Terminating a macromolecular helix. Structural model for the minor proteins of bacteriophage M13

Cryo-electron microscopy of the f1 filamentous phage reveals insights into viral infection and assembly

Phages are viruses that infect bacteria and dominate every ecosystem on our planet. As well as impacting microbial ecology, physiology and evolution, phages are exploited as tools in molecular biology and biotechnology. This is particularly true for the Ff (f1, fd or M13) phages, which represent a widely distributed group of filamentous viruses. Over nearly five decades, Ffs have seen an extraordinary range of applications, yet the complete structure of the phage capsid and consequently the mechanisms of infection and assembly remain largely mysterious. In this work, we use cryo-electron microscopy and a highly efficient system for production of short Ff-derived nanorods to determine a structure of a filamentous virus including the tips. We show that structure combined with mutagenesis can identify phage domains that are important in bacterial attack and for release of new progeny, allowing new models to be proposed for the phage lifecycle.

The Transmembrane Morphogenesis Protein gp1 of Filamentous Phages Contains Walker A and Walker B Motifs Essential for Phage Assembly

In contrast to lytic phages, filamentous phages are assembled in the inner membrane and secreted across the bacterial envelope without killing the host. For assembly and extrusion of the phage across the host cell wall, filamentous phages code for membrane-embedded morphogenesis proteins. In the outer membrane of Escherichia coli, the protein gp4 forms a pore-like structure, while gp1 and gp11 form a complex in the inner membrane of the host. By comparing sequences with other filamentous phages, we identified putative Walker A and B motifs in gp1 with a conserved lysine in the Walker A motif (K14), and a glutamic and aspartic acid in the Walker B motif (D88, E89). In this work we demonstrate that both, Walker A and Walker B, are essential for phage production. The crucial role of these key residues suggests that gp1 might be a molecular motor driving phage assembly. We further identified essential residues for the function of the assembly complex. Mutations in three out of six cysteine residues abolish phage production. Similarly, two out of six conserved glycine residues are crucial for gp1 function. We hypothesise that the residues represent molecular hinges allowing domain movement for nucleotide binding and phage assembly.

Architectural insight into inovirus-associated vectors (IAVs) and development of IAV-based vaccines inducing humoral and cellular responses: implications in HIV-1 vaccines

Inovirus-associated vectors (IAVs) are engineered, non-lytic, filamentous bacteriophages that are assembled primarily from thousands of copies of the major coat protein gp8 and just five copies of each of the four minor coat proteins gp3, gp6, gp7 and gp9. Inovirus display studies have shown that the architecture of inoviruses makes all coat proteins of the inoviral particle accessible to the outside. This particular feature of IAVs allows foreign antigenic peptides to be displayed on the outer surface of the virion fused to its coat proteins and for more than two decades has been exploited in many applications including antibody or peptide display libraries, drug design, and vaccine development against infectious and non-infectious diseases. As vaccine carriers, IAVs have been shown to elicit both a cellular and humoral response against various pathogens through the display of antibody epitopes on their coat proteins. Despite their high immunogenicity, the goal of developing an effective vaccine against HIV-1 has not yet materialized. One possible limitation of previous efforts was the use of broadly neutralizing antibodies, which exhibited autoreactivity properties. In the past five years, however, new, more potent broadly neutralizing antibodies that do not exhibit autoreactivity properties have been isolated from HIV-1 infected individuals, suggesting that vaccination strategies aimed at producing such broadly neutralizing antibodies may confer protection against infection. The utilization of these new, broadly neutralizing antibodies in combination with the architectural traits of IAVs have driven the current developments in the design of an inovirus-based vaccine against HIV-1. This article reviews the applications of IAVs in vaccine development, with particular emphasis on the design of inoviral-based vaccines against HIV-1.

Love-wave sensors combined with microfluidics for fast detection of biological warfare agents

The following paper examines a time-efficient method for detecting biological warfare agents (BWAs). The method is based on a system of a Love-wave immunosensor combined with a microfluidic chip which detects BWA samples in a dynamic mode. In this way a continuous flow-through of the sample is created, promoting the reaction between antigen and antibody and allowing a fast detection of the BWAs. In order to prove this method, static and dynamic modes have been simulated and different concentrations of BWA simulants have been tested with two immunoreactions: phage M13 has been detected using the mouse monoclonal antibody anti-M13 (AM13), and the rabbit immunoglobulin (Rabbit IgG) has been detected using the polyclonal antibody goat anti-rabbit (GAR). Finally, different concentrations of each BWA simulants have been detected with a fast response time and a desirable level of discrimination among them has been achieved.

