Your search keyword '"Ian A. Taylor"' showing total 8 results

1. Structure of the Capsid Amino-Terminal Domain from the Betaretrovirus, Jaagsiekte Sheep Retrovirus

Author

William R. Taylor, David C. Goldstone, Ian A. Taylor, Gulnahar B. Mortuza, Massimo Palmarini, Clare Pashley, Jonathan P. Stoye, and Lesley F. Haire

Subjects

biology, Viral protein, viruses, Amino terminal, Molecular Sequence Data, Avian leukosis, Alpharetrovirus, Jaagsiekte sheep retrovirus, biochemical phenomena, metabolism, and nutrition, Crystallography, X-Ray, biology.organism_classification, medicine.disease_cause, Virology, Protein Structure, Secondary, Virus, Protein Structure, Tertiary, Solutions, Capsid, Structural Biology, medicine, Capsid Proteins, Amino Acid Sequence, Betaretrovirus, Molecular Biology

Abstract

Jaagsiekte sheep retrovirus is a betaretrovirus and the causative agent of pulmonary adenocarcinoma, a transmissible lung tumour of sheep. Here we report the crystal structure of the capsid amino-terminal domain and examine the self-association properties of Jaagsiekte sheep retrovirus capsid. We find that the structure is remarkably similar to the amino-terminal domain of the alpharetrovirus, avian leukosis virus, revealing a previously undetected evolutionary similarity. Examination of capsid self-association suggests a mode of assembly not driven by the strong capsid carboxy-terminal domain interactions that characterise capsid assembly in the lentiviruses. Based on these data, we propose this structure provides a model for the capsid of betaretroviruses including the HML-2 family of endogenous human betaretroviruses.

Published

2009

2. Preferential binding of fd gene 5 protein to tetraplex nucleic acid structures 1 1Edited by A. Klug

Author

Geoff Kneale, I. Bogdarina, Ian A. Taylor, Ewald Schroeder, and Antony W. Oliver

Subjects

Circular dichroism, biology, Biochemistry, Structural Biology, Oligonucleotide, Binding protein, Nucleic acid, RNA, biology.organism_classification, Molecular Biology, Filamentous bacteriophage fd, Gene, Nucleoprotein

Abstract

The gene 5 protein of filamentous bacteriophage fd is a single-stranded DNA-binding protein that binds non-specifically to all single-stranded nucleic acid sequences, but in addition is capable of specific binding to the sequence d(GT5G4CT4C) and the RNA equivalent r(GU5G4CU4C), the latter interaction being important for translational repression. We show that this sequence preference arises from the formation of a tetraplex structure held together by a central block of G-quartets, the structure of which persists in the complex with gene 5 protein. Binding of gene 5 protein to the tetraplex leads to formation of a ∼170 kDa nucleoprotein complex consisting of four oligonucleotide strands and eight gene 5 protein dimers, with a radius of gyration of 45 A and an overall maximum dimension of 120–130 A. A model of the complex is presented that is consistent with the data obtained. It is proposed that the G-quartet may act as a nucleation site for binding gene 5 protein to adjacent single-stranded regions, suggesting a novel mechanism for translational repression.

Published

2000

3. The crystal structure of the L1 metallo-β-lactamase from Stenotrophomonas maltophilia at 1.7 å resolution 1 1Edited by K. Nagai

Author

Jakir Hussain Ullah, J. Spencer, Timothy R. Walsh, Chandra S. Verma, Steven J. Gamblin, D.C. Emery, and Ian A. Taylor

Subjects

biology, Chemistry, Stereochemistry, Active site, chemistry.chemical_element, Protonation, Zinc, Trigonal bipyramidal molecular geometry, Protein structure, Tetramer, Structural Biology, Hydrolase, biology.protein, Binding site, Molecular Biology

