Major coat protein and single-stranded DNA-binding protein of filamentous virus Pf3

Genome comparison in silico in Neisseria suggests integration of filamentous bacteriophages by their own transposase

We have identified filamentous prophages, Nf (Neisserial filamentous phages), during an in silico genome comparison in Neisseria. Comparison of three genomes of Neisseria meningitidis and one of Neisseria gonorrhoeae revealed four subtypes of Nf. Eleven intact copies are located at different loci in the four genomes. Each intact copy of Nf is flanked by duplication of 5'-CT and, at its right end, carries a transposase homologue (pivNM/irg) of RNaseH/Retroviral integrase superfamily. The phylogeny of these putative transposases and that of phage-related proteins on Nfs are congruent. Following circularization of Nfs, a promoter-like sequence forms. The sequence at the junction of these predicted circular forms (5'-atCTtatat) was found in a related plasmid (pMU1) at a corresponding locus. Several structural variants of Nfs--partially inverted, internally deleted and truncated--were also identified. The partial inversion seems to be a product of site-specific recombination between two 5'-CTtat sequences that are in inverse orientation, one at its end and the other upstream of pivNM/irg. Formation of internally deleted variants probably proceeded through replicative transposition that also involved two 5'-CTtat sequences. We concluded that the PivNM/Irg transposase on Nfs integrated their circular forms into the chromosomal 5'-CT-containing sequences and probably mediated the above rearrangements.

Proton-decoupled 15N and 31P solid-state NMR investigations of the Pf3 coat protein in oriented phospholipid bilayers

The coat proteins of filamentous phage are first synthesized as transmembrane proteins and then assembled onto the extruding viral particles. We investigated the transmembrane conformation of the Pseudomonas aeruginosa Pf3 phage coat protein using proton-decoupled 15N and 31P solid-state NMR spectroscopy. The protein was either biochemically purified and uniformly labelled with 15N or synthesized chemically and labelled at specific sites. The proteins were then reconstituted into oriented phospholipid bilayers and the resulting samples analysed. The data suggest a model in which the protein adopts a tilted helix with an angle of approximately 30 degrees and an N-terminal 'swinging arm' at the membrane surface.

The role of lipids in membrane insertion and translocation of bacterial proteins

Phospholipids are essential building blocks of membranes and maintain the membrane permeability barrier of cells and organelles. They provide not only the bilayer matrix in which the functional membrane proteins reside, but they also can play direct roles in many essential cellular processes. In this review, we give an overview of the lipid involvement in protein translocation across and insertion into the Escherichia coli inner membrane. We describe the key and general roles that lipids play in these processes in conjunction with the protein components involved. We focus on the Sec-mediated insertion of leader peptidase. We describe as well the more direct roles that lipids play in insertion of the small coat proteins Pf3 and M13. Finally, we focus on the role of lipids in membrane assembly of oligomeric membrane proteins, using the potassium channel KcsA as model protein. In all cases, the anionic lipids and lipids with small headgroups play important roles in either determining the efficiency of the insertion and assembly process or contributing to the directionality of the insertion process.

Filamentous phage active on the gram-positive bacterium Propionibacterium freudenreichii

We present the first description of a single-stranded DNA filamentous phage able to replicate in a gram-positive bacterium. Phage B5 infects Propionibacterium freudenreichii and has a genome consisting of 5,806 bases coding for 10 putative open reading frames. The organization of the genome is very similar to the organization of the genomes of filamentous phages active on gram-negative bacteria. The putative coat protein exhibits homology with the coat proteins of phages PH75 and Pf3 active on Thermus thermophilus and Pseudomonas aeruginosa, respectively. B5 is, therefore, evolutionarily related to the filamentous phages active on gram-negative bacteria.

Insertion and glycosylation of Pf3-derived membrane proteins in microsomes

To get insight into the insertion mechanism of small newly synthesized single-spanning membrane proteins, Pf3 coat protein mutants were constructed with potential glycosylation sites in the N-terminus. Some of these proteins, when synthesized in vitro in the presence of microsomes, became efficiently glycosylated, proving that they insert into the membrane and translocate their N-terminus to the lumenal side. Such Pf3 constructs also insert efficiently into Escherichia coli vesicles and even in pure lipid vesicles, suggesting a common mechanism, which might be spontaneous. Glycosylation was sensitive to changes in the amino acid sequence of the N-terminus, suggesting that it depends on the structure of the protein and/or its positioning with respect to the lipid-water interface.

