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.     

The role of structural changes in T4 bacteriophage tail proteins

Conformational changes in bacteriophage tail proteins after heating and ionic strength alteration leading to dissociation of tail sheath have been studied using protein fluorescence, differential scanning microcalorimetry and electron microscopy methods. Autonomous structural changes in tube-baseplate proteins have been revealed. They take place under the same conditions as those which release the bonds holding the sheath protein subunits to those of the tube in isolated sheathed tails. The conformational changes in the tube-baseplates are reversible similarly to the process of assembly and disassembly of the extended sheath. Morphological changes in the tube have been found at the temperature above the transition registered by protein fluorescence but not by calorimetry. This suggests that revealed spectral alterations reflect changes in quaternary structure of tail tube in particular.     

Bacteriophage T4 tail length is controlled by its baseplate

Purified T4 baseplate, when treated with high concentrations of pancreatic RNase, are inactive in $\text{in}\text{vitro}$ complementation assays. Their ability to initiate tail tube assembly is not altered; but the most probably length of the tube-baseplate formed is only 800A, compared to 1000A, the normal tube length, when untreated baseplates are used. Thus, baseplates help to regulate tube length, possibly by a template mechanism. Several minor baseplate proteins which may be involved in determining the length, including gp54, are missing from RNase - treated base-plates. These effects may be due to an unidentified protease contaminant of the RNase, since they are inhibited by phenylmethane sulfonyl fluoride.     

Molecular assembly and structure of the bacteriophage T4 tail

The tail of bacteriophage T4 undergoes large structural changes upon infection while delivering the phage genome into the host cell. The baseplate is located at the distal end of the contractile tail and plays a central role in transmitting the signal to the tail sheath that the tailfibers have been adsorbed by a host bacterium. This then triggers the sheath contraction. In order to understand the mechanism of assembly and conformational changes of the baseplate upon infection, we have determined the structure of an in vