ORF334 in Vibrio phage KVP40 plays the role of gp27 in T4 phage to form a heterohexameric complex

KVP40 is a T4-related phage, composed of 386 open reading frames (ORFs), that has a broad host range. Here, we overexpressed, purified, and biophysically characterized two of the proteins encoded in the KVP40 genome, namely, gp5 and ORF334. Homology-based comparison between KVP40 and its better-characterized sister phage, T4, was used to estimate the two KVP40 proteins' functions. KVP40 gp5 shared significant homology with T4 gp5 in the N- and C-terminal domains. Unlike T4 gp5, KVP40 gp5 lacked the internal lysozyme domain. Like T4 gp5, KVP40 gp5 was found to form a homotrimer in solution. In stark contrast, KVP40 ORF334 shared no significant homology with any known proteins from T4-related phages. KVP40 ORF334 was found to form a heterohexamer with KVP40 gp5 in solution in a fashion nearly identical to the interaction between the T4 gp5 and gp27 proteins. Electron microscope image analysis of the KVP40 gp5-ORF334 complex indicated that it had dimensions very similar to those of the T4 gp5-gp27 structure. On the basis of our biophysical characterization, along with positional genome information, we propose that ORF334 is the ortholog of T4 gp27 and that it plays the role of a linker between gp5 and the phage baseplate.     

Identification of the lower baseplate protein as the antireceptor of the temperate lactococcal bacteriophages TP901-1 and Tuc2009

The first step in the infection process of tailed phages is recognition and binding to the host receptor. This interaction is mediated by the phage antireceptor located in the distal tail structure. The temperate Lactococcus lactis phage TP901-1 belongs to the P335 species of the Siphoviridae family, which also includes the related phage Tuc2009. The distal tail structure of TP901-1 is well characterized and contains a double-disk baseplate and a central tail fiber. The structural tail proteins of TP901-1 and Tuc2009 are highly similar, but the phages have different host ranges and must therefore encode different antireceptors. In order to identify the antireceptors of TP901-1 and Tuc2009, a chimeric phage was generated in which the gene encoding the TP901-1 lower baseplate protein (bppL(TP901-1)) was exchanged with the analogous gene (orf53(2009)) of phage Tuc2009. The chimeric phage (TP901-1C) infected the Tuc2009 host strain efficiently and thus displayed an altered host range compared to TP901-1. Genomic analysis and sequencing verified that TP901-1C is a TP901-1 derivative containing the orf53(2009) gene in exchange for bppL(TP901-1); however, a new sequence in the late promoter region was also discovered. Protein analysis confirmed that TP901-1C contains ORF53(2009) and not the lower baseplate protein BppL(TP901-1), and it was concluded that BppL(TP901-1) and ORF53(2009) constitute antireceptor proteins of TP901-1 and Tuc2009, respectively. Electron micrographs revealed altered baseplate morphology of TP901-1C compared to that of the parental phage.     

Structural and Functional Studies of gpX of Escherichia coli Phage P2 Reveal a Widespread Role for LysM Domains in the Baseplates of Contractile-Tailed Phages

A variety of bacterial pathogenicity determinants, including the type VI secretion system and the virulence cassettes from Photorhabdus and Serratia, share an evolutionary origin with contractile-tailed myophages. The well-characterized Escherichia coli phage P2 provides an excellent system for studies related to these systems, as its protein composition appears to represent the “minimal” myophage tail. In this study, we used nuclear magnetic resonance (NMR) spectroscopy to determine the solution structure of gpX, a 68-residue tail baseplate protein. Although the sequence and structure of gpX are similar to those of LysM domains, which are a large family associated with peptidoglycan binding, we did not detect a peptidoglycan-binding activity for gpX. However, bioinformatic analysis revealed that half of all myophages, including all that possess phage T4-like baseplates, encode a tail protein with a LysM-like domain, emphasizing a widespread role for this domain in baseplate function. While phage P2 gpX comprises only a single LysM domain, many myophages display LysM domain fusions with other tail proteins, such as the DNA circulation protein found in Mu-like phages and gp53 of T4-like phages. Electron microscopy of P2 phage particles with an incorporated gpX-maltose binding protein fusion revealed that gpX is located at the top of the baseplate, near the junction of the baseplate and tail tube. gpW, the orthologue of phage T4 gp25, was also found to localize to this region. A general colocalization of LysM-like domains and gpW homologues in diverse phages is supported by our bioinformatic analysis.     