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.

Next generation phage display by use of pVII and pIX as display scaffolds

Phage display technology has evolved to become an extremely versatile and powerful platform for protein engineering. The robustness of the phage particle, its ease of handling and its ability to tolerate a range of different capsid fusions are key features that explain the dominance of phage display in combinatorial engineering. Implementation of new technology is likely to ensure the continuation of its success, but has also revealed important short comings inherent to current phage display systems. This is in particular related to the biology of the two most popular display capsids, namely pIII and pVIII. Recent findings using two alternative capsids, pVII and pIX, located to the phage tip opposite that of pIII, suggest how they may be exploited to alleviate or circumvent many of these short comings. This review addresses important aspects of the current phage display standard and then discusses the use of pVII and pIX. These may both complement current systems and be used as alternative scaffolds for display and selection to further improve phage display as the ultimate combinatorial engineering platform.

Phage display as a method for discovering cellular targets of small molecules

Phage display can be used for the discovery of cellular targets of small molecules in order to unravel their mechanism of action, which is important in the drug discovery field to assess biological effects of drugs at the molecular level and to investigate pharmacokinetic characteristics of drugs in clinical use. The potential of phage display in the drug discovery field is shown by a lot of successful cellular target identifications of drug-like small molecules in the last decade. More recently, phage display was also introduced in environmental science to predict risks of small molecules, like nickel, 17β estradiol and bisphenol A on both environmental and human health, wherefore knowledge about the mechanism of action and cellular targets is essential. This paper discusses some important aspects of the phage display approach for the discovery of cellular targets of small molecules. The different phage display libraries and immobilization strategies used for the discovery of cellular target of small molecules are described. In general, the phage display approach is very useful in drug discovery and environmental science as a fast and cost-effective in vitro tool to determine cellular targets of small molecules, which increases our understanding of the mechanisms of action of small molecules.

M13 bacteriophage display framework that allows sortase-mediated modification of surface-accessible phage proteins

We exploit bacterial sortases to attach a variety of moieties to the capsid proteins of M13 bacteriophage. We show that pIII, pIX, and pVIII can be functionalized with entities ranging from small molecules (e.g., fluorophores, biotin) to correctly folded proteins (e.g., GFP, antibodies, streptavidin) in a site-specific manner, and with yields that surpass those of any reported using phage display technology. A case in point is modification of pVIII. While a phage vector limits the size of the insert into pVIII to a few amino acids, a phagemid system limits the number of copies actually displayed at the surface of M13. Using sortase-based reactions, a 100-fold increase in the efficiency of display of GFP onto pVIII is achieved. Taking advantage of orthogonal sortases, we can simultaneously target two distinct capsid proteins in the same phage particle and maintain excellent specificity of labeling. As demonstrated in this work, this is a simple and effective method for creating a variety of structures, thus expanding the use of M13 for materials science applications and as a biological tool.

Design and screening of M13 phage display cDNA libraries

The last decade has seen a steady increase in screening of cDNA expression product libraries displayed on the surface of filamentous bacteriophage. At the same time, the range of applications extended from the identification of novel allergens over disease markers to protein-protein interaction studies. However, the generation and selection of cDNA phage display libraries is subjected to intrinsic biological limitations due to their complex nature and heterogeneity, as well as technical difficulties regarding protein presentation on the phage surface. Here, we review the latest developments in this field, discuss a number of strategies and improvements anticipated to overcome these challenges making cDNA and open reading frame (ORF) libraries more readily accessible for phage display. Furthermore, future trends combining phage display with next generation sequencing (NGS) will be presented.

Viruses: incredible nanomachines. New advances with filamentous phages

During recent decades, bacteriophages have been at the cutting edge of new developments in molecular biology, biophysics, and, more recently, bionanotechnology. In particular filamentous viruses, for example bacteriophage M13, have a virion architecture that enables precision building of ordered and defect-free two and three-dimensional structures on a nanometre scale. This could not have been possible without detailed knowledge of coat protein structure and dynamics during the virus reproduction cycle. The results of the spectroscopic studies conducted in our group compellingly demonstrate a critical role of membrane embedment of the protein both during infectious entry of the virus into the host cell and during assembly of the new virion in the host membrane. The protein is effectively embedded in the membrane by a strong C-terminal interfacial anchor, which together with a simple tilt mechanism and a subtle structural adjustment of the extreme end of its N terminus provides favourable thermodynamical association of the protein in the lipid bilayer. This basic physicochemical rule cannot be violated and any new bionanotechnology that will emerge from bacteriophage M13 should take this into account.

