Bacteriophage T4 baseplate components. I. Binding and location of the folic acid.

Two different proteins with high affinities for the pteridine ring of folic acid have been used to determine the location of this portion of the folate molecule in the tail plate of T4D and other T-even bacteriophage particles. The two proteins used were (i) antibody specific for folic acid and (ii) the folate-binding protein from bovine milk. Both proteins were examined for their effect on various intact and incomplete phage particles. Intact T2H was weakly inactivated by the antiserum but not by the milk protein. No other intact T-even phage, including T4D, was affected by these two proteins. When incomplete T4D particles were exposed in an in vitro morphogenesis system, it was found that neither of the two proteins affected either the addition of the long tail fibers to fiberless particles or the addition of tail cores to tail plates. On the other hand, these two proteins specifically blocked the addition of T4D gene 11 product to the bottom of T4D baseplates. After the addition of the gene 11 protein, these two reagents did not inhibit the further addition of the gene 12 protein to the baseplate. It can be concluded that the phage folic acid is a tightly bound baseplate constituent and that the pteridine portion of the folic acid is largely covered by the gene 11 protein.     

Dual Functions of Bacteriophage T4D Gene 28 Product: Structural Component of the Viral Tail Baseplate Central Plug and Cleavage Enzyme for Folyl Polyglutamates II. Folate Metabolism and Polyglutamate Cleavage Activity of Uninfected and Infected Escherichia coli Cells and Bacteriophage Particles

We investigated the role of the T4D bacteriophage gene 28 product in folate metabolism in infected Escherichia coli cells by using antifolate drugs and a newly devised assay for folyl polyglutamate cleavage activity. Preincubation of host E. coli cells with various sulfa drugs inhibited phage production by decreasing the burst size when the phage particles produced an altered gene 28 product (i.e., after infection under permissive conditions with T4D 28^ts or T4D am28). In addition, we found that another folate analog, pyrimethamine, also inhibited T4D 28^ts production and T4D 28am production, but this analog did not inhibit wild-type T4D production. A temperature-resistant revertant of T4D 28^ts was not sensitive to either sulfa drugs or pyrimethamine. We developed an assay to measure the enzymatic cleavage of folyl polyglutamates. The high-molecular-weight folyl polyglutamate substrate was isolated from E. coli B cells infected with T4D am28 in the presence of labeled glutamic acid and was characterized as a folate compound containing 12 to 14 labeled glutamate residues. Extracts of uninfected bacteria liberated glutamate residues from this substrate with a pH optimum of 8.4 to 8.5. Extracts of bacteriophage T4D-infected E. coli B cells exhibited an additional new folyl polyglutamate cleavage activity with a pH optimum of about 6.4 to 6.5, which was clearly distinguished from the preexisting activity in the uninfected host cells. This new activity was induced in E. coli B cells by infection with wild-type T4D and T4D amber mutants 29⁻, 26⁻, 27⁻, 51⁻, and 10⁻, but it was not induced under nonpermissive conditions by T4D am28 or by T4D 28^ts. Mutations in gene 28 affected the properties of the induced cleavage enzyme. Wild-type T4D-induced cleavage activity was not inhibited by pyrimethamine, whereas the T4D 28^ts activity induced at a permissive temperature was inhibited by this folate analog. Folyl polyglutamate cleavage activity characteristic of the activity induced in host cells by wild-type T4D or by T4D gene 28 mutants was also found in highly purified preparations of these phage ghost particles. The T4D-induced cleavage activity could be inhibited by antiserum prepared against highly purified phage baseplates. We concluded that T4D infection induced the formation of a new folyl polyglutamate cleavage enzyme and that this enzyme was coded for by T4D gene 28. Furthermore, since this gene product was a baseplate tail plug component which had both its antigenic sites and its catalytic sites exposed on the phage particle, it was apparent that this enzyme formed part of the distal surface of the phage baseplate central tail plug.     

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.     