Structure of the central hub of bacteriophage Mu baseplate determined by X-ray crystallography of gp44

Bacteriophage Mu is a double-stranded DNA phage that consists of an icosahedral head, a contractile tail with baseplate and six tail fibers, similar to the well-studied T-even phages. The baseplate of bacteriophage Mu, which recognizes and attaches to a host cell during infection, consists of at least eight different proteins. The baseplate protein, gp44, is essential for bacteriophage Mu assembly and the generation of viable phages. To investigate the role of gp44 in baseplate assembly and infection, the crystal structure of gp44 was determined at 2.1A resolution by the multiple isomorphous replacement method. The overall structure of the gp44 trimer is similar to that of the T4 phage gp27 trimer, which forms the central hub of the T4 baseplate, although these proteins share very little primary sequence homology. Based on these data, we confirm that gp44 exists as a trimer exhibiting a hub-like structure with an inner diameter of 25A through which DNA can presumably pass during infection. The molecular surface of the gp44 trimer that abuts the host cell membrane is positively charged, and it is likely that Mu phage interacts with the membrane through electrostatic interactions mediated by gp44.     

Endolysin of bacteriophage BFK20: evidence of a catalytic and a cell wall binding domain

A gene product of ORF24' was identified on the genome of corynephage BFK20 as a putative phage endolysin. The protein of endolysin BFK20 (gp24') has a modular structure consisting of an N-terminal amidase_2 domain (gp24CD) and a C-terminal cell wall binding domain (gp24BD). The C-terminal domain is unrelated to any of the known cell wall binding domains of phage endolysins. The whole endolysin gene and the sequences of its N-terminal and C-terminal domains were cloned; proteins were expressed in Escherichia coli and purified to homogeneity. The lytic activities of endolysin and its catalytic domain were demonstrated on corynebacteria and bacillus substrates. The binding activity of cell wall binding domain alone and in fusion with green fluorescent protein (gp24BD-GFP) were shown by specific binding assays to the cell surface of BFK20 host Brevibacterium flavum CCM 251 as well as those of other corynebacteria.     

Structural protein analysis of the polyvalent staphylococcal bacteriophage 812

Phage 812 is a polyvalent phage with a very broad host range in the genus Staphylococcus, which makes it a suitable candidate for phage therapy of staphylococcal infections. This proteomic study, combining the results of both 1-DE and 2-DE followed by PMF, led to the identification of 24 virion proteins. Twenty new proteins, not yet identified by proteome analysis of closely related staphylococcal phages K and G1 were identified using this approach. Fifteen proteins were assigned unambiguously to the head-tail genome module; the remaining nine proteins are encoded by genes of the left or right arms of the phage genome. As expected, the most abundant proteins in the electrophoretic patterns are the major capsid protein, the major tail sheath protein and proteins identical to ORF 50 and ORF 95 of phage K, although their function is only putative. Identification of these 20 new proteins contributes substantially to a detailed characterization of phage virions, knowledge of which is necessary for rational phage therapy.     

The receptor specificity of bacteriophages can be determined by a tail fiber modifying protein.

