Bacteriophage T4 baseplate components. II. Binding and location of bacteriophage-induced dihydrofolate reductase.

The location of T4D phage-induced dihydrofolate reductase (dfr) has been determined in intact and incomplete phage particles. It has been found that phage mutants inducing a temperature-sensitive dfr (dfrts) procude heat-labile phage particles. The structural dfr produced by these ts mutants was shown to assume different configurations depending on the temperature at which the phage is assembled. Morphogenesis of incomplete phage particles lacking the gene 11 protein on their baseplates was found to be inhibited by reagents binding to dfr, such as antibodies to dfr. Further, cofactor molecules for dfr, such as reduced nicotinamide adenine dinucleotide phosphate and reduced nicotinamide adenine dinucleotide, also inhibited the step in morphogenesis involving the addition of gene 11 product. On the other hand, inhibitors of dfr, such as adenosine dephosphoribose, stimulated the addition of the gene 11 protein. It has been concluded that the phage-induced dfr is a baseplate component which is partially covered by the gene 11 protein. The properties of phage particles produced after infection of the nonpermissive host with the one known T4D mutant containing a nonsense mutation in its dfr gene suggested that these progeny particles contained a partial polypeptide, which was large enough to serve as a structural element.     

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.     

Bacteriophage Tail Components: II. Dihydrofolate Reductase in T4D Bacteriophage

The protein component of the T-even bacteriophage coat which binds the phage-specific dihydropteroyl polyglutamate has been identified as the phage-induced dihydrofolate reductase. Dihydrofolate reductase activity has been found in highly purified preparations of T-even phage ghosts and phage substructures after partial denaturation. The highest specific enzymatic activity was found in purified tail plate preparations, and it was concluded that this enzyme was a structural component of the phage tail plate. Phage viability was directly correlated with the enzymological properties of the phage tail plate dihydrofolate reductase. All reactions catalyzed by this enzyme which changed the oxidation state of the phage dihydrofolate also inactivated the phage. Properties of two T4D dihydrofolate reductase-negative mutants, wh1 and wh11, have been examined. Various lines of evidence support the view that the product of the wh locus of the phage genome is normally incorporated into the phage tail structure. The effects of various dihydrofolate reductase inhibitors on phage assembly in in vitro complementation experiments with various extracts of conditional lethal T4D mutants have been examined. These inhibitors were found to specifically block complementation when added to extracts which did not contain preformed tail plates. If tail plates were present, inhibitors such as aminopterin, did not affect further phage assembly. This specific inhibition of tail plate formation in vitro confirms the analytical and genetic evidence that this phage-induced "early" enzyme is a component of the phage coat.     

Bacteriophage Tail Components V. Complementation of T4D Gene 28?-Infected Bacterial Extracts with Pteroyl Hexaglutamate

Synthetic pteroyl hexaglutamate (9 x 10(-6) M) stimulated the formation of new T4D particles in vitro in extracts of Escherichia coli B infected with T4D gene 28(-). The stimulation was specific for this form of folic acid since neither pteroyl pentaglutamate nor pteroyl heptaglutamate stimulated phage formation. T4D formation in vitro in E. coli B extracts prepared after infection with 11 other phage mutants known to be involved in phage tail plate formation (5(-), 6(-), 7(-), 8(-), 10(-), 25(-), 26(-), 27(-), 29(-), 51(-), 53(-)) was not stimulated by the addition of pteroyl hexaglutamate. It can be concluded that the T4D gene 28 product is involved in the formation of the phage tail plate pteroyl hexaglutamate.     

Inactivation of T4D Bacteriophage by Antiserum Against Bacteriophage Dihydrofolate Reductase

Antiserum was prepared against highly purified T4D bacteriophage-induced dihydrofolate reductase (DFR). This serum not only inactivated the enzyme but also inactivated all strains of T4D examined. T6 was inactivated to a lesser extent, and T2L, T2H, and T5 were unaffected by the antiserum. The phage-killing power of the serum could be blocked by prior incubation with partially purified T4D dfr obtained from host cells unable to make phage structural proteins. These observations confirm earlier results that the phage dfr is a structural component of the phage particle, and they offer new evidence on the manner in which this enzyme in incorporated into the tail structure.     