Filamentous phage fs1 of Vibrio cholerae O139

Filamentous phage, fs1, was obtained from Vibrio cholerae O139. The lysogenized strains produced a large amount of fs1 phage in the culture supernatant. This phage was previously reported as novel fimbriae of that organism. The genome of the phage was a 6.5 kb single-stranded DNA. The capsid of fsl consists of a small molecule peptide (about 2.5 kDa).

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.

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.

Secondary structure of the single-stranded DNA binding protein encoded by filamentous phage Pf3 as determined by NMR

Nuclear magnetic resonance spectroscopy was employed to study the single-stranded DNA binding protein encoded by the filamentous Pseudomonas bacteriophage Pf3. The protein is 78 amino acids long and occurs in solution predominantly as a homodimer with a molecular mass of 18 kDa. Sequence-specific 1H and 15N resonance assignments have been obtained using homo- and heteronuclear two- and three-dimensional experiments. The secondary structure of the protein monomer was determined from a qualitative interpretation of nuclear Overhauser enhancement spectra and amide exchange data. It consists of a five-stranded antiparallel beta-sheet and three beta-hairpins. Problems caused by the protein's tendency to aggregate at concentrations needed for NMR spectroscopy were largely overcome by designing a mutant (Phe36-->His) which exhibits significantly improved solubility characteristics over the wild-type protein. It is shown that this mutation only locally affects the structure of the protein; the chemical shifts of the wild-type and mutant species differ only for a few residues near the site of the mutation, and the secondary structures of the proteins are identical. The secondary structure of the Pf3 single-stranded DNA binding protein is compared to that of the Ff gene V protein, the only single-stranded DNA binding protein for which the complete three-dimensional structure is known to date [Folkers, P. J. M., Nilges, M., Folmer, R. H. A., Konings, R. N. H. & Hilbers, C. W. (1994) J. Mol. Biol. 236, 229-246; Skinner, M. M., Zhang, H., Leschnitzer, D. H., Guan, Y., Bellamy, H., Sweet, R. M., Gray, C. W., Konings, R. N. H., Wang, A. H.-J. & Terwilliger, T. C. (1994) Proc. Natl Acad. Sci. USA 91, 2071-2075]. It is found that the secondary structures of the two proteins are very similar which supports the hypothesis that a five-stranded antiparallel beta-sheet with protruding beta-hairpins is a common motif in a certain class of single-stranded DNA binding proteins. In addition, the sequence and folding predicted earlier for the DNA binding wing in the single-stranded DNA binding protein of phage Pf3 [de Jong, E. A. M., van Duynhoven, J. P. M., Harmsen, B. J. M., Tesser, G. I., Konings, R. N. H. & Hilbers, C. W. (1989) J. Mol. Biol. 206, 133-156] is borne out by the present study. It closely resembles that in the single-stranded DNA binding protein of phage Ff, which may indicate that such a wing is a recurrent motif as well.

Characterization of the Pf3 single-strand DNA binding protein by circular dichroism spectroscopy

We have used circular dichroism (CD) spectroscopy and gel electrophoresis to characterize the single-strand DNA binding protein (ssDBP) of the bacteriophage Pf3 and its complexes with Pf3 DNA and various DNA and RNA homopolymers. The secondary structure of Pf3 ssDBP had < 1% alpha-helix and therefore was probably a beta-sheet structure like the fd gene 5 protein (g5p). From CD titrations, the binding stoichiometry of Pf3 ssDBP was two nucleotides per protein monomer (n = 2) for complexes formed with all of the nucleic acids except poly[r(U)], for which n = 3 (in a buffer of 10 mM Tris-HCl and 70 mM NaCl, pH 8.2). Evidence of an additional binding mode of n = 4 for complexes formed with Pf3 DNA was found by gel electrophoresis experiments. Pf3 ssDBP showed a marked sequence dependence in binding affinities similar to that known for the fd g5p.

Raman spectroscopic study on the conformation of a peptide fragment representing the DNA-binding domain of filamentous virus Pf3 coat protein

Raman spectra have been measured of a nonapeptide which has an amino acid sequence identical to that of the C-terminal region of the major coat protein subunit of filamentous bacteriophage Pf3. The peptide shows a strong tendency to form a beta-sheet structure in aqueous solution. The beta-sheet formation is significantly promoted by complexation with single-stranded DNA but not with double-stranded DNA. It is suggested that the C-terminal region of the Pf3 coat protein binds to the single-stranded DNA genome in the virion with a beta-sheet conformation, in sharp contrast with the alpha-helical binding in other filamentous bacteriophages.

