Bacteriophage SPO1 structure and morphogenesis. I. Tail structure and length regulation

The Robust Self-Assembling Tubular Nanostructures Formed by gp053 from Phage vB_EcoM_FV3

The recombinant phage tail sheath protein, gp053, from Escherichia coli infecting myovirus vB_EcoM_FV3 (FV3) was able to self-assemble into long, ordered and extremely stable tubular structures (polysheaths) in the absence of other viral proteins. TEM observations revealed that those protein nanotubes varied in length (~10–1000 nm). Meanwhile, the width of the polysheaths (~28 nm) corresponded to the width of the contracted tail sheath of phage FV3. The formed protein nanotubes could withstand various extreme treatments including heating up to 100 °C and high concentrations of urea. To determine the shortest variant of gp053 capable of forming protein nanotubes, a set of N- or/and C-truncated as well as poly-His-tagged variants of gp053 were constructed. The TEM analysis of these mutants showed that up to 25 and 100 amino acid residues could be removed from the N and C termini, respectively, without disturbing the process of self-assembly. In addition, two to six copies of the gp053 encoding gene were fused into one open reading frame. All the constructed oligomers of gp053 self-assembled in vitro forming structures of different regularity. By using the modification of cysteines with biotin, the polysheaths were tested for exposed thiol groups. Polysheaths formed by the wild-type gp053 or its mutants possess physicochemical properties, which are very attractive for the construction of self-assembling nanostructures with potential applications in different fields of nanosciences.

The Bacteriophage Head-to-Tail Interface

Many icosahedral viruses use a specialized portal vertex for genome encapsidation in the viral capsid (or head). This structure then controls release of the viral genetic information to the host cell at the beginning of infection. In tailed bacteriophages, the portal system is connected to a tail device that delivers their genome to the bacterial cytoplasm. The head-to-tail interface is a multiprotein complex that locks the viral DNA inside the phage capsid correctly positioned for egress and that controls its ejection when the viral particle interacts with the host cell receptor. Here we review the molecular mechanisms how this interface is assembled and how it carries out those two critical steps in the life cycle of tailed phages.

Genomics of staphylococcal Twort-like phages--potential therapeutics of the post-antibiotic era

Polyvalent bacteriophages of the genus Twort-like that infect clinically relevant Staphylococcus strains may be among the most promising phages with potential therapeutic applications. They are obligatorily lytic, infect the majority of Staphylococcus strains in clinical strain collections, propagate efficiently and do not transfer foreign DNA by transduction. Comparative genomic analysis of 11 S. aureus/S. epidermidis Twort-like phages, as presented in this chapter, emphasizes their strikingly high similarity and clear divergence from phage Twort of the same genus, which might have evolved in hosts of a different species group. Genetically, these phages form a relatively isolated group, which minimizes the risk of acquiring potentially harmful genes. The order of genes in core parts of their 127 to 140-kb genomes is conserved and resembles that found in related representatives of the Spounavirinae subfamily of myoviruses. Functions of certain conserved genes can be predicted based on their homology to prototypical genes of model spounavirus SPO1. Deletions in the genomes of certain phages mark genes that are dispensable for phage development. Nearly half of the genes of these phages have no known homologues. Unique genes are mostly located near termini of the virion DNA molecule and are expressed early in phage development as implied by analysis of their potential transcriptional signals. Thus, many of them are likely to play a role in host takeover. Single genes encode homologues of bacterial virulence-associated proteins. They were apparently acquired by a common ancestor of these phages by horizontal gene transfer but presumably evolved towards gaining functions that increase phage infectivity for bacteria or facilitate mature phage release. Major differences between the genomes of S. aureus/S. epidermidis Twort-like phages consist of single nucleotide polymorphisms and insertions/deletions of short stretches of nucleotides, single genes, or introns of group I. Although the number and location of introns may vary between particular phages, intron shuffling is unlikely to be a major factor responsible for specificity differences.

