Head morphogenesis of bacteriophage T4. II. The role of gene 40 in initiating prehead assembly

Isolation, characterization, and comparative genomic analysis of vB_PlaM_Pd22F, a new bacteriophage of the family Myoviridae

The use of phage and phage-based products for the prevention and treatment of bee disease is one of the promising natural alternatives to chemical or antibiotic treatments in beekeeping. A novel lysogenic bacteriophage, phage Pd22F (vB_PlaM_Pd22F), was isolated from Paenibacillus dendritiformis by the prophage induction method. This phage, which is capable of infecting Paenibacillus larvae and P. dendritiformis strains, was characterized by microbiological and comparative genomic analysis. Transmission electron microscopy images showed that phage Pd22F had the morphology of a myovirus. Whole-genome sequencing results showed that vB_Pla M_Pd22F has an 86,388-bp linear dsDNA genome with a GC content of 50.68%. This genome has 124 coding sequences (CDSs), 53% of which encode functionally unknown proteins and 57 of which encode proteins that show similarity to known proteins. In addition, one tRNA gene was found. The phage Pd22F genome does not contain any antimicrobial resistance genes. The similarity between the genome sequence of phage Pd22F and the whole genome sequences of other Paenibacillus phages available in the NCBI Virus Database was found to be below 50% (42%), indicating that phage Pd22F differs greatly from previously characterized phages at the DNA level. The results of comparative genomics and phylogenetic analysis revealed that Pd22F is a new phage belonging to the family Myoviridae, order Caudovirales. This is the first report of genomic and morphological characterization of a Paenibacillus dendritiformis prophage.

The Mottled Capsid of the Salmonella Giant Phage SPN3US, a Likely Maturation Intermediate with a Novel Internal Shell

“Giant” phages have genomes of >200 kbp, confined in correspondingly large capsids whose assembly and maturation are still poorly understood. Nevertheless, the first assembly product is likely to be, as in other tailed phages, a procapsid that subsequently matures and packages the DNA. The associated transformations include the cleavage of many proteins by the phage-encoded protease, as well as the thinning and angularization of the capsid. We exploited an amber mutation in the viral protease gene of the Salmonella giant phage SPN3US, which leads to the accumulation of a population of capsids with distinctive properties. Cryo-electron micrographs reveal patterns of internal density different from those of the DNA-filled heads of virions, leading us to call them “mottled capsids”. Reconstructions show an outer shell with T = 27 symmetry, an embellishment of the HK97 prototype composed of the major capsid protein, gp75, which is similar to some other giant viruses. The mottled capsid has a T = 1 inner icosahedral shell that is a complex network of loosely connected densities composed mainly of the ejection proteins gp53 and gp54. Segmentation of this inner shell indicated that a number of densities (~12 per asymmetric unit) adopt a “twisted hook” conformation. Large patches of a proteinaceous tetragonal lattice with a 67 Å repeat were also present in the cell lysate. The unexpected nature of these novel inner shell and lattice structures poses questions as to their functions in virion assembly.

Portal Protein: The Orchestrator of Capsid Assembly for the dsDNA Tailed Bacteriophages and Herpesviruses

Tailed, double-stranded DNA bacteriophages provide a well-characterized model system for the study of viral assembly, especially for herpesviruses and adenoviruses. A wealth of genetic, structural, and biochemical work has allowed for the development of assembly models and an understanding of the DNA packaging process. The portal complex is an essential player in all aspects of bacteriophage and herpesvirus assembly. Despite having low sequence similarity, portal structures across bacteriophages share the portal fold and maintain a conserved function. Due to their dynamic role, portal proteins are surprisingly plastic, and their conformations change for each stage of assembly. Because the maturation process is dependent on the portal protein, researchers have been working to validate this protein as a potential antiviral drug target. Here we review recent work on the role of portal complexes in capsid assembly, including DNA packaging, as well as portal ring assembly and incorporation and analysis of portal structures.