Abstract

The structure of the L1 metallo-beta-lactamase from the opportunistic pathogen Stenotrophomonas maltophilia has been determined at 1.7 A resolution by the multiwavelength anomalous dispersion (MAD) approach exploiting both the intrinsic binuclear zinc centre and incorporated selenomethionine residues. L1 is unique amongst all known beta-lactamases in that it exists as a tetramer. The protein exhibits the alphabeta/betaalpha fold found only in the metallo-beta-lactamases and displays several unique features not previously observed in these enzymes. These include a disulphide bridge and two substantially elongated loops connected to the active site of the enzyme. Two closely spaced zinc ions are bound at the active site with tetrahedral (Zn1) and trigonal bipyramidal (Zn2) co-ordination, respectively; these are bridged by a water molecule which we propose acts as the nucleophile in the hydrolytic reaction. Ligation of the second zinc ion involves both residues and geometry which have not been previously observed in the metallo-beta-lactamases. Simulated binding of the substrates ampicillin, ceftazidime and imipenem suggests that the substrate is able to bind to the enzyme in a variety of different conformations whose common features are direct interactions of the beta-lactam carbonyl oxygen and nitrogen with the zinc ions and of the beta-lactam carboxylate with Ser187. We describe a catalytic mechanism whose principal features are a nucleophilic attack of the bridging water on the beta-lactam carbonyl carbon, electrostatic stabilisation of a negatively charged tetrahedral transition state and protonation of the beta-lactam nitrogen by a second water molecule co-ordinated by Zn2. Further, we propose that direct metal:substrate interactions provide a substantial contribution to substrate binding and that this may explain the lack of specificity which is a feature of this class of enzyme.

Published

1998

4. Structural and functional architecture of the yeast cell-cycle transcription factor swi6 1 1Edited by K. Nagai

Author

Steven Howell, Ana Christina Adam, Stephen J. Smerdon, Ian A. Taylor, Brian A. Morgan, Ad Spanos, Monika K Treiber, Geoffrey R. Banks, Rachel Foord, Steven G. Sedgwick, and Naheed Kanuga

Subjects

Protease, medicine.diagnostic_test, medicine.medical_treatment, Proteolysis, Biology, Cell biology, Turn (biochemistry), Transactivation, Biochemistry, Structural Biology, medicine, Transcriptional regulation, Ankyrin repeat, Molecular Biology, Linker, Transcription factor

Abstract

The structural and functional organisation of Swi6, a transcriptional regulator of the budding yeast cell cycle has been analysed by a combination of biochemical, biophysical and genetic methods. Limited proteolysis indicates the presence of a approximately 15 kDa N-terminal domain which is dispensable for Swi6 activity in vivo and which is separated from the rest of the molecule by an extended linker of at least 43 residues. Within the central region, a 141 residue segment that is capable of transcriptional activation encompasses a structural domain of approximately 85 residues. In turn, this is tightly associated with an adjacent 28 kDa domain containing at least four ankyrin-repeat (ANK) motifs. A second protease sensitive region connects the ANK domain to the remaining 30 kDa C-terminal portion of Swi6 which contains a second transcriptional activator and sequences required for heteromerisation with Swi4 or Mbp1. Transactivation by the activating regions of Swi6 is antagonised when either are combined with the central ankyrin repeat motifs. Hydrodynamic measurements indicate that an N-terminal 62 kDa fragment comprising the first three domains is monomeric in solution and exhibits an unusually high frictional coefficient consistent with the extended, multi-domain structure suggested by proteolytic analysis.

