Your search keyword '"Burnett, Roger M."' showing total 4 results

1. Insights into assembly from structural analysis of bacteriophage PRD1.

Author

Abrescia NG, Cockburn JJ, Grimes JM, Sutton GC, Diprose JM, Butcher SJ, Fuller SD, San Martín C, Burnett RM, Stuart DI, Bamford DH, and Bamford JK

Subjects

Amino Acid Sequence, Capsid chemistry, Capsid ultrastructure, Cryoelectron Microscopy, Crystallography, X-Ray, Models, Molecular, Molecular Sequence Data, Protein Structure, Quaternary, Protein Subunits chemistry, Viral Structural Proteins ultrastructure, Virion ultrastructure, Bacteriophage PRD1 chemistry, Bacteriophage PRD1 ultrastructure, Viral Structural Proteins chemistry, Virion chemistry, Virus Assembly

Abstract

The structure of the membrane-containing bacteriophage PRD1 has been determined by X-ray crystallography at about 4 A resolution. Here we describe the structure and location of proteins P3, P16, P30 and P31. Different structural proteins seem to have specialist roles in controlling virus assembly. The linearly extended P30 appears to nucleate the formation of the icosahedral facets (composed of trimers of the major capsid protein, P3) and acts as a molecular tape-measure, defining the size of the virus and cementing the facets together. Pentamers of P31 form the vertex base, interlocking with subunits of P3 and interacting with the membrane protein P16. The architectural similarities with adenovirus and one of the largest known virus particles PBCV-1 support the notion that the mechanism of assembly of PRD1 is scaleable and applies across the major viral lineage formed by these viruses.

Published

2004

2. The receptor binding protein P2 of PRD1, a virus targeting antibiotic-resistant bacteria, has a novel fold suggesting multiple functions.

Author

Xu L, Benson SD, Butcher SJ, Bamford DH, and Burnett RM

Subjects

Amino Acid Sequence, Escherichia coli virology, Molecular Sequence Data, Protein Structure, Secondary, Protein Structure, Tertiary, Bacteriophage PRD1 metabolism, Capsid Proteins metabolism

Abstract

Bacteriophage PRD1 is unusual, with an internal lipid membrane, but has striking resemblances to adenovirus that include receptor binding spikes. The PRD1 vertex complex contains P2, a 590 residue monomer that binds to receptors on antibiotic-resistant strains of E. coli and so is the functional counterpart to adenovirus fiber. P2 structures from two crystal forms, at 2.2 and 2.4 A resolution, reveal an elongated club-shaped molecule with a novel beta propeller "head" showing pseudo-6-fold symmetry. An extended loop with another novel fold forms a long "tail" containing a protruding proline-rich "fin." The head and fin structures are well suited to recognition and attachment, and the tail is likely to trigger the processes of vertex disassembly, membrane tube formation, and subsequent DNA injection.

Published

2003

3. Minor proteins, mobile arms and membrane-capsid interactions in the bacteriophage PRD1 capsid.

Author

San Martín C, Huiskonen JT, Bamford JK, Butcher SJ, Fuller SD, Bamford DH, and Burnett RM

Subjects

Bacteriophage PRD1 genetics, Cloning, Molecular, Crystallography, X-Ray, Intracellular Membranes metabolism, Models, Molecular, Bacteriophage PRD1 metabolism, Capsid metabolism

Abstract

Bacteriophage PRD1 shares many structural and functional similarities with adenovirus. A major difference is the PRD1 internal membrane, which acts in concert with vertex proteins to translocate the phage genome into the host. Multiresolution models of the PRD1 capsid, together with genetic analyses, provide fine details of the molecular interactions associated with particle stability and membrane dynamics. The N- and C-termini of the major coat protein (P3), which are required for capsid assembly, act as conformational switches bridging capsid to membrane and linking P3 trimers. Electrostatic P3-membrane interactions increase virion stability upon DNA packaging. Newly revealed proteins suggest how the metastable vertex works and how the capsid edges are stabilized.

Published

2002

4. The X-ray crystal structure of P3, the major coat protein of the lipid-containing bacteriophage PRD1, at 1.65 A resolution.

Author

Benson SD, Bamford JK, Bamford DH, and Burnett RM

Subjects

Crystallography, X-Ray, Models, Molecular, Molecular Structure, Virion chemistry, Bacteriophage PRD1 chemistry, Capsid chemistry, Lipids chemistry

Abstract

P3 has been imaged with X-ray crystallography to reveal a trimeric molecule with strikingly similar characteristics to hexon, the major coat protein of adenovirus. The structure of native P3 has now been extended to 1.65 A resolution (R(work) = 19.0% and R(free) = 20.8%). The new high-resolution model shows that P3 forms crystals through hydrophobic patches solvated by 2-methyl-2,4-pentanediol molecules. It reveals details of how the molecule's high stability may be achieved through ordered solvent in addition to intra- and intersubunit interactions. Of particular importance is a 'puddle' at the top of the molecule containing a four-layer deep hydration shell that cross-links a complex structural feature formed by 'trimerization loops'. These loops also link subunits by extending over a neighbor to reach the third subunit in the trimer. As each subunit has two eight-stranded viral jelly rolls, the trimer has a pseudo-hexagonal shape to allow close packing in its 240 hexavalent capsid positions. Flexible regions in P3 facilitate these interactions within the capsid and with the underlying membrane. A selenometh-ionine P3 derivative, with which the structure was solved, has been refined to 2.2 A resolution (R(work) = 20.1% and R(free) = 22.8%). The derivatized molecule is essentially unchanged, although synchrotron radiation has the curious effect of causing it to rotate about its threefold axis. P3 is a second example of a trimeric 'double-barrel' protein that forms a stable building block with optimal shape for constructing a large icosahedral viral capsid. A major difference is that hexon has long variable loops that distinguish different adenovirus species. The short loops in P3 and the severe constraints of its various interactions explain why the PRD1 family has highly conserved coat proteins.

Published

2002