Protein-lipid interactions of bacteriophage M13 gene 9 minor coat protein (Review)

Gene 9 protein is one of the minor coat proteins of bacteriophage M13. The protein plays a role in the assembly process by associating with the host membrane by protein-lipid interactions. The availability of chemically synthesized protein has enabled the biophysical characterization of the membrane-bound state of the protein by using model membrane systems. This paper summarizes, discusses and further interprets this work in the light of the current state of the literature, leading to new possible models of the coat protein in a membrane. The biological implications of these findings related to the membrane-bound phage assembly are indicated.

Anchoring mechanisms of membrane-associated M13 major coat protein

Bacteriophage M13 major coat protein is extensively used as a biophysical, biochemical, and molecular biology reference system for studying membrane proteins. The protein has several elements that control its position and orientation in a lipid bilayer. The N-terminus is dominated by the presence of negatively charged amino acid residues (Glu2, Asp4, and Asp5), which will always try to extend into the aqueous phase and therefore act as a hydrophilic anchor. The amphipathic and the hydrophobic transmembrane part contain the most important hydrophobic anchoring elements. In addition there are specific aromatic and charged amino acid residues in these domains (Phe 11, Tyr21, Tyr24, Trp26, Phe42, Phe45, Lys40, Lys43, and Lys44) that fine-tune the association of the protein to the lipid bilayer. The interfacial Tyr residues are important recognition elements for precise protein positioning, a function that cannot be performed optimally by residues with an aliphatic character. The Trp26 anchor is not very strong: depending on the context, the tryptophan residue may move in or out of the membrane. On the other hand, Lys residues and Phe residues at the C-terminus of the protein act in a unique concerted action to strongly anchor the protein in the lipid bilayer.

Protein-lipid interactions of bacteriophage M13 major coat protein

During the past years, remarkable progress has been made in our understanding of the replication cycle of bacteriophage M13 and the molecular details that enable phage proteins to navigate in the complex environment of the host cell. With new developments in molecular membrane biology in combination with spectroscopic techniques, we are now in a position to ask how phages carry out this delicate process on a molecular level, and what sort of protein-lipid and protein-protein interactions are involved. In this review we will focus on the molecular details of the protein-protein and protein-lipid interactions of the major coat protein (gp8) that may play a role during the infection of Escherichia coli by bacteriophage M13.

Structural characterization of bacteriophage M13 solubilization by amphiphiles

The structural properties of bacteriophage M13 during disassembly were studied in different membrane model systems, composed of a homologue series of the detergents sodium octyl sulfate, sodium decyl sulfate, and sodium dodecyl sulfate. The structural changes during phage disruption were monitored by spin-labeled electron spin resonance (ESR) and circular dichroism spectroscopy. For the purpose of ESR spectroscopy the major coat protein mutants V31C and G38C were site-directed spin labeled in the intact phage particle. These mutants were selected because the mutated sites are located in the hydrophobic part of the protein, and provide good reporting locations for phage integrity. All amphiphiles studied were capable of phage disruption. However, no significant phage disruption was detected below the critical micelle concentration of the amphiphile used. Based on this finding and the linear dependence of phage disruption by amphiphiles on the phage concentration, it is suggested that the solubilization of the proteins of the phage coat by amphiphiles starts with an attachment to and penetration of amphiphile molecules into the phage particle. The amphiphile concentration in the phage increases in proportion to the amphiphile concentration in the aqueous phase. Incorporation of the amphiphile in the phage particle is accompanied with a change in local mobility of the spin-labeled part of the coat protein and its secondary structure. With increasing the amphiphile concentration in the phage particle, a concentration is reached where the concentration of the amphiphile in the aqueous phase is around its critical micelle concentration. A further increase in amphiphile concentration results in massive phage disruption. Phage disruption by amphiphiles appears to be dependent on the phage coat mutations. It is concluded that phage disruption is dependent on a hydrophobic effect, since phage solubilization could significantly be increased by keeping the hydrophilic part of the amphiphile constant, while increasing its hydrophobic part.