Structural changes in proteins of the bacteriophage T4 basal plate resulting from the attachment of long fibrils

The effect of the attachment of long tail fibers on the structure of proteins of the bacteriophage T4 baseplate was studied by digital processing of electron microscopic images. The attachment of the long fibers was found to result in dramatical changes of the proteins of the baseplate plag, while the wedges, to which the long fibers are attached, undergo only slight changes. We studied the baseplates with one to six attached fibers and found that the attachment of one fiber resulted in the change of the entire baseplate, although the wedge located in the vicinity of the fiber attachment changed to a greater extent. Only after the attachment of three and more fibers the changes of the same kind occurred through the entire baseplate.     

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.     

The bacteriophage T4 DNA injection machine

The tail of bacteriophage T4 consists of a contractile sheath surrounding a rigid tube and terminating in a multiprotein baseplate, to which the long and short tail fibers of the phage are attached. Upon binding of the fibers to their cell receptors, the baseplate undergoes a large conformational switch, which initiates sheath contraction and culminates in transfer of the phage DNA from the capsid into the host cell through the tail tube. The baseplate has a dome-shaped sixfold-symmetric structure, which is stabilized by a garland of six short tail fibers, running around the periphery of the dome. In the center of the dome, there is a membrane-puncturing device, containing three lysozyme domains, which disrupts the intermembrane peptidoglycan layer during infection.     

Dual Functions of Bacteriophage T4D Gene 28 Product: Structural Component of the Viral Tail Baseplate Central Plug and Cleavage Enzyme for Folyl Polyglutamates I. Identification of T4D Gene 28 Product in the Tail Plug

The T4D bacteriophage gene 28 product is a component of the central plug of the tail baseplate, as shown by the following two independent lines of evidence. (i) A highly sensitive method for radioactive labeling of only tail baseplate plug components was developed. These labeled plug components were incorporated by a complementation procedure into new phage particles and were analyzed by radioautography after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three new structural proteins were found in addition to the three known tail plug proteins (i.e., gP29, gP27, and gP5). One of the three newly identified components had a molecular weight of 24,000 to 25,000 and appeared to be a product of T4D gene 28. (ii) Characterization of mutants of Escherichia coli bacteriophage T4D which produced altered gene 28 products also indicated that the gene 28 product was a viral tail component. T4D 28^ts phage particles produced at the permissive temperature had altered heat labilities compared with parent T4D particles. We isolated a single-step temperature revertant of T4D 28^ts and found that it produced phage particles which phenotypically resembled the original T4D particles. Since the properties of the phage baseplate components usually determine heat lability, these two changes in physical stability after two sequential single mutations in gene 28 supported the other evidence that the gene 28 product was a viral baseplate component. Also, compared with parent T4D particles, T4D 28^ts and T4D 28am viral particles adsorbed at different rates to various types of host cells. In addition, T4D 28^ts particles exhibited a different host range than parent T4D particles. This T4D mutant formed plaques with an extremely low efficiency on all E. coli K-12 strains tested. We found that although T4D 28^ts particles adsorbed rapidly and irreversibly to the E. coli K-12 strains, as judged by gene rescue experiments, these particles were not able to inject their DNA into the E. coli K-12 strains. On the other hand, the T4D 28^ts revertant had a plating efficiency on E. coli K-12 strains that was quite similar to the plating efficiency of the original parent, T4D. These properties of phage particles containing an altered gene 28 product supported the analytical finding that the gene 28 product is a structural component of the central plug of the T4D tail baseplate. They also indicated that this component plays a role in both host cell recognition and viral DNA injection.     

Mutants of bacteriophage T4 that produce infective fibreless particles

In wild type bacteriophage T4 the long tail fibres serve both in the initial attachment of the phage to its host and in the triggering of tail contraction. A two-step model for the control of triggering suggests that particles lacking the product of gene 9, which are also structurally fibreless, might be infective. This is shown to be the case, even though such phage do not plate on restrictive strains of bacteria. However, starting from phage carrying an amber mutation in gene 9 it is easy to isolate additional mutations which, under restrictive conditions, permit fibreless plating (pfp mutations). Three such pfp mutations, having also a temperature-sensitive phenotype, have been isolated and shown to map in genes coding for structural components of the baseplate. The mode of action of these pfp mutations is not clear, though they certainly destabilize the baseplate, thereby making triggering easier. The pfp mutations are effective only when in combination with an amber mutation in gene 9 and not with amber mutations in tail fibre genes, establishing the essentially inhibitory nature of the control of triggering exercised by gene 9 product.     