Long noncontractile tail machines of bacteriophages

In this chapter, we describe the structure, assembly, function, and evolution of the long, noncontractile tail of the siphophages, which comprise ∼60% of the phages on earth. We place -particular emphasis on features that are conserved among all siphophages, and trace evolutionary connections between these phages and myophages, which possess long contractile tails. The large number of high-resolution structures of tail proteins solved recently coupled to studies of tail-related complexes by electron microscopy have provided many new insights in this area. In addition, the availability of thousands of phage and prophage genome sequences has allowed the delineation of several large families of tail proteins that were previously unrecognized. We also summarize current knowledge pertaining to the mechanisms by which siphophage tails recognize the bacterial cell surface and mediate DNA injection through the cell envelope. We show that phages infecting Gram-positive and Gram-negative bacteria possess distinct families of proteins at their tail tips that are involved in this process. Finally, we speculate on the evolutionary advantages provided by long phage tails.

Characterization of Bacillus phage-K2 isolated from chungkookjang, a fermented soybean foodstuff

An investigation of a virulent Bacillus phage-K2 (named Bp-K2) isolated from chungkookjang (a fermented soybean foodstuff) was made. Bp-K2 differed in infectivity against a number of Bacillus subtilis strains including starter strains of chungkookjang and natto, being more infectious to Bacillus strains isolated from the chungkookjang, but much less active against a natto strain. Bp-K2 is a small DNA phage whose genome size is about 21 kb. Bp-K2 is a tailed bacteriophage with an isometric icosahedral head (50 nm long on the lateral side, 80 nm wide), a long contractile sheath (85-90 nm × 28 nm), a thin tail fiber (80-85 nm long, 10 nm wide), and a basal plate (29 nm long, 47 nm wide) with a number of spikes, but no collar. The details of the structures of Bp-K2 differ from natto phage ϕBN100 as well as other known Bacillus phages such as SPO1-like or ϕ 29-like viruses. These data suggest that Bp-K2 would be a new member of the Myoviridae family of Bacillus bacteriophages.

Structural analysis of a Synechococcus myovirus S-CAM4 and infected cells by atomic force microscopy

A tailed cyanophage, S-CAM4 (family Myoviridae) from California coastal waters that infects Synechococcus, was characterized by atomic force microscopy. Capsomeric clusters of protein composing the 85 nm diameter icosahedral head were resolved and indicated a triangulation number of T=16. The 140 nm tail assembly, exhibiting a helical appearance with a 13 nm pitch, was seen in both extended and contracted states, the latter exposing the injection tube within. Attached below the base plate were six 50 nm long fibres, and six fibres 275-300 nm in length protruded from the periphery of the base plate. Protein-free DNA was abundant from ruptured heads. Virus attached en masse, in clusters and individually to cells, and cell fragments were recorded, as were perforated cells lysed by the phages. The capsid structure appears most closely related to that of the cyanophage Syn9 and the Bacillus subtilis phage SPO1, which may, in turn, be evolutionarily related to herpesvirus.

The SPO1-related bacteriophages

A large and diverse group of bacteriophages has been termed 'SPO1-like viruses'. To date, molecular data and genome sequences are available for Bacillus phage SPO1 and eight related phages infecting members of other bacterial genera. Many additional bacteriophages have been described as SPO1-related, but very few data are available for most of them. We present an overview of putative 'SPO1-like viruses' and shall discuss the available data in view of the recently proposed expansion of this group of bacteriophages to the tentative subfamily Spounavirinae. Characteristics of SPO1-related phages include (a) the host organisms are Firmicutes; (b) members are strictly virulent myoviruses; (c) all phages feature common morphological properties; (d) the phage genome consists of a terminally redundant, non-permuted dsDNA molecule of 127-157 kb in size; and (e) phages share considerable amino acid homology. The number of phages isolated consistent with these parameters is large, suggesting a ubiquitous nature of this group of viruses.

Classification of Myoviridae bacteriophages using protein sequence similarity

Background

We advocate unifying classical and genomic classification of bacteriophages by integration of proteomic data and physicochemical parameters. Our previous application of this approach to the entirely sequenced members of the Podoviridae fully supported the current phage classification of the International Committee on Taxonomy of Viruses (ICTV). It appears that horizontal gene transfer generally does not totally obliterate evolutionary relationships between phages.

