Bacteriophage F1 Research Articles

High-frequency interconversion of turbid and clear plaque strains of bacteriophage f1 and associated host cell death

High-frequency interconversion of turbid and clear plaque strains of bacteriophage f1 and associated host cell death

A family of multifunctional thiamine-repressible expression vectors for fission yeast.

A series of thiamine-repressible shuttle vectors has been constructed to allow a more efficient DNA manipulation in Schizosaccharomyces pombe. These high-copy-number vectors with regulatable expression (pJR) are based on the backbone of the pREP-3X, pREP-41X and pREP-81X plasmids. The pJR vectors are all uniform in structure, containing: (a) sequences for replication (ori) and selection (AmpR) in Escherichia coli; (b) the f1 ori sequence of the phage f1 for packaging of ssDNA, making them suitable for site-directed mutagenesis; and (c) the ars1 sequence for replication in S. pombe. The pJR vectors differ among them in: (a) the selectable marker (Saccharomyces cerevisiae LEU 2 gene, which complements S. pombe leu1- gene and S. pombe ura4+ and his3+ genes); (b) the thiamine-repressible nmt1 promoter (3X, 41X and 81X with extremely high, moderate or low transcription efficiency, respectively); and (c) the multiple cloning site (two multiple cloning sites, with 12 restriction sites each). The expression level of the pJR vectors has been analysed using the beta-galactosidase gene as reporter. Three levels of expression for each nmt1 promoter version, with any selectable marker and for either repressed or induced conditions, have been found. The expression is dependent on the distance to the initiation codon, varying from 0.001 to 15 times the activity characterized for the pREP plasmids. Also, the gene expression has been found to be extremely sensitive to the nucleotide sequence prior to the initiation codon, being up to 50-fold higher with an A/T sequence than with a G/C sequence. Finally, the beta-galactosidase mRNA levels were found to be similar in each nmt1 series, suggesting a translational effect on gene expression. As a result, any of these 18 new vectors allow performing gene expression in fission yeast, as well as a more versatile cloning, sequencing and mutagenesis, directly in the plasmid without the need for subcloning into intermediary vectors.

Changing views on the nature of the bacterial cell: from biochemistry to cytology.

When the authors were graduate students in the 1960s, the bacterial cell was generally viewed as an amorphous vessel housing a homogeneous solution of proteins. Trained as biochemists, we would break cells open, subject the disrupted cells to centrifugation, and separate the supernatant fluid from the membranous material that collected at the bottom of the centrifuge tube. Some enzymes, such as the replicase for the RNA phage F2, the subject of thesis research by L.S., were to be found in the supernatant fluid. Other enzymes, such as those involved in the biosynthesis of the O-antigen component of the lipopolysaccharide of Salmonella, the subject of doctoral work by R.L., were associated with the membrane. No differentiation was imagined other than the distinction between membrane proteins and cytoplasmic proteins. This is a view that persisted for a surprisingly long time. Of course, some bacteria have conspicuous proteinaceous appendages, such as flagella and pili, and some bacteria, such as Caulobacter crescentus, are conspicuously asymmetric. But only in this decade, and chiefly over the last few years, has it become apparent that cytoplasmic and membrane proteins can, and often do, have particular subcellular addresses, that these addresses can change over time, sometimes with extraordinary rapidity, and that an understanding of function requires knowledge not only of what a protein does but often of where it is in the cell.

The Shigella flexneri bacteriophage Sf6 tailspike protein (TSP)/endorhamnosidase is related to the bacteriophage P22 TSP and has a motif common to exo- and endoglycanases, and C-5 epimerases.

