Secretion and membrane integration of a filamentous phage-encoded morphogenetic protein

The filamentous phage-encoded gene IV protein is required at high levels for virus assembly, although it is not a constituent of the virion. It is an integral membrane protein that does not contain an extended hydrophobic region of the kind often required for stable integration in the inner membrane. Rather, like a number of Escherichia coli outer membrane proteins, pIV is rich in charged amino acid residues and is predicted to consist of extensive beta-sheet structures. In phage-producing cells, pIV is primarily detected in the outer membrane, while in cells that produce it from the cloned gene, pIV is found in both the inner and outer membranes. The protein is synthesized as a precursor. Following cleavage of the signal sequence and translocation into the periplasm, the mature form is initially found as a soluble species. Soluble pIV then integrates into the membrane with a half-time of one to two minutes. Neither phage assembly nor other phage proteins are needed for this membrane integration, and phage assembly does not require the presence of the soluble form. The gene IV protein may be part of the structure through which the assembling phage is extruded.     

The pI and pXI assembly proteins serve separate and essential roles in filamentous phage assembly.

Three non-capsid, phage-encoded proteins, pI, pIV and pXI, are required for assembly of the filamentous bacteriophage at the envelope of Escherichia coli. pIV forms the outer membrane component of the assembly site, and pI and pXI are predicted to form the cytoplasmic membrane component. pXI is the result of an in-frame internal translational initiation event in gene I and is identical with the carboxyl-terminal third of pI in amino acid sequence, membrane localization and topology. The two proteins share a cytoplasmic domain predicted to be an amphipathic helix, a transmembrane domain, and a periplasmic domain. By mutating the initiation site for pXI, a phage was made that produced only pI and was shown to absolutely require functional plasmid-encoded pXI for growth. Further mutational analysis was done to examine the functional determinants of the amphipathic helix and periplasmic domains of the pI and pXI proteins. The results show that the amphipathic helix region is very important for pI function but not for pXI function. Mutational analysis of the periplasmic domains of pI and pXI implies that these domains also perform separate functions, and suggests that the interaction between pI and pIV in the periplasm is critical for assembly. The results are discussed with regard to the separate roles that the pI and pXI proteins play in the overall process of phage assembly.     

The C-terminal domain of the secretin PulD contains the binding site for its cognate chaperone, PulS, and confers PulS dependence on pIVf1 function

Related outer membrane proteins, termed secretins, participate in the secretion of macromolecules across the outer membrane of many Gram-negative bacteria. In the pullulanase-secretion system, PulS, an outer membrane-associated lipoprotein, is required both for the integrity and the proper outer membrane localization of the PulD secretin. Here we show that the PulS-binding site is located within the C-terminal 65 residues of PulD. Addition of this domain to the filamentous phage secretin, pIV, or to the unrelated maltose-binding protein rendered both proteins dependent on PulS for stability. A chimeric protein composed of bacteriophage f1 pIV and the C-terminal domain of PulD required properly localized PulS to support phage assembly. An in vivo complex formed between the pIV-PulD₆₅ chimera and PulS was detected by co-immunoprecipitation and by affinity chromatography.     

A trans-envelope protein complex needed for filamentous phage assembly and export

Assembly and export of filamentous phage requires four non-capsid proteins: the outer membrane protein, pIV; the inner membrane proteins, pI and pXI; and a cytoplasmic host factor, thioredoxin. Chemical cross-linking of intact cells demonstrates a trans-membrane complex containing pI and pIV. Formation of the complex protects pI from proteolytic cleavage by an endogenous protease. This protection also requires pXI, which is identical to the C-terminal portion of pI. This indicates that pXI, which is required for phage assembly in its own right, is also part of the complex. This complex forms in the absence of any other phage proteins or the DNA substrate; hence, it represents the first preinitiation step of phage morphogenesis. On the basis of protease protection data, we propose that the preinitiation complex is converted to an initiation complex by binding phage DNA, thioredoxin and the initiating minor coat protein(s).     

Mutants at conserved positions in gene IV, a gene required for assembly and secretion of filamentous phages

The filamentous phage protein pIV is required for assembly and secretion of the virus and possesses regions homologous to those found in a number of Gram-negative bacterial proteins that are essential components of a widely distributed extracellular protein-export system. These proteins form multimers that may constitute an outer membrane channel that allows phage/protein egress. Three sets of f1 gene IV mutants were isolated at positions that are absolutely (G355 and P375) or largely (F381) conserved amongst the 16 currently known family members. The G355 mutants were non-functional, interfered with assembly of plV⁺ phage, and made Escherichia coli highly sensitive to deoxycholate. The P375 mutants were non-functional and defective in multimerization. Many of the F381 mutants retained substantial function, and even those in which charged residues had been introduced supported some phage assembly. Some inferences about the roles of these conserved amino acids are made from the mutant phenotypes.     

