Isolation and characterization of bacteriophage T4 mutant preheads.

To determine the function of individual gene products in the assembly and maturation of the T4 prehead, we have isolated and characterized aberrant preheads produced by mutations in three of the T4 head genes. Mutants in gene 21, which codes for the T4 maturation proteases, produce rather stable preheads whose morphology and protein composition are consistent with a wild-type prehead blocked in the maturation cleavages. Mutants in gene 24 produce similar structures which are unstable because they have gaps at all of their icosahedral vertices except the membrane attachment site. In addition, greatly elongated "giant preheads" are produced, suggesting that in the absence of P24 at the vertices, the distal cap of the prehead is unstable, allowing abnormal elongation of broth the prehead core and its shell. Vertex completion by P24 is required to allow the maturation cleavages to occur, and 24- preheads can be matured to capsids in vitro by the addition of P24. Preheads produced by a temperature-sensitive mutant in gene 23 are deficient in core proteins. We show that the shell of these preheads has the expanded lattice characteristic of the mature capsid as well as the binding sites for the proteins hoc and soc, even though none of the maturation cleavage takes place. We also show that 21- preheads composed of wild-type P23 can be expanded in vitro without cleavage.     

Assembly of bacteriophage T4 head-related strucutres. II. In vitro assembly of prehead-like structures

A protein mixture which is derived from bacteriophage T4 preheads formed in vivo contains all the important prehead proteins: i.e. protein P23, which forms the icosahedral prehead shell; the core proteins P22 and internal protein III; and two quantitatively minor proteins, P24 and P20. Conditions are described under which these proteins assemble in vitro into structures that (1) resemble preheads when visualized by electron microscopy, (2) contain all prehead proteins, and (3) have a similar length and diameter as preheads formed in vivo. It is concluded that prehead-like structures can be assembled in vitro, and that the mechanism that determines the length and diameter of the T4 prehead is active in our in vitro system. Evidence is presented that the core proteins play an important role in specifying the prehead diameter. The result of assembly experiments after partial fractionation of the protein mixture by gel filtration suggests that P20 plays a key role in the assembly of prehead-like structures in vitro, whereas P24 is not required. A possible mechanism by which P20 governs tha assembly of P23 and the core proteins is discussed.     

Evidence that a phage T4 DNA packaging enzyme is a processed form of the major capsid gene product

A phage T4 DNA packaging enzyme appears to arise as a processed form of the major T4 capsid structural protein gp23. The enzyme activity and antigen are missing from all head gene mutants that block the morphogenetic proteolytic processing reactions of the head proteins in vivo. The enzyme antigen can be formed in vitro by T4 (gp21) specific processing of gp23 containing extracts. Enzyme antigen is found in active processed proheads but not in full heads. The enzyme and the major capsid protein show immunological cross-reactivity, produce common peptides upon proteolysis, and share an assembly-conformation-dependent ATP binding site. The packaging enzyme and the mature capsid protein (gp23*) both appear to arise from processing of gp23, the former as a minor product of a specific gp23 structure in the prohead, acting in DNA packaging as a DNA-dependent ATPase, and a headful-dependent terminase.     

P15 and P3, the tail completion proteins of bacteriophage T4, both form hexameric rings

Two proteins, gp15 and gp3 (gp for gene product), are required to complete the assembly of the T4 tail. gp15 forms the connector which enables the tail to bind to the head, whereas gp3 is involved in terminating the elongation of the tail tube. In this work, genes 15 and 3 were cloned and overexpressed, and the purified gene products were studied by analytical ultracentrifugation, electron microscopy, and circular dichroism. Determination of oligomerization state by sedimentation equilibrium revealed that both gp15 and gp3 are hexamers of the respective polypeptide chains. Electron microscopy of the negatively stained P15 and P3 (P denotes the oligomeric state of the gene product) revealed that both proteins form hexameric rings, the diameter of which is close to that of the tail tube. The differential roles between gp15 and gp3 upon completion of the tail are discussed.     

Broad-host-range Yersinia phage PY100: genome sequence, proteome analysis of virions, and DNA packaging strategy

PY100 is a lytic bacteriophage with a broad host range within the genus Yersinia. The phage forms plaques on strains of the three human pathogenic species Yersinia enterocolitica, Y. pseudotuberculosis, and Y. pestis at 37°C. PY100 was isolated from farm manure and intended to be used in phage therapy trials. PY100 has an icosahedral capsid containing double-stranded DNA and a contractile tail. The genome consists of 50,291 bp and is predicted to contain 93 open reading frames (ORFs). PY100 gene products were found to be homologous to the capsid proteins and proteins involved in DNA metabolism of the enterobacterial phage T1; PY100 tail proteins possess homologies to putative tail proteins of phage AaΦ23 of Actinobacillus actinomycetemcomitans. In a proteome analysis of virion particles, 15 proteins of the head and tail structures were identified by mass spectrometry. The putative gene product of ORF2 of PY100 shows significant homology to the gene 3 product (small terminase subunit) of Salmonella phage P22 that is involved in packaging of the concatemeric phage DNA. The packaging mechanism of PY100 was analyzed by hybridization and sequence analysis of DNA isolated from virion particles. Newly replicated PY100 DNA is cut initially at a pac recognition site, which is located in the coding region of ORF2.     

