Morphology of Pasteurella multocida bacteriophages

Twenty-one tailed phages with icosahedral heads belong to the Myoviridae, Siphoviridae, and Podoviridae families and to four morphological types. Type AU, with 10 phages, has a contractile tail and is morphologically identical with coliphage P2. Lysates contain contracted tail sheaths assembled end-to-end and abnormal structures with long tails and multiple tail sheaths. Types C-2 and 32, with one and three phages, respectively, have long, noncontractile tails. Type 22 includes seven phages, has a short tail, and resembles coliphage T7. Our results agree with previous biological data and suggest that types AU, C-2, 32, and 22 correspond to four different phage species.     

Bacteriophages of Clostridium saccharoperbutylacetonicum

The morphological properties of the twelve previously described HM-phages were examined by electron microscopy. Specimens were prepared by air-drying and shadow-casting method using purified phage suspensions. As a result, the HM-phages were classified into three morphologically distinct groups, 1, 11 and 111. Group 1 phages were HM 1, HM 2, HM 8, HM 9, HM 10, HM 11 and HM 12. These phages had a spherical head about 100 mμ in diameter and a rudimentary tail. Group 11 phages were HM 3, HM 4, HM 5 and HM 6. These phages had a spherical head about 100 mμ in diameter and a tail with contractile sheath, and the normal tail of these phages was about 100 mμ in length, and the contracted sheath was about 50 mμ in length, Group 111 phage was HM 7 alone. This phage had a spherical head about 120 mμ in diameter and a relatively long tail about 350 mμ in length.     

Morphology of Bacteriophages of Lactobacillus bulgaricus, L. lactis and L. helveticus

Eleven virulent phages isolated from cheese or yoghurt factories and active on thermophilic lactobacilli used as starters were examined by electron microscopy. Five phages active on Lactobacillus bulgaricus belonged to Bradley's group B and can be divided into two groups with different host specificity. The three phages of the first group (two isolated in France, one in the USA) differ in size; the heads are either icosahedrons or octahedrons and the tails end in short-pronged base plates. The two phages of the second group, isolated in the USA. appear very similar. These are similar in length, have collars and octahedral heads. The non-contractile tails end in clusters of short fibres. An L. lactis phage, isolated in Finland, belongs to the same morphological group. It is similar in overall appearance to the two latter phages of the second group of L. bulgaricus , and there were numerous ghosts with polytails. Five phages. active on L. helveticus belong to Bradley's group A and may be divided into two groups with different host specificity. The first group contains a phage isolated in Finland. The second group is composed of four similar phages isolated in France. The Finnish phage is the largest, but the five phages show similar morphology. They have octahedral heads, firmly attached to the tails by connector devices, and they possess necks. The contractile sheaths have a helicoidal arrangement of hollow tubular subunits. They appear contracted either in a distal or a cervical position, revealing axial cores. Short tail fibres are probably present at the tail tip.     

Phylogeny of the major head and tail genes of the wide-ranging T4-type bacteriophages

We examined a number of bacteriophages with T4-type morphology that propagate in different genera of enterobacteria, Aeromonas, Burkholderia, and Vibrio. Most of these phages had a prolate icosahedral head, a contractile tail, and a genome size that was similar to that of T4. A few of them had more elongated heads and larger genomes. All these phages are phylogenetically related, since they each had sequences homologous to the capsid gene (gene 23), tail sheath gene (gene 18), and tail tube gene (gene 19) of T4. On the basis of the sequence comparison of their virion genes, the T4-type phages can be classified into three subgroups with increasing divergence from T4: the T-evens, pseudoT-evens, and schizoT-evens. In general, the phages that infect closely related host species have virion genes that are phylogenetically closer to each other than those of phages that infect distantly related hosts. However, some of the phages appear to be chimeras, indicating that, at least occasionally, some genetic shuffling has occurred between the different T4-type subgroups. The compilation of a number of gene 23 sequences reveals a pattern of conserved motifs separated by sequences that differ in the T4-type subgroups. Such variable patches in the gene 23 sequences may determine the size of the virion head and consequently the viral genome length. This sequence analysis provides molecular evidence that phages related to T4 are widespread in the biosphere and diverged from a common ancestor in acquiring the ability to infect different host bacteria and to occupy new ecological niches.     

