Your search keyword '"Teresa F. G. Machado"' showing total 6 results

1. Allosteric inhibition of Acinetobacter baumannii ATP phosphoribosyltransferase by protein:dipeptide and protein:protein Interactions

Author

Benjamin J. Read, Gemma Fisher, Oliver L. R. Wissett, Teresa F. G. Machado, John Nicholson, John B. O. Mitchell, Rafael G. da Silva, EPSRC, University of St Andrews. School of Biology, University of St Andrews. School of Chemistry, University of St Andrews. Biomedical Sciences Research Complex, and University of St Andrews. EaSTCHEM

Subjects

Acinetobacter baumannii, Enzyme inhibition, Infectious Diseases, Protein interaction, Kinetic mechanism, QR180, NDAS, QD, QR180 Immunology, QD Chemistry, ATP phosphoribosyltransferase, AC

Abstract

This work was supported by the Biotechnology and Biological Sciences Research Council (BBSRC) (Grant BB/M010996/1) via EASTBIO Doctoral Training Partnership studentships to B.J.R. and G.F., and by the Engineering and Physical Sciences Research Council (EPSRC) [grant number EP/L016419/1] via a CRITICAT Centre for Doctoral Training studentship to T.F.G.M. ATP phosphoribosyltransferase (ATPPRT) catalyzes the first step of histidine biosynthesis in bacteria, namely, the condensation of ATP and 5-phospho-α-d-ribosyl-1-pyrophosphate (PRPP) to generate N1-(5-phospho-β-d-ribosyl)-ATP (PRATP) and pyrophosphate. Catalytic (HisGS) and regulatory (HisZ) subunits assemble in a hetero-octamer where HisZ activates HisGS and mediates allosteric inhibition by histidine. In Acinetobacter baumannnii, HisGS is necessary for the bacterium to persist in the lung during pneumonia. Inhibition of ATPPRT is thus a promising strategy for specific antibiotic development. Here, A. baumannii ATPPRT is shown to follow a rapid equilibrium random kinetic mechanism, unlike any other ATPPRT. Histidine noncompetitively inhibits ATPPRT. Binding kinetics indicates histidine binds to free ATPPRT and to ATPPRT:PRPP and ATPPRT:ATP binary complexes with similar affinity following a two-step binding mechanism, but with distinct kinetic partition of the initial enzyme:inhibitor complex. The dipeptide histidine-proline inhibits ATPPRT competitively and likely uncompetitively, respectively, against PRPP and ATP. Rapid kinetics analysis shows His-Pro binds to the ATPPRT:ATP complex via a two-step binding mechanism. A related HisZ that shares 43% sequence identity with A. baumannii HisZ is a tight-binding allosteric inhibitor of A. baumannii HisGS. These findings lay the foundation for inhibitor design against A. baumannii ATPPRT. Postprint

Published

2022

2. Allosteric Inhibition of

Author

Benjamin J, Read, Gemma, Fisher, Oliver L R, Wissett, Teresa F G, Machado, John, Nicholson, John B O, Mitchell, and Rafael G, da Silva

Subjects

Acinetobacter baumannii, Kinetics, Histidine, Dipeptides, ATP Phosphoribosyltransferase

Abstract

ATP phosphoribosyltransferase (ATPPRT) catalyzes the first step of histidine biosynthesis in bacteria, namely, the condensation of ATP and 5-phospho-α-d-ribosyl-1-pyrophosphate (PRPP) to generate

Published

2021

3. Transition states for psychrophilic and mesophilic (R)-3-hydroxybutyrate dehydrogenase-catalyzed hydride transfer at sub-zero temperatures

Author

Teresa F. G. Machado, Miha Purg, Rafael G. Silva, Johan Åqvist, EPSRC, University of St Andrews. Biomedical Sciences Research Complex, and University of St Andrews. School of Biology

Subjects

0303 health sciences, Chemistry, 030302 biochemistry & molecular biology, Kinetics, Dehydrogenase, Hydride transfer, DAS, QD Chemistry, Biochemistry, 03 medical and health sciences, Crystallography, Reaction rate constant, Deuterium, Kinetic isotope effect, QD, Enzyme kinetics, Redox reactions, Psychrophile, Mesophile, Hydrogen isotopes