A three-dimensional cryo-electron microscopy structure of the bacteriophage phiKZ head

The three-dimensional structure of the Pseudomonas aeruginosa bacteriophage phiKZ head has been determined by cryo-electron microscopy and image reconstruction to 18A resolution. The head has icosahedral symmetry measuring 1455 A in diameter along 5-fold axes and a unique portal vertex to which is attached an approximately 1800 A-long contractile tail. The 65 kDa major capsid protein, gp120, is organized into a surface lattice of hexamers, with T = 27 triangulation. The shape and size of the hexamers is similar to the hexameric building blocks of the bacteriophages T4, phi29, P22, and HK97. Pentameric vertices of the capsid are occupied by complexes composed of several special vertex proteins. The double-stranded genomic DNA is packaged into a highly condensed series of layers, separated by 24 A, that follow the contour of the inner wall of the capsid.     

Probable localization of the bacteriophage T4 prehead proteinase zymogen in the center of the prehead core.

During the assembly of the bacteriophage T4 prehead, a T4-coded protease zymogen (P21) is built into the structure. At a certain stage in head formation, the protease precursor is activated and specifically cleaves most of the prehead proteins. In this paper we show that a correlation existed between the presence of proteinaceous material in the center of the prehead core, observed by electron microscopy, and the availability of P21 during prehead assembly. In the absence of P21, the core enclosed a hold of about 35 nm long and 20 nm wide. We found the same for (i) in vitro-assembled, negatively stained prehead-like structures and (ii) in vivo-formed preheads in thin sections of T4-infected cells. We concluded that P21 was localized in the center of the prehead core.     

The structure of bacteriophage T4 gene product 9: the trigger for tail contraction.

BACKGROUND: The T4 bacteriophage consists of a head, filled with double-stranded DNA, and a complex contractile tail required for the ejection of the viral genome into the Escherichia coli host. The tail has a baseplate to wh?ch are attached six long and six short tail fibers. These fibers are the sensing devices for recognizing the host. When activated by attachment to cell receptors, the fibers cause a conformational transition in the baseplate and subsequently in the tail sheath, which initiates DNA ejection. The baseplate is a multisubunit complex of proteins encoded by 15 genes. Gene product 9 (gp9) is the protein that connects the long tail fibers to the baseplate and triggers the tail contraction after virus attachment to a host cell. RESULTS: The crystal structure of recombinant gp9, determined to 2.3 A resolution, shows that the protein of 288 amino acid residues assembles as a homotrimer. The monomer consists of three domains: the N-terminal domain generates a triple coiled coil; the middle domain is a mixed, seven-stranded beta sandwich with a topology not previously observed; and the C-terminal domain is an eight-stranded, antiparallel beta sandwich having some resemblance to 'jelly-roll' viral capsid protein structures. CONCLUSIONS: The biologically active form of gp9 is a trimer. The protein contains flexible interdomain hinges, which are presumably required to facilitate signal transmission between the long tail fibers and the baseplate. Structural and genetic analyses show that the C-terminal domain is bound to the baseplate, and the N-terminal coiled-coil domain is associated with the long tail fibers.     

Bacteriophage T4 tail assembly: proteins of the sheath, core and baseplate

Structural intermediates in phage tail formation have been isolated by sucrose gradient centrifugation from cells infected with mutants blocked at various stages in tail assembly. The polypeptide chains of these structures containing ¹⁴C-labeled amino acids have been analyzed by sodium dodecyl sulfate—acrylamide gel electrophoresis, enabling us to identify the proteins forming the various morphological components of the tail. Comparison of sheathed tails with corebaseplates shows that the contractile sheath is composed of a single species of subunit, the product of gene 18 (mol.wt 80,000). The site for head attachment terminating the tail is composed of the product of gene 15 (mol.wt 35,000). Comparison of core-baseplates with free baseplates shows that the tail core is composed of a single species of subunit, the product of gene 19 (mol.wt 21,000).Free baseplates are composed of at least twelve species of proteins: the products of genes 6, 7, 8, 9, 10, 11, 12 and 29, and four genetically unidentified species.The incomplete tails which accumulate in cells infected with mutants defective in genes 9, 11 and 12, which specify proteins on the outside of the baseplate, have also been characterized. Tails from 9^? lysates lack only P9. Tails from 11^? lysates lack both Pll and P12. Tails from 12^? infection lack only P12. Incorporation of P12 into the baseplate requires the function of gene 57, which is also required for tail fiber assembly. P57 thus appears to take part in the maturation of three different phage structural proteins.The sequential nature of the protein interactions in tail formation is discussed in terms of the regulation of morphogenesis at the level of assembly.     

