Isolation and chemcial properties of A-protein from filamentous phage Fd.

A-Protein was isolated from a purified male-specific filamentous phage fd particle. A-Protein has a molecular weight of approximately 60,000 daltons, as estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The amino-terminal residue was glycine as determined by the dansylation technique. Amino acid analysis showed that histidine, arginine, and cysteine, which are not contained in B-protein, are present in A-protein.     

Isolation and characterization of pigment mutants from a filamentous cyanobacterium

Five strains of a pigment mutant were isolated following UV irradiation and N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) mutagenesis from a non-nitrogen fixing mutant of the cyanobacteriumGloeotrichia ghosei. Two of them (B-1 and V-1) were isolated by UV mutagenesis and other three (B-3, B-7 and Br-6) by MNNG mutagenesis. Among the five strains cultures of three strains (B-1, B-3 and B-7) were typically blue-green in colour. Culture of strain V-1 was found to be violet-pink and of Br-6 was brownish in colour. The parent strain of these mutants was dark-blue in colour. Blue-green mutants showed the predominance of phycocyanin (610 nm) whereas violet-pink and brown strains showed the predominance of phycoerythrin (550 nm) in the absorption spectra of water-soluble pigments. In contrast to these strains their parent strain showed both the absorption peaks (at 550 and 610 nm). Occurrence of stable pigment mutants of a filamentous cyanobacterium indicates that the synthesis of water-soluble pigments is genetically controlled in these mutant strains.     

The fascinating biology behind phage display: filamentous phage assembly

With the recently awarded Nobel Prize to the inventor of Phage Display, George Smith, the technique has once more gained attention. However, one should not forget about the biology behind the method. Almost always ignored is how the structure of this bacterial virus is assembled. In contrast to lytic phages, filamentous phages are constantly being extruded through the bacterial membranes without lysis. Such filamentous phages are found in all aquatic environments, such as rivers and lakes, in the deep sea, in arctic ice, in hot springs and, associated with their hosts, in plants and animals including humans. While most filamentous phages infect Gram‐negative hosts, inoviruses of Gram‐positive hosts have also been described. Despite being among the minority within the phage family with an estimate of less than 5%, filamentous phages are real parasites as they exist at the expense of the host, but do not kill it. In contrast to lytic bacteriophages, filamentous phages are assembled in the host’s membrane and extruded across the cellular envelope while the bacterium continues to grow. In this review, we focus on this complex and yet poorly understood process of assembly and secretion of filamentous phages.     

Isolation and properties of recombinant DNA from a plasmid and filamentous phage

In the course of studying extrachromosomal DNA with composite replicons, a hybrid has been constructed by the in vitro recombination of the filamentous phage M13mp2 DNA (RF) and plasmid pUR222 (ApR). Both parental DNAs contain a fragment of lac-operon (ca. 800 bp), which includes the distal end of lacI gene, lacPO segments, and the lacZ gene proximal region coding for 145 N-terminal amino acid residues of beta-galactosidase and thus providing for alpha-complementation, the effect being cancelled with a polynucleotide insertion at the unique EcoRI site in the lacZ gene segment. E. coli BMH71-18 cells were transformed with the ligated mixture of EcoRI restricts of both DNAs. A phage-like nucleoprotein was isolated from colourless plaques (on the Xgal- and IPTG-supplemented medium); its deproteinization yielded a DNA which contains the ApR-determinant and, according to PAGE, structurally specific staining, restriction analysis, sequencing by the Sanger procedure, and electron microscopy data, is a linear double-stranded molecule comprising the phage and plasmid genomes in an equimolar ratio. Since the hybrid DNA does not display the alpha-complementation effect, both bacterial inserts are in the opposite orientation. Transformation of both phage (F+) and plasmid (F-) hosts with the hybrid DNA led to cultures which, after precipitation of the nucleoprotein from the extracellular medium and deproteinization, afforded the same composite DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetics of filamentous phage assembly

Filamentous phages release their progeny particles by a secretory process without lysing the bacterial cell. By this process about 6 viral particles per min are secreted from each cell. We show here that when the major coat protein (gp8) is provided from a plasmid we observe a phage progeny production rate depending on the induction of gp8 by IPTG. We also show that a transfection of Escherichia coli lacking F-pili is observed using a mutant of M13 that carries an ampicillin resistance gene, and phage particles are secreted in the absence of an F-plasmid. Extruding phage was visualized by atomic force microscopy (AFM) and by transmission electron microscopy (TEM) using gold-labeled antibodies to the major coat protein.     

Direct selection of EGF mutants displayed on filamentous phage using cells overexpressing EGF receptor.