Phage display of cDNA repertoires: the pVI display system and its applications for the selection of immunogenic ligands

The selection of phage displayed cDNA repertoires on an immobilised target has been reported to be an efficient way to rapidly identify interacting partners. To date, however, only a few successful applications have been reported. Here, we present a review of the current status of the display and selection of cDNA libraries using phage. As an example, we report the construction of a set of phage display vectors suitable for cDNA display based on fusion to the minor bacteriophage coat protein 6 (pVI) of filamentous phage. We have evaluated these vectors through the display of the C(H)3 domain of human IgG and of the Escherichia coli alkaline phosphatase (PhoA) gene. Both the C(H)3 domain of IgG and PhoA are shown to be displayed on pVI, and PhoA is also shown to be enzymatically active. We have constructed primary colorectal tumor cDNA repertoires in these vectors and performed selections on both a monoclonal antibody to beta2 microglobulin (beta2M) and polyclonal antibody sera to human IgG. In both cases, relevant ligands were recovered from the phage displayed cDNA repertoire. These vectors may be used for selection of phage displayed cDNA libraries with polyclonal sera from patients. This will allow the identifying antigenic cDNA products in such diseases as cancer, viral/bacterial infections or autoimmune disease. Furthermore, by selections with other specific biomolecules, this display system may aid the identification of interacting partners in functional genomics.

The basic structure of filamentous phage and its use in the display of combinatorial peptide libraries

Combinatorial peptide libraries have been playing a major role in the search for new drugs, ligands, enzyme substrates, and other specifically interacting molecules. The principal features of these libraries require a versatile repertoire, an easily identifiable tag for each of the library members, a simple method of synthesis, and a compatibility with the biochemical milieu. Two types of combinatorial libraries are in use: synthetic libraries and biological (mainly phage display) ones. An advantage of the biological libraries is due to the ability of each of the library members to replicate itself and to the fact that they carry their own coding sequences. The uniqueness of filamentous phage is that of its five virion proteins, three can tolerate the insertion of foreign peptides, each in a distinctive manner. The major coat protein, pVIII, is capable of displaying hundreds of peptide copies over the phage virion, pIII can display either one or five copies, and pVI, as opposed to the first two, displays its peptides such that the carboxy terminus is oriented outward. A major drawback of filamentous phage is its size. The length of an intact phage particle is 930 nm and it contains an ssDNA of 6400 bp. 2800 copies of the major coat protein form a "fish scale" cover over most of the virion DNA, whereas five copies of pIII, which has been the major protein used for library display, and five copies of pVI are located at one end of the filamentous virion. There is no doubt that in order to improve the quality of filamentous phage libraries, the size of phage should be drastically reduced. Comprehensive research on the phage life cycle and its structure will lead us to the construction of miniature phage and to other methods that will enable an in vivo expanding of the library repertoire as well as to binding-induced specific clone-proliferation.

Filamentous phage are released from the bacterial membrane by a two-step mechanism involving a short C-terminal fragment of pIII

Filamentous phage assemble at the membrane of infected cells. The phage filament is released from the membrane at the end of assembly, after four to five copies of the minor proteins, pIII and pVI, have been added to the end of the virion. In the absence of pIII or pVI, phage filaments are not released, but remain associated with the cells. The C-terminal portion of pIII, termed the "C" domain, is required for the release of stable virions. With the use of pIII C-terminal fragments of increasing size, termination of assembly can be divided into various steps. An 83-residue fragment leads to the incorporation of pVI into the assembling phage, but does not release it from the membrane. A slightly longer fragment (93 residues) is sufficient to release the particle into the culture supernatant. However, these released particles are unstable in the detergent, sarkosyl, which does not disrupt wild-type phage. A fragment of >121 residues is needed for the particle to become detergent resistant. Thus, the C-domain can be divided into two subdomains: C2, sufficient for release, and C1, required for virion stability.A model for termination of phage assembly is proposed in which pIII and pVI dock to the membrane-associated filament and form a pre- termination complex. Then, a conformational change involving the C2 domain of pIII disrupts the hydrophobic interactions with the inner membrane, releasing the phage from the cells. The pIII-mediated release of phage from the membranes points to one possible mechanism for excision of membrane-anchored protein complexes from lipid bilayers.