The temperate bacteriophage Sf6 infects Shigella flexneri strains of serotype X or Y, converting them into serotypes 3a or 3b, respectively. The tailspike protein (TSP) of Sf6 possesses endo-1,3-alpha-L-rhamnosidase (endorhamnosidase) activity which results in cleavage of the lipopolysaccharide O-antigen receptor during the adsorption of the phage to the cell surface. When used in Southern hybridization, a P22 gene 9 (encoding P22 TSP) DNA probe hybridized with restriction fragment Pstl-7 of Sf6. DNA sequencing and analysis of Pstl-7 and the adjacent Pstl-8 fragment revealed an open reading frame (ORF1) of 1872 bp (624 amino acids) bearing amino acid sequence homology to the bacteriophage P22 TSP N-terminal head-binding domain. High conservation of key residues was suggestive of similar secondary and tertiary N-terminal protein structure and a similar function of the Sf6 TSP in this region. In addition, an amino acid sequence motif (DFGX3DGX6AX3A) was identified between residues 164 and 184 which was also found to exist in various prokaryotic and eukaryotic exo-/endoglycanases, C-5 epimerases and bacteriophage proteins. Expression of ORF1 from a T7 promoter produced a 67 kDa protein (detected by L-[35S]methionine labelling and SDS-PAGE). Assay of heat-treated cytoplasmic extracts containing the ORF1-encoded protein by incubation with whole Sh. flexneri Y cells demonstrated that O-antigen hydrolysis activity was present; ORF1 therefore encodes Sf6 TSP. Sf6 TSP exhibited specific and preferential activity for long-chain Sh. flexneri serotype X or Y O-antigen, cleavage of which resulted in the release of oligosaccharide fragments, consistent with octasaccharides in size, as detected by fluorophore-assisted carbohydrate electrophoresis (FACE).

Roles of polyadenylation and nucleolytic cleavage in the filamentous phage mRNA processing and decay pathways in Escherichia coli.

To define basic features of mRNA processing and decay in Escherichia coli, we have examined a set of mRNAs encoded by the filamentous phage f1 that have structures typical of bacterial mRNAs. They bear a stable hairpin stem-loop on the 3' end left from rho-independent termination and are known to undergo processing by RNase E. A small percentage of the f1 mRNAs were found to bear poly(A) tails that were attached to heterogeneous positions near the common 3' end. In a poly(A) polymerase-deficient host, the later-appearing processed mRNAs were stabilized, and a novel small RNA accumulated. This approximately 125-nt RNA proved to arise via RNase E cleavage from the 3'-terminal region of the mRNAs bearing the terminator. Normally ribosomes translating gene VIII appear to protect this cleavage site from RNase E, so that release of the fragment from the mRNAs occurs very slowly. The data presented define additional steps in the f1 mRNA processing and decay pathways and clarify how features of the pathways are used in establishing and maintaining the persistent filamentous phage infection. Although the primary mode of decay is endonucleolytic cleavage generating a characteristic 5' --> 3' wave of products, polyadenylation is involved in part in degradation of the processed mRNAs and is required for turnover of the 125-nt mRNA fragment. The results place polyadenylation at a later rather than an initiating step of decay. They also provide a clear illustration of how stably structured RNA 3' ends act as barriers to 3' --> 5' exonucleolytic mRNA decay.

Latent Periodicity of Protein Sequences

This article is in the area of protein sequence investigation. It studies protein sequence periodicity. The notion of latent periodicity is introduced. A mathematical method for searching for latent periodicity in protein sequences is developed. Implementation of the method developed for known cases of perfect and imperfect periodicity is demonstrated. Latent periodicity of many protein sequences from the SWISS-PROT data bank is revealed by the method and examples of latent periodicity of amino acid sequences are demonstrated for: the translation initiation factor EIF-2B (epsilon subunit) of Saccharomyces cerevisiae from the E2BE_YEAST sequence; the E.coli ferrienterochelin receptor from the FEPA_ECOLI sequence; the lysozyme of Bacteriophage SF6 from the LY_BPSF6 sequence; lipoamide dehydrogenase of Azotobacter vinelandii from the DLDH_AZOVI sequence. These protein sequences have latent periods equal to six, two, seven and 19 amino acids, respectively. We propose that a possible purpose of the amino acid sequence latent periodicity is to determine certain protein structures.

Hole-istic medicine.