Published

1998

5. Surface Labelling of the Type I Methyltransferase M.EcoR124I Reveals Lysine Residues Critical for DNA Binding

Author

Ian A. Taylor, Michelle Webb, and Geoff Kneale

Subjects

Site-Specific DNA-Methyltransferase (Adenine-Specific), Methyltransferase, Sequence analysis, Protein subunit, Molecular Sequence Data, Lysine, Biology, Methylation, complex mixtures, Conserved sequence, chemistry.chemical_compound, Structural Biology, Amino Acid Sequence, Amino Acids, Molecular Biology, Peptide sequence, Conserved Sequence, DNA, Peptide Fragments, Biochemistry, chemistry, alpha-MSH, bacteria, Sequence Analysis, Protein Binding

Abstract

The type IC methyltransferase M.EcoR124I consists of a specificity subunit (HsdS) and two methylation subunits (HsdM). Using chemical modifications, we have investigated the accessibility of lysine residues in the free enzyme and in the complex with its DNA recognition sequence. A total of 41 of the 109 lysine residues in the enzyme are susceptible to modification, of which 19 are located in the HsdS subunit and 11 in each of the two HsdM subunits. DNA binding results in extensive protection of lysine residues in the HsdS subunit, while those in the HsdM subunit are only protected weakly. The DNA binding activity of the methylase is abolished when a small fraction of the accessible lysine residues are modified. Peptide mapping and N-terminal sequencing has been used to locate the rapidly modified lysine residues in HsdS that are critical for DNA binding. Highly modified residues (K297, K261 and K327) are found in the C-terminal variable domain that is responsible for DNA recognition, but others (K196, K203 and K210) are found in the conserved regions that had not previously been implicated in DNA binding.

Published

1996

6. Assembly of a 20-nm protein cage by Escherichia coli 2-hydroxypentadienoic acid hydratase

Author

Steve P. Wood, M.G. Montgomery, Alun R. Coker, and Ian A. Taylor

Subjects

Models, Molecular, Pentamer, Protein subunit, Size-exclusion chromatography, Molecular Sequence Data, Protein Data Bank (RCSB PDB), Nanoparticle, medicine.disease_cause, Crystallography, X-Ray, chemistry.chemical_compound, Structural Biology, medicine, Escherichia coli, Molecule, Amino Acid Sequence, Protein Structure, Quaternary, Molecular Biology, Hydro-Lyases, DNA Primers, Sequence Homology, Amino Acid, Chemistry, Protein Stability, Escherichia coli Proteins, Phosphate, Recombinant Proteins, Protein Structure, Tertiary, Crystallography, Protein Subunits, Genes, Bacterial, Nanoparticles, Protein Multimerization, Crystallization

Abstract

The pentameric Escherichia coli enzyme 2-hydroxypentadienoic acid hydratase assembles to form a 20-nm-diameter particle comprising 60 protein subunits, arranged with 532 symmetry when crystallised at low pH in the presence of phosphate or sulphate ions. The particles form rapidly and are stable in solution during gel filtration at low pH. They are probably formed through trimers of pentamers, which are stabilised by the interaction of two phosphate ions with residues of the N-terminal domains of subunits at the 3-fold axis. Once the particles are formed at high concentrations of phosphate (or sulphate), they remain stable in solution at 20-fold lower concentrations of the anion. Guest molecules can be trapped within the hollow protein shell during assembly. The C-termini of the subunits are freely accessible on the surface of the protein cage and thus are ideal sites for addition of affinity tags or other modifications. These particles offer a convenient model system for studying the assembly of large symmetrical structures and a novel protein nanoparticle for encapsulation and cargo delivery.

Published

2009

7. Structure of B-MLV capsid amino-terminal domain reveals key features of viral tropism, gag assembly and core formation

Author

David C. Goldstone, Mark P. Dodding, Jonathan P. Stoye, Ian A. Taylor, Gulnahar B. Mortuza, and Lesley F. Haire

Subjects

Models, Molecular, Viral protein, viruses, Molecular Sequence Data, Gene Products, gag, Sequence alignment, Random hexamer, Biology, Cleavage (embryo), medicine.disease_cause, Crystallography, X-Ray, Cell Line, Structural Biology, medicine, Animals, Humans, Point Mutation, Amino Acid Sequence, Molecular Biology, Peptide sequence, Tropism, chemistry.chemical_classification, Virology, Amino acid, Protein Structure, Tertiary, Leukemia Virus, Murine, Capsid, chemistry, Amino Acid Substitution, Biophysics, Mutagenesis, Site-Directed, Capsid Proteins, Sequence Alignment

