Your search keyword '"Stephen J. Headey"' showing total 3 results

1. Structural and biochemical insights into the disulfide reductase mechanism of DsbD, an essential enzyme for neisserial pathogens

Author

Shakeel Mowlaboccus, Martin J. Scanlon, Roxanne P. Smith, Geqing Wang, Charlene M. Kahler, Begoña Heras, Martin Williams, Stephen J. Headey, Biswaranjan Mohanty, Pramod Subedi, Jason J. Paxman, and Bradley C. Doak

Subjects

0301 basic medicine, Models, Molecular, Protein Conformation, medicine.disease_cause, Crystallography, X-Ray, Biochemistry, 03 medical and health sciences, Protein structure, Bacterial Proteins, Protein Domains, Oxidoreductase, Catalytic Domain, medicine, Amino Acid Sequence, Disulfides, Molecular Biology, Escherichia coli, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, Chemistry, Cell Biology, Periplasmic space, biology.organism_classification, Neisseria gonorrhoeae, 3. Good health, Transmembrane domain, 030104 developmental biology, Protein Structure and Folding, Protein folding, Neisseria, Oxidoreductases, Oxidation-Reduction

Abstract

The worldwide incidence of neisserial infections, particularly gonococcal infections, is increasingly associated with antibiotic-resistant strains. In particular, extensively drug-resistant Neisseria gonorrhoeae strains that are resistant to third-generation cephalosporins are a major public health concern. There is a pressing clinical need to identify new targets for the development of antibiotics effective against Neisseria-specific processes. In this study, we report that the bacterial disulfide reductase DsbD is highly prevalent and conserved among Neisseria spp. and that this enzyme is essential for survival of N. gonorrhoeae. DsbD is a membrane-bound protein that consists of two periplasmic domains, n-DsbD and c-DsbD, which flank the transmembrane domain t-DsbD. In this work, we show that the two functionally essential periplasmic domains of Neisseria DsbD catalyze electron transfer reactions through unidirectional interdomain interactions, from reduced c-DsbD to oxidized n-DsbD, and that this process is not dictated by their redox potentials. Structural characterization of the Neisseria n- and c-DsbD domains in both redox states provides evidence that steric hindrance reduces interactions between the two periplasmic domains when n-DsbD is reduced, thereby preventing a futile redox cycle. Finally, we propose a conserved mechanism of electron transfer for DsbD and define the residues involved in domain–domain recognition. Inhibitors of the interaction of the two DsbD domains have the potential to be developed as anti-neisserial agents.

Published

2018

2. The structure of integrin α1I domain in complex with a collagen-mimetic peptide

Author

Paul A. McEwan, James D. Swarbrick, Martin Scanlon, Yanni Ka-Yan Chin, Rahul Chandrakant Patil, Stephen J. Headey, Jonas Emsley, Biswaranjan Mohanty, Jamie S. Simpson, and Terrence D. Mulhern

Subjects

Conformational change, Stereochemistry, Integrin, Integrin alpha1, Plasma protein binding, Biology, Biochemistry, Molecular Docking Simulation, Protein Structure, Secondary, Protein structure, X-Ray Diffraction, Biomimetic Materials, Scattering, Small Angle, Humans, Binding site, Protein Structure, Quaternary, Molecular Biology, Binding selectivity, Cell Biology, Protein Structure, Tertiary, Docking (molecular), Protein Structure and Folding, biology.protein, Collagen, Peptides, Protein Binding

Abstract

We have determined the structure of the human integrin α1I domain bound to a triple-helical collagen peptide. The structure of the α1I-peptide complex was investigated using data from NMR, small angle x-ray scattering, and size exclusion chromatography that were used to generate and validate a model of the complex using the data-driven docking program, HADDOCK (High Ambiguity Driven Biomolecular Docking). The structure revealed that the α1I domain undergoes a major conformational change upon binding of the collagen peptide. This involves a large movement in the C-terminal helix of the αI domain that has been suggested to be the mechanism by which signals are propagated in the intact integrin receptor. The structure suggests a basis for the different binding selectivity observed for the α1I and α2I domains. Mutational data identify residues that contribute to the conformational change observed. Furthermore, small angle x-ray scattering data suggest that at low collagen peptide concentrations the complex exists in equilibrium between a 1:1 and 2:1 α1I-peptide complex.

Published

2013

3. Solution structure of the squash aspartic acid proteinase inhibitor (SQAPI) and mutational analysis of pepsin inhibition

Author

Michele A. Wright, Jolyon K. Claridge, Ursula K. MacAskill, Stephen J. Headey, Patrick J. B. Edwards, Steven M. Pascal, Peter C. Farley, John T. Christeller, and William A. Laing

Subjects

medicine.medical_treatment, Biology, Cleavage (embryo), Biochemistry, Protein Structure, Secondary, Serine, Protein structure, Cucurbita, Aspartic acid, medicine, Protease Inhibitors, Binding site, Molecular Biology, Nuclear Magnetic Resonance, Biomolecular, Plant Proteins, chemistry.chemical_classification, Protease, Binding Sites, Cell Biology, Cystatins, Pepsin A, Enzyme, chemistry, Structural Homology, Protein, Protein Structure and Folding, Cystatin

Abstract

The squash aspartic acid proteinase inhibitor (SQAPI), a proteinaceous proteinase inhibitor from squash, is an effective inhibitor of a range of aspartic proteinases. Proteinaceous aspartic proteinase inhibitors are rare in nature. The only other example in plants probably evolved from a precursor serine proteinase inhibitor. Earlier work based on sequence homology modeling suggested SQAPI evolved from an ancestral cystatin. In this work, we determined the solution structure of SQAPI using NMR and show that SQAPI shares the same fold as a plant cystatin. The structure is characterized by a four-strand anti-parallel beta-sheet gripping an alpha-helix in an analogous manner to fingers of a hand gripping a tennis racquet. Truncation and site-specific mutagenesis revealed that the unstructured N terminus and the loop connecting beta-strands 1 and 2 are important for pepsin inhibition, but the loop connecting strands 3 and 4 is not. Using ambiguous restraints based on the mutagenesis results, SQAPI was then docked computationally to pepsin. The resulting model places the N-terminal strand of SQAPI in the S' side of the substrate binding cleft, whereas the first SQAPI loop binds on the S side of the cleft. The backbone of SQAPI does not interact with the pepsin catalytic Asp(32)-Asp(215) diad, thus avoiding cleavage. The data show that SQAPI does share homologous structural elements with cystatin and appears to retain a similar protease inhibitory mechanism despite its different target. This strongly supports our hypothesis that SQAPI evolved from an ancestral cystatin.

Published

2010