Tiago A. S. Brandão scite author profile

Catalysis by protein-tyrosine phosphatase 1B (PTP1B) occurs through a two-step mechanism involving a phosphocysteine intermediate. We have solved crystal structures for the transition state analogs for both steps. Together with previously reported crystal structures of apo-PTP1B, the Michaelis complex of an inactive mutant, the phosphoenzyme intermediate, and the product complex, a full picture of all catalytic steps can now be depicted. The transition state analog for the first catalytic step comprises a ternary complex between the catalytic cysteine of PTP1B, vanadate, and the peptide DADEYL, a fragment of a physiological substrate. The equatorial vanadate oxygen atoms bind to the P-loop, and the apical positions are occupied by the peptide tyrosine oxygen and by the PTP1B cysteine sulfur atom. The vanadate assumes a trigonal bipyramidal geometry in both transition state analog structures, with very similar apical O-O distances, denoting similar transition states for both phosphoryl transfer steps. Detailed interactions between the flanking peptide and the enzyme are discussed.The phosphorylation of tyrosine residues by protein-tyrosine kinases and the reverse action by protein-tyrosine phosphatases (PTPs) 4 is a common mechanism for the control of biological pathways (1-3). Protein-tyrosine phosphatase 1B (PTP1B) is a biomedically important phosphatase with several roles, including negative regulation of insulin signaling by dephosphorylation of the insulin receptor tyrosine kinase (4). Knock-out studies show that loss of PTP1B is associated with an increased insulin sensitivity and suppression of weight gain in mice (5). As a result, this enzyme has been considered a significant target for treatment of type 2 diabetes and obesity (6, 7). PTP1B also down-regulates cell growth by dephosphorylating the epidermal growth factor receptor (8). Overexpression has been observed in human breast and ovarian cancer, where it is believed to suppress potential tumors by antagonizing signaling of oncogenic factors (9, 10). Other PTPs are known virulence factors for a number of human diseases (11-13).Reactions catalyzed by PTPs take place by a ping-pong mechanism ( Fig. 1) (2). In the first step, a nucleophilic cysteine thiolate attacks the phosphate ester moiety of the substrate, resulting in formation of a phosphoenzyme intermediate with release of the peptidyl tyrosine. The second step occurs via attack of water on the phosphoenzyme intermediate and yields the final products inorganic phosphate and the regenerated enzyme. The central binding site for the substrate is the P-loop, a region at the bottom of a pocket that includes the nucleophilic cysteine and backbone amide groups oriented in a horseshoe fashion. The amide protons in the P-loop, together with a conserved arginine residue, hydrogen-bond to the phosphoryl group of the substrate and orient it for nucleophilic attack, providing transition state (TS) stabilization. Substrate binding is followed by conformational changes that culminate with closure of the activ...

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Impaired Acid Catalysis by Mutation of a Protein Loop Hinge Residue in a YopH Mutant Revealed by Crystal Structures

Brandão

Robinson

Johnson

et al. 2008

J. Am. Chem. Soc.

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Catalysis by the Yersinia protein-tyrosine phosphatase YopH is significantly impaired by the mutation of the conserved Trp354 residue to Phe. Though not a catalytic residue, this Trp is a hinge residue in a conserved flexible loop (the WPD-loop) that must close during catalysis. To learn why this seemingly conservative mutation reduces catalysis by 2 orders of magnitude, we have solved high-resolution crystal structures for the W354F YopH in the absence and in the presence of tungstate and vanadate. Oxyanion binding to the P-loop in W354F is analogous to that observed in the native enzyme. However, the WPD-loop in the presence of oxyanions assumes a half-closed conformation, in contrast to the fully closed state observed in structures of the native enzyme. This observation provides an explanation for the impaired general acid catalysis observed in kinetic experiments with Trp mutants. A 1.4 Å structure of the W354F mutant obtained in the presence of vanadate reveals an unusual divanadate species with a cyclic [VO] 2 core, which has precedent in small molecules but has not been previously reported in a protein crystal structure.

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The molecular details of WPD-loop movement differ in the protein-tyrosine phosphatases YopH and PTP1B

Brandão

Johnson

Hengge

2012

Archives of Biochemistry and Biophysics

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The movement of a conserved protein loop (the WPD-loop) is important in catalysis by protein tyrosine phosphatases (PTPs). Using kinetics, isotope effects, and X-ray crystallography, the different effects arising from mutation of the conserved tryptophan in the WPD-loop were compared in two PTPs, the human PTP1B, and the bacterial YopH from Yersinia. Mutation of the conserved tryptophan in the WPD-loop to phenylalanine has a negligible effect on kcat in PTP1B and full loop movement is maintained. In contrast, the corresponding mutation in YopH reduces kcat by two orders of magnitude and the WPD loop locks in an intermediate position, disabling general acid catalysis. During loop movement the indole moiety of the WPD-loop tryptophan moves in opposite directions in the two enzymes. Comparisons of mammalian and bacterial PTPs reveal differences in the residues forming the hydrophobic pocket surrounding the conserved tryptophan. Thus, although WPD-loop movement is a conserved feature in PTPs, differences exist in the molecular details, and in the tolerance to mutation, in PTP1B compared to YopH. Despite high structural similarity of the active sites in both WPD-loop open and closed conformations, differences are identified in the molecular details associated with loop movement in PTPs from different organisms.