Results

CoreGenes/CoreExtractor proteome comparison techniques applied to 102 Myoviridae suggest the establishment of three subfamilies (Peduovirinae, Teequatrovirinae, the Spounavirinae) and eight new independent genera (Bcep781, BcepMu, FelixO1, HAP1, Bzx1, PB1, phiCD119, and phiKZ-like viruses). The Peduovirinae subfamily, derived from the P2-related phages, is composed of two distinct genera: the "P2-like viruses", and the "HP1-like viruses". At present, the more complex Teequatrovirinae subfamily has two genera, the "T4-like" and "KVP40-like viruses". In the genus "T4-like viruses" proper, four groups sharing >70% proteins are distinguished: T4-type, 44RR-type, RB43-type, and RB49-type viruses. The Spounavirinae contain the "SPO1-"and "Twort-like viruses."

Conclusion

The hierarchical clustering of these groupings provide biologically significant subdivisions, which are consistent with our previous analysis of the Podoviridae.

The P22 tail machine at subnanometer resolution reveals the architecture of an infection conduit

The portal channel is a key component in the life cycle of bacteriophages and herpesviruses. The bacteriophage P22 portal is a 1 megadalton dodecameric oligomer of gp1 that plays key roles in capsid assembly, DNA packaging, assembly of the infection machinery, and DNA ejection. The portal is the nucleation site for the assembly of 39 additional subunits generated from multiple copies of four gene products (gp4, gp10, gp9, and gp26), which together form the multifunctional tail machine. These components are organized with a combination of 12-fold (gp1, gp4), 6-fold (gp10, trimers of gp9), and 3-fold (gp26, gp9) symmetry. Here we present the 3-dimensional structures of the P22 assembly-naive portal formed from expressed subunits (gp1) and the intact tail machine purified from infectious virions. The assembly-naive portal structure exhibits a striking structural similarity to the structures of the portal proteins of SPP1 and phi29 derived from X-ray crystallography.

The X-ray crystal structure of the phage lambda tail terminator protein reveals the biologically relevant hexameric ring structure and demonstrates a conserved mechanism of tail termination among diverse long-tailed phages

The tail terminator protein (TrP) plays an essential role in phage tail assembly by capping the rapidly polymerizing tail once it has reached its requisite length and serving as the interaction surface for phage heads. Here, we present the 2.7-A crystal structure of a hexameric ring of gpU, the TrP of phage lambda. Using sequence alignment analysis and site-directed mutagenesis, we have shown that this multimeric structure is biologically relevant and we have delineated its functional surfaces. Comparison of the hexameric crystal structure with the solution structure of gpU that we previously solved using NMR spectroscopy shows large structural changes occurring upon multimerization and suggests a mechanism that allows gpU to remain monomeric at high concentrations on its own, yet polymerize readily upon contact with an assembled tail tube. The gpU hexamer displays several flexible loops that play key roles in head and tail binding, implying a role for disorder-to-order transitions in controlling assembly as has been observed with other lambda morphogenetic proteins. Finally, we have found that the hexameric structure of gpU is very similar to the structure of a putative TrP from a contractile phage tail even though it displays no detectable sequence similarity. This finding coupled with further bioinformatic investigations has led us to conclude that the TrPs of non-contractile-tailed phages, such as lambda, are evolutionarily related to those of contractile-tailed phages, such as P2 and Mu, and that all long-tailed phages may utilize a conserved mechanism for tail termination.

The genome of Bacillus subtilis bacteriophage SPO1

We report the genome sequence of Bacillus subtilis phage SPO1. The unique genome sequence is 132,562 bp long, and DNA packaged in the virion (the chromosome) has a 13,185-bp terminal redundancy, giving a total of 145,747 bp. We predict 204 protein-coding genes and 5 tRNA genes, and we correlate these findings with the extensive body of investigations of SPO1, including studies of the functions of the 61 previously defined genes and studies of the virion structure. Sixty-nine percent of the encoded proteins show no similarity to any previously known protein. We identify 107 probable transcription promoters; most are members of the promoter classes identified in earlier studies, but we also see a new class that has the same sequence as the host sigma K promoters. We find three genes encoding potential new transcription factors, one of which is a distant homologue of the host sigma factor K. We also identify 75 probable transcription terminator structures. Promoters and terminators are generally located between genes and together with earlier data give what appears to be a rather complete picture of how phage transcription is regulated. There are complete genome sequences available for five additional phages of Gram-positive hosts that are similar to SPO1 in genome size and in composition and organization of genes. Comparative analysis of SPO1 in the context of these other phages yields insights about SPO1 and the other phages that would not be apparent from the analysis of any one phage alone. These include assigning identities as well as probable functions for several specific genes and inferring evolutionary events in the phages' histories. The comparative analysis also allows us to put SPO1 into a phylogenetic context. We see a pattern similar to what has been noted in phage T4 and its relatives, in which there is minimal successful horizontal exchange of genes among a "core" set of genes that includes most of the virion structural genes and some genes of DNA metabolism, but there is extensive horizontal transfer of genes over the remainder of the genome. There is a correlation between genes in rapid evolutionary flux through these genomes and genes that are small.