The putative single-stranded DNA-binding protein of the filamentous bacteriophage, Ifl. Amino acid sequence of the protein and structure of the gene

The protein product corresponding to the gene located in the region of the coliphage Ifl genome shown to contain the code for the single-stranded DNA (ssDNA)-binding proteins of all filamentous phages so far studied has been isolated from infected bacterial cells and its amino acid sequence determined. The mature protein contains 95 amino acids (calculated molecular mass 10553 Da). Its sequence corresponds to that predicted from the DNA sequence but lacks the initiating methionine residue. Although there is little direct sequence homology between the phage Ifl protein and the ssDNA-binding proteins of the other filamentous phages that have been studied, computer-based comparisons of various physical and structural parameters showed that the phage Ifl protein contains a domain that is closely related to domains in the coliphage T4 gene 32 protein and the Pseudomonas phage Pfl ssDNA-binding protein and suggest that the Ifl protein does have a ssDNA-binding function although we were unable to show this directly.

A CD determination of the alpha-helix contents of the coat proteins of four filamentous bacteriophages: fd, IKe, Pf1, and Pf3

The CD spectra of four filamentous bacteriophages--fd, IKe, Pf1, and Pf3--were analyzed to determine the alpha-helix contents of their major coat proteins. Measured spectra included the 192-nm band so that analyses could be carried out over the full wavelength range of the reference spectra for protein secondary structures available (a) from globular proteins [J.T. Yang, C.S.C. Wu, and H.M. Martinez (1986) Methods in Enzymology 130, 208-269] and (b) from poly(L-lysine) [N. Greenfield and G.D. Fasman (1960) Biochemistry 8, 4108-4116]. Extended analyses were also performed with the addition of the spectrum of a model beta-turn to the Greenfield and Fasman reference set, with the spectrum of a short alpha-helix in the Yang et al. reference set, and with an estimate of the spectrum of Trp added to both reference sets. The reference set based on the simple poly(L-lysine) polypeptide, plus a spectrum of a model beta-turn or of Trp, gave reasonably good fits to the measured spectra for all four phages and yielded the largest percentages of alpha-helix. The class I phages--fd and IKe--had large percentages of alpha-helix of 98 +/- 2 and 97 +/- 5%, respectively, while the two class II phages--Pf1 and Pf3--had similar but smaller alpha-helix contents of 83 +/- 6 and 84 +/- 2, respectively. While these alpha-helix contents were within the ranges previously reported from CD spectra of these phages in solution, they were more precise, and they indicated that the coat proteins of the intact phages have CD spectra that are probably modeled better by the reference spectra of polypeptides than by those of globular proteins.

Codon usage in Pseudomonas aeruginosa

We have generated a codon usage table for Pseudomonas aeruginosa. Codon usage in P. aeruginosa is extremely biased. In contrast to E. coli and yeast, P. aeruginosa preferentially uses those codons within a synonymous codon group with the strongest predicted codon-anticodon interaction. We were unable to correlate a particular codon usage pattern with predicted levels of mRNA expressivity. The choice of a third base reflects the high guanine plus cytosine content of the P. aeruginosa genome (67.2%) and cytosine is the preferred nucleotide for the third codon position.

A theory of the symmetries of filamentous bacteriophages

A mathematical model is presented which explains the symmetries observed for the protein coats of filamentous bacterial viruses. Three viruses (Ff, IKe, and If1) all have five-start helices with rotation angles of 36 degrees and axial translations of 16 A (Type I symmetry), and three other viruses (Pf1, Xf, and Pf3) all have one-start helices with rotation angles of approximately equal to 67 degrees and translations of approximately 3 A (Type II symmetry). The coat protein subunits in each group diverge from each other in amino acid sequence, and Type II viruses differ dramatically in DNA structure. Regardless of the differences, both Type I and Type II symmetry can be understood as direct, natural consequences of the close-packing of alpha-helical protein subunits. In our treatment, an alpha-helical subunit is modeled as consisting of two interconnected, flexible tubular segments that follow helical paths around the DNA, one in an inner layer and the other in an outer layer. The mathematical model is a set of algebraic equations describing the disposition of the flexible segments. Solutions are described by newly introduced symmetry indices and other parameters. An exhaustive survey over the range of indices has produced a library of all structures that are geometrically feasible within our modeling scheme. Solutions which correspond in their rotation angles to Type I and Type II viruses occur over large ranges of the parameter space. A few solutions with other symmetries are also allowed, and viruses with these symmetries may exist in nature. One solution to the set of equations, obtained without any recourse to the x-ray data, yields a calculated x-ray diffraction pattern for Pf1 which compares reasonably with experimental patterns. The close-packing geometry we have used helps explain the near constant linear mass density of known filamentous phages. Helicoid, rigid cylinder, and maximum entropy structure models proposed by others for Pf1 are reconciled with the flexible tube models and with one another.