Ultrastructure and Viral Metagenome of Bacteriophages from an Anaerobic Methane Oxidizing Methylomirabilis Bioreactor Enrichment Culture

With its capacity for anaerobic methane oxidation and denitrification, the bacterium Methylomirabilis oxyfera plays an important role in natural ecosystems. Its unique physiology can be exploited for more sustainable wastewater treatment technologies. However, operational stability of full-scale bioreactors can experience setbacks due to, for example, bacteriophage blooms. By shaping microbial communities through mortality, horizontal gene transfer, and metabolic reprogramming, bacteriophages are important players in most ecosystems. Here, we analyzed an infected Methylomirabilis sp. bioreactor enrichment culture using (advanced) electron microscopy, viral metagenomics and bioinformatics. Electron micrographs revealed four different viral morphotypes, one of which was observed to infect Methylomirabilis cells. The infected cells contained densely packed ~55 nm icosahedral bacteriophage particles with a putative internal membrane. Various stages of virion assembly were observed. Moreover, during the bacteriophage replication, the host cytoplasmic membrane appeared extremely patchy, which suggests that the bacteriophages may use host bacterial lipids to build their own putative internal membrane. The viral metagenome contained 1.87 million base pairs of assembled viral sequences, from which five putative complete viral genomes were assembled and manually annotated. Using bioinformatics analyses, we could not identify which viral genome belonged to the Methylomirabilis- infecting bacteriophage, in part because the obtained viral genome sequences were novel and unique to this reactor system. Taken together these results show that new bacteriophages can be detected in anaerobic cultivation systems and that the effect of bacteriophages on the microbial community in these systems is a topic for further study.

Structure and function of bacteriophage T4

Bacteriophage T4 is the most well-studied member of Myoviridae, the most complex family of tailed phages. T4 assembly is divided into three independent pathways: the head, the tail and the long tail fibers. The prolate head encapsidates a 172 kbp concatemeric dsDNA genome. The 925 Å-long tail is surrounded by the contractile sheath and ends with a hexagonal baseplate. Six long tail fibers are attached to the baseplate's periphery and are the host cell's recognition sensors. The sheath and the baseplate undergo large conformational changes during infection. X-ray crystallography and cryo-electron microscopy have provided structural information on protein-protein and protein-nucleic acid interactions that regulate conformational changes during assembly and infection of Escherichia coli cells.

Structure-function analysis of the DNA translocating portal of the bacteriophage T4 packaging machine

Tailed bacteriophages and herpesviruses consist of a structurally well conserved dodecameric portal at a special 5-fold vertex of the capsid. The portal plays critical roles in head assembly, genome packaging, neck/tail attachment, and genome ejection. Although the structures of portals from phages φ29, SPP1, and P22 have been determined, their mechanistic roles have not been well understood. Structural analysis of phage T4 portal (gp20) has been hampered because of its unusual interaction with the Escherichia coli inner membrane. Here, we predict atomic models for the T4 portal monomer and dodecamer, and we fit the dodecamer into the cryo-electron microscopy density of the phage portal vertex. The core structure, like that from other phages, is cone shaped with the wider end containing the "wing" and "crown" domains inside the phage head. A long "stem" encloses a central channel, and a narrow "stalk" protrudes outside the capsid. A biochemical approach was developed to analyze portal function by incorporating plasmid-expressed portal protein into phage heads and determining the effect of mutations on head assembly, DNA translocation, and virion production. We found that the protruding loops of the stalk domain are involved in assembling the DNA packaging motor. A loop that connects the stalk to the channel might be required for communication between the motor and the portal. The "tunnel" loops that project into the channel are essential for sealing the packaged head. These studies established that the portal is required throughout the DNA packaging process, with different domains participating at different stages of genome packaging.

Genome annotation and intraviral interactome for the Streptococcus pneumoniae virulent phage Dp-1

Streptococcus pneumoniae causes several diseases, including pneumonia, septicemia, and meningitis. Phage Dp-1 is one of the very few isolated virulent S. pneumoniae bacteriophages, but only a partial characterization is currently available. Here, we confirmed that Dp-1 belongs to the family Siphoviridae. Then, we determined its complete genomic sequence of 56,506 bp. It encodes 72 open reading frames, of which 44 have been assigned a function. We have identified putative promoters, Rho-independent terminators, and several genomic clusters. We provide evidence that Dp-1 may be using a novel DNA replication system as well as redirecting host protein synthesis through queuosine-containing tRNAs. Liquid chromatography-mass spectrometry analysis of purified phage Dp-1 particles identified at least eight structural proteins. Finally, using comprehensive yeast two-hybrid screens, we identified 156 phage protein interactions, and this intraviral interactome was used to propose a structural model of Dp-1.