The tail sheath structure of bacteriophage T4: a molecular machine for infecting bacteria

The contractile tail of bacteriophage T4 is a molecular machine that facilitates very high viral infection efficiency. Its major component is a tail sheath, which contracts during infection to less than half of its initial length. The sheath consists of 138 copies of the tail sheath protein, gene product (gp) 18, which surrounds the central non-contractile tail tube. The contraction of the sheath drives the tail tube through the outer membrane, creating a channel for the viral genome delivery. A crystal structure of about three quarters of gp18 has been determined and was fitted into cryo-electron microscopy reconstructions of the tail sheath before and after contraction. It was shown that during contraction, gp18 subunits slide over each other with no apparent change in their structure.

Complete genomic sequence and mass spectrometric analysis of highly diverse, atypical Bacillus thuringiensis phage 0305phi8-36

To investigate the apparent genomic complexity of long-genome bacteriophages, we have sequenced the 218,948-bp genome (6479-bp terminal repeat), and identified the virion proteins (55), of Bacillus thuringiensis bacteriophage 0305phi8-36. Phage 0305phi8-36 is an atypical myovirus with three large curly tail fibers. An accurate mode of DNA pyrosequencing was used to sequence the genome and mass spectrometry was used to accomplish the comprehensive virion protein survey. Advanced informatic techniques were used to identify classical morphogenesis genes. The 0305phi8-36 genes were highly diverged; 19% of 247 closely spaced genes have similarity to proteins with known functions. Genes for virion-associated, apparently fibrous proteins in a new class were found, in addition to strong candidates for the curly fiber genes. Phage 0305phi8-36 has twice the virion protein coding sequence of T4. Based on its genomic isolation, 0305phi8-36 is a resource for future studies of vertical gene transmission.

Spontaneous tail length variation in a Salmonella myovirus

Salmonella phage SPT-1, a member of the Myoviridae family and a relative of phage O1, produces abnormally long tails with coordinate variations of sheath and core length. The length of abnormal tails varies between 140 and 445 nm.

Lactobacillus plantarum bacteriophage LP65: a new member of the SPO1-like genus of the family Myoviridae

The virulent Lactobacillus plantarum myophage LP65 was isolated from industrial meat fermentation. Tail contraction led to reorganization of the tail sheath and the baseplate; a tail tube was extruded. In ultrathin section the phage adsorbed via its baseplate to the exterior of the cell, while the tail tube tunneled through the thick bacterial cell wall. Convoluted membrane structures were induced in the infected cell. Progeny phage was detected 100 min postinfection, and lysis occurred after extensive digestion of the cell wall. Sequence analysis revealed a genome of 131,573 bp of nonredundant DNA. Four major genome regions and a large tRNA gene cluster were observed. One module corresponded to DNA replication genes. Helicase/primase and two replication/recombination enzymes represented the only links to T4-like Myoviridae from gram-negative bacteria. Another module corresponded to the structural genes. Sequence relatedness identified links with Listeria phage A511, Staphylococcus phage K, and Bacillus phage SPO1. LP65 structural proteins were identified by two-dimensional proteome analysis and mass spectrometry. The putative tail sheath protein showed a shear-induced change in electrophoretic migration behavior. The genome organization of the structural module in LP65 resembled that of Siphoviridae from the lambda supergroup.