Conformational and aggregational properties of the gene 9 minor coat protein of bacteriophage M13 in membrane-mimicking systems

The membrane-bound state of the gene 9 minor coat protein of bacteriophage M13 was studied in various membrane-mimicking systems, including organic solvents, detergent micelles, and phospholipid bilayers. For this purpose we determined the conformational and aggregational properties of the chemically synthesized protein by CD, FTIR, and HPSEC. The protein appears to be in a monomeric or small oligomeric alpha-helical state in TFE but adopts a mixture of alpha-helical and random structure after subsequent incorporation into SDS or DOPG. When solubilized by sodium cholate, however, the protein undergoes a transition in time into large aggregates, which contain mainly beta-sheet conformation. The rate of this beta-polymerization process was decreased at lower temperature and higher concentrations of sodium cholate. This aggregation was reversed only upon addition of high concentrations of the strong detergent SDS. By reconstitution of the cholate-solubilized protein into DOPG, it was found that the state of the protein, whether initially alpha-helical monomeric/oligomeric or beta-sheet aggregate, did not change. On the basis of our results, we propose that the principal conformational state of membrane-bound gene 9 protein in vivo is alpha-helical.

Solution structure of the M13 major coat protein in detergent micelles: a basis for a model of phage assembly involving specific residues

The three-dimensional structure of the major coat protein of bacteriophage M13, solubilized in detergent micelles, has been determined using heteronuclear multidimensional NMR and restrained molecular dynamics. The protein consists of two alpha-helices, running from residues 8 to 16 and 25 to 45, respectively. These two helices are connected by a flexible and distorted helical hinge region. The structural properties of the coat protein make it resemble a flail, in which the hydrophobic helix (residues 25 to 45) is the handle and the other, amphipathic, helix the swingle. In this metaphor, the hinge region is the connecting piece of leather. The mobility of the residues in the hinge region is likely to enable a smooth transformation from the membrane-bound form, mimicked by the structure in detergent micelles, into the structure in the mature phage. A specific distribution of the residues over the surface of the two helices was observed in the presented high-resolution structure of the membrane-bound form of the major coat protein as well as in the structure in the mature phage. All data suggest that this arrangement of residues is important for the interactions of the protein with the membrane, for correct protein-DNA and protein-protein interactions in the phage and for a proper growth of the phage during the assembly process. By combining our findings with earlier NMR results on the major coat protein in detergent micelles, we were able to construct a model that addresses the role of specific residues in the assembly process.

Mimicking initial interactions of bacteriophage M13 coat protein disassembly in model membrane systems

The structure and changes in environment of the M13 major coat protein were studied in model systems, mimicking the initial molecular process of the phage disassembly. For this purpose we have systematically studied protein associations with various detergents and lipids in two different coat protein assemblies: phage particles and S-forms. It is remarkable that the major coat protein can change its conformation to accommodate three distinctly different environments: phage filament, S-form, and membrane-bound form. The structural and environmental changes during this protein transformations were studied by site-directed spin labeling, fluorescence labeling, and CD spectroscopy in different membrane model systems. The phage particles were disrupted only by strong ionic detergents [sodium dodecyl sulfate (SDS) and cetyltrimethylammonium bromide and (CTAB)] but were not affected by sodium cholate and sodium deoxycholate, nonionic detergents, and dilauroyl-l-alpha-phosphatidylcholine (DLPC) lipid bilayers. Conversion of the phage particles into S-forms by addition of chloroform rendered the coat protein accessible for the association with different ionic and nonionic detergents, as well as DLPC lipids. The disruption of the S-form by all detergents studied was instantaneous but was slower with DLPC vesicles. Only small unilamellar vesicles effectively solubilized the S-form. The data suggest that the viral protein coat is inherently unstable when the major coat protein is exposed to amphiphilic molecules. During conversion from the phage to the S-form, and subsequently to the membrane-bound form, the coat protein undergoes pronounced changes in environment, and in response the alpha-helix content decreases and the local protein structure changes dramatically. This adaptation of the protein conformation enables a stable association of the protein with the membrane.

