of local electrostatic and hydrogen-bonding distributions using 19F NMR. Measurements on three beta-PGM-MgF-3 -sugar phosphate complexes show a remarkable relationship between NMR chemical shifts, primary isotope shifts, NOEs, cross hydrogen bond F...H-N scalar couplings, and the atomic positions determined from the high-resolution crystal structure of the beta-PGM-MgF--3 -G6P complex. The measurements provide independent validation of the structural and isoelectronic MgF--3 model of near-transition state conformations.

Published

2010

3. MgF(3)(-) and alpha-galactose 1-phosphate in the active site of beta-phosphoglucomutase form a transition state analogue of phosphoryl transfer.

Author

Baxter NJ, Hounslow AM, Bowler MW, Williams NH, Blackburn GM, and Waltho JP

Subjects

Catalytic Domain, Fluorides metabolism, Magnesium Compounds metabolism, Phosphates metabolism, Phosphoglucomutase metabolism, Fluorides chemistry, Glucosephosphates chemistry, Magnesium Compounds chemistry, Phosphates chemistry, Phosphoglucomutase chemistry

Abstract

(19)F-based NMR analysis and hydrogen/deuterium primary isotope shifts establish the formation of a highly populated solution-state trigonal bipyramidal complex involving beta-phosphoglucomutase (beta-PGM), alpha-galactose 1-phosphate (alphaGal1P), and trifluoromagnesate (MgF(3)(-)), PGM-MgF(3)-alphaGal1P, that is a transition state analogue for phosphoryl transfer. Full backbone resonance assignment of the protein shows that its structure is in the closed conformation required for catalytic activity and is closely related to the corresponding complex with glucose 6-phosphate, which we have recently identified using NMR analysis in solution and X-ray crystallography in the solid state. The previous identification of three structural waters in a PGM-alphaGal1P binary substrate complex had indicated that, in the presence of alphaGal1P, magnesium ions, and fluoride, beta-PGM should indeed form a PGM-MgF(3)-alphaGal1P-TSA complex whereas, in the solid-state, apparently it did not. This cast doubt on the validity of the interpretation of MgF(3)(-) complexes. The present work establishes that, in solution, the expectation that a PGM-MgF(3)-alphaGal1P-TSA complex should readily form is fulfilled. These results thus refute the final evidence used to claim that the trigonal bipyramidal species observed in some solid-state structures of complexes involving beta-PGM are pentaoxyphosphorane intermediates.

Published

2009

4. Kinetic analysis of beta-phosphoglucomutase and its inhibition by magnesium fluoride.

Author

Golicnik M, Olguin LF, Feng G, Baxter NJ, Waltho JP, Williams NH, and Hollfelder F

Subjects

Biocatalysis, Crystallography, X-Ray, Enzyme Inhibitors chemistry, Fluorides chemistry, Glucosephosphates chemical synthesis, Glucosephosphates chemistry, Kinetics, Magnesium Compounds chemistry, Molecular Structure, Phosphoglucomutase metabolism, Protein Binding, Enzyme Inhibitors pharmacology, Fluorides pharmacology, Magnesium Compounds pharmacology, Phosphoglucomutase antagonists & inhibitors

Abstract

The isomerization of beta-glucose-1-phosphate (betaG1P) to beta-glucose-6-phosphate (G6P) catalyzed by beta-phosphoglucomutase (betaPGM) has been examined using steady- and presteady-state kinetic analysis. In the presence of low concentrations of beta-glucose-1,6-bisphosphate (betaG16BP), the reaction proceeds through a Ping Pong Bi Bi mechanism with substrate inhibition (kcat = 65 s(-1), K(betaG1P) = 15 microM, K(betaG16BP) = 0.7 microM, Ki = 122 microM). If alphaG16BP is used as a cofactor, more complex kinetic behavior is observed, but the nonlinear progress curves can be fit to reveal further catalytic parameters (kcat = 74 s(-1), K(betaG1P) = 15 microM, K(betaG16BP) = 0.8 microM, Ki = 122 microM, K(alphaG16BP) = 91 microM for productive binding, K(alphaG16BP) = 21 microM for unproductive binding). These data reveal that variations in the substrate structure affect transition-state affinity (approximately 140,000-fold in terms of rate acceleration) substantially more than ground-state binding (110-fold in terms of binding affinity). When fluoride and magnesium ions are present, time-dependent inhibition of the betaPGM is observed. The concentration dependence of the parameters obtained from fitting these progress curves shows that a betaG1P x MgF3(-) x betaPGM inhibitory complex is formed under the reaction conditions. The overall stability constant for this complex is approximately 2 x 10(-16) M(5) and suggests an affinity of the MgF3(-) moiety to this transition-state analogue (TSA) of < or = 70 nM. The detailed kinetic analysis shows how a special type of TSA that does not exist in solution is assembled in the active site of an enzyme. Further experiments show that under the conditions of previous structural studies, phosphorylated glucose only persists when bound to the enzyme as the TSA. The preference for TSA formation when fluoride is present, and the hydrolysis of substrates when it is not, rules out the formation of a stable pentavalent phosphorane intermediate in the active site of betaPGM.

