B.V. Norledge scite author profile

The structural data, supported by the mutagenesis data, suggest a reaction mechanism where Glu196 acts as a proton acceptor and Asp204 acts as a proton donor. Asp176 is paired with Glu196 and is important for optimizing the catalytic proton transfer properties of Glu196. In the predicted mode of substrate binding, an oxyanion hole stabilizes the transition state by binding the thioester oxygen. The presence of a buried peroxisomal targeting signal suggests that dienoyl-CoA isomerase is prevented from reaching its hexameric structure in the cytosol.

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Understanding protein lids: structural analysis of active hinge mutants in triosephosphate isomerase

Kursula

Salin²,

Sun³

et al. 2004

Protein Engineering Design and Selection

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The conformational switch from open to closed of the flexible loop 6 of triosephosphate isomerase (TIM) is essential for the catalytic properties of TIM. Using a directed evolution approach, active variants of chicken TIM with a mutated C-terminal hinge tripeptide of loop 6 have been generated (Sun,J. and Sampson,N.S., Biochemistry, 1999, 38, 11474-11481). In chicken TIM, the wild-type C-terminal hinge tripeptide is KTA. Detailed enzymological characterization of six variants showed that some of these (LWA, NPN, YSL, KTK) have decreased catalytic efficiency, whereas others (KVA, NSS) are essentially identical with wild-type. The structural characterization of these six variants is reported. No significant structural differences compared with the wild-type are found for KVA, NSS and LWA, but substantial structural adaptations are seen for NPN, YSL and KTK. These structural differences can be understood from the buried position of the alanine side chain in the C-hinge position 3 in the open conformation of wild-type loop 6. Replacement of this alanine with a bulky side chain causes the closed conformation to be favored, which correlates with the decreased catalytic efficiency of these variants. The structural context of loop 6 and loop 7 and their sequence conservation in 133 wild-type sequences is also discussed.

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The tissue factor/factor VIIa/factor Xa complex: A model built by docking and site‐directed mutagenesis

et al. 2003

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Factor X is activated to factor Xa (fXa) in the extrinsic coagulation pathway by the tissue factor (TF)/factor VIIa (fVIIa) complex. Upon activation, the fXa molecule remains associated with the TF/fVIIa complex, and this ternary complex is known to activate protease-activated receptors (PARs) 1 and 2. Activation of fVII in the TF complex by fXa is also seen at physiologic concentrations. The ternary complexes TF/fVII/fXa, TF/fVIIa/fX, and TF/fVIIa/fXa are therefore all physiologically relevant and of interest as targets for inhibition of both coagulation and cell-signaling pathways that are important in cardiovascular disease and inflammation. We therefore present a model of the TF/fVIIa/fXa complex, built with the use of the available structures of the TF/fVIIa complex and fXa by protein-protein docking calculations with the program Surfdock. The fXa model has an extended conformation, similar to that of fVIIa in the TF/fVIIa complex, with extensive interactions with TF and the protease domain of fVIIa. All four domains of fXa are involved in the interaction. The gamma-carboxyglutamate (Gla) and epithelial growth factor (EGF1 and EGF2) domains of fVIIa are not significantly involved in the interaction. Docking of the Gla domain of fXa to TF/fVIIa has been reported previously. The docking results identify potential interface residues, allowing rational selection of target residues for site-directed mutagenesis. This combination of docking and mutagenesis confirms that residues Glu51 and Asn57 in the EGF1 domain, Asp92 and Asp95 in the EGF2 domain, and Asp 185a, Lys 186, and Lys134 in the protease domain of factor Xa are involved in the interaction with TF/fVIIa. Other fX protease domain residues predicted to be involved in the interaction come from the 160s loop and the N-terminus of the fX protease domain, which is oriented in such a way that activation of both fVII by fXa, and the reciprocal fX activation by fVIIa, is possible.

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The ionization of a buried glutamic acid is thermodynamically linked to the stability of Leishmania mexicana triose phosphate isomerase

Lambeir¹,

Backmann²,

Ruiz-Sanz³

et al. 2000

European Journal of Biochemistry

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The amino acid sequence of Leishmania mexicana triose phosphate isomerase is unique in having at position 65 a glutamic acid instead of a glutamine. The stability properties of LmTIM and the E65Q mutant were investigated by pH and guanidinium chloride-induced unfolding. The crystal structure of E65Q was determined. Three important observations were made: (a) there are no structural rearrangements as the result of the substitution; (b) the mutant is more stable than the wild-type; and (c) the stability of the wild-type enzyme shows strong pH dependence, which can be attributed to the ionization of Glu65. Burying of the Glu65 side chain in the uncharged environment of the dimer interface results in a shift in pK a of more than 3 units. The pH-dependent decrease in overall stability is due to weakening of the monomer±monomer interactions (in the dimer). The E65Q substitution causes an increase in stability as the result of the formation of an additional hydrogen bond in each subunit (DDG 8 of 2 kcal´mol 21 per monomer) and the elimination of a charged group in the dimer interface (DDG 8 of at least 9 kcal´mol 21 per dimer). The computated shift in pK a and the stability of the dimer calculated from the charge distribution in the protein structure agree closely with the experimental results.The guanidinium chloride dependence of the unfolding constant was smaller than expected from studies involving monomeric model proteins. No intermediates could be identified in the unfolding equilibrium by combining fluorescence and CD measurements. Study of a stable monomeric triose phosphate isomerase variant confirmed that the phenomenon persists in the monomer.Keywords: Leishmania mexicana; pK a calculations; stability; triose phosphate isomerase.Burying a titratable group in a protein without an oppositely charged group nearby has been shown to change the pK a value of the charged group substantially [1]. Several examples of pK a shifts being related to the overall stability of proteins have been reported [2±7].Leishmania mexicana triose phosphate isomerase (LmTIM) is unique because it contains a substitution in an otherwise conserved sequence (64±66) located at the beginning of loop 3, namely Q65E [8]. In the related trypanosomal TIM (TbTIM) Gln65 is completely buried in the dimer interface and participates in an intersubunit hydrogen-bond network [9±10]. From the crystal structure of LmTIM, it was evident that no major structural rearrangements had taken place in the vicinity of the Glu65 side chain [11] and that Glu65 was protonated. Substituting Glu65 in LmTIM for a Gln yielded a protein with considerably greater thermostability than the wild-type. Moreover, the mutation abolished the pH dependence (pH 5±9) of the thermostability of wild-type LmTIM, indicating that the ionization of Glu65 has a significant impact on the overall stability of the dimer [11].The availability of the E65Q mutant and the high-resolution crystal structure of LmTIM provided us with a system that is eminently suited to the study of the effects of...

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Towards a Molecular Understanding of Phase Separation in the Lens: a Comparison of the X-ray Structures of Two HighTcγ-Crystallins, γE and γF, with Two LowTcγ-Crystallins, γB and γD

Norledge

Hay

Bateman

et al. 1997

Experimental Eye Research

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B.V. Norledge

The crystal structure of dienoyl-CoA isomerase at 1.5 å resolution reveals the importance of aspartate and glutamate sidechains for catalysis

Understanding protein lids: structural analysis of active hinge mutants in triosephosphate isomerase

The tissue factor/factor VIIa/factor Xa complex: A model built by docking and site‐directed mutagenesis

The ionization of a buried glutamic acid is thermodynamically linked to the stability of Leishmania mexicana triose phosphate isomerase

Towards a Molecular Understanding of Phase Separation in the Lens: a Comparison of the X-ray Structures of Two HighTcγ-Crystallins, γE and γF, with Two LowTcγ-Crystallins, γB and γD

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