It is a mystery how some viruses are able to replicate inside the host cell, producing progeny that escape without damaging the host's plasma membrane. In a Perspective, [Joshua Zimmerberg][1] describes new research ([ Marciano et al .][2]) demonstrating that the f1 phage (a virus that infects bacteria) is able to export new progeny out of the bacterial host using a phage-encoded pIV protein, which forms a gated channel in the bacterial outer membrane. Zimmerberg compares this mechanism of export to that of other viruses and discusses what these new findings teach us about protein translocation in eukaryotic cells. [1]: http://www.sciencemag.org/cgi/content/full/284/5419/1475 [2]: http://www.sciencemag.org/cgi/content/short/284/5419/1516

An aqueous channel for filamentous phage export.

Filamentous phage f1 exits its Escherichia coli host without killing the bacterial cell. It has been proposed that f1 is secreted through the outer membrane via a phage-encoded channel protein, pIV. A functional pIV mutant was isolated that allowed E. coli to grow on large maltodextrins and rendered E. coli sensitive to large hydrophilic antibiotics that normally do not penetrate the outer membrane. In planar lipid bilayers, both mutant and wild-type pIV formed highly conductive channels with similar permeability characteristics but different gating properties: the probability of the wild-type channel being open was much less than that of the mutant channel. The high conductivity of pIV channels suggests a large-diameter pore, thus implicating pIV as the outer membrane phage-conducting channel.

Expansion and Deletion of Triplet Repeat Sequences inEscherichia coli Occur on the Leading Strand of DNA Replication

Expansions and deletions of triplet repeat sequences that cause human hereditary neurological diseases were previously suggested to be mediated by the formation of DNA hairpins on the lagging strand during replication. The replication properties of CTG.CAG, CGG.CCG, and TTC.GAA repeats were studied in Escherichia coli using an in vivo phagemid system as a model for continuous leading strand synthesis. The repeats were substantially deleted when the CTG, CGG, and GAA repeats were the templates for rolling circle replication from the f1 phage origin. The deletions may be mediated by hairpins formed by these repeat tracts. The distributions of the deletion products of the CTG.CAG and CGG.CCG tracts indicated that hairpins of discrete sizes mediate deletions during complementary strand synthesis. Deletions during rolling circle synthesis are caused by larger hairpins of specific sizes. Thus, most deletion products were of defined lengths, suggesting a preference for specific hairpin intermediates. Small expansions of the CTG.CAG and CGG.CCG repeats were also observed, presumably due to the formation of CTG and CGG hairpins on the nascent complementary strand. Since rolling circle replication has been established in vitro as a model for leading strand synthesis, we conclude that triplet repeat instability can also occur on the leading strand of DNA replication.

T Cell Proliferation-Augmenting Activities of the Gene 3 Protein Derived from a Phage Library Clone with CD80-Binding Activity

We have isolated a phage clone, F2, by panning a phage library with a CTLA4-conformation recognizing mAb (anti-CTLA4 mAb). The unique sequence of 15 amino acids with an internal disulfide bond was inserted in the gene 3 proteins of F2 phage clone (F2-g3p). We show here that 1) F2-g3p was recognized with anti-CTLA4 mAb but not with anti-CD28 mAb, and 2) F2-g3p bound to CD80 but not to CD86. The surface plasmon resonance analysis showed that F2-g3p strongly bound CD80. F2-g3p inhibited the binding of CTLA4 to CD80 but not to CD86. In contrast, F2-g3p weakly inhibited the binding of CD28 with CD80. When hen egg lysozyme (HEL)-primed lymph node cells were stimulated with HEL in the presence of F2-g3p in vitro, cell proliferation was highly potentiated. In the absence of antigenic stimulation, F2-g3p induced no T cell proliferation, indicating the costimulatory nature of F2-g3p. The T cell-augmenting activity of the F2 clone was eliminated when the F2 clone was preincubated with CD80-Ig before the addition to the cultures, indicating the involvement of CD80-binding in the F2-g3p-mediated immunopotentiation. Thus, the F2 motif conferred CD80-binding activity and an immunoregulatory function to the g3p.