Molecular reorganization in the hexagon to star transition of the baseplate of bacteriophage T4

The baseplate of bacteriophage T4 is a complex structure containing at least 14 different structural proteins. It undergoes a transition from a hexagonal to a star-shaped configuration during infection of the host bacterial cell. We have used a combination of genetics and image processing of electron micrographs to analyse both the wild-type structure and a series of mutant structures lacking specific gene products. Besides describing the basic anatomy of the hexagon and star configurations, we have been able to locate the products of genes 9, 11 and 12.Gene 9 product occupies a peripheral position in hexagons and stars consistent with its providing a binding site for the long tail fibres. Gene 11 product in the hexagon forms the distal part of the tail pin, which folds out to form the point of the hexagram in the star configuration. Gene 12 product is visualized as an extended 350 Å fibre in stars and broken baseplates but appears to have a more compact configuration in hexagons and intact phage.We demonstrate the structural relationship between the hexagonal and starshaped configurations and show how the positions of the specific gene products alter as a result of the structural transition. We suggest a speculative model for the role of gene 9 and gene 12 products in triggering the rearrangement of the baseplate and tail contraction.     

Structural Characterization of the Bacteriophage T7 Tail Machinery

Most bacterial viruses need a specialized machinery, called “tail,” to inject their genomes inside the bacterial cytoplasm without disrupting the cellular integrity. Bacteriophage T7 is a well characterized member of the Podoviridae family infecting Escherichia coli, and it has a short noncontractile tail that assembles sequentially on the viral head after DNA packaging. The T7 tail is a complex of around 2.7 MDa composed of at least four proteins as follows: the connector (gene product 8, gp8), the tail tubular proteins gp11 and gp12, and the fibers (gp17). Using cryo-electron microscopy and single particle image reconstruction techniques, we have determined the precise topology of the tail proteins by comparing the structure of the T7 tail extracted from viruses and a complex formed by recombinant gp8, gp11, and gp12 proteins. Furthermore, the order of assembly of the structural components within the complex was deduced from interaction assays with cloned and purified tail proteins. The existence of common folds among similar tail proteins allowed us to obtain pseudo-atomic threaded models of gp8 (connector) and gp11 (gatekeeper) proteins, which were docked into the corresponding cryo-EM volumes of the tail complex. This pseudo-atomic model of the connector-gatekeeper interaction revealed the existence of a common molecular architecture among viruses belonging to the three tailed bacteriophage families, strongly suggesting that a common molecular mechanism has been favored during evolution to coordinate the transition between DNA packaging and tail assembly.     

Affinity labeling of the P site of Drosophila ribosomes: a comparison of results from (bromoacetyl)phenylalanyl-tRNA and mercurated fragment affinity reactions

The binding site of the peptidyl group of peptidyl-tRNA in the P site of Drosophila ribosomes was probed with (bromoacetyl)phenylalanyl-tRNA (BrAcPhe-tRNA). This affinity label binds specifically to the P site by virtue of its ability to participate in peptide bond formation with puromycin following its attachment to ribosomes. As many as nine ribosomal proteins may be labeled under these conditions; however, the majority of the labeling is associated with three large-subunit proteins and two small-subunit proteins. Two of the large-subunit proteins, L4 and L27, are electrophoretically very similar to the proteins labeled by the same reagent in Escherichia coli ribosomes L2 and L27. Reexamination by a different two-dimensional gel system of the ribosomal components labeled by a second P site reagent, the 3' pentanucleotide fragment of N-acetylleucyl-tRNA which is derivatized to contain mercury atoms at the C-5 position of all three cytosine residues, shows two major and three minor labeled proteins. These proteins, L10/L11, L26, S1/S4, S13, and S20, are likely present in the binding site of the 3' end of peptidyl-tRNA, a site that appears to span both subunits. These results have allowed us to construct a model for the protein positions in and near the peptidyl-tRNA binding site of Drosophila ribosomes.     

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.     

Gene 67, a new,essential bacteriophage T4 head gene codes for a prehead core component,PIP: II. The construction in vitro of unconditionally lethal mutants and their maintenance

We have obtained frameshift mutations of the bacteriophage T4 gene 67 by manipulating restriction cleavage sites within the gene cloned onto small plasmids. When these mutated genes were recombined back into the T4 genome the resulting phages were inviable. They could only be propagated by complementation in strains carrying a cloned, non-mutated copy of the gene on a plasmid. These experiments demonstrate that gene 67 is essential for T4 growth. Electron microscopy of bacteria infected with 67^? phages revealed that phage head morphogenesis was blocked at an early stage and particles resembling abnormal preheads were found in large numbers. The gene 67 product, PIP, is therefore essential for correct prehead assembly.     