Understanding receptor-ligand interactions, and the signal transduction pathways they activate, is of great interest for the discovery of novel antagonists and agonists. In this report we describe a rapid and efficient procedure to evaluate the importance of several different epidermal growth factor (EGF) residues for the binding and activation of its receptor (EGFR). We constructed an EGF mutant library randomized at positions 13, 15 and 16 and expressed them on filamentous phages. Phage display is a powerful system, allowing rapid isolation of binding mutants. Since many of the most pharmacologically interesting receptors cannot be produced in a soluble form, we developed a technique to rapidly select receptor-binding molecules directly on cells. A luciferase assay, simple to perform, was then used to test their biological transduction activity and to rapidly detect mutants of interest. Analysis of the resulting sequences revealed that the wild-type amino acids at positions 13, 15 and 16 are optimized for binding and activity. EGF mutants with agonist properties were also isolated and tolerated substitutions were identified.     

Analysis of the structure and subcellular location of filamentous phage pIV.

The gene IV protein of filamentous bacteriophages is an integral membrane protein required for phage assembly and export. A series of gene IV::phoA fusion, gene IV deletion, and gene IV missense mutations have been isolated and characterized. The alkaline phosphatase activity of the fusion proteins suggests that pIV lacks a cytoplasmic domain. Cell fractionation studies indicate that the carboxy-terminal half of pIV mediates its assembly into the membrane, although there is no single, discrete membrane localization domain. The properties of gene IV missense and deletion mutants, combined with an analysis of the similarities between pIVs from various filamentous phage and related bacterial export-mediating proteins, suggest that the amino-terminal half of pIV consists of a periplasmic substrate-binding domain that confers specificity to the assembly-export system.     

Isolation and structure of phage lambda head-mutant DNA

High molecular weight DNA accumulates in bacteria in which λ is multiplying but cannot complete the formation of new phage particles due to a defect in head assembly. Accumulated λ DNA has been isolated from induced mitomycin C-treated lysogens by means of a shift in buoyant density labels from heavy to light and fractionation by density-gradient sedimentation for completely light DNA. Head formation was blocked in these lysogens by amber mutations in genes D or E, which specify the two major head proteins. The purified DNA is at least 80% λ by DNA-DNA hybridization and some preparations are close to 100% λ by this test.     

Isolation of pigmentation mutants of the green filamentous photosynthetic bacterium Chloroflexus aurantiacus.

Mutants deficient in the production of bacteriochlorophyll c (Bchl c) and one mutant lacking colored carotenoids were isolated from the filamentous gliding bacterium Chloroflexus aurantiacus. Mutagenesis was achieved by using UV radiation or N-methyl-N'-nitro-N-nitrosoguanidine. Several clones were isolated that were deficient in Bchl c synthesis. All reverted. One double mutant deficient both in Bchl c synthesis and in the synthesis of colored carotenoids under anaerobic conditions was isolated. Isolation of a revertant in Bchl c synthesis from this double mutant produced a mutant strain of Chloroflexus that grew photosynthetically under anaerobic conditions and lacked colored carotenoids. Analysis of pigment contents and growth rates of the mutants revealed a positive association between growth rate and content of Bchl c under light-limiting conditions.     

A new filamentous phage cloning vector: fd-tet

We have constructed a hybrid chromosome composed of the genome of wild-type fd (a filamentous, male-specific bacteriophage) and a segment of transposon Tn10 coding for tetracycline resistance but not including the Tn10 insertion sequences. The hybrid phage infects male E. coli, thereby transducing the infected cells to tetracycline resistance. The phage DNA can also be propagated in F- cells after transfection. This new phage, fd-tet, may be used as a cloning vector to produce large quantities of cloned DNA in single-stranded form. Its usefulness has been demonstrated by cloning of a fragment from bacteriophage lambda. Some unexpected sequence alterations have been identified in lambda cloning experiments.     

The symmetries of filamentous phage particles

The helical symmetries of two classes of filamentous bacteriophage particles are distinctly different. The symmetry of the class I particles is²C₅S_~2.0 (a 5-fold rotation axis combined with an approximately 2-fold screw axis). The symmetry of the class II particles is C₁S_5.4 (a one-start helix with 27 subunits equally spaced along five turns). The same basic α-helical interlocking arrangement of the largely α-helical coat protein subunits can be accommodated by the symmetry of the two classes of phage particles. The conservation of this structural pattern reflects intrinsic packing properties of α-helices. The difference between the symmetries of the class I and class II particles suggests that different assembly processes may have evolved to form these structures with very similar protein packing architectures.     