Bacteriophage-coded thymidylate synthetase. Evidence that the T4 enzyme is a capsid protein

It has previously been shown that T4 bacteriophage-coded dihydrofolate reductase is a capsid protein, specifically an element of the tail plate. This paper presents evidence that thymidylate synthetase is also a structural protein. Antiserum prepared against purified T4 thymidylate synthetase neutralizes T4 infectivity. Evidence is presented that structural thymidylate synthetase is the target of the antiphage component of the serum.The td gene in T4 codes for thymidylate synthetase. We have crossed the td gene from phage T6 into T4 and eliminated other T6 genetic material from the hybrid phage by extensive backcrossing. The hybrid phage, T4td^T6, is inactivated at 60 °C significantly more rapidly than the parent phage, T4D. Thus, the td gene is a determinant of a physical property of the virion, providing direct confirmation that thymidylate synthetase is a capsid protein. At present the role of the virion-bound enzyme is unknown.     

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.     

Location of the ss--mutation of bacteriophage T7 in genes 10, the structural gene for the major capsid protein.

T7+ phage are unable to plate on a strain of Shigella sonnei D2 371-48. Spontaneous phage mutants arise (ss--mutants) that are able to plate on this strain of Shigella. We have shown by complementation studies and genetic crosses that the ss--mutation maps in gene 10, the structural gene for the major protein of the capsid. This finding implies that the gene 10 protein may interact with a host protein during phage development and that the abortive infection of T7 observed in S. sonnei D2 371-48 with T7+ phage may be a defect in head morphogenesis. Our studies also reveal that various T7 strains commonly contain deletions in nonessential regions. T7 ss--mutants selected after growth of T7+ on Shigella D2 371-48 often acquire a deletion in the 0.7 gene that is not necessary for the ss--phenotype. Finally, we have found a new nonessential region of the T7 chromosome that is located between 33 and 35.5% of the T7 genome length.     

Identification of bacteriophage T4D gene products 26 and 51 as baseplate hub structural components

Products of two bacteriophage T4D genes, 26 and 51, both known to be essential for the formation of the central hub of the phage tail baseplate, have been partially characterized chemically, and their biological role has been examined. The gene 26 product was found to be a protein with a molecular size of 41,000 daltons and the gene 51 product a protein of 16,500 daltons. The earlier proposal (L. M. Kozloff and J. Zorzopulos, J. Virol. 40:635-644), from observations of a 40,000-dalton protein in labeled hubs, that the gene 26 product is a structural component of the baseplate, has been confirmed. The gene 51 product, not yet detected in phage particles, appears from indirect evidence also to be a structural component of the baseplate hub. These current conclusions about the gene 26 and 51 products are based on properties of T4 mutant particles containing altered gene 26 or 51 products and include (i) changes in heat lability, (ii) changes in adsorption rates, and (iii) changes in plating efficiencies on different hosts, and with the results of previous isotope incorporation experiments indicate that T4 particles contain three copies of the gene 26 product and possibly one or at most two copies of the gene 51 product. Properties of these mutant particles indicate that the gene 26 product, together with the other hub components such as the gene 28 product, plays a critical role in phage DNA injection into the host cell, whereas the 51 product seems essential in initiating baseplate hub assembly.     

Bacteriophage T4 Virion Baseplate Thymidylate Synthetase and Dihydrofolate Reductase

Additional evidence is presented that both the phage T4D-induced thymidylate synthetase (gp td) and the T4D-induced dihydrofolate reductase (gp frd) are baseplate structural components. With regard to phage td it has been found that: (i) low levels of thymidylate synthetase activity were present in highly purified preparations of T4D ghost particles produced after infection with td⁺, whereas particles produced after infection with td⁻ had no measurable enzymatic activity; (ii) a mutation of the T4D td gene from td^ts to td⁺ simultaneously produced a heat-stable thymidylate synthetase enzyme and heat-stable phage particles (it should be noted that the phage baseplate structure determines heat lability); (iii) a recombinant of two T4D mutants constructed containing both td^ts and frd^ts genes produced particles whose physical properties indicate that these two molecules physically interact in the baseplate. With regard to phage frd it has been found that two spontaneous revertants each of two different T4D frd^ts mutants to frd⁺ not only produced altered dihydrofolate reductases but also formed phage particles with heat sensitivities different from their parents. Properties of T4D particles produced after infection with parental T4D mutants presumed to have a deletion of the td gene and/or the frd gene indicate that these particles still retain some characteristics associated with the presence of both the td and the frd molecules. Furthermore, the particles produced by the deletion mutants have been found to be physically different from the parent particles.     