Some Bacteriophages Active Against Rhizobium trifolii Strain W19

Fourteen soil bacteriophages active against Rhizobium trifolii W19 have been studied which fall into four structural groups. Group 1 phages have contractile tails. Some particles show double base plates to which at least three spikes are attached, and fibers are attached to the base plates. Group 2 phages also have contractile tails. At least five spikes are attached to the base plate, and there are spherical bodies adjacent to the tail, at the ends of fibers attached to the tail base. Group 3 phages have contractile tails, but are larger than phages of groups 1 and 2. The end of the tail has a complex structure. Group 4 phages have long, noncontractile tails.     

Degrees of relatedness of T-even type E. coli phages using different or the same receptors and topology of serologically cross-reacting sites

The relatedness of a series of T-even like phages which use the Escherichia coli outer membrane protein OmpA as a receptor, and the classical phages T2, T4 and T6 has been investigated. Immunoelectron microscopy and the pattern of phage resistance in bacterial mutants revealed that: (i) phages of this morphology do not necessarily cross-react serologically; (ii) phages using different receptors may bind heterologous IgG everywhere except to the tip (comprising approximately 10% of one fiber polypeptide) of the long tail fibers; (iii) cross-reacting OmpA-specific phages may bind heterologous IgG only to the tip of these fibers: (iv) OmpA-specific phages not cross-reacting at the tip of the tail fibers use different receptor sites on the protein. Absence of cross-reactivity appears to reflect high degrees of dissimilarity. A DNA probe consisting of genes encoding the two most distal tail fiber proteins of T4 detected homologies only in DNA from phages serologically cross-reacting at this fiber. Even under conditions of low stringency, allowing the formation of stable hybrids with almost 30% base mismatch, no such homologies could be found in serologically unrelated phages. Thus, in the collection of phages examined, there are sets of very similar and very dissimilar tail fiber genes and even of such gene segments.     

Some Properties of Five New Salmonella Bacteriophages

Five bacteriophages were isolated from lysogenic strains of Salmonella potdam. On the basis of plaque morphology, thermostability, serology, host range, one-step growth parameters, and phage morphology, they were divided into three groups: group A, phages P4 and P9c; group B, phages P3 and P9a; and group C, phage P10. Group A phages had a hexagonal head 55 nm in diameter with a short tail 15 nm long. These phages were particularly characterized by high thermostability, lack of serological relationship with any of the other phages, and restriction of lysis to other Salmonella strains of Kauffmann-White group C(1). Group B phages had a head identical in size and shape to that of the A phages, but they possessed a tail 118 nm long with a contractile sheath. A unique feature was the occurrence of tail fibers at the end of the core rather than at the base of the sheath. These phages were considerably less thermostable, had extended host ranges, and were serologically distinct from each other but unrelated to the A phages. The group C phage, P10, had a head identical to that of the A and B phages. It had a tail 95 nm in length, with tail fibers attached to a base plate at the end of a contractile sheath. P10 was highly sensitive to heat, lysed only smooth strains of Salmonella, and showed a degree of serological relationship to both B phages. The relationship of these phage groups to previous Salmonella phage grouping schemes is discussed.     

The occurrence and taxonomic value of PBS X-like defective phages in the genus Bacillus

72 strains of 24 Bacillus species were induced with mitomycin C. The lysates were examined for the presence of defective phages resembling PBS X in morphology. All strains tested of B. amyloliquefaciens. B, licheniformis, B. pumilus and B. subtilis contained such phages. Five morphological types of defective, PBS X-like phage could be distinguished, differing in their tail lengths and in the number of cross-striations on the tail. The quaternary structure of the tail, the molecular weight of the main tail protein and the antigenic properties of the phages were identical. The killing ranges of the defective phages have been determined and their possible use in taxonomy discussed.     