Biodistribution of filamentous phage peptide libraries in mice

In vivo phage display is a new approach to acquire peptide molecules that bind stably to a given target. Phage peptide display libraries have been selected in mice and humans and numerous vasculature-targeting peptides have been reported. However, in vivo phage display has not typically produced molecules that extravasate to target specific organ or tumor antigens. Phage selections in animals have been performed for very short times without optimization for biodistribution or clearance rates to a particular organ. It is hypothesized that peptides that home to a desired antigen/organ can be obtained from in vivo phage experiments by optimization of incubation times, phage extraction and propagation procedures. To accomplish this goal, one must first gain a better understanding of the in vivo biodistribution and rate of clearance of engineered phage peptide display libraries. While the fate of wild type phage in rodents has been reported, the in vivo biodistribution of the commonly used engineered fd-tet M13 phage peptide display libraries (such as in the fUSE5 vector system) have not been well established. Here we report the biodistribution and clearance properties of fd-tet fifteen amino acid random peptide display libraries in fUSE5 phage in three common mouse models employed for drug discovery - CF-1, nude, and SCID mice.     

Isolation of Salmonella typhimurium mutants affecting the plaque morphology of phage P22

Summary Salmonella typhimurium mutants affecting the plaque morphology of P22 and other phages have been isolated. Using one such bacterial mutant phage mutants making turbid plaques have been isolated.     

Isolation of phage P2-186 intervarietal hybrids and 186 insertion mutants

Summary Intervarietal hybrids formed between coliphages P2 and 186 have been isolated and their preliminary genetic characterization described. Three insertion mutants of 186 have also been isolated.     

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 compability 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.     

Antibody-selectable filamentous fd phage vectors: affinity purification of target genes

Foreign DNA fragments can be inserted into a minor coat protein gene of filamentous phage, creating a fusion protein that is incorporated into the virion; we call these particles "fusion phage". The foreign amino acids are displayed on the surface, allowing fusion phage bearing antigenic determinants from a target gene to be purified in infectious form by affinity to antibody directed against the gene product. Here we introduce fusion-phage vectors that accept foreign DNA inserts with little effect on phage function; and describe affinity purification of virions bearing a target determinant from a 10(8)-fold excess of phage not bearing the determinant, using minute amounts of antibody. These "antibody-selectable" vectors are a promising alternative to conventional expression systems for using antibodies to clone genes, though the ability to isolate rare clones from actual libraries remains to be demonstrated.     

Reprogramming the infection mechanism of a filamentous phage

When they infect Escherichia coli cells, the filamentous phages IF1 and fd first interact with a pilus and then target TolA as their common receptor. They use the domains N2 and N1 of their gene-3-proteins (G3P) for these interactions but differ in the mechanism of infection. In G3P of phage IF1, N1 and N2 are independent modules that are permanently binding-active. G3P of phage fd is usually in a closed state in which N1 and N2 are tightly associated. The TolA binding site is thus inaccessible and the phage incompetent for infection. Partial unfolding and prolyl isomerization must occur to abolish the domain interactions and expose the TolA binding site. This complex mechanism of phage fd could be changed to the simple infection mechanism of phage IF1 by reprogramming its G3P following physicochemical rules of protein stability. The redesigned phage fd was robust and as infectious as wild-type phage fd.     

Nonsense mutants of Serratia phage Kappa

Summary Auxotrophs of Serr. marcescens HY, which behaved like nonsense mutants when tested according to Whitfield et al. (1966), were induced to revert to anauxotrophy. Some of the revertants (called su ⁺), together with the parental auxotrophs (called su ^-), allowed to isolate conditional-lethal (sus) mutants of phage Kappa, which produce infectious progeny only in su ⁺ bacteria. All su ⁺ mutants of Serr. marcescens HY were identified as nonsense suppressors using su ⁺ _amber, su ⁺ _ochre, and su ^- strains of Salm. typhimurium as references and the flagella-specific phage Chi as the main tool to connect the Salmonella system with that of Serratia.After treatment of Kappa with three different mutagens 128 sus mutants were isolated which comprise at least 19 complementation groups. 18 sus mutants, representing different cistrons, and the unselective markers c1, c2, and c49 were mapped mainly by two-factor crosses. Reciprocal three-factor crosses of the general type a x bz and az x b (i.e. with outside markers) revealed a circular linkage map of an estimated maximum length of 90 RU (recombination units). Joined rescue of outside markers, e.g. sus ⁺ A94 and e49, from UV-irradiated phage supported the assumption of circular gene linkage. Some data indicate that certain regions of the phage genome might have a higher chance to recombine than others.Abbreviations moi multiplicity of infection - eop efficiency of plating - RU recombination units - MR marker rescue