Chemically Induced Cofactor Requirement for Bacteriophage T4D

The treatment of bacteriophage T4D with 2-hydroxy-5-nitrobenzyl bromide, a specific reagent for alkylating the indole ring of tryptophan residues, converts these particles from a cofactor-independent form to a cofactor-sensitive form. These treated T4D particles phenotypically resemble T4B particles in certain respects. Their ability to form plaques on minimal medium plates is increased by the addition of l-tryptophan and is inhibited by the addition of indole. In liquid medium, their rate of adsorption is dependent on the presence of the cofactor l-tryptophan. l-Tryptophan-requiring phage have been produced by in vitro assembly of treated tail-fiberless particles of a T4D amber mutant plus untreated tail fiber preparation. When treated tail fibers were used with untreated tail-fiberless particles, the newly assembled particles did not require cofactor. A model of the tail structure of all the T-even bacteriophages is presented which postulates that the active configuration of the tail fibers requires that there be either (i) an endogenous tryptophan residue of the phage particle itself or (ii) an exogenously added l-tryptophan molecule complexed with a specific tryptophan receptor site, most likely on the phage base plate.     

Analysis of T4 bacteriophage deletion mutants that lack td and frd genes.

The roles of bacteriophage T4-encoded thymidylate synthase and dihydrofolate reductase as virion structural components have been further investigated. Two mutants, del(63-32)7 and del(63-32)9, bearing deletions in the gene 63 to 32 region of the T4 genome, were characterized by Southern blotting analysis, as well as by enzyme and immunological assays. Our results have confirmed the original report of Homyk and Weil (Virology 61:505-523, 1974) that del7 and del9 each carries a deletion of about 4.0 kilobases, which totally eliminates the frd gene, encoding dihydrofolate reductase, and the td gene, encoding thymidylate synthase. With the well-characterized deletion mutants, along with newly prepared antisera against T4-encoded thymidylate synthase and dihydrofolate reductase, we have reevaluated the experimental results supporting the idea that T4-induced dihydrofolate reductase and thymidylate synthase are essential T4 baseplate components and antigenic determinants of phage particles. These deletion mutant phages are not targets for neutralization by antisera against either dihydrofolate reductase or thymidylate synthase purified from cloned genes. Furthermore, these newly prepared antisera also cannot neutralize the infectivity of T4D. Those results suggest that the phage-neutralizing components in the old antisera used in the earlier studies were not antibodies against either dihydrofolate reductase or thymidylate synthase but were antibodies against minor components of the purified enzyme preparations. Study of the biological properties of the deletion mutants indicates that T4-induced thymidylate synthase and dihydrofolate reductase play significant roles in growth of the phage beyond their known roles in nucleotide biosynthesis, even though they are apparently not essential for phage viability. The deletion mutants should be useful in defining these roles.     

Zinc uptake and incorporation into proteins in T4D bacteriophage-infected Escherichia coli.

The metabolism of Zn2+ in Escherichia coli infected with T4D bacteriophage and various T4D mutants has been examined. E. coli B infected with T4D, and all T4D mutants except T4D 12-, took up zinc ions at a rate identical to that of uninfected cells. E. coli B infected with T4D 12- had a markedly decreased rate of zinc uptake. The incorporation of zinc into proteins of infected cells has also been studied. T4D phage infection was found to shut off the synthesis of all bacterial host zinc metalloproteins while allowing the formation of viral-induced zinc proteins. The amount of zinc incorporated into viral proteins was affected by the absence of various T4D gene products. Cells infected with T4D 12-, and to a much less extent those infected with T4D 29-, incorporated the least amount of zinc into proteins, while cells infected with T4D 11- and T4D 51- incorporated increased amounts of zinc into the zinc metalloproteins. In cells infected with T4D 11- and 51- most of the zinc protein was found to be the product of gene 12. The marked effect of infection of E. coli with T4D 12- on both zinc uptake and zinc incorporation into protein supports the conclusion that T4D gene 12 protein is a zinc metalloprotein. Additionally, these observations have indicated that this metalloprotein interacts with host cell membrane.     

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.     

Bacterial ice nucleation activity after T4 bacteriophage infection.