NMR studies of the major coat protein of bacteriophage M13. Structural information of gVIIIp in dodecylphosphocholine micelles

The membrane-bound form of the major coat protein (gVIIIp) of bacteriophage M13 has been studied using nuclear magnetic resonance spectroscopy. As membrane mimetics, we used dodecylphosphocholine (DodPCho) detergent micelles to solubilize the protein. We were able to nearly completely assign all resonances of the protein solubilized in DodPCho micelles by using both homonuclear and heteronuclear multidimensional experiments. Based on the patterns of the nuclear Overhauser enhancements and the chemical shifts of the resonances, we deduced the secondary structure of the protein. Additional structural information was obtained from amide proton exchange data and J-coupling constants. The protein consists of two alpha-helices which are connected by a hinge region around residue 21. From spin-label experiments, the location of the protein relative to the DodPCho micelles was determined. One, hydrophobic, helix spans the micelle, and another, amphipathic, helix, is located beneath the surface of the micelle. Comparison of the data of gVIIIp in DodPCho micelles with those of gVIIIp in sodium dodecyl sulfate (SDS) micelles [Van de Ven, F. J. M., van Os, J. W. M., Aelen, J. M. A., Wymenga, S. S., Remerowski, M. L., Konings, R. N. H. & Hilbers, C. W. (1993) Biochemistry 32, 8322-8328; Papavoine, C. H. M., Konings, R. N. H., Hilbers, C. W. & Van de Ven, F. J. M. (1994) Biochemistry 33, 12,990-12,997] reveals that the structures of the protein in the two detergent micelles are very similar. They differ only in the arrangement of the detergent molecules around the protein. For gVIIIp in SDS micelles, we found a micellar structure which is distorted near the C-terminus of the protein; whereas for DodPCho micelles, both distorted and regular elliptical micelles occur. This distortion is probably due to the interaction of the positively charged lysine side chains with the negatively charged head group of the detergent molecules.

Surface expression and ligand-based selection of cDNAs fused to filamentous phage gene VI

We describe a novel phage display system that affords the surface expression and hence affinity selection of cDNAs. The strategy is based on a new approach to functionally display proteins on filamentous phage through the attachment to the C-terminus of the minor coat protein VI. The utility of the method was evaluated using a cDNA library derived from the parasite Ancylostoma caninum. cDNA sequences were fused in each of the three reading frames to the 3'-end of the M13 gene VI expressed by a phagemid vector. Phages rescued from this cDNA expression library were subjected to biopanning against two serine proteases, trypsin and the human coagulation factor Xa. This led to the identification of cDNAs encoding novel members of two different families of serine protease inhibitors. The authenticity of the cDNA selected with trypsin as the target was demonstrated by purifying the encoded potent Kunitz-type inhibitor from an Ancylostoma caninum extract. The rapid isolation of specific cDNAs with the protein VI monovalent display system should facilitate the search for novel biologically important ligands.

The role of the adsorption complex in the termination of filamentous phage assembly

The adsorption complex of filamentous phage fd consists of two minor coat proteins, g3p and g6p, and is considered to be not only a structural entity, but also a functional unit to terminate phage assembly. Cells were infected with phage M13am8H1, which cannot assemble because it lacks the major coat protein g8p, although producing all of the other minor coat proteins. The membranes of infected cells were solubilized and analysed by non-denaturing PAGE and gel filtration. The data suggest the presence of the adsorption complex in these membranes. Furthermore, the non-polar gene 3 amber-mutant phage R171 was shown to lack g6p in the phage coat as well. The termination of assembly of this phage is disturbed, resulting in synthesis of polyphages. Electron micrographs and transient electrical birefringence show that these polyphages are eight times longer as compared to unit length phage. From these results, we conclude that the formation of the g3p-g6p complex is essential for correct termination of filamentous phage assembly.

The adsorption protein of bacteriophage fd and its neighbour minor coat protein build a structural entity

The adsorption protein g3p and another minor coat protein, g6p, are located at one end of the filamentous bacteriophage fd [Grant, R.A., Lin, T.C., Konigsberg, W.E. & Webster, R.E. (1981) J. Biol. Chem. 256, 539-546]. Both proteins, representing the proximal tip, were detached as an entity by a technique that allowed for gentle solubilization. Disrupting the phage particle with the detergent sodium deoxycholate and chloroform dissociates the major coat protein g8p, frees the phage DNA, but leaves g3p and g6p associated with each other. The g3p-g6p complex, which we termed the adsorption complex, and an oligomeric form of g3p with lower molecular mass were isolated and purified by gel-filtration chromatography in the presence of deoxycholate. These different oligomeric structures of g3p showed a different mobility in non-denaturing polyacrylamide-gel electrophoresis. Both forms were also found in non-denaturing polyacrylamide-gel electrophoresis from deoxycholate- and Triton-X-100-solubilized phage without prior chromatographic separation. The two oligomeric forms of g3p are composed of two g3p polypeptide chains in the case of the low-molecular-mass species, and four g3p and four g6p polypeptide chains for the adsorption complex.