Comparative Genomics of Streptococcus thermophilus Phage Species Supports a Modular Evolution Theory

The comparative analysis of five completely sequenced Streptococcus thermophilus bacteriophage genomes demonstrated that their diversification was achieved by a combination of DNA recombination events and an accumulation of point mutations. The five phages included lytic and temperate phages, both pac site and cos site, from three distinct geographical areas. The units of genetic exchange were either large, comprising the entire morphogenesis gene cluster, excluding the putative tail fiber genes, or small, consisting of one or maximally two genes or even segments of a gene. Many indels were flanked by DNA repeats. Differences in a single putative tail fiber gene correlated with the host ranges of the phages. The predicted tail fiber protein consisted of highly conserved domains containing conspicuous glycine repeats interspersed with highly variable domains. As in the T-even coliphage adhesins, the glycine-containing domains were recombinational hot spots. Downstream of a highly conserved DNA replication region, all lytic phages showed a short duplication; in three isolates the origin of replication was repeated. The lytic phages could conceivably be derived from the temperate phages by deletion and multiple rearrangement events in the lysogeny module, giving rise to occasional selfish phages that defy the superinfection control systems of the corresponding temperate phages.     

Morphology of the Bacteriophages of Lactic Streptococci

Electron microscope studies have been made of a number of phages of lactic streptococci, seven of which were phages of Streptococcus lactis C10. Two of the phages are thought to be identical; five have been classified by the method of Tikhonenko as belonging to group IV (phages with noncontractile tails) with type III tail plates; one belongs to group V (phages with tails possessing a contractile sheath). Both prolate polyhedral heads and isometric polyhedral heads are represented among the group IV phages. The phage drc3 of S. diacetilactis DRC3 has been shown to have similar structure to the group IV phages of S. lactis C10 with prolate polyhedral heads. The phages ml1, hp, c11, and z8 of the S. cremoris strains ML1, HP, C11, and Z8, respectively, were shown to belong to the group IV phages with type III tail plates by the method of Tikhonenko. All had octahedral heads and tended to be larger than most of the other phages studied.     

两株枯草芽孢杆菌的噬菌体

从三门峡酶制剂厂分离到与过去形态不同的两种噬菌体BS3l和BS32。BS31有收缩尾鞘,头部为六边形;BS32有复杂的短尾,形态与φ29相似,寄主范围窄且有差异,用限制酶分析,噬菌体DNA的分子量分别为62kb和17kb。根据解链温度计算噬菌体DNA的G十c含量分别为45．7mol％和40．7mol％。两株噬菌体的结构蛋白经SDS聚丙烯酰胺凝胶电沫测定,BS3l有2条主带,10条次带;BS32有3条主带和6条次带。     

DNA sequences of the tail fiber genes of bacteriophage P2: evidence for horizontal transfer of tail fiber genes among unrelated bacteriophages.

We have determined the DNA sequence of the bacteriophage P2 tail genes G and H, which code for polypeptides of 175 and 669 residues, respectively. Gene H probably codes for the distal part of the P2 tail fiber, since the deduced sequence of its product contains regions similar to tail fiber proteins from phages Mu, P1, lambda, K3, and T2. The similarities of the carboxy-terminal portions of the P2, Mu, ann P1 tail fiber proteins may explain the observation that these phages in general have the same host range. The P2 H gene product is similar to the products of both lambda open reading frame (ORF) 401 (stf, side tail fiber) and its downstream ORF, ORF 314. If 1 bp is inserted near the end of ORF 401, this reading frame becomes fused with ORF 314, creating an ORF that may represent the complete stf gene that encodes a 774-amino-acid-long side tail fiber protein. Thus, a frameshift mutation seems to be present in the common laboratory strain of lambda. Gene G of P2 probably codes for a protein required for assembly of the tail fibers of the virion. The entire G gene product is very similar to the products of genes U and U' of phage Mu; a region of these proteins is also found in the tail fiber assembly proteins of phages TuIa, TuIb, T4, and lambda. The similarities in the tail fiber genes of phages of different families provide evidence that illegitimate recombination occurs at previously unappreciated levels and that phages are taking advantage of the gene pool available to them to alter their host ranges under selective pressures.     