Published

2009

5. Anionic charge is prioritized over geometry in aluminum and magnesium fluoride transition state analogs of phosphoryl transfer enzymes.

Author

Baxter NJ, Blackburn GM, Marston JP, Hounslow AM, Cliff MJ, Bermel W, Williams NH, Hollfelder F, Wemmer DE, and Waltho JP

Subjects

Anions chemistry, Binding Sites, Catalysis, Geobacillus stearothermophilus enzymology, Hydrogen-Ion Concentration, Ligands, Magnetic Resonance Spectroscopy methods, Magnetic Resonance Spectroscopy standards, Models, Molecular, Molecular Conformation, Protein Structure, Tertiary, Reference Standards, Aluminum Compounds chemistry, Fluorides chemistry, Magnesium Compounds chemistry, Phosphoglycerate Kinase chemistry, Phosphoric Monoester Hydrolases chemistry, Phosphotransferases (Phosphomutases) chemistry

Abstract

Phosphoryl transfer reactions are ubiquitous in biology and metal fluoride complexes have played a central role in structural approaches to understanding how they are catalyzed. In particular, numerous structures of AlFx-containing complexes have been reported to be transition state analogs (TSAs). A survey of nucleotide kinases has proposed a correlation between the pH of the crystallization solution and the number of coordinated fluorides in the resulting aluminum fluoride TSA complexes formed. Enzyme ligands crystallized above pH 7.0 were attributed to AlF3, whereas those crystallized at or below pH 7.0 were assigned as AlF4-. We use 19F NMR to show that for beta-phosphoglucomutase from Lactococcus lactis, the pH-switch in fluoride coordination does not derive from an AlF4- moiety converting into AlF3. Instead, AlF4- is progressively replaced by MgF3- as the pH increases. Hence, the enzyme prioritizes anionic charge at the expense of preferred native trigonal geometry over a very broad range of pH. We demonstrate similar behavior for two phosphate transfer enzymes that represent typical biological phosphate transfer catalysts: an amino acid phosphatase, phosphoserine phosphatase from Methanococcus jannaschii and a nucleotide kinase, phosphoglycerate kinase from Geobacillus stearothermophilus. Finally, we establish that at near-physiological ratios of aluminum to magnesium, aluminum can dominate over magnesium in the enzyme-metal fluoride inhibitory TSA complexes, and hence is the more likely origin of some of the physiological effects of fluoride.

Published

2008

6. A Trojan horse transition state analogue generated by MgF3- formation in an enzyme active site.

Author

Baxter NJ, Olguin LF, Golicnik M, Feng G, Hounslow AM, Bermel W, Blackburn GM, Hollfelder F, Waltho JP, and Williams NH

Subjects

Amides chemistry, Binding Sites, Catalysis, Enzyme Stability, Fluorides chemistry, Glucose-6-Phosphate chemistry, Glucosephosphates chemistry, Magnesium Compounds chemistry, Nuclear Magnetic Resonance, Biomolecular, Phosphoglucomutase antagonists & inhibitors, Phosphoglucomutase chemistry, Fluorides metabolism, Lactococcus lactis enzymology, Magnesium Compounds metabolism, Phosphoglucomutase metabolism

Abstract

Identifying how enzymes stabilize high-energy species along the reaction pathway is central to explaining their enormous rate acceleration. beta-Phosphoglucomutase catalyses the isomerization of beta-glucose-1-phosphate to beta-glucose-6-phosphate and appeared to be unique in its ability to stabilize a high-energy pentacoordinate phosphorane intermediate sufficiently to be directly observable in the enzyme active site. Using (19)F-NMR and kinetic analysis, we report that the complex that forms is not the postulated high-energy reaction intermediate, but a deceptively similar transition state analogue in which MgF(3)(-) mimics the transferring PO(3)(-) moiety. Here we present a detailed characterization of the metal ion-fluoride complex bound to the enzyme active site in solution, which reveals the molecular mechanism for fluoride inhibition of beta-phosphoglucomutase. This NMR methodology has a general application in identifying specific interactions between fluoride complexes and proteins and resolving structural assignments that are indistinguishable by x-ray crystallography.

Published

2006