Abstract

This work was supported by the Engineering and Physical Sciences Research Council (EPSRC) (Grant EP/L016419/1) via a CRITICAT Centre for Doctoral Training studentship to T.F.G.M., and by the Swedish Research Council and KAW Foundation grants to J.Å. (R)-3-Hydroxybutyrate dehydrogenase (HBDH) catalyzes the NADH-dependent reduction of 3-oxocarboxylates to (R)-3-hydroxycarboxylates. The active sites of a pair of cold- and warm-adapted HBDHs are identical except for a single residue, yet kinetics evaluated at −5, 0, and 5 °C show a much higher steady-state rate constant (kcat) for the cold-adapted than for the warm-adapted HBDH. Intriguingly, single-turnover rate constants (kSTO) are strikingly similar between the two orthologues. Psychrophilic HBDH primary deuterium kinetic isotope effects on kcat (Dkcat) and kSTO (DkSTO) decrease at lower temperatures, suggesting more efficient hydride transfer relative to other steps as the temperature decreases. However, mesophilic HBDH Dkcat and DkSTO are generally temperature-independent. The DkSTO data allowed calculation of intrinsic primary deuterium kinetic isotope effects. Intrinsic isotope effects of 4.2 and 3.9 for cold- and warm-adapted HBDH, respectively, at 5 °C, supported by quantum mechanics/molecular mechanics calculations, point to a late transition state for both orthologues. Conversely, intrinsic isotope effects of 5.7 and 3.1 for cold- and warm-adapted HBDH, respectively, at −5 °C indicate the transition state becomes nearly symmetric for the psychrophilic enzyme, but more asymmetric for the mesophilic enzyme. His-to-Asn and Asn-to-His mutations in the psychrophilic and mesophilic HBDH active sites, respectively, swap the single active-site position where these orthologues diverge. At 5 °C, the His-to-Asn mutation in psychrophilic HBDH decreases Dkcat to 3.1, suggesting a decrease in transition-state symmetry, while the His-to-Asn mutation in mesophilic HBDH increases Dkcat to 4.4, indicating an increase in transition-state symmetry. Hence, temperature adaptation and a single divergent active-site residue may influence transition-state geometry in HBDHs. Postprint

Published

2021

4. Transition States for Psychrophilic and Mesophilic (

Author

Teresa F G, Machado, Miha, Purg, Johan, Åqvist, and Rafael G, da Silva

Subjects

Cold Temperature, Models, Molecular, Hydroxybutyrate Dehydrogenase, Kinetics, Bacterial Proteins, Catalytic Domain, Psychrobacter

Abstract

(

Published

2021

5. Dissecting the Mechanism of (R)-3-Hydroxybutyrate Dehydrogenase by Kinetic Isotope Effects, Protein Crystallography, and Computational Chemistry

Author

Rafael G. Silva, Stephen A. McMahon, Tracey M. Gloster, Benjamin J. Read, Verena Oehler, Johan Åqvist, Teresa F. G. Machado, Miha Purg, The Wellcome Trust, EPSRC, University of St Andrews. School of Biology, and University of St Andrews. Biomedical Sciences Research Complex

Subjects

Stereochemistry, QH301 Biology, Dehydrogenase, 010402 general chemistry, 01 natural sciences, enzyme catalysis, Catalysis, Enzyme catalysis, 3-hydroxybutyrate dehydrogenase, QH301, chemistry.chemical_compound, isotope effects, hydride transfer, Kinetic isotope effect, QD, quantum mechanics/molecular mechanics, R2C, chemistry.chemical_classification, Organisk kemi, 010405 organic chemistry, Chemistry, Organic Chemistry, Enantioselective synthesis, Biochemistry and Molecular Biology, DAS, General Chemistry, QD Chemistry, 0104 chemical sciences, Monomer, Enzyme, X-ray crystallography, BDC, Biokemi och molekylärbiologi, Research Article