Escherichia coli Capsule Bacteriophages II. Morphology

The Escherichia coli capsule bacteriophages (K phages) described herein are specific for certain capsular strains of E. coli, all of them test strains for different E. coli K antigens. The phages are not adsorbed to the acapsular mutants of their host organisms nor to similar strains with serologically and chemically different capsular polysaccharides. Thirteen E. coli (and one Klebsiella) K phages were visualized in the electron microscope. Most viruses are similar to P22 and thus belong to Bradley group C; however, one each of group A (long, contractile tail) and group B (long, noncontractile tail) was also found. All K phages were seen to carry spikes but no tail fibers were detected. These results suggest that the structures responsible for the recognition of the thick (about 400 nm or more) capsular polysaccharide gels are located in these spikes.     

Divergence and mosaicism among virulent soil phages of the Burkholderia cepacia complex

We have determined the genomic sequences of four virulent myophages, Bcep1, Bcep43, BcepB1A, and Bcep781, whose hosts are soil isolates of the Burkholderia cepacia complex. Despite temporal and spatial separations between initial isolations, three of the phages (Bcep1, Bcep43, and Bcep781, designated the Bcep781 group) exhibit 87% to 99% sequence identity to one another and most coding region differences are due to synonymous nucleotide substitutions, a hallmark of neutral genetic drift. Phage BcepB1A has a very different genome organization but is clearly a mosaic with respect to many of the genes of the Bcep781 group, as is a defective prophage element in Photorhabdus luminescens. Functions were assigned to 27 out of 71 predicted genes of Bcep1 despite extreme sequence divergence. Using a lambda repressor fusion technique, 10 Bcep781-encoded proteins were identified for their ability to support homotypic interactions. While head and tail morphogenesis genes have retained canonical gene order despite extreme sequence divergence, genes involved in DNA metabolism and host lysis are not organized as in other phages. This unusual genome arrangement may contribute to the ability of the Bcep781-like phages to maintain a unified genomic type. However, the Bcep781 group phages can also engage in lateral gene transfer events with otherwise unrelated phages, a process that contributes to the broader-scale genomic mosaicism prevalent among the tailed phages.     

Electron microscopy of virulent phages for Streptococcus lactis.

Electron microscopic studies were made on eight virulent Streptococcus lactis bacteriophages. These phages were taken as representative of eight host range groups established in a study of 75 phage isolates and 253 hosts (213 S. lactis, 22 S. cremoris, 18 S. diacetilactis). The phages studied were shown to have an isometric hexagonal head and noncontractile tails, usually several times longer than the head diameter. The virus heads were octahedral. The phages investigated represented three morphological types on the basis of head diameter , tail thickness, and tail length. These dimensions were approximately: for type I phages, 63, 172, and 11 nm, respectively; type II, 73, 200, and 20 nm, respectively; and type III, represented here by a single phage, 98, 551, and 12 nm, respectively. The tail surface revealed a different arrangment of the structural subunits which lent a helical appearance to the tails of type I and II phages and a guaffered tube appearance to the tail of type III phage. The number of turns along the tail axis, turn length, axial pitch, and helix angle were: type I, 32, 12 to 13 nm, 7.14 nm, and 11 degrees 43', respectively; type II, 24, 24, to 28 nm, 40.00 nm, and 32 degrees 30', respectively; and type III, 120, 12 nm, and no visible slope towards the axis. The morphology types showed complete correlation with serological groups, but not with groups based on host range pattern.     