Bacteriophage T4 self-assembly: localization of gp3 and its role in determining tail length

Gene 3 of bacteriophage T4 participates at a late stage in the T4 tail assembly pathway, but the hypothetical protein product, gp3, has never been identified in extracts of infected cells or in any tail assembly intermediate. In order to overcome this difficulty, we expressed gp3 in a high-efficiency plasmid expression vector and subsequently purified it for further analysis. The N-terminal sequence of the purified protein showed that the initial methionine had been removed. Variant C-terminal amino acid sequences were resolved by determining the cysteine content of the protein. The molecular mass of 20.6 kDa for the pure protein was confirmed by Western blotting, using a specific anti-gp3 serum for which the purified protein was the immunogen. We also demonstrated, for the first time, the physical presence of gp3 in the mature T4 phage particle and localized it to the tail tube. By finding a nonleaky, nonpermissive host for a gene 3 mutant, we could clearly demonstrate a new phenotype: the slow, aberrant elongation of the tail tube in the absence of gp3.

Tailed bacteriophages: the order caudovirales

Tailed bacteriophages have a common origin and constitute an order with three families, named Caudovirales. Their structured tail is unique. Tailed phages share a series of high-level taxonomic properties and show many facultative features that are unique or rare in viruses, for example, tail appendages and unusual bases. They share with other viruses, especially herpesviruses, elements of morphogenesis and life-style that are attributed to convergent evolution. Tailed phages present three types of lysogeny, exemplified by phages lambda, Mu, and P1. Lysogeny appears as a secondary property acquired by horizontal gene transfer. Amino acid sequence alignments (notably of DNA polymerases, integrases, and peptidoglycan hydrolases) indicate frequent events of horizontal gene transfer in tailed phages. Common capsid and tail proteins have not been detected. Tailed phages possibly evolved from small protein shells with a few genes sufficient for some basal level of productive infection. This early stage can no longer be traced. At one point, this precursor phage became perfected. Some of its features were perfect enough to be transmitted until today. It is tempting to list major present-day properties of tailed phages in the past tense to construct a tentative history of these viruses: 1. Tailed phages originated in the early Precambrian, long before eukaryotes and their viruses. 2. The ur-tailed phage, already a quite evolved virus, had an icosahedral head of about 60 nm in diameter and a long non-contractile tail with sixfold symmetry. The capsid contained a single molecule of dsDNA of about 50 kb, and the tail was probably provided with a fixation apparatus. Head and tail were held together by a connector. a. The particle contained no lipids, was heavier than most viruses to come, and had a high DNA content proportional to its capsid size (about 50%). b. Most of its DNA coded for structural proteins. Morphopoietic genes clustered at one end of the genome, with head genes preceding tail genes. Lytic enzymes were probably coded for. A part of the phage genome was nonessential and possibly bacterial. Were tailed phages general transductants since the beginning? 3. The virus infected its host from the outside, injecting its DNA. Replication involved transcription in several waves and formation of DNA concatemers. Novel phages were released by burst of the infected cell after lysis of host membranes by a peptidoglycan hydrolase (and a holin?). a. Capsids were assembled from a starting point, the connector, and around a scaffold. They underwent an elaborate maturation process involving protein cleavage and capsid expansion. Heads and tails were assembled separately and joined later. b. The DNA was cut to size and entered preformed capsids by a headful mechanism. 4. Subsequently, tailed phages diversified by: a. Evolving contractile or short tails and elongated heads. b. Exchanging genes or gene fragments with other phages. c. Becoming temperate by acquiring an integrase-excisionase complex, plasmid parts, or transposons. d. Acquiring DNA and RNA polymerases and other replication enzymes. e. Exchanging lysin genes with their hosts. f. Losing the ability to form concatemers as a consequence of acquiring transposons (Mu) or proteinprimed DNA polymerases (phi 29). Present-day tailed phages appear as chimeras, but their monophyletic origin is still inscribed in their morphology, genome structure, and replication strategy. It may also be evident in the three-dimensional structure of capsid and tail proteins. It is unlikely to be found in amino acid sequences because constitutive proteins must be so old that relationships were obliterated and most or all replication-, lysogeny-, and lysis-related proteins appear to have been borrowed. However, the sum of tailed phage properties and behavior is so characteristic that tailed phages cannot be confused with other viruses.