Abstract

This work was supported by the Engineering and Physical Sciences Research Council (EPSRC) [grant no. EP/L016419/1] via a CRITICAT Centre for Doctoral Training studentship to T.F.G.M., by the Wellcome Trust via a Research Career Development Fellowship to T.M.G., by the Biotechnology and Biological Sciences Research Council (BBSRC) (Grant BB/M010996/1) via an EASTBIO Doctoral Training Partnership studentship to B.J.R., and by the Swedish Research Council and KAW Foundation grants to J.Å. The enzyme (R)-3-hydroxybutyrate dehydrogenase (HBDH) catalyzes the enantioselective reduction of 3-oxocarboxylates to (R)-3-hydroxycarboxylates, the monomeric precursors of biodegradable polyesters. Despite its application in asymmetric reduction, which prompted several engineering attempts of this enzyme, the order of chemical events in the active site, their contributions to limit the reaction rate, and interactions between the enzyme and non-native 3-oxocarboxylates have not been explored. Here, a combination of kinetic isotope effects, protein crystallography, and quantum mechanics/molecular mechanics (QM/MM) calculations were employed to dissect the HBDH mechanism. Initial velocity patterns and primary deuterium kinetic isotope effects establish a steady-state ordered kinetic mechanism for acetoacetate reduction by a psychrophilic and a mesophilic HBDH, where hydride transfer is not rate limiting. Primary deuterium kinetic isotope effects on the reduction of 3-oxovalerate indicate that hydride transfer becomes more rate limiting with this non-native substrate. Solvent and multiple deuterium kinetic isotope effects suggest hydride and proton transfers occur in the same transition state. Crystal structures were solved for both enzymes complexed to NAD+:acetoacetate and NAD+:3-oxovalerate, illustrating the structural basis for the stereochemistry of the 3-hydroxycarboxylate products. QM/MM calculations using the crystal structures as a starting point predicted a higher activation energy for 3-oxovalerate reduction catalyzed by the mesophilic HBDH, in agreement with the higher reaction rate observed experimentally for the psychrophilic orthologue. Both transition states show concerted, albeit not synchronous, proton and hydride transfers to 3-oxovalerate. Setting the MM partial charges to zero results in identical reaction activation energies with both orthologues, suggesting the difference in activation energy between the reactions catalyzed by cold- and warm-adapted HBDHs arises from differential electrostatic stabilization of the transition state. Mutagenesis and phylogenetic analysis reveal the catalytic importance of His150 and Asn145 in the respective orthologues. Publisher PDF

Published

2020

6. Catalytic and Anticatalytic snapshots of a short-form ATP Phosphoribosyltransferase

Author

Magnus S. Alphey, Gemma Fisher, Ying Ge, Eoin R. Gould, Teresa F. G. Machado, Huanting Liu, Gordon J. Florence, James H. Naismith, Rafael G. da Silva, The Leverhulme Trust, University of St Andrews. School of Biology, University of St Andrews. School of Chemistry, University of St Andrews. Biomedical Sciences Research Complex, and University of St Andrews. EaSTCHEM

Subjects

0301 basic medicine, Catalytic activation, HisZ, QH301 Biology, NDAS, Psychrophilic, General Chemistry, HisG, 010402 general chemistry, Biosynthesis, QD Chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, 03 medical and health sciences, QH301, 030104 developmental biology, Histidine, QD, Allostery, BDC, ATP phosphoribosyltransferase, R2C

Abstract

This work was supported by the University of St Andrews, a Leverhulme Trust grant (RL - 2012 - 025) to G.J.F, the Engineering and Physical Sciences Research Council (EPSRC) [grant number EP/L016419/1] via a CRITICAT Centre for Doctoral Training studentship to TFGM, and the Biotechnology and Biological Sciences Research Council (BBSRC) [grant number BB/M010996/1] via an EASTBIO Doctoral Training Partnership studentship to GF. Allosteric modulation of catalysis is a common regulatory strategy of flux-controlling biosynthetic enzymes. The enzyme ATP phosphoribosyltransferase (ATPPRT) catalyzes the first reaction in histidine biosynthesis, the magnesium-dependent condensation of ATP and 5-phospho-α-d-ribosyl-1-pyrophosphate (PRPP) to generate N1-(5-phospho-β-d-ribosyl)-ATP (PRATP) and pyrophosphate (PPi). ATPPRT is allosterically inhibited by the final product of the pathway, histidine. Hetero-octameric ATPPRT consists of four catalytic subunits (HisGS) and four regulatory subunits (HisZ) engaged in intricate catalytic regulation. HisZ enhances HisGS catalysis in the absence of histidine while mediating allosteric inhibition in its presence. Here we report HisGS structures for the apoenzyme and complexes with substrates (PRPP, PRPP-ATP, PRPP-ADP), product (PRATP), and inhibitor (AMP), along with ATPPRT holoenzyme structures in complexes with substrates (PRPP, PRPP-ATP, PRPP-ADP) and product (PRATP). These 10 crystal structures provide an atomic view of the catalytic cycle and allosteric activation of Psychrobacter arcticus ATPPRT. In both ternary complexes with PRPP-ATP, the adenine ring is found in an anticatalytic orientation, rotated 180° from the catalytic rotamer. Arg32 interacts with phosphate groups of ATP and PRPP, bringing the substrates in proximity for catalysis. The negative charge repulsion is further attenuated by a magnesium ion sandwiched between the α- and β-phosphate groups of both substrates. HisZ binding to form the hetero-octamer brings HisGS subunits closer together in a tighter dimer in the Michaelis complex, which poises Arg56 from the adjacent HisGS molecule for cross-subunit stabilization of the PPi leaving group at the transition state. The more electrostatically preorganized active site of the holoenzyme likely minimizes the reorganization energy required to accommodate the transition state. This provides a structural basis for allosteric activation in which chemistry is accelerated by facilitating leaving group departure. Postprint

Published

2018