Identification of the gate regions in the primary structure of the secretin pIV

Secretins are a family of large bacterial outer membrane channels that serve as exit ports for folded proteins, filamentous phage and surface structures. Despite the large size of their substrates, secretins do not compromise the barrier function of the outer membrane, implying a gating mechanism. The region in the primary structure that forms the putative gate has not previously been determined for any secretin. To identify residues involved in gating the pIV secretin of filamentous bacteriophage f1, we used random mutagenesis of the gene followed by positive selection for mutants with compromised barrier function (‘leaky’ mutants). We identified mutations in 34 residues, 30 of which were clustered into two regions located in the centre of the conserved C‐terminal secretin family domain: GATE1 (that spanned 39 residues) and GATE2 (that spanned 14 residues). An internal deletion constructed in the GATE2 region resulted in a severely leaky phenotype. Three of the four remaining mutations are located in the region that encodes the N‐terminal, periplasmic portion of pIV and could be involved in triggering gate opening. Two missense mutations in the 24‐residue region that separates GATE1 and GATE2 were also constructed. These mutant proteins were unstable, defective in multimerization and non‐functional.     

Essential role of a sodium dodecyl sulfate-resistant protein IV multimer in assembly-export of filamentous phage.

Filamentous phage f1 encodes protein IV (pIV), a protein essential for phage morphogenesis that localizes to the outer membrane of Escherichia coli, where it is found as a multimer of 10 to 12 subunits. Introduction of internal His or Strep affinity tags at different sites in pIV interfered with its function to a variable extent. A spontaneous second-site suppressor mutation in gene IV allowed several different insertion mutants to function. The identical mutation was also isolated as a suppressor of a multimerization-defective missense mutation. A high-molecular-mass pIV species is the predominant form of pIV present in cells. This species is stable in 4% sodium dodecyl sulfate at temperatures up to 65 degrees C and is largely preserved at 100 degrees C in Laemmli protein sample buffer containing 4% sodium dodecyl sulfate. The suppressor mutation makes the high-molecular-mass form of wild-type pIV extremely resistant to dissociation, and it stabilizes the high-molecular-mass form of several mutant pIV proteins to extents that correlate with their level of function. Mixed multimers of pIV(f1) and pIV(Ike) also remain associated during heating in sodium dodecyl sulfate-containing buffers. Thus, sodium dodecyl sulfate- and heat-resistant high-molecular-mass pIV is derived from pIV multimer and reflects the physiologically relevant form of the protein essential for assembly-export.     

Structure of the filamentous phage pIV multimer by cryo-electron microscopy

The homo-multimeric pIV protein constitutes a channel required for the assembly and export of filamentous phage across the outer membrane of Escherichia coli. We present a 22 A-resolution three-dimensional reconstruction of detergent-solubilized pIV by cryo-electron microscopy associated with image analysis. The structure reveals a barrel-like complex, 13.5 nm in diameter and 24 nm in length, with D14 point-group symmetry, consisting of a dimer of unit multimers. Side views of each unit multimer exhibit three cylindrical domains named the N-ring, the M-ring and the C-ring. Gold labeling of pIV engineered to contain a single cysteine residue near the N or C terminus unambiguously identified the N-terminal region as the N-ring, and the C-terminal region was inferred to make up the C-ring. A large pore, ranging in inner diameter from 6.0 nm to 8.8 nm, runs through the middle of the multimer, but a central domain, the pore gate, blocks it. Moreover, the pore diameter at the N-ring is smaller than the phage particle. We therefore propose that the pIV multimer undergoes a large conformational change during phage transport, with reorganization of the central domain to open the pore, and widening at the N-ring in order to accommodate the 6.5 nm diameter phage particle.     

The filamentous bacteriophage assembly proteins require the bacterial SecA protein for correct localization to the membrane.

The noncapsid assembly proteins pI and pI of the filamentous bacteriophage f1 are inserted into the inner membrane of Escherichia coli via an internal signal sequence. Inhibition of the activity of SecA with low concentrations of sodium azide results in rapid accumulation of pI and pI proteins in the cytoplasm. However, both proteins are inserted into the membrane under the same conditions when synthesized in bacteria containing a secA azide resistance mutation. The other noncapsid assembly protein, pIV, is an outer membrane protein synthesized with a cleavable signal sequence. Wild-type bacteria accumulate the precursor to pIV when protein synthesis is in the presence of low concentrations of sodium azide. These results suggest that the f1 bacteriophage assembly proteins require SecA and consequently the bacterial Sec system to reach their proper membrane location.     