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Activating Water: Important Effects of Non‐leaving Groups on the Hydrolysis of Phosphate Triesters

Kirby

Medeiros

Oliveira

et al. 2011

Chemistry A European J

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The high rate of spontaneous hydrolysis of tris-2-pyridyl phosphate (TPP) is explained by the activating effects of the non-leaving ("spectator") groups on P-OAr cleavage, and not by intramolecular catalysis. Previous work on phosphate-transfer reactions has concentrated on the contributions to reactivity of the nucleophile and the leaving group, but our results make clear that the effects of the non-leaving groups on phosphorus can be equally significant. Rate measurements for three series of phosphate triesters showed that sensitivities to the non-leaving groups are substantial for spontaneous hydrolysis reactions, although significantly smaller for reactions with good nucleophiles. There are clear differences between triaryl and dialkyl aryl triesters in sensitivities to leaving and non-leaving groups with the more reactive triaryl systems showing lower values for both β(LG) and β(NLG). Intramolecular catalysis of the hydrolysis of TPP by the neighbouring pyridine nitrogens is insignificant, primarily because of their low basicity.

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Reaction of Bis(2,4-dinitrophenyl) Phosphate with Hydrazine and Hydrogen Peroxide. Comparison of O- and N- Phosphorylation

et al. 2004

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Nonionic hydrazine reacts with anionic bis(2,4-dinitrophenyl) phosphate (BDNPP), giving 2,4-dinitrophenyl hydrazine and dianionic 2,4-dinitrophenyl phosphate by an S(N)2(Ar) reaction, and at the phosphoryl center, giving 2,4-dinitrophenoxide ion and a transient phosphorylated hydrazine that rearranges intramolecularly to N-(2,4-dinitrophenyl)-N-phosphonohydrazine. Approximately 58% of the reaction at pD = 10 occurs by N-phosphorylation, as shown by (31)P NMR spectroscopy. Reaction of HO(2)(-) is wholly at phosphorus, and the intermediate peroxophosphate reacts intramolecularly, displacing a second 2,4-dinitrophenoxide ion, or with H(2)O(2), giving 2,4-dinitrophenyl phosphate and O(2). Rate constants of O- and N-phosphorylation in reactions at phosphorus of NH(2)NH(2), HO(2)(-), and NH(2)OH and its methyl derivatives follow Bronsted relationships with similar slopes, but plots differ for oxygen and nitrogen nucleophiles. The reaction with NH(2)NH(2) has been probed by using both NMR spectroscopy and electrospray ionization mass and tandem mass spectrometry, with the novel interception of key reaction intermediates in the course of reaction.

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Mechanisms of Nucleophilic Substitution Reactions of Methylated Hydroxylamines with Bis(2,4-dinitrophenyl)phosphate. Mass Spectrometric Identification of Key Intermediates

et al. 2004

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Mono- and dimethylation of hydroxylamine on nitrogen does not significantly affect rates of initial attack of NHMeOH and NMe(2)OH on bis(2,4-dinitrophenyl)phosphate (BDNPP), which is largely by oxygen phosphorylation. O-Methylation, however, blocks this reaction and NH(2)OMe then slowly reacts with BDNPP via N-attack at phosphorus and at the aryl group. With NHMeOH, the initial product of O-attack at phosphorus reacts further, either by reaction with a second NHMeOH or by a spontaneous shift of NHMe to the aryl group via a transient cyclic intermediate. There is a minor N-attack of NHMeOH on BDNPP in an S(N)2(Ar) reaction. Reactions occurring via N-attack are blocked by N-dimethylation, and reaction of NMe(2)OH with BDNPP occurs via O-attack, generating a long-lived product. Reaction mechanisms have been probed, and intermediates identified, by using both NMR and MS spectroscopy, with the novel interception of key reaction intermediates in the course of reaction by electrospray ionization mass and tandem mass spectrometry.

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Hydroxylamine as an Oxygen Nucleophile. Structure and Reactivity of Ammonia Oxide

et al. 2006

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Intramolecular Catalysis of Phosphodiester Hydrolysis by Two Imidazoles

et al. 2010

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Two imidazole groups act together to catalyze the hydrolysis of the phosphodiester bis(2-(1-methyl-1H-imidazolyl)phenyl) phosphate (BMIPP). A full investigation involving searching computational and electrospray ionization (ESI-MS-/MS) and ultra mass spectrometry (LTQ-FT) experiments made possible a choice between two kinetically equivalent mechanisms. The preferred pathway, involving intramolecular nucleophilic catalysis by imidazole, assisted by intramolecular general acid catalysis by the imidazolium group, offers the first simple model for the mechanism used by the extensive phospholipase D superfamily.

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