Molecular models and structural comparisons of native and mutant class I filamentous bacteriophages Ff (fd, f1, M13), If1 and IKe

The filamentous bacteriophages are flexible rods about 1 to 2 microns long and 6 nm in diameter, with a helical shell of protein subunits surrounding a DNA core. The approximately 50-residue coat protein subunit is largely alpha-helix and the axis of the alpha-helix makes a small angle with the axis of the virion. The protein shell can be considered in three sections: the outer surface, occupied by the N-terminal region of the subunit, rich in acidic residues that interact with the surrounding solvent and give the virion a low isoelectric point; the interior of the shell, including a 19-residue stretch of apolar side-chains, where protein subunits interact mainly with each other; and the inner surface, occupied by the C-terminal region of the subunit, rich in basic residues that interact with the DNA core. The fact that virtually all protein side-chain interactions are between different subunits in the coat protein array, rather than within subunits, makes this a useful model system for studies of interactions between alpha-helix subunits in a macromolecular assembly. We describe molecular models of the class I filamentous bacteriophages. This class includes strains fd, f1, M13 (these 3 very similar strains are members of the Ff group), If1 and IKe. Our model of fd has been refined to fit quantitative X-ray fibre diffraction data to 30 A resolution in the meridional direction and 7 A resolution in the equatorial direction. A simulated 3.3 A resolution diffraction pattern from this model has the same general distribution of intensity as the experimental diffraction pattern. The observed diffraction data at 7 A resolution are fitted much better by the calculated diffraction pattern of our molecular model than by that of a model in which the alpha-helix subunit is represented by a rod of uniform density. The fact that our fd model explains the fd diffraction data is only part of our structure analysis. The atomic details of the model are supported by non-diffraction data, in part previously published and in part newly reported here. These data include information about permitted or forbidden side-chain replacements, about the effect of chemical modification, and about spectroscopic experiments.(ABSTRACT TRUNCATED AT 400 WORDS)

Assignment of 1H, 15N, and backbone 13C resonances in detergent-solubilized M13 coat protein via multinuclear multidimensional NMR: a model for the coat protein monomer

The major coat protein (gVIIIp) of bacteriophage M13 complexed with SDS detergent micelles was used as a model system to study the lipid-bound conformation of the protein. Conditions were found that allowed the recording of good quality of NMR spectra. By making extensive use of three-dimensional heteronuclear (13C, 15N) NMR, we obtained a complete set of resonance assignments for 1HN, 1H alpha, 1H beta, 13C alpha, CO, and 15N and partially assigned the rest of the 1H spectrum. Analysis of NOE and chemical shift data reveals that gVIIIp is composed of two alpha-helical domains, one ranging from Pro-6 to Glu20 and the other ranging from Tyr-24 all the way to the C-terminus Ser-50. In contrast to the results reported by Henry and Sykes [Henry, G.D., & Sykes, B.D. (1992) Biochemistry 31, 5285-5297], at a high SDS to protein ratio the protein appears to be monomeric.

Structural constraints on the display of foreign peptides on filamentous bacteriophages

Strategies for the construction of vehicles for phage display are evaluated here on the basis of structural studies of filamentous bacteriophages. Potential sites for the insertion of foreign peptides into the major coat protein, gp8, of M13 are identified. Currently, the insertion of peptides into gp8 has two basic limitations: all insertion sites that have been used successfully are located within 5 amino acids (aa) of the N terminus, and in virions containing only mutant coat proteins, insertions larger than about 6 aa have not been successfully incorporated. The possible reasons for these limitations are discussed in terms of the structures of gp8 and the minor structural proteins, gp7 and gp9. Potential strategies for overcoming these limitations are outlined. Reasons for the successful incorporation of larger inserts into hybrid phage containing both native and mutant coat proteins are also discussed. The structures of gp6, gp7, and gp9 are described, and it is concluded that insertion sites in these minor proteins are unlikely to have substantial advantages over those currently being used in gp3. The structure of the coat protein of another filamentous phage, Pseudomonas phage Pf1, is also described. Its structure provides a number of clues for the successful design of phage display insertion sites. Because it contains a 7-aa surface loop in the major coat protein, the Pf1 coat protein may have significant advantages over gp8 of M13 as a vehicle for phage display.