T-Even type bacteriophages recognize their cellular receptors with the distal ends of their long tail fibers. The distal part of these fibers consists of a dimer of gene product (gp) 37. The assembly of this gp to a functional dimer requires the action of two other proteins, gp57 and gp38. Genes (g) 38 have been cloned from five T-even type phages which use the Escherichia coli outer membrane protein OmpA as a receptor. The phages used differ in their ability to infect a series of ompA mutants producing altered OmpA proteins, i.e., each phage has a specific host range for these mutants. The cloned genes 38 complemented g38 amber mutants of phage T2, which uses the outer membrane protein OmpF as a receptor. The complemented phages had become phenotypically OmpA-dependent and, with one exception, OmpF-independent, but regained the host range of T2 upon growth in a host lacking the cloned g38. The host range of the complemented phages, as determined on the ompA mutants, was identical to, similar to, or different from that of the phage, from which the cloned g38 originated. The results presented show that gp38 from one phage can phenotypically 'imprint', in a finely-tuned manner, a host range onto gp37 of another phage with a different host specificity. In view of the extreme diversity of host ranges observed, it is suggested that gp38 of T2 and of the OmpA-specific phages may remain attached to gp37 in the phage particle and in cooperation with gp37 determine the host range.     

Characterization and Genome Sequencing of Phage Abp1, a New phiKMV-Like Virus Infecting Multidrug-Resistant Acinetobacter baumannii

While screening for alternative antibiotics against multidrug-resistant Acinetobacter baumannii, we isolated a virulent A. baumannii bacteriophage Abp1. Transmission electron microscopy revealed that the phage had an icosahedral head with a short tail and should be classified as a member of the Podoviridae family. SDS-PAGE showed that Abp1 contained at least one major and nine minor proteins. In a single-step growth test, we demonstrated that Abp1 had a latent period of 10 min and a burst size of 350. Abp1 also had a relatively narrow host range. The entire genome was sequenced, and the final assembly yielded a 42,185 bp, linear, double-stranded DNA molecule with a G+C content of 39.15 % and containing 54 putative genes. Among these genes, 26 were functionally known, leaving 28 unknown putative genes. Abp1 is a new member of the phiKMV-like virus subgroup of the T7 group; its genome sequence is very similar to that of the A. baumannii phage phiAB1.     

The Bacteriophage HK97 gp15 Moron Element Encodes a Novel Superinfection Exclusion Protein

A phage moron is a DNA element inserted between a pair of genes in one phage genome that are adjacent in other related phage genomes. Phage morons are commonly found within phage genomes, and in a number of cases, they have been shown to mediate phenotypic changes in the bacterial host. The temperate phage HK97 encodes a moron element, gp15, within its tail morphogenesis region that is absent in most closely related phages. We show that gp15 is actively expressed from the HK97 prophage and is responsible for providing the host cell with resistance to infection by phages HK97 and HK75, independent of repressor immunity. To identify the target(s) of this gp15-mediated resistance, we created a hybrid of HK97 and the related phage HK022. This hybrid phage revealed that the tail tube or tape measure proteins likely mediate the susceptibility of HK97 to inhibition by gp15. The N terminus of gp15 is predicted with high probability to contain a single membrane-spanning helix by several transmembrane prediction programs. Consistent with this putative membrane localization, gp15 acts to prevent the entry of phage DNA into the cytoplasm, acting in a manner reminiscent of those of several previously characterized superinfection exclusion proteins. The N terminus of gp15 and its phage homologues bear sequence similarity to YebO proteins, a family of proteins of unknown function found ubiquitously in enterobacteria. The divergence of their C termini suggests that phages have co-opted this bacterial protein and subverted its activity to their advantage.     

Tail-associated structural protein gp61 of Staphylococcus aureus phage phi MR11 has bifunctional lytic activity.

A tailed bacteriophage, phi MR11 (siphovirus), was selected as a candidate therapeutic phage against Staphylococcus aureus infections. Gene 61, one of the 67 ORFs identified, is located in the morphogenic module. The gene product (gp61) has lytic domains homologous to CHAP (corresponding to an amidase function) at its N-terminus and lysozyme subfamily 2 (LYZ2) at its C-terminus. Each domain of gp61 was purified as a recombinant protein. Both the amidase [amino acids (aa) 1-150] and the lysozyme (aa 401-624) domains but not the linker domain (aa 151-400) caused efficient lysis of S. aureus. Immunoelectron microscopy localized gp61 to the tail tip of the phi MR11 phage. These data strongly suggest that gp61 is a tail-associated lytic factor involved in local cell-wall degradation, allowing the subsequent injection of phi MR11 DNA into the host cytoplasm. Staphylococcus aureus lysogenized with phi MR11 was also lysed by both proteins. Staphylococcus aureus strains on which phi MR11 phage can only produce spots but not plaques were also lysed by each protein, indicating that gp61 may be involved in 'lysis from without'. This is the first report of the presence of a tail-associated virion protein that acts as a lysin, in an S. aureus phage.     