Portal control of viral prohead expansion and DNA packaging

Bacteriophage T4 terminase packages DNA in vitro into empty small or large proheads (esps or elps). In vivo maturation of esps yields the more stable and voluminous elps required to contain the 170 kb T4 genome. Functional proheads can be assembled containing portal-GFP fusion proteins. In the absence of terminase activity these accumulated in esps in vivo, whereas wild-type portals were found in elps. By nuclease protection assay dsDNAs of lengths 0.1, 0.2, 0.5, 5, 11, 20, 40 or 170 kb were efficiently packaged into wild-type elps in vitro, but less so into esps and gp20-GFP elps; particularly with DNAs shorter than 11 kb. However, 0.1 kb substrates were equally efficiently packaged into all types of proheads as judged by fluorescence correlation spectroscopy. These data suggest the portal controls the expansion of the major capsid protein lattice during prohead maturation, and that this expansion is necessary for DNA protection but not for packaging.

Portal fusion protein constraints on function in DNA packaging of bacteriophage T4

Architecturally conserved viral portal dodecamers are central to capsid assembly and DNA packaging. To examine bacteriophage T4 portal functions, we constructed, expressed and assembled portal gene 20 fusion proteins. C-terminally fused (gp20-GFP, gp20-HOC) and N-terminally fused (GFP-gp20 and HOC-gp20) portal fusion proteins assembled in vivo into active phage. Phage assembled C-terminal fusion proteins were inaccessible to trypsin whereas assembled N-terminal fusions were accessible to trypsin, consistent with locations inside and outside the capsid respectively. Both N- and C-terminal fusions required coassembly into portals with approximately 50% wild-type (WT) or near WT-sized 20am truncated portal proteins to yield active phage. Trypsin digestion of HOC-gp20 portal fusion phage showed comparable protection of the HOC and gp20 portions of the proteolysed HOC-gp20 fusion, suggesting both proteins occupy protected capsid positions, at both the portal and the proximal HOC capsid-binding sites. The external portal location of the HOC portion of the HOC-gp20 fusion phage was confirmed by anti-HOC immuno-gold labelling studies that showed a gold 'necklace' around the phage capsid portal. Analysis of HOC-gp20-containing proheads showed increased HOC protein protection from trypsin degradation only after prohead expansion, indicating incorporation of HOC-gp20 portal fusion protein to protective proximal HOC-binding sites following this maturation. These proheads also showed no DNA packaging defect in vitro as compared with WT. Retention of function of phage and prohead portals with bulky internal (C-terminal) and external (N-terminal) fusion protein extensions, particularly of apparently capsid tethered portals, challenges the portal rotation requirement of some hypothetical DNA packaging mechanisms.

Molecular architecture of bacteriophage T4

In studying bacteriophage T4--one of the basic models of molecular biology for several decades--there has come a Renaissance, and this virus is now actively used as object of structural biology. The structures of six proteins of the phage particle have recently been determined at atomic resolution by X-ray crystallography. Three-dimensional reconstruction of the infection device--one of the most complex multiprotein components--has been developed on the basis of cryo-electron microscopy images. The further study of bacteriophage T4 structure will allow a better understanding of the regulation of protein folding, assembly of biological structures, and also mechanisms of functioning of the complex biological molecular machines.

Structure of viral connectors and their function in bacteriophage assembly and DNA packaging

The viruses have been an attractive model for the study of basic mechanisms of protein/protein and protein/nucleic acid interactions involved in the assembly of macromolecular aggregates. This has been due primarily to their relative genetic simplicity as compared to their structural and functional complexity. Although most of the initial studies were carried out on bacterial and plant viruses, increasing data has also been accumulated from animal viruses, which has led to an understanding of some basic principles, as well as to many specific strategies in every system. The study of virus assembly has been a source of ideas that underlie our present knowledge of the organization of biological systems. It has also provided, since the production of bacteriophage mutants which have allowed the study of assembly intermediates, the first system in which the genetic studies played a dominant role. The increasing volume of data over the last years has revealed how the structural components can interact sequentially through an ordered pathway to yield macromolecular assemblies that satisfy the demands of stability required for a successful transfer of genetic information from host to host.

Novel second-site suppression of a cold-sensitive defect in phage P22 procapsid assembly