Attachment of tail fibers in bacteriophage T4 assembly. Identification of the baseplate protein to which tail fibers attach

A phage-neutralizing rabbit antiserum collected after immunization with tail-fiberless bacteriophage T4 particles was adsorbed with complete T4 phage. The resulting adsorbed serum inhibited tail fiber attachment in vitro. To identify the antigens against which this inhibitory activity was directed, blocking experiments were carried out with the adsorbed serum. Isolated complete baseplates and mutant-infected-cell extracts lacking known baseplate gene products but containing gene 9 product showed similar high levels of blocking activity. By contrast, both tail-fiberless particles lacking gene 9 product and infected-cell extracts made with gene 9 mutants showed 30-fold to 100-fold lower blocking activity. These results strongly support the conclusion that gene 9 product is the baseplate protein to which tail fibers attach.     

Characterization of a novel Vibrio parahaemolyticus phage, KVP241, and its relatives frequently isolated from seawater

A vibriophage, KVP241, and six of its relatives were isolated independently from seawater using Vibrio parahaemolyticus as the host. All of the phages had the same morphology (a hexagonal head and a tail with a contractile sheath) and the same host range (specific for some V. parahaemolyticus strains). DNA-DNA hybridization experiments elucidated that their genomes are highly homologous to each other. Analyses of amino acid sequences of putative major capsid proteins indicated that KVP241 may be weakly related to T4-type phages having a more elongated head.     

Functional empty capsid precursors produced by lambda mutant defective for late lambda DNA replication.

This report described lambda phage morphogenesis in a mutant system in which the normal pathways for late phage DNA (concatemer) synthesis are blocked and early (monomeric circular) DNA replication products accumulate. As shown earlier (Dawson et al., 1975) under these conditions, late proteins are synthesized and assembled into headlike structures. These structures that accumulate in the mutant are empty, suggesting the monomeric circular DNA molecules cannot be encapsulated. The present results show that crude extracts of induced lysogens of the mutant contain the complementation activities of preheads (the empty precursors to DNA-filled heads), tails, and DNA terminigenerating protein(s). Sucrose gradients of these crude extracts yield fractions containing prehead activity in relative amounts expected from the concentration of late proteins and empty structures. Furthermore, the proteins present in these fractions coelectrophorese with the known capsid proteins of preheads, and empty structures that look like preheads are observed in electron microscope examination of samples from the fractions. Based on our biological, biochemical, and electron microscope analyses, we conclude that the empty structures that accumulate in the induced lysogen of the mutant are normal preheads, which could become filled phage heads if DNA of the appropriate structure (i.e., "late DNA") were available.     

Structure and size determination of bacteriophage P2 and P4 procapsids: function of size responsiveness mutations

Bacteriophage P4 is dependent on structural proteins supplied by a helper phage, P2, to assemble infectious virions. Bacteriophage P2 normally forms an icosahedral capsid with T=7 symmetry from the gpN capsid protein, the gpO scaffolding protein and the gpQ portal protein. In the presence of P4, however, the same structural proteins are assembled into a smaller capsid with T=4 symmetry. This size determination is effected by the P4-encoded protein Sid, which forms an external scaffold around the small P4 procapsids. Size responsiveness (sir) mutants in gpN fail to assemble small capsids even in the presence of Sid. We have produced large and small procapsids by co-expression of gpN with gpO and Sid, respectively, and applied cryo-electron microscopy and three-dimensional reconstruction methods to visualize these procapsids. gpN has an HK97-like fold and interacts with Sid in an exposed loop where the sir mutations are clustered. The T=7 lattice of P2 has dextro handedness, unlike the laevo lattices of other phages with this fold observed so far.     

Cryo-EM structure of a bacteriophage T4 gp24 bypass mutant: the evolution of pentameric vertex proteins in icosahedral viruses

Many large viral capsids require special pentameric proteins at their fivefold vertices. Nevertheless, deletion of the special vertex protein gene product 24 (gp24) in bacteriophage T4 can be compensated by mutations in the homologous major capsid protein gp23. The structure of such a mutant virus, determined by cryo-electron microscopy to 26 angstroms, shows that the gp24 pentamers are replaced by mutant major capsid protein (gp23) pentamers at the vertices, thus re-creating a viral capsid prior to the evolution of specialized major capsid proteins and vertex proteins. The mutant gp23* pentamer is structurally similar to the wild-type gp24* pentamer but the insertion domain is slightly more distant from the gp23* pentamer center. There are additional SOC molecules around the gp23* pentamers in the mutant virus that were not present around the gp24* pentamers in the wild-type virus.