gpwac of the T4-type bacteriophages: structure, function, and evolution of a segmented coiled-coil protein that controls viral infectivity

The wac gene product (gpwac) or fibritin of bacteriophage T4 forms the six fibers that radiate from the phage neck. During phage morphogenesis these whiskers bind the long tail fibers (LTFs) and facilitate their attachment to the phage baseplate. After the cell lysis, the gpwac fibers function as part of an environmental sensing device that retains the LTFs in a retracted configuration and thus prevents phage adsorption in unfavorable conditions. A comparative analysis of the sequences of 5 wac gene orthologs from various T4-type phages reveals that the approximately 50-amino-acid N-terminal domain is the only highly conserved segment of the protein. This sequence conservation is probably a direct consequence of the domain's strong and specific interactions with the neck proteins. The sequence of the central fibrous region of gpwac is highly plastic, with only the heptad periodicity of the coiled-coil structure being conserved. In the various gpwac sequences, the small C-terminal domain essential for initiation of the folding of T4 gpwac is replaced by unrelated sequences of unknown origin. When a distant T4-type phage has a novel C-terminal gpwac sequence, the phage's gp36 sequence that is located at the knee joint of the LTF invariably has a novel domain in its C terminus as well. The covariance of these two sequences is compatible with genetic data suggesting that the C termini of gpwac and gp36 engage in a protein-protein interaction that controls phage infectivity. These results add to the limited evidence for domain swapping in the evolution of phage structural proteins.     

Solution structure of bacteriophage T4D and icosahedral capsid geometry visualized in freeze-fractured, deep-etched replicas

The prolate icosahedral capsid geometry of wild type bacteriophage T4D has been determined by direct visualization of the triangular faces in stereoimages of transmission electron micrographs of phage particles. Bacteriophage T4 was prepared for transmission electron microscopy (TEM) following a protocol of freeze-fracturing, deep-etching (FDET) and replication by vertical deposition (80 degrees angle) of a thin platinum-carbon (Pt-C) metal layer of 1.01 nm. From direct statistical measurements of the ratio of the head length to width and of stereometric angles on T4 heads, we have estimated a Q number of 21. This confirms previous indirect studies on T4 and agrees with determinations on bacteriophage T2. Many of the structural features of T4 observed in FDET preparations differ significantly from those observed by classical negative staining methods for TEM imaging. Most important among the differences are the conformation of the baseplate (a closed rosebud) and the positioning of the tail fibers (retracted). The retracted position of the tail fibers in the FDET preparations has been confirmed by negatively staining phage previously fixed suspended in solution with 2% glutaraldehyde. The FDET protocols appear to reveal important structural features not seen in negative stained preparations. These have implications for bacteriophage T4 conformation in solution, viral assembly and phage conformation states prior to tail contraction and DNA ejection.     

Solution Structure of Bacteriophage T4D and Icosahedral Capsid Geometry Visualized in Freeze-Fractured,Deep-Etched Replicas

Abstract

The prolate icosahedral capsid geometry of wild type bacteriophage T4D has been determined by direct visualization of the triangular faces in stereoimages of transmission electron micrographs of phage particles. Bacteriophage T4 was prepared for transmission electron microscopy (TEM) following a protocol of freeze-fracturing, deep-etching (FDET) and replication by vertical deposition (80° angle) of a thin platinum-carbon (Pt-C) metal layer of 1.01 nm. From direct statistical measurements of the ratio of the head length to width and of stereometric angles on T4 heads, we have estimated a Q number of 21. This confirms previous indirect studies on T4 and agrees with determinations on bacteriophage T2. Many of the structural features of T4 observed in FDET preparations differ significantly from those observed by classical negative staining methods for TEM imaging. Most important among the differences are the conformation of the baseplate (a closed rosebud) and the positioning of the tail fibers (retracted). The retracted position of the tail fibers in the FDET preparations has been confirmed by negatively staining phage previously fixed suspended in solution with 2% glutaraldehyde. The FDET protocols appear to reveal important structural features not seen in negative stained preparations. These have implications for bacteriophage T4 conformation in solution, viral assembly and phage conformation states prior to tail contraction and DNA ejection.     