Spontaneous deletion mutants of bacteriophage Pf3: mapping of signals involved in replication and assembly

Defective deletion mutants (miniphages) arise spontaneously during serial propagation of the filamentous bacteriophage Pf3. They contain a circular single-stranded (ss) DNA molecule which is up to 80% smaller than the wild-type single-stranded genome. Analysis of the genomic structure of three of these miniphages revealed that they consist of sequences that in the wild-type genome are flanked by direct repeats 5-8 nucleotides long; only one copy of these repeats was found again in the miniphage genome. One miniphage genome contained a tandemly duplicated sequence, and from its structure we concluded that the duplication had occurred after a primary deletion event. Also, short direct repeats must have been involved in the duplication process. We conclude that the deletion and duplication events have occurred by an identical recombination process, probably the "slipped mispairing" mechanism. In the presence of helper functions, the three miniphage genomes are replicated and assembled into ssDNA containing virus-like particles. Hence, the assembly signal and the replication origins for viral and complementary strand synthesis are located within the region shared by all three miniphage genomes, i.e., nucleotides 4092-4678 of the wild-type genome (Luiten et al., 1985).

The region of phage T4 genes 34, 33 and 59: primary structures and organization on the genome

The product of gene 33 is essential for the regulation of late transcription and gene product 59 is required in recombination, DNA repair and replication. The exact functions of both proteins are not known. Restriction fragments spanning the genomic area of genes 33 and 59 have been cloned into phage M13 and a 4.9 kb nucleotide sequence has been determined. Translation of the DNA sequence predicted that gp33 contains 112 amino acids with a mol.wt. of 12.816 kd while gp59 is composed of 217 amino acids adding up to a mol.wt. of 25.967 kd. The genomic area studied here also contains 3 open reading frames of genes not identified to date and it is thought to include the NH2-terminal part of g34. One of the open reading frames seems to code for the 10 kd protein, probably involved in the regulation of transcription of bacteriophage T4. This protein is predicted to consist of 89 amino acid residues with a mol.wt. of 10.376 kd. Gene 33 and the gene for the 10 kd protein were cloned separately on high expression vectors resulting in over-production of the two proteins.

Nucleotide sequence of the genome of Pf3, an IncP-1 plasmid-specific filamentous bacteriophage of Pseudomonas aeruginosa

The circular, single-stranded DNA genome of the Pf3 bacteriophage was sequenced in its entirety by each of two methods, the M13-dideoxy chain termination method and the chemical degradation method. It consists of 5,833 nucleotides. With respect to both the DNA and the protein sequences, there is virtually no homology between Pf3 and the phages Ff (M13, f1, and fd) and IKe. However, similarities between these phages were noted with respect to their overall genome organizations. The gene for the single-stranded DNA-binding protein is followed by the gene for the major coat protein and then by a transcription termination signal. Open reading frames for seven other proteins were predicted, and their sizes and order show a fair correspondence to the sizes and order of the genes of the Ff phages and IKe. In addition, several regions have the potential to form stem and loop structures similar to those in the intergenic region of the Ff phage genome, but in Pf3 some are within open reading frames. Evolutionary relationships between Pf3 and the Ff phages and IKe are thus apparent through the correspondence of overall gene order rather than through primary sequence homologies.

Subunit secondary structure in filamentous viruses: predictions and observations

The algorithm of Garnier, Osguthorpe and Robson (J. Mol. Biol. 120, 97-120, 1978) for prediction of protein secondary structure has been applied to the coat protein sequences of six filamentous bacteriophages: fd, If1, IKe, Pf1, Xf and Pf3. For subunits of Class I virions (fd, If1, IKe), the algorithm predicts a very high percentage of helix in comparison to other structure types, which is in accord with the results of laser Raman and circular dichroism measurements. For subunits of the Class II virions (Pf1, Xf, Pf3), the algorithm consistently predicts a predominance of beta structure, which is compatible with the demonstrated facility for conversion of Class II subunits from alpha-helix to beta-strand under appropriate experimental conditions (Thomas, Prescott and Day, J. Mol. Biol. 165, 321-356, 1983). Even when the algorithm is biased to favor helix, the Class II virion subunits are predicted to contain considerably more strand than helix. Qualitatively similar results are obtained using the algorithm of Chou and Fasman (Adv. Enzym. 47, 45-148, 45-148). Therefore, both predictive and experimental methods indicate a distinction between Class I and II subunits, which is reflected in a greater tendency of the latter to adopt other than uniform alpha-helical conformation. The results suggest a possible model for the disassembly of filamentous viruses which may involve the unraveling of coat protein helices at the N terminus.