Abstract

The Gag polyprotein is the major structural protein found in all classes of retroviruses. Interactions between Gag molecules control key events at several stages in the cycle of infection. In particular, the capsid (CA) domain of Gag mediates many of the protein-protein interactions that drive retrovirus assembly, maturation and disassembly. Moreover, in murine leukaemia virus (MLV), sequence variation in CA confers N and B tropism that determines susceptibility to the intracellular restriction factors Fv1n and Fv1b. We have determined the structure of the N-terminal domain (NtD) of CA from B-tropic MLV. A comparison of this structure with that of the NtD of CA from N-tropic MLV reveals that although the crystals belong to different space groups, CA monomers are packed with the same P6 hexagonal arrangement. Moreover, interhexamer crystal contacts between residues located at the periphery of the discs are conserved, indicating that switching of tropism does not result in large differences in the backbone conformation, nor does it alter the quaternary arrangement of the disc. We have also examined crystals of the N-tropic MLV CA containing both N- and C-terminal domains. In this case, the NtD hexamer is still present; however, the interhexamer spacing is increased and the conserved interhexamer contacts are absent. Investigation into the effects of mutation of residues that mediate interhexamer contacts reveals that amino acid substitutions at these positions cause severe defects in viral assembly, budding and Gag processing. Based on our crystal structures and mutational analysis, we propose that in MLV, interactions between the NtDs of CA are required for packing of Gag molecules in the early part of immature particle assembly. Moreover, we present a model where proteolytic cleavage at maturation results in migration of CA C-terminal domains into interstitial spaces between NtD hexamers. As a result, NtD-mediated interhexamer contacts present in the immature particle are displaced and the less densely packed lattice with increased hexamer-hexamer spacing characteristic of the viral core is produced.

Published

2007

8. Probing the domain structure of the type IC DNA methyltransferase M.EcoR124I by limited proteolysis

Author

Geoff Kneale, Michelle Webb, Ian A. Taylor, and Keith Firman

Subjects

S-Adenosylmethionine, Site-Specific DNA-Methyltransferase (Adenine-Specific), Methyltransferase, Protein subunit, Proteolysis, Molecular Sequence Data, DNA methyltransferase, Peptide Mapping, Recognition sequence, Structural Biology, medicine, Chymotrypsin, Trypsin, Amino Acid Sequence, Molecular Biology, Peptide sequence, biology, medicine.diagnostic_test, Base Sequence, DNA, Molecular biology, Peptide Fragments, Protein Structure, Tertiary, Biochemistry, biology.protein, Sequence Analysis, medicine.drug

Abstract

Limited proteolysis has been used to probe the domain structure of the type I DNA methyltransferase M.EcoR124I. Trypsin digestion of the methyltransferase generates two fragments derived from the HsdS subunit, a 28 kDa N-terminal domain and a 19 kDa C-terminal domain, leaving the HsdM subunit intact. Extensive digestion by chymotrypsin, however, removes 59 amino acid residues from the N terminus of the HsdM subunit to leave a 52 kDa C-terminal domain. Binding of the cofactor S-adenosyl methionine has no appreciable effect on the rate of cleavage, but binding of a 30 bp DNA duplex containing the cognate recognition sequence confers almost total protection. Following trypsin cleavage of the methyltransferase, a stable proteolytic product is produced which has been purified for biochemical characterisation. The trypsinised enzyme is shown to be a multimeric complex containing two intact HsdM subunits and both fragments of the HsdS subunit, consistent with the circular model proposed for the organisation of domains in the specificity subunit in type IC methyltransferases. Gel retardation studies show that the proteolysed enzyme still retains DNA binding activity, but its specificity for the DNA recognition sequence is dramatically reduced.

Published

1995