The changes in ice nucleation activity of transformed Ina+ Escherichia coli K12 after infection with T4D bacteriophage have been examined. Within 2 min after infection class A nucleation activity (measured at -4 degrees C) fell about 100-1000-fold whilst class B (measured at -5.5 degrees C) and class C (measured at -9 degrees C) nucleation activities increased 50-100-fold and then rapidly decreased. These changes also occurred after interaction with T4D ghost particles or T4D 11-/12- particles. Since ghost particles lack DNA and 11-/12- particles lack short tail fibres, the T4D particles appear to be exerting their effect by the attachment of the phage long tail fibres to the cell. The changes were not influenced by the addition of chloramphenicol.     

Assembly of Bacillus subtilis phage phi29. 1. Mutants in the cistrons coding for the structural proteins.

The effect of mutations in the cistrons coding for the phage structural proteins has been studied by analyzing the phage-related structures accumulated after restrictive infection. Infection with susmutants in cistron 8, lacking both the major head and the fiber protein, does not produce any phage-related structure, suggesting a single route for the assembly of phage phi29; infection with ts mutants in this cistron produces isometric particles. Mutants is cistron 9, coding for the tail protein, TP1, produce DNA-free prolate heads with an internal core; these particles are abortive and contain the head proteins HPO, HP1 and HP3, the upper collar protein NP2 and the nonstructural proteins p7, p15 and p16. Mutants in cistron 10, coding for the upper collar protein, NP2, produce DNA-free isometric heads also with an internal core; they contain the head proteins and the nonstructural protein p7, suggesting that this protein forms the internal core. Mutants in cistrons 11 and 12, coding for the lower collar protein, NP3, and the neck appendages, NP1, respectively, give rise to the formation of DNA-containing normal capsids and DNA-free prolate particles, more rounded at the corners than the normal capsids and with an internal core; the DNA-containing 11-particles are formed by the head proteins and the upper collar protein; the DNA-free 11-particles contain, besides these proteins, the nonstructural protein p7 and a small amount of proteins p15 and 16. The DNA-containing 12-particles have all the normal phage structural proteins except the neck appendages, formed by protein NP1; the DNA-free particles are similar to the DNA-free 11-particles. After restricitive infection mutant sus14(1241) has a delayed lysis phenotype and produces a phage burst higher than normal, after artificial lysis. It produces DNA-containing particles, identical to wild-type phage, which have all the normal phage structural proteins, and DNA-free prolate particles, more rounded at the corners than the final phage particles and with an internal core; the last particles contain the same proteins as the DNA-free 11 or 12-particles. These particles could represent a prohead state, ready for DNA encapsulation. None of the DNA-containing particles have the nonstructural proteins p7, p15 or p16, suggesting that these proteins are released from the proheads upon DNA encapsulation.     

T-even-type bacteriophages use an adhesin for recognition of cellular receptors

Protein 38 of the Escherichia coli phage T4 is thought to be required catalytically for the assembly of the long tail fibers of this phage. It is shown that this protein of phage T2 and the T-even-type phage K3 and Ox2 act differently. It was found that NH2-terminal fragments of the protein, expressed from cloned fragments of gene 38 of phage K3, bind to gene 38 amber mutants of phage T2. Such phage or T2 gene 38 amber mutants, grown on a non-permissive host, possess a complete set of six tail fibers but are non-infectious. Both types of non-infectious phage could be repaired by incubation with an extract of cells harboring a cloned gene 38 of a host range mutant of phage K3, K3hx. The repaired phages had the host range of K3hx and not of T2. Immuno-electron microscopy showed that protein 38 is located at the free ends of the long tail fibers of phages T2, K3 and Ox2. The protein serves the recognition of the cellular receptor, i.e. it acts as an adhesin.     

Identification of T4 gene 25 product, a component of the tail baseplate, as a 15K lysozyme

Summary The proteins synthesized in Escherichia coli B cells after infection with various T4 bacteriophage tail baseplate mutants were analysed by the immunoblotting method for the presence of the 15 Kilodalton lysozyme found in phage T4 particles. Using three different antisera: anti-phage, anti-baseplate and anti-15K lysozyme, it has been found that the 15K lysozyme is not present in lysates of bacteria infected with T4 gene 25 amber mutants. The 15K lysozyme was also found to be expressed in E. coli B cells transformed with a plasmid containing only a small portion of the T4 genome but which included T4 gene 25. These observations indicate that the 15K lysozyme is the gene 25 product.     

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.