The opening of the SPP1 bacteriophage tail, a prevalent mechanism in Gram-positive-infecting siphophages

The SPP1 siphophage uses its long non-contractile tail and tail tip to recognize and infect the Gram-positive bacterium Bacillus subtilis. The tail-end cap and its attached tip are the critical components for host recognition and opening of the tail tube for genome exit. In the present work, we determined the cryo-electron microscopic (cryo-EM) structure of a complex formed by the cap protein gp19.1 (Dit) and the N terminus of the downstream protein of gp19.1 in the SPP1 genome, gp21(1-552) (Tal). This complex assembles two back-to-back stacked gp19.1 ring hexamers, interacting loosely, and two gp21(1-552) trimers interacting with gp19.1 at both ends of the stack. Remarkably, one gp21(1-552) trimer displays a "closed" conformation, whereas the second is "open" delineating a central channel. The two conformational states dock nicely into the EM map of the SPP1 cap domain, respectively, before and after DNA release. Moreover, the open/closed conformations of gp19.1-gp21(1-552) are consistent with the structures of the corresponding proteins in the siphophage p2 baseplate, where the Tal protein (ORF16) attached to the ring of Dit (ORF15) was also found to adopt these two conformations. Therefore, the present contribution allowed us to revisit the SPP1 tail distal-end architectural organization. Considering the sequence conservation among Dit and the N-terminal region of Tal-like proteins in Gram-positive-infecting Siphoviridae, it also reveals the Tal opening mechanism as a hallmark of siphophages probably involved in the generation of the firing signal initiating the cascade of events that lead to phage DNA release in vivo.     

Bacteriophage P22 tail accessory factor GP26 is a long triple-stranded coiled-coil

P22 is a well characterized tailed bacteriophage that infects Salmonella enterica serovar Typhimurium. It is characterized by a "short" tail, which is formed by five proteins: the dodecameric portal protein (gp1), three tail accessory factors (gp4, gp10, gp26), and six trimeric copies of the tail-spike protein (gp9). We have isolated the gene encoding tail accessory factor gp26, which is responsible for stabilization of viral DNA within the mature phage, and using a variety of biochemical and biophysical techniques we show that gp26 is very likely a triple stranded coiled-coil protein. Electron microscopic examination of purified gp26 indicates that the protein adopts a rod-like structure approximately 210 angstroms in length. This trimeric rod displays an exceedingly high intrinsic thermostability (T(m) approximately 85 degrees C), which suggests a potentially important structural role within the phage tail apparatus. We propose that gp26 forms the thin needle-like fiber emanating from the base of the P22 neck that has been observed by electron microscopy of negatively stained P22 virions. By analogy with viral trimeric coiled-coil class I membrane fusion proteins, gp26 may represent the membrane-penetrating device used by the phage to pierce the host outer membrane.     

Domain organization and polarity of tail needle GP26 in the portal vertex structure of bacteriophage P22