Electron microscopic studies on intracellular phage development--history and perspectives

This review is centered on the applications of thin sections to the study of intracellular precursors of bacteriophage heads. Results obtained with other preparation methods are included in so far as they are essential for the comprehension of the biological problems. This type of work was pioneered with phage T4, which contributed much to today's understanding of morphogenesis and form determination. The T4 story is rich in successes, but also in many fallacies. Due to its large size, T4 is obviously prone to preparation artefacts such as emptying, flattening and others. Many of these artefacts were first encountered in T4. Artefacts are mostly found in lysates, however, experience shows that they are not completely absent from thin sections. This can be explained by the fact that permeability changes induced by fixatives occur. The information gained from T4 was profitably used for the study of other phages. They are included in this review as far as electron microscopic studies played a major role in the elucidation of their morphogenetic pathways. Research on phage assembly pathways and form determination is a beautiful illustration for the power of the integrated approach which combines electron microscopy with biochemistry, genetics and biophysics. As a consequence, we did not restrict ourselves to the review of electron microscopic work but tried to integrate pertinent data which contribute to the understanding of the molecular mechanisms acting in determining the form of supramolecular structures.

Nucleotide sequence of the tail sheath gene of bacteriophage T4 and amino acid sequence of its product

The nucleotide sequence of gene 18 of bacteriophage T4 was determined by the Maxam-Gilbert method, partially aided by the dideoxy method. To confirm the deduced amino acid sequence of the tail sheath protein (gp18) that is encoded by gene 18, gp18 was extensively digested by trypsin or lysyl endopeptidase and subjected to reverse-phase high-performance liquid chromatography. Approximately 40 peptides, which cover 88% of the primary structure, were fractionated, the amino acid compositions were determined, and the corresponding sequences in DNA were identified. Furthermore, the amino acid sequences of 10 of the 40 peptides were determined by a gas phase protein sequencer, including N- and C-terminal sequences. Thus, the complete amino acid sequence of gp18, which consists of 658 amino acids with a molecular weight of 71,160, was determined.

Potential length determiner and DNA injection protein is extruded from bacteriophage T4 tail tubes in vitro

Bacteriophage T4 tails contain a set of extended protein molecules in the central channel of the tail tube through which the DNA must exit during infection. Treatment of tails with guanidine hydrochloride separates the baseplates, leaving the tail tube and several specific tube-associated proteins. Methods were developed to purify these structures. Using specific antisera, immunoblotting, and electrophoretic analysis, these structures were shown to contain proteins gp19, 29, and 48. Electron microscopy showed specifically defined stain penetration into the tail tube, a bulge at one end, and a short fiber extruded from the tube. These structures could be removed by proteases but the gp19 tube itself was resistant. Structural studies of tails and intact phage show that the bulge and fiber are at the end of the tube that interacts with the cell membrane during infection. Since the fiber did not protrude from baseplates or from incomplete (short) tube-baseplates, we propose that it is first assembled as a compact structure formed of six copies of a tube-associated protein, which elongates during tail tube formation to fill the central channel, span the length of the tube, and regulate its length. We suggest that the exit of this fiber during infection signals DNA ejection.

Bacteriophage SPO1 structure and morphogenesis. III. SPO1 proteins and synthesis

The virion proteins of SPO1 have been determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis methods on purified phage components and on phage lysates. The phage head contains 16 proteins, and the connector or neck structure has an additional 3 proteins not found in the head. The proximal part of the tail, composed of sheath, tube and connecting components, contains six proteins. The distal baseplate is the most complex structure, with 28 proteins identifiable on sodium dodecyl sulfate gels. The maximum number of proteins found in phage subassemblies is 53, which would account for nearly half the coding capacity of the SPO1 genome.

Bacteriophage SPO1 structure and morphogenesis. II. Head structure and DNA size

The capsid of bacteriophage SPO1 is icosahedral, and the subunit arrangement on the 87-nm-diameter head suggests the triangulation number T = 16. The major capsid protein (45,700 daltons) is cleaved from a 47,700-dalton precursor. Tubular heads (polyheads) are produced by mutations in genes 5 and 8 and contain cores as well as capped ends. The lattice constant of these structures is 13.4 nm; diameter is 109.5 nm. The size of the double-stranded SPO1 DNA (containing 5' hydroxymethyl uracil in place of thymine) was measured by sedimentation analysis and electron microscopy and has a molecular weight of 86 X 10(6) (about 140 kilobase pairs), which is smaller than several previously reported values.