Filamentous phage assembly: variation on a protein export theme

Biogenesis of both filamentous phage and type-IV pili involves the assembly of many copies of a small, integral inner membrane protein (the phage major coat protein or pilin) into a helical, tubular array that passes through the outer membrane. The occurrence of related proteins required for assembly and export in both systems suggests that there may be similarities at the mechanistic level as well. This report summarizes the properties of filamentous phage and the proteins required for their assembly, with particular emphasis on features they may share with bacterial protein export and pilus biogenesis systems, and it presents evidence that supports the hypothesis that one of the phage proteins functions as an outer membrane export channel.     

Filamentous phage infection: required interactions with the TolA protein.

Infection of Escherichia coli by the filamentous phage f1 is initiated by binding of the phage to the tip of the F conjugative pilus via the gene III protein. Subsequent translocation of phage DNA requires the chromosomally encoded TolQ, TolR, and TolA proteins, after the pilus presumably has withdrawn, bringing the phage to the bacterial surface. Of these three proteins, TolA is proposed to span the periplasm, since it contains a long helical domain (domain II), which connects a cytoplasmic membrane anchor domain (domain I) to the carboxyl-terminal domain (domain III). By using a transducing phage, the requirement for TolA in an F+ strain was found to be absolute. The role of TolA domains II and III in the infective process was examined by analyzing the ability of various deletion mutants of tolA to facilitate infection. The C-terminal domain III was shown to be essential, whereas the polyglycine region separating domains I and II could be deleted with no effect. Deletion of helical domain II reduced the efficiency of infection, which could be restored to normal by retaining the C-terminal half of domain II. Soluble domain III, expressed in the periplasm but not in the cytoplasm or in the medium, interfered with infection of a tolA+ strain. The essential interaction of TolA domain III with phage via gene III protein appears to require interaction with a third component, either the pilus tip or a periplasmic entity.     

Membrane insertion defects caused by positive charges in the early mature region of protein pIII of filamentous phage fd can be corrected by prlA suppressors.

The filamentous phage coat protein pIII has been used to display a variety of peptides and proteins to allow easy screening for desirable binding properties. We have examined the biological constraints that restrict the expression of short peptides located in the early mature region of pIII, adjacent to the signal sequence cleavage site. Many functionally defective pIII fusion proteins contained several positively charged amino acids in this region. These residues appear to inhibit proper insertion of pIII into the Escherichia coli inner membrane, blocking the assembly and extrusion of phage particles. Suppressor mutations in the prlA (secY) component of the protein export apparatus dramatically alleviate the phage growth defect caused by the positively charged residues. We conclude that insertion of pIII fusion proteins into the inner membrane can occur by a sec gene-dependent mechanism. The suppressor strains should be useful for increasing the diversity of peptides displayed on pIII in phage libraries.     

Genomic sequence and receptor for the Vibrio cholerae phage KSF-1phi: evolutionary divergence among filamentous vibriophages mediating lateral gene transfer

KSF-1phi, a novel filamentous phage of Vibrio cholerae, supports morphogenesis of the RS1 satellite phage by heterologous DNA packaging and facilitates horizontal gene transfer. We analyzed the genomic sequence, morphology, and receptor for KSF-1phi infection, as well as its phylogenetic relationships with other filamentous vibriophages. While strains carrying the mshA gene encoding mannose-sensitive hemagglutinin (MSHA) type IV pilus were susceptible to KSF-1phi infection, naturally occurring MSHA-negative strains and an mshA deletion mutant were resistant. Furthermore, d-mannose as well as a monoclonal antibody against MSHA inhibited infection of MSHA-positive strains by the phage, suggesting that MSHA is the receptor for KSF-1phi. The phage genome comprises 7,107 nucleotides, containing 14 open reading frames, 4 of which have predicted protein products homologous to those of other filamentous phages. Although the overall genetic organization of filamentous phages appears to be preserved in KSF-1phi, the genomic sequence of the phage does not have a high level of identity with that of other filamentous phages and reveals a highly mosaic structure. Separate phylogenetic analysis of genomic sequences encoding putative replication proteins, receptor-binding proteins, and Zot-like proteins of 10 different filamentous vibriophages showed different results, suggesting that the evolution of these phages involved extensive horizontal exchange of genetic material. Filamentous phages which use type IV pili as receptors were found to belong to different branches. While one of these branches is represented by CTXphi, which uses the toxin-coregulated pilus as its receptor, at least four evolutionarily diverged phages share a common receptor MSHA, and most of these phages mediate horizontal gene transfer. Since MSHA is present in a wide variety of V. cholerae strains and is presumed to express in the environment, diverse filamentous phages using this receptor are likely to contribute significantly to V. cholerae evolution.     