The attachment of tailed bacteriophages to the host cell wall as well as the penetration and injection of the viral genome into the host is mediated by the virion tail complex. In phage P22, a member of the Podoviridae family that infects Salmonella enterica, the tail contains an approximately 220 A elongated protein needle, previously identified as tail accessory factor gp26. Together with tail factors gp4 and gp10, gp26 is critical to close the portal protein channel and retain the viral DNA inside the capsid. By virtue of its topology and position in the virion, the tail needle gp26 is thought to function as a penetrating device to perforate the Salmonella cell wall. Here, we define the domain organization of gp26, characterize the structural determinants for its stability, and define the polarity of the gp26 assembly into the phage portal vertex structure. We have found that the N-terminal 27 residues of gp26 form a functional domain that, although not required for gp26 trimerization and overall stability, is essential for the correct attachment to gp10, which is thought to plug the portal vertex structure. The region downstream of domain I, domain II, folds into helical core, which exhibits four trimerization octad repeats with consensus Ile-xx-Leu-xxx-Val/Tyr. We demonstrate that in vitro, domain II represents the main self-assembling, highly stable trimerization core of gp26, which retains a folded conformation both in an anhydrous environment and in the presence of 10% SDS. The C terminus of gp26, immediately downstream of domain II, contains a beta-sheet-rich region, domain III, and a short coiled coil, domain IV, which, although not required for gp26 trimerization, enhance its thermodynamic stability. We propose that domains III and IV of the tail needle form the tip utilized by the phage to penetrate the host cell wall.     

Tail-associated structural protein gp61 of Staphylococcus aureus phage φMR11 has bifunctional lytic activity

A tailed bacteriophage, φMR11 (siphovirus), was selected as a candidate therapeutic phage against Staphylococcus aureus infections. Gene 61, one of the 67 ORFs identified, is located in the morphogenic module. The gene product (gp61) has lytic domains homologous to CHAP (corresponding to an amidase function) at its N-terminus and lysozyme subfamily 2 (LYZ2) at its C-terminus. Each domain of gp61 was purified as a recombinant protein. Both the amidase [amino acids (aa) 1–150] and the lysozyme (aa 401–624) domains but not the linker domain (aa 151–400) caused efficient lysis of S . aureus . Immunoelectron microscopy localized gp61 to the tail tip of the φMR11 phage. These data strongly suggest that gp61 is a tail-associated lytic factor involved in local cell-wall degradation, allowing the subsequent injection of φMR11 DNA into the host cytoplasm. Staphylococcus aureus lysogenized with φMR11 was also lysed by both proteins. Staphylococcus aureus strains on which φMR11 phage can only produce spots but not plaques were also lysed by each protein, indicating that gp61 may be involved in 'lysis from without'. This is the first report of the presence of a tail-associated virion protein that acts as a lysin, in an S. aureus phage.     

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.     

Bioinformatic analysis of the Acinetobacter baumannii phage AB1 genome

As one of the pathogens of hospital-acquired infections, Acinetobacter baumannii poses great challenges to the public health. A. baumannii phage could be an effective way to fight multi-resistant A. baumannii. Here, we completed the whole genome sequencing of the complete genome of A. baumannii phage AB1, which consists of 45,159bp and is a double-stranded DNA molecule with an average GC content of 37.7%. The genome encodes one tRNA gene and 85 open reading frames (ORFs) and the average size of the ORF is 531bp in length. Among 85 ORFs, only 14 have been identified to share significant sequence similarities to the genes with known functions, while 28 are similar in sequence to the genes with function-unknown genes in the database and 43 ORFs are uniquely present in the phage AB1 genome. Fourteen function-assigned genes with putative functions include five phage structure proteins, an RNA polymerase, a big sub-unit and a small sub-unit of a terminase, a methylase and a recombinase and the proteins involved in DNA replication and so on. Multiple sequence alignment was conducted among those homologous proteins and the phylogenetic trees were reconstructed to analyze the evolutionary courses of these essential genes. From comparative genomics analysis, it turned out clearly that the frame of the phage genome mainly consisted of genes from Xanthomonas phages, Burkholderia ambifaria phages and Enterobacteria phages and while it comprises genes of its host A. baumannii only sporadically. The mosaic feature of the phage genome suggested that the horizontal gene transfer occurred among the phage genomes and between the phages and the host bacterium genomes. Analyzing the genome sequences of the phages should lay sound foundation to investigate how phages adapt to the environment and infect their hosts, and even help to facilitate the development of biological agents to deal with pathogenic bacteria.     