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.     

Assembly of the tail of bacteriophage T4

The protein products of at least 21 phage genes are needed for the formation of the tail of bacteriophage T4. Cells infected with amber mutants defective in these genes are blocked in the assembly process. By characterizing the intermediate structures and unassembled proteins accumulating in mutant-infected cells, we have been able to delineate most of the gene-controlled steps in tail assembly. Both the organized structures and unassembled proteins serve as precursors for in vitro tail assembly. We review here studies on the initiation, polymerization, and termination of the tail tube and contractile sheath and the genetic control of these processes. These studies make clear the importance of the baseplate; if baseplate formation is blocked (by mutation) the tube and sheath subunits remain essentially unaggregated, in the form of soluble subunits. Seventeen of the 21 tail genes specify proteins involved in baseplate assembly. The genes map contiguously in two separate clusters, one of nine genes and the other of eight genes. Recent studies show that the hexagonal baseplate is the end-product of two independent subassembly pathways. The proteins of the first gene cluster interact to form a structure which probably represents one-sixth of the outer radius. The products of the other gene cluster interact to form the central part of the baseplate. Most of the phage tail precursor proteins appear to be synthesized in a non-aggregating form; they are converted to a reactive form upon incorporation into preformed substrate complexes, without proteolytic cleavage. Thus reactive sites are limited to growing structures.     

Properties of bacteriophage T4 modified with cetyltrimethylammonium bromide

Treating of the bacteriophage T4B with cetyltrimethylammonium bromide results in extension of long fibers and contraction of tail sheaths. The unreorganized hexagonal baseplate attachment to the distal end of the tail core remains intact. Such aberrantly contracted phages are shown to retain the ability to absorb on the bacterial surface. The absorption is inhibited by sucrose and does not require the presence of 1-tryptophan. The aberrantly contracted phages lose the infection ability.     

Effect of thermoinduced changes in T4 bacteriophage structure on the process of molecular recognition of 'host' cells.

By means of high-precision acoustic measurements and by methods of fluorescent and electron microscopy, investigations have been performed of thermoinduced conformational changes in T4 bacteriophage and its thermolabile mutants altered in baseplate proteins (gene products 7, 8, 10). A relationship was found between the conformational changes in T4 bacteriophage structure in the temperature range of 33-45 degrees C and the efficiency of bacteriophage adsorption and the changes in the orientation of long tail fibers. The possibility of heat regulation of 'recognition' of 'host' cells by bacterial viruses is suggested.     

The role of temperature as a factor of structure and functional fit of a "prey" virus based on the example of phage T4]

By means of high-precision acoustic measurements and by the methods of fluorescent and electron microscopy investigations were performed of thermoinduced conformational changes in T4 bacteriophage and its thermolabile mutants altered in baseplate proteins (gene products "7", "8", "10"). A relationship was found between the conformational changes in T4 bacteriophage structure in the temperature range of 33-45 degrees C and the efficiency of bacteriophage adsorption and changes in the orientation of long tail fibers. Possibility of heat regulation of "recognition" of "host" cells by bacterial viruses is suggested.     

The function of tail fibers in triggering baseplate expansion of bacteriophage T4

Normal particles of bacteriophage T4 have six long tail fibers attached to a hexagonal baseplate. T4 particles having various complements of tail fibers were prepared by in vitro addition of fibers to fiberless particles, and the infectivity of the particles was determined. Particles having fewer than six fibers (partially fibered) were found to have a decreased probability of infection. Partially fibered particles having T4 fibers were completed by addition of T6 fibers, and the infectivity was determined on a host that lacked the T6 tail fiber receptor. Attachment of the additional fibers increased the infectivity even though the T6 fibers could not bind to the host cell. The infectivity of particles having mixtures of T4 and T6 fibers was determined on cells having only one type of receptor. The results indicated that particles bound by only three fibers have a low probability of infection. The effect of thermolabile baseplate mutations was also examined. Studies of partially fibered particles and particles with mixtures of fibers indicated that particles with altered baseplates have a less stringent requirement for binding of the tail fibers for infection.     