Conserved translational frameshift in dsDNA bacteriophage tail assembly genes

A programmed translational frameshift similar to frameshifts in retroviral gag-pol genes and bacterial insertion elements was found to be strongly conserved in tail assembly genes of dsDNA phages and to be independent of sequence similarities. In bacteriophage lambda, this frameshift controls production of two proteins with overlapping sequences, gpG and gpGT, that are required for tail assembly. We developed bioinformatic approaches to identify analogous -1 frameshifting sites and experimentally confirmed our predictions for five additional phages. Clear evidence was also found for an unusual but analogous -2 frameshift in phage Mu. Frameshifting sites could be identified for most phages with contractile or noncontractile tails whose length is controlled by a tape measure protein. Phages from a broad spectrum of hosts spanning Eubacteria and Archaea appear to conserve this frameshift as a fundamental component of their tail assembly mechanisms, supporting the idea that their tail genes share a common, distant ancestry.     

Multilocus Characterization Scheme for Shiga Toxin-Encoding Bacteriophages

Shiga toxin-producing Escherichia coli (STEC) strains are food-borne pathogens whose ability to produce Shiga toxin (Stx) is due to integration of Stx-encoding lambdoid bacteriophages. These Stx phages are both genetically and morphologically heterogeneous, and here we report the design and validation of a PCR-based multilocus typing scheme. PCR primer sets were designed for database variants of a range of key lambdoid bacteriophage genes and applied to control phages and 70 stx⁺ phage preparations induced from a collection of STEC isolates. The genetic diversity residing within these populations could be described, and observations were made on the heterogeneity of individual gene targets, including the unexpected predominance of short-tailed phages with a highly conserved tail spike protein gene. Purified Stx phages can be profiled using this scheme, and the lambdoid phage-borne genes in induced STEC preparations can be identified as well as those residing in the noninducible prophage complement. The ultimate goal is to enable robust and realistically applicable epidemiological studies of Stx phages and their traits. The impact of Stx phage on STEC epidemiology is currently unknown.     

Mapping the Tail Fiber as the Receptor Binding Protein Responsible for Differential Host Specificity of Pseudomonas aeruginosa Bacteriophages PaP1 and JG004

The first step in bacteriophage infection is recognition and binding to the host receptor, which is mediated by the phage receptor binding protein (RBP). Different RBPs can lead to differential host specificity. In many bacteriophages, such as Escherichia coli and Lactococcal phages, RBPs have been identified as the tail fiber or protruding baseplate proteins. However, the tail fiber-dependent host specificity in Pseudomonas aeruginosa phages has not been well studied. This study aimed to identify and investigate the binding specificity of the RBP of P. aeruginosa phages PaP1 and JG004. These two phages share high DNA sequence homology but exhibit different host specificities. A spontaneous mutant phage was isolated and exhibited broader host range compared with the parental phage JG004. Sequencing of its putative tail fiber and baseplate region indicated a single point mutation in ORF84 (a putative tail fiber gene), which resulted in the replacement of a positively charged lysine (K) by an uncharged asparagine (N). We further demonstrated that the replacement of the tail fiber gene (ORF69) of PaP1 with the corresponding gene from phage JG004 resulted in a recombinant phage that displayed altered host specificity. Our study revealed the tail fiber-dependent host specificity in P. aeruginosa phages and provided an effective tool for its alteration. These contributions may have potential value in phage therapy.     

Ultrastructure and Host Specificity of Bacteriophages of Streptococcus cremoris, Streptococcus lactis subsp. diacetylactis, and Leuconostoc cremoris from Finnish Fermented Milk "Viili"

"Viili," a fermented milk product, has a firm but viscous consistency. It is produced with traditional mesophilic mixed-strain starters, which have various stabilities in dairy practice. Thirteen morphologically different types of phages were found in 90 viili samples studied by electron microscopy. Ten of the phage types had isometric heads with long, noncontractile tails, two had elongated heads with long, noncontractile tails, and one had a unique, very long elongated head with a short tail. Further morphological differences were found in the tail size and in the presence or absence of a collar, a baseplate, and a tail fiber. To find hosts for the industrially significant phages, we examined the sensitivities of 500 bacterial isolates from starters of the viili. Seven of the phages attacked Streptococcus cremoris strains, three attacked S. lactis subsp. diacetylactis strains, and four attacked Leuconostoc cremoris strains. Some phages differed only in their host specificity. Hosts were not found for 4 of the 13 morphological types of phages.