The DNA packaging portal of the phage P22 procapsid is formed of 12 molecules of the 90,000 dalton gene 1 protein. The assembly of this dodecameric complex at a unique capsid vertex requires scaffolding subunits. The mechanism that ensures the location of the 12-fold symmetrical portal at only one of the 12 5-fold vertices of an icosahedral virus capsid presents a unique assembly problem, which, in some viruses, is solved by the portal also acting as initiator of procapsid assembly. Phage P22 procapsids, however, are formed in the absence of the portal protein. The 1-csH137 mutation prevents the incorporation of the portal protein into procapsids. In a mixed infection with cs+ phage, the mutant subunits are able to form functional portals, suggesting that the cold-sensitivity does not affect portal-portal interactions, but affects the interaction of portal subunits with some other molecular species involved in the initiation of portal assembly. Interestingly, the cs defect is suppressed by temperature-sensitive folding mutations at four sites in the P22 tailspike gene 9. The suppression is allele-specific; other tailspike tsf mutations fail to suppress the cs defect. Translation through a suppressor site is required for suppression. This observation is unexpected, since analysis of nonsense mutations in this gene indicates that it is not required for procapsid assembly. Examination of the nucleic acid sequences in the neighborhood of each of the suppressor sites shows significant sequence similarity with the scaffolding gene translational initiation region on the late message. This supports a previously proposed model, in which procapsid assembly is normally initiated in a region on the late messenger RNA that includes the gene 8 start site. By this model, the suppressor mutations may be acting through protein-RNA interactions, changing sequences that identify alternative or competing sites at which the mutant portal subunits may be organized for assembly into the differentiated vertex of the phage capsid.

Conformational changes in bacteriophage phi 29 connector prevents DNA-binding activity

In vitro DNA packaging activity in a defined system derived from bacteriophage phi 29 depends upon the chemical integrity of the connector protein p10. Proteolytic cleavage of p10 rendered the proheads inactive for DNA packaging. A similar treatment on isolated connectors abolished the DNA-binding activity of the native p10, but the general shape and size of the connector was not changed as revealed by electron microscopy. Analytical ultracentrifugation showed that the proteolyzed connectors had a smaller sedimentation coefficient, while amino acid analysis after dialysis of the proteolyzed p10 confirmed the loss of 16 and 19 amino acids from the amino and carboxy termini, respectively. Low angle X-ray scattering revealed that proteolysis was followed by a small decrease in the radius of gyration and a reorganization of the distal domain of the cylindrical inner part of the connector. Characterization of the cleavage sites in the primary sequence allowed us to propose the location of the DNA-binding domain in the connector model.

Membrane-associated assembly of a phage T4 DNA entrance vertex structure studied with expression vectors

The DNA entrance vertex of the phage head is critical for prohead assembly and DNA packaging. A single structural protein comprises this dodecameric ring substructure of the prohead. Assembly of the phage T4 prohead occurs on the cytoplasmic membrane through a specific attachment at or near the gp20 DNA entrance vertex. An auxiliary head assembly gene product, gp40, was hypothesized to be involved in assembling the gp20 substructure. T4 genes 20, 40 and 20 + 40 were cloned into expression vectors under lambda pL promoter control. The corresponding T4 gene products were synthesized in high yield and were active as judged by their ability to complement the corresponding infecting T4 mutants in vivo. The cloned T4 gene 20 and gene 40 products were inserted into the cytoplasmic membrane as integral membrane proteins; however, gp20 was inserted into the membrane only when gp40 was also synthesized, whereas gp40 was inserted in the presence or absence of gp20. The gp20 insertion required a membrane potential, was not dependent upon the Escherichia coli groE gene, and assumed a defined membrane-spanning conformation, as judged by specific protease fragments protected by the membrane. The inserted gp20 structure could be probed by antibody binding and protein A-gold immunoelectron microscopy. The data suggest that a specific gp20-gp40-membrane insertion structure constitutes the T4 prohead assembly initiation complex.

Initiation of P22 procapsid assembly in vivo

The procapsids of all double-stranded DNA phages have a unique portal vertex, which is the locus of DNA packaging and DNA injection. Procapsid assembly is also initiated at this vertex, which is defined by the presence of a cyclic dodecamer of the portal protein. Assembly of the procapsid shell of phage P22 requires the gene 5 coat protein and the gene 8 scaffolding protein. We report here that removal of gene product (gp) 1 portal protein of P22 by mutation does not slow the rate of polymerization of coat and scaffolding subunits into shells, indicating that the portal ring is dispensable for shell initiation. Mutant scaffolding subunits specified by tsU172 copolymerize with coat subunits into procapsids at restrictive temperature, and also correctly autoregulate their synthesis. However, the shell structures formed from the temperature-sensitive scaffolding subunits fail to incorporate the portal ring and the three minor DNA injection proteins. This mutation identifies a domain of the scaffolding protein specifically involved in organization of the portal vertex. The results suggest that it is a complex of the scaffolding protein that initiates procapsid assembly and organizes the portal ring.