Appropriate expression of filamentous phage f1 DNA replication genes II and X requires RNase E-dependent processing and separate mRNAs.

The products of in-frame overlapping genes II and X carried by the filamentous phage f1 genome are proteins with required but opposing functions in phage DNA replication. Their normal relative levels are important for continuous production of phage DNA without killing infected Escherichia coli hosts. Here we identify several factors responsible for determining the relative levels of pII and pX and that, if perturbed, alter the normal distribution of the phage DNA species in infected hosts. Translation of the two proteins is essentially relegated to separate mRNAs. The mRNAs encoding genes II and X are also differentially sensitive to cleavage dependent on rne, the gene encoding the only E. coli endo-RNase known to have a global role in mRNA stability. Whereas pII levels are limited at the level of mRNA stability, normal pX levels require transcription in sufficient amounts from the promoter for the smaller mRNA encoding only pX.

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 TolQRA proteins are required for membrane insertion of the major capsid protein of the filamentous phage f1 during infection.

Infection of Escherichia coli by the filamentous bacteriophage f1 is initiated by interaction of the end of the phage particle containing the gene III protein with the tip of the F conjugative pilus. This is followed by the translocation of the phage DNA into the cytoplasm and the insertion of the major phage capsid protein, pVIII, into the cytoplasmic membrane. DNA transfer requires the chromosomally encoded TolA, TolQ, and TolR cytoplasmic membrane proteins. By using radiolabeled phages, it can be shown that no pVIII is inserted into the cytoplasmic membrane when the bacteria contain null mutations in tolQ, -R and -A. The rate of infection can be varied by using bacteria expressing various mutant TolA proteins. Analysis of the infection process in these strains demonstrates a direct correlation between the rate of infection and the incorporation of infecting bacteriophage pVIII into the cytoplasmic membrane.

Characterization of the Small Subunit of the Terminase Enzyme of theBacillus subtilisBacteriophage SPP1

The small subunit of bacteriophages SPP1 and SF6 terminase, G1P, share 71% identity clustered in three conserved segments (I, II, and III). Within segment I the helix–turn–helix DNA-binding domain was mapped, whereas segment III was found to be nonessential. For terminase activity, chimeric G1Ps, obtained by domain swapping between gene1of SPP1 and the SF6 origin (Chi1 to Chi4), were purified. The chimeric proteins behave in all respects similarly to the G1P of SPP1 or SF6. The major determinant for G1P:G1P interactions was found to lie within segment II. We showed that a G1P derivative (G1P*) lacking the 62 N-terminal residues (segment I), and Chi1 lacking the 45 C-terminal residues (segment III) interact with G1P. The N-terminal domain of G1P is necessary for terminase subunit assembly, because the large subunit of the terminase (G2P) interacts only with G1P and Chi1, but fails to do so with G1P*. These results suggest that segment III and the extended C-terminal part of SPP1 G1P do not play a major role in DNA recognition and that G1P recognizes an extended nucleotide sequence and DNA structure.

Translation limits synthesis of an assembly-initiating coat protein of filamentous phage IKe.

Translation is shown to be downregulated sharply between genes V and VII of IKe, a filamentous bacteriophage classed with the Ff group (phages f1, M13, and fd) but having only 55% DNA sequence identity to it. Genes V and VII encode the following proteins which are used in very different amounts: pV, used to coat the large number of viral DNA molecules prior to assembly, and pVII, used to serve as a cap with pIX in 3 to 5 copies on the end of the phage particle that emerges first from Escherichia coli. The genes are immediately adjacent to each other and are represented in the same amounts on the Ff and IKe mRNAs. Ff gene VII has an initiation site that lacks detectable intrinsic activity yet through coupling is translated at a level 10-fold lower than that of upstream gene V. The experiments reported reveal that by contrast, the IKe gene VII initiation site had detectable activity but was coupled only marginally to upstream translation. The IKe gene V and VII initiation sites both showed higher activities than the Ff sites, but the drop in translation at the IKe V-VII junction was unexpectedly severe, approximately 75-fold. As a result, gene VII is translated at similarly low levels in IKe- and Ff-infected hosts, suggesting that selection to limit its expression has occurred.