Structure of a Bacterial Virus DNA-Injection Protein Complex Reveals a Decameric Assembly with a Constricted Molecular Channel

The multi-layered cell envelope structure of Gram-negative bacteria represents significant physical and chemical barriers for short-tailed phages to inject phage DNA into the host cytoplasm. Here we show that a DNA-injection protein of bacteriophage Sf6, gp12, forms a 465-kDa, decameric assembly in vitro. The electron microscopic structure of the gp12 assembly shows a ~150-Å, mushroom-like architecture consisting of a crown domain and a tube-like domain, which embraces a 25-Å-wide channel that could precisely accommodate dsDNA. The constricted channel suggests that gp12 mediates rapid, uni-directional injection of phage DNA into host cells by providing a molecular conduit for DNA translocation. The assembly exhibits a 10-fold symmetry, which may be a common feature among DNA-injection proteins of P22-like phages and may suggest a symmetry mismatch with respect to the 6-fold symmetric phage tail. The gp12 monomer is highly flexible in solution, supporting a mechanism for translocation of the protein through the conduit of the phage tail toward the host cell envelope, where it assembles into a DNA-injection device.     

Haloarchaeal myovirus φCh1 harbours a phase variation system for the production of protein variants with distinct cell surface adhesion specificities

The φCh1 myovirus, which infects the haloalkaliphilic archaeon Natrialba magadii, contains an invertible region that comprises the convergent open reading frames (ORFs) 34 and 36, which code for the putative tail fibre proteins gp34 and gp36 respectively. The inversion leads to an exchange of the C-termini of these proteins, thereby creating different types of tail fibres. Gene expression experiments revealed that only ORF34 is transcribed, indicating that φCh1 produces tail fibre proteins exclusively from this particular ORF. Only one of the two types of tail fibres encoded by ORF34 is able to bind to Nab. magadii in vitro. This is reflected by the observation that during the early phases of the infection cycle, the lysogenic strain L11 carries its invertible region exclusively in the orientation that produces that specific type of tail fibre. Obviously, Nab. magadii can only be infected by viruses carrying this particular type of tail fibre. By mutational analysis, the binding domain of gp34 was localized to the C-terminal part of the protein, particularly to a galactose-binding domain. The involvement of galactose residues in cell adhesion was supported by the observation that the addition of α-D-galactose to purified gp34 or whole virions prevented their attachment to Nab. magadii.     

Structure and location of gene product 8 in the bacteriophage T4 baseplate

Many bacteriophages, such as T4, T7, RB49, and phi29, have complex, sometimes multilayered, tails that facilitate an almost 100% success rate for the viral particles to infect host cells. In bacteriophage T4, there is a baseplate, which is a multiprotein assembly, at the distal end of the contractile tail. The baseplate communicates to the tail that the phage fibers have attached to the host cell, thereby initiating the infection process. Gene product 8 (gp8), whose amino acid sequence consists of 334 residues, is one of at least 16 different structural proteins that constitute the T4 baseplate and is the sixth baseplate protein whose structure has been determined. A 2.0A resolution X-ray structure of gp8 shows that the two-domain protein forms a dimer, in which each monomer consists of a three-layered beta-sandwich with two loops, each containing an alpha-helix at the opposite sides of the sandwich. The crystals of gp8 were produced in the presence of concentrated chloride and bromide ions, resulting in at least 11 halide-binding sites per monomer. Five halide sites, situated at the N termini of alpha-helices, have a protein environment observed in other halide-containing protein crystal structures. The computer programs EMfit and SITUS were used to determine the positions of six gp8 dimers within the 12A resolution cryo-electron microscopy image reconstruction of the baseplate-tail tube complex. The gp8 dimers were found to be located in the upper part of the baseplate outer rim. About 20% of the gp8 surface is involved in contacts with other baseplate proteins, presumed to be gp6, gp7, and gp10. With the structure determination of gp8, a total of 53% of the volume of the baseplate has now been interpreted in terms of its atomic structure.