Purification and organization of the gene 1 portal protein required for phage P22 DNA packaging

The gene 1 protein of Salmonella bacteriophage P22 is located at the DNA packaging vertex of the mature particle. The protein is incorporated into the procapsid shell during shell assembly and is required for DNA packaging. The unassembled precursor form of the gene 1 protein has been purified from cells infected with mutants blocked in procapsid assembly. The purified 90,000-dalton protein was dimeric or monomeric; upon storage in the cold it formed 20S cyclic dodecamers. Computer filtering of negatively stained electron micrographs revealed 12 arms and knobs projecting from a central ring, with a 30-A channel at the center. Similar dodecameric rings were released from disrupted procapsid shells. These results indicate that the gene 1 protein is organized as a cyclic dodecamer within the procapsid shell and serves as the portal through which P22 DNA is threaded during DNA packaging. The presence of a 12-fold ring located at a 5-fold portal vertex appears to be a conserved structural theme of the DNA packaging apparatus of double-stranded DNA phages.

Temperature sensitivity of the multiplication of bacteriophage T4 amber mutants on nonpermissive host: characterization of the phenomenon

The existence of temperature sensitivity of the multiplication of amber mutants on a nonpermissive host has been established for a considerable number of mutants in tail and head genes and for mutants in some other T4 genes as well. Temperature sensitivity of multiplication appears to be gene specific, and is typical of amber mutants in genes the products of which are not numerous per phage or which play the role of catalytic factor. Moreover, in most cases temperature sensitivity is characteristic of amber mutants in definite gene clusters.

Isolation and reassembly of bacteriophage T4 core proteins

The products of genes 22, 67 and 68, and the internal proteins IPI, IPII and IPIII, as components of the scaffolding core of the bacteriophage T4 prohead, have been isolated and purified by hydroxylapatite column chromatography. Under conditions promoting reassembly in vitro, the proteins associated into elongated particles of practically constant width but variable length that we have called polycores. Preliminary optical diffraction experiments indicate that polycores may have an ordered structure, possibly helical, as has been suggested for the polyhead core. The coassembly of core proteins and the purified shell protein gp23 results in the formation of core-containing polyheads. Occasionally, prolate core-like particles have been observed but their reproducible formation has not been attained. Attempts to investigate the role of the minor prohead component gp20 in core assembly have been made through the cloning of the corresponding gene in an expression vector and subsequent purification of the protein.

Prohead core of bacteriophage T4 can act as an intermediate in the T4 head assembly pathway

Bacteriophage T4 assembly was impaired in Escherichia coli hdB3-1 at an incubation temperature below 30 degrees C. Naked prohead cores (head scaffold) bound to the inner surface of the plasma membrane accumulated, and the major shell protein (gp23) precipitated into visible intracellular aggregates in the cytoplasm. Shifting the temperature to 42 degrees C allowed newly synthesized gp23 to assemble around the accumulated cores. We conclude that synchronous assembly of the scaffold and shell is not obligatory and that naked cores can serve as intermediates in the T4 assembly pathway.

Formation of the prohead core of bacteriophage T4 in vivo

Formation of the prohead core of bacteriophage T4 was not dependent on shell assembly. In mutant infections, where the production or assembly of active shell protein was not possible, naked core structures were formed. The particles were generally attached to the bacterial inner membrane and possessed defined prolate dimensions. The intracellular yield varied between 15 and 71% of a corresponding prohead yield and was dependent on the temperature of incubation. The products of genes 21 and 22 were found to be essential for in vivo core formation, whereas those of genes 20, 23, 24, 31, and 40, as well as the internal proteins I to III, were dispensable.

Gene 20 product of bacteriophage T4. II. Its structural organization in prehead and bacteriophage

The location of gene 20 product of bacteriophage T4 in phage and phage percursors has been determined by immunochemical analysis of polyacrylamide gels, immunoturbidimetry and immunoelectron microscopy. The protein is present at the membrane attachment site of the prehead, a head precursor, and is accessible to the antibodies in the solution. It is present at the tail attachment site of the capsid, partially buried in the structure. In complete phage particles it is totally buried in the structure. It is in contact with the major shell proteins, gp23 and gp23*, respectively, in preheads and capsids, as revealed by partial crosslinking experiments. It forms the upper collar of the neck in necked tails. The lower collar is constructed from other gene products. On the basis of these data a structural model of the neck region of the phage has been derived. This model is consistent with a number of events in phage assembly, such as the role of gp20 in head assembly and DNA packaging, prehead detachment from the bacterial membrane and head-tail attachment. The symmetry mismatch known to occur between head and tail has been localized at the gp20-gp23* contact area.