Attachment of tail fibers in bacteriophage T4 assembly: role of the phage whiskers.

The collar and whiskers of bacteriophage T4 extend outward from the top of the tail and play a role in regulating retraction of the tail fibers (Conley &; Wood, 1975). The collar and whiskers also are required for efficient tail fiber attachment during phage assembly. The structural gene for the collar/whisker protein is called wac. In vitro, infected-cell extracts that contain tail fibers activate whiskerless (wac) tail fiberless particles and ordinary (wac⁺) tail fiberless particles at equal rates if the extracts contain the wac⁺ gene product. However, extracts that contain tail fibers but no wac⁺ gene product activate wac particles about ten times more slowly. In vivo, whiskers are not essential for plaque formation, but a wac mutation causes a delay in the appearance of intracellular phage and a fivefold decrease in the burst size of infectious particles.The effect of the whiskers on tail fiber attachment is due to an interaction between the whisker and the distal half of the tail fiber, similar if not identical to the interaction that controls tail fiber retraction in complete phage. The following observations support this view: a slow rate of in vitro tail fiber attachment similar to that described above is seen with wac⁺ particles when they are pretreated with anti-whisker serum, or when the tail fibers carry a mutational alteration in gp36, a structural protein in the distal half fiber near the central kink. Lack of whiskers does not affect the slow rate of attachment of proximal half fibers to the baseplate of fiberless particles, but lack of whiskers greatly decreases the rate at which particles with attached proximal half fibers are activated by addition of distal half fibers. Since whiskers normally are attached to the phage only after head—tail union (Coombs &; Eiserling, 1977; Terzaghi et al., 1978), these findings explain why tail fibers do not attach efficiently to the baseplates of free tails.     

Vibrio cholerae bacteriophage CP-T1: characterization of bacteriophage DNA and restriction analysis

Temperature bacteriophage CP-T1 of Vibrio cholerae has a capsid that is 45 nm in diameter, a contractile tail 65 nm long and 9.5 nm wide, and a baseplate with several spikes or short tail fibers. The linear double-stranded DNA is 43.5 +/- 1.4 kilobases long, and the phage genome is both terminally redundant and partially circularly permuted. The extent of terminal redundancy is ca. 4%, and circular permutation is up to ca. 44%. Circular restriction maps have been constructed for the enzymes HindIII, EcoRI, BamHI, and PstI. By restriction endonuclease and heteroduplex analyses of phage DNA, the presence and location of a site (pac) at which packaging of phage DNA is initiated was established.     

Structural Characteristics of the Short-Tail Fibers of T4 Bacteriophage

The characteristics of pure preparations of short-tail fibers of bacteriophage T4 have been studied in the optical and electron microscope. Three main structures were observed: 1) spheres of 8.1 nm diameter; 2) fibers 43 nm long and 3.8 nm thick; and 3) fibers 54 nm long and 3.2 nm thick. Both types of fibers exhibited a regular beaded appearance. The 43-nm fibers were the most abundant structure. During the process of purification of the short-tail fibers, the formation of aggregates was observed each time the material containing the short-tail fibers was dialyzed against saline solutions. These aggregates became increasingly fibrous (as observed in the optical microscope) as the material used was increasingly enriched in short-tail fibers. Finally, most of the aggregates were of the fibrous type when they were formed from a purified preparation of short-tail fibers. In the electron microscope, it was found that the filamentous aggregates were organized in well-defined bundles. The amino acid composition of the highly purified short-tail fibers was also determined. Among the known fibrous proteins, the ones that most resemble the amino acid composition of the short-tail fibers are actin and fibrinogen. These observations are discussed in relation to the T4 short-tail fiber structure and their localization on the hexagonal baseplate of the T4 tail structure.