Comprehensive mutagenesis of the C-terminal domain of the M13 gene-3 minor coat protein: the requirements for assembly into the bacteriophage particle

Filamentous bacteriophage assemble at the host membrane in a non-lytic process; the gene-3 minor coat protein (P3) is required for release from the membrane and subsequently, for recognition and infection of a new host. P3 contains at least three distinct domains: two N-terminal domains that mediate host recognition and infection, and a C-terminal domain (P3-C) that is required for release from the host cell following phage assembly and contributes to the structural stability of the phage particle. A comprehensive mutational analysis of the 150 residue P3-C revealed that only 24 side-chains, located within the last 70 residues of sequence, were necessary for efficient incorporation into a wild-type coat. The results reveal that the requirements for the assembly of P3 into the phage particle are quite lax and involve only a few key side-chains. These findings shed light on the functional and structural requirements for filamentous phage assembly, and they may provide guidelines for the engineering of improved coat proteins as scaffolds for phage display technology.     

The Salmonella typhimurium InvH protein is an outer membrane lipoprotein required for the proper localization of InvG

The secretion of pathogenicity factors by Salmonella typhimurium is mediated by a type III secretion system that includes an outer membrane protein of the secretin family. Related secretins are also required for f1 phage assembly and type II secretion. When the C-terminal 43 amino acids of the S. typhimurium secretin InvG are added to f1 pIV, the chimeric f1 pIV-'InvG₄₃ protein becomes dependent on the co-expression of another gene, invH , for function in phage assembly. [³H]-palmitic acid labelling, globomycin sensitivity and density gradient flotation were used to demonstrate that InvH is an outer membrane lipoprotein that is processed by signal peptidase II. A complex between chimeric f1 pIV-'InvG₄₃ and InvH was demonstrated in vivo. InvH was shown to be required for the proper localization of InvG in the outer membrane and for the secretion of the virulence factor SipC. These results suggest that InvH and InvG are part of the functional outer membrane translocation complex in type III secretion systems.     

The adsorption protein of phage IKe. Localization by deletion mutagenesis of domains involved in infectivity

We constructed a set of plasmid-encoded internal deletion mutants within the gene for the adsorption protein (g3p) of phage IKe. All mutant proteins still contain the signal and membrane anchor sequence, as those are known to be indispensable for proper localization and hence assembly of the g3p into phage. These various deletions comprise all internal parts of the protein and are properly incorporated into phage, which remarkably shows that signal and anchor sequence are sufficient for incorporation of g3p. The data furthermore reveal that two separate sections within the IKe g3p are essential for infection: one amino-terminal, preceding the glycine-rich stretch, and the other carboxy-terminal. We conclude that this latter domain is involved in penetration because mutants lacking it are not infectious, but still bind to the receptor. The amino-terminal region, essential for infection, bears the receptor-recognizing domain and a sequence homologous to the penetration domain of the evolutionary related Ff phages, which is probably also involved in penetration of phage IKe. The prominent glycine-rich stretch of the IKe g3p is not essential for infection but significantly promotes it.     

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.     

Recombinant forms of M13 procoat with an OmpA leader sequence or a large carboxy-terminal extension retain their independence of secY function.

The assembly of phage M13 procoat protein into the plasma membrane of Escherichia coli is independent of the secY protein. To test whether this is caused by the unusually small size of procoat, we fused DNA encoding 103 amino acids to the carboxy-terminal end of the procoat gene. The resulting fusion protein, which attains the same membrane-spanning conformation as mature coat protein, still does not require the secY function for membrane assembly. To determine whether the leader sequence governs interaction with the secY protein, we genetically exchanged the leader peptides between procoat and pro-OmpA, a protein which does require secY for its membrane assembly. Each of the resulting hybrid proteins assembles across the plasma membrane, though at a reduced rate. Membrane assembly of the fusion of procoat leader and OmpA required secY function, whereas assembly of the pro-OmpA leader/coat protein fusion was independent of secY. Properties of the entire procoat molecule, rather than its small size or a specific property of its leader peptide determines its mode of membrane assembly.