Versatile Action of Escherichia coli ClpXP as Protease or Molecular Chaperone for Bacteriophage Mu Transposition

The molecular chaperone ClpX of Escherichia coli plays two distinct functions for bacteriophage Mu DNA replication by transposition. As specificity component of a chaperone-linked protease, it recognizes the Mu immunity repressor for degradation by the peptidase component ClpP, thus derepressing Mu transposition functions. After strand exchange has been promoted by MuA transposase, ClpX alone can alter the conformation of the transpososome (the complex of MuA with Mu ends), and the remodeled MuA promotes transition to replisome assembly. Although ClpXP can degrade MuA, the presence of both ClpP and ClpX in the reconstituted transposition system did not destroy MuA essential for initiation of DNA replication by specific host replication enzymes. Levels of ClpXP needed to overcome inhibition by the repressor did not prevent MuA from promoting strand transfer, and ClpP stimulated alteration of the transpososome by ClpX. Apparently intact MuA was still present in the resulting transpososome, promoting initiation of Mu DNA replication by specific replication enzymes. The results indicate that ClpXP can discriminate repressor and MuA in the transpososome as substrates of the protease or the molecular chaperone alone, degrading repressor while remodeling MuA for its next critical function.

Molecular analysis of a filamentous phage (fsl) of Vibrio cholerae O139

A filamentous bacteriophage from Vibrio cholerae O139 strain Al-4450 was isolated (fsl). The phage fsl had a ssDNA genome and dsDNA as a replicative form (RF) in lysogenic host cell. The DNA sequence of fsl RF was determined. It consisted of 6340 bp and had a G+C content of 43.5%. Fifteen possible ORFs were found in fsl. One of them, ORF384, was estimated to encode 384 amino acid residues (44.6 kDa) and had homologous regions with the zot gene of V. cholerae and gene I of the coliphage group. ORF104, located upstream of ORF384, was homologous to gene 93 protein of Pf3 (filamentous phage of Pseudomonas sp.) corresponding to gene VI of coliphage. Other than ORF384 and ORF104, the ORF81, ORF44, ORF29, and ORF193 were speculated to correspond to gene V, gene VII, gene IX, and gene III, respectively, in the order as reported on f1 phage.

The filamentous phage pIV multimer visualized by scanning transmission electron microscopy.

A family of homomultimeric outer-membrane proteins termed secretins mediates the secretion of large macromolecules such as enzymes and filamentous bacteriophages across bacterial outer membranes to the extracellular milieu. The secretin encoded by filamentous phage f1 was purified. Mass determination of individual molecules by scanning transmission electron microscopy revealed two forms, a unit multimer composed of about 14 subunits and a multimer dimer. The secretin is roughly cylindrical and has an internal diameter of about 80 angstroms, which is large enough to accommodate filamentous phage (diameter of 65 angstroms).

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.

Filamentous phage infection-mediated gene expression: construction and propagation of the gIII deletion mutant helper phage R408d3

We describe the use of transcriptional fusions to the phage shock protein ( psp) promoter. These fusions are expressed only when cells are infected by filamentous phage. In an application, the psp promoter was fused to the protein coding part of filamentous phage gene I I I ( gIII). Protein III (pIII) is needed to complement mutant f1 phage containing a deletion of gIII, but its synthesis also renders cells resistant to infection. By inducing pIII production from psp– gIII only in the cells that are already infected with phage, it was possible to obtain plaques from phage in which gIII had been completely deleted. gIII was deleted from two helper phages: R408 and VCSM13, which were then propagated on cells containing the psp– gIII fusion. These two phages were tested for use in a phage display method that requires generation of noninfectious, phagemid-containing virion-like particles. Both helpers worked, but R408d3 was superior to VCSM13d3, because it generated about 1800-times fewer background infectious particles.