Dual importance of positive charge in the C-terminal region of filamentous bacteriophage coat protein for membrane insertion and DNA-protein interaction in virus assembly

Structure and assembly of filamentous bacteriophages

Filamentous bacteriophages are interesting paradigms in structural molecular biology, in part because of the unusual mechanism of filamentous phage assembly. During assembly, several thousand copies of an intracellular DNA-binding protein bind to each copy of the replicating phage DNA, and are then displaced by membrane-spanning phage coat proteins as the nascent phage is extruded through the bacterial plasma membrane. This complicated process takes place without killing the host bacterium. The bacteriophage is a semi-flexible worm-like nucleoprotein filament. The virion comprises a tube of several thousand identical major coat protein subunits around a core of single-stranded circular DNA. Each protein subunit is a polymer of about 50 amino-acid residues, largely arranged in an α-helix. The subunits assemble into a helical sheath, with each subunit oriented at a small angle to the virion axis and interdigitated with neighbouring subunits. A few copies of "minor" phage proteins necessary for infection and/or extrusion of the virion are located at each end of the completed virion. Here we review both the structure of the virion and aspects of its function, such as the way the virion enters the host, multiplies, and exits to prey on further hosts. In particular we focus on our understanding of the way the components of the virion come together during assembly at the membrane. We try to follow a basic rule of empirical science, that one should chose the simplest theoretical explanation for experiments, but be prepared to modify or even abandon this explanation as new experiments add more detail.

C2, and unusual filamentous bacterial virus: protein sequence and conformation, DNA size and conformation, and nucleotide/subunit ratio

Inovirus C2 is 1295 nm long and 6.8 nm in diameter, and its mass is 24 million Da. Its genome is a topologically circular, single-stranded DNA molecule of 8100 nucleotides. The DNA is packed in the virion as two antiparallel strands, with a rise per nucleotide in each strand of 3.2 A; it can be assigned spectroscopic properties like those of base-stacked, right-handed, double-stranded DNA. The stoichiometric ratio (n/s) of nucleotides to subunits of the major coat protein is close to 2. The protein subunit contains 52 amino acids, and the DNA sequence of its gene does not encode a signal peptide. The protein conformation in the virion is helical, mostly alpha-helix with perhaps some 3(10)-helix. The amino acid sequence of the DNA interaction domain of the subunit is unique among Inovirus species. On the basis of its coat protein sequence and available theories of helical symmetry in such structures, C2 appears to be either an unusual member of filamentous virus symmetry class II or the defining member of a new symmetry class.

Selection of antibody ligands from a large library of oligopeptides expressed on a multivalent exposition vector

Practically any oligopeptide can be exposed on the surface of the bacteriophage capsid by fusion to the major coat protein of filamentous bacteriophages. A phage expressing a particular peptide tag can be selected from a mixture of tens of millions of clones, exposing oligopeptides of random sequence, by affinity purification with a protein ligand. In this respect, pVIII can be used as an alternative and complement to the exposition vectors based on the product of gene III (pIII). We have constructed a phagemid vector that contains gene VIII under the control of the pLac promoter. This vector can be conveniently used to construct libraries of oligopeptides with a random amino acid sequence. An antipeptide monoclonal antibody was used to affinity-purify phagemids exposing oligopeptides which can interact with the monoclonal antibody. DNA sequencing of the amino terminus of gene VIII of the recovered clones predicts the synthesis of hybrid proteins whose aminoterminal amino acid sequence is related to that of the oligopeptide used to raise the antibody. In other words, only oligopeptides that bind a very small portion of the immunoglobulin G surface are affinity-purified by this method, implying that the antigen binding site possesses molecular properties that renders it much stickier than the remainder of the molecule.

Export of infectious particles by Escherichia coli transfected with the RF DNA of Pf1, a virus of Pseudomonas aeruginosa strain K

Pf1 is a filamentous, single-stranded DNA virus that has Pseudomonas aeruginosa (strain K) as host. It is the longest of the filamentous bacterial viruses, and the DNA within it has the most extended conformation known. Pf1 virus cannot infect Escherichia coli (strain MM294) cells, but when these cells are transfected with the double-stranded replicative form of Pf1 DNA (RF DNA, 7.35 kb), they export low levels of infectious particles that create plaques on lawns of P. aeruginosa. Several different structural species, at least two of which are infectious, are exported. One of them, called Epf1, has virtually the same structure as Pf1, but the amount of Epf1 exported by E. coli is 10(4) lower than the amount of Pf1 exported by P. aeruginosa. The results imply that host factors affect not only the efficiency of virus assembly and export, but also the actual structures of the species exported.

Neutron diffraction studies of the structure of filamentous bacteriophage Pf1. Demonstration that the coat protein consists of a pair of alpha-helices with an intervening, non-helical surface loop

The structure of filamentous bacteriophage Pf1 has been studied using neutron diffraction from magnetically oriented gels of native and specifically deuterated phage. These methods have been used to determine the positions of the two methionine, two tyrosine and six isoleucine residues of the coat protein. Combined with the positions of the five valine residues previously determined, they represent one third (15 of 46) of the residues of the coat protein. These 15 amino acid residue positions have been used as the basis for constructing a model for the protein consisting of two alpha-helices with an intervening surface loop. The first helix extends from near the amino terminus to Ile12. The second helix extends from Lys20 to at least Met42, and may contain a bend between Ile32 and Val35. The two helices are tilted by about 15 degrees relative to one another, and are positioned in such a way that they appear to be bound end-to-end by main-chain hydrogen bonds. The intervening, non-helical loop, made up of Thr13 to Met19, connects the two helices without disrupting the pattern of main-chain hydrogen bonding, but does not result in a bend in the otherwise continuous helical structure. This model is used to predict the approximate positions of all amino acid residues in the Pf1 protein coat, providing a basis for further understanding of a number of viral properties including the symmetry transitions, the non-isomorphism of heavy-atom derivatives, and the protein-protein and protein-DNA interactions in the virion.

Membrane-mediated assembly of filamentous bacteriophage Pf1 coat protein

Filamentous bacteriophage Pf1 assembles by a membrane-mediated process during which the viral DNA is secreted through the membrane while being encapsulated by the major coat protein. Neutron diffraction studies showed that in the virus most of the coat protein consists of two alpha-helical segments arranged end-to-end with an intervening mobile surface loop. Nuclear magnetic resonance studies of the coat protein in the membrane-bound form have shown that the secondary structure is essentially identical to that in the intact virus. A comparison indicates that during membrane-mediated viral assembly, while the secondary structure of the coat protein is largely conserved, its tertiary structure changes substantially.

Regulation of filamentous bacteriophage length by modification of electrostatic interactions between coat protein and DNA

Bacteriophage fd gene VIII, which encodes the major capsid protein, was mutated to convert the serine residue at position 47 to a lysine residue (S47K), thereby increasing the number of positively charged residues in the C-terminal region of the protein from four to five. The S47K coat protein underwent correct membrane insertion and processing but could not encapsidate the viral DNA, nor was it incorporated detectably with wild-type coat proteins into hybrid bacteriophage particles. However, hybrid virions could be constructed from the S47K coat protein and a second mutant coat protein, K48Q, the latter containing only three lysine residues in its C-terminal region. K48Q phage particles are approximately 35% longer than wild-type. Introducing the S47K protein shortened these particles, the S47K/K48Q hybrids exhibiting a range of lengths between those of K48Q and wild-type. These results indicate that filamentous bacteriophage length (and the DNA packaging underlying it) are regulated by unusually flexible electrostatic interactions between the C-terminal domain of the coat protein and the DNA. They strongly suggest that wild-type bacteriophage fd makes optimal use of the minimum number of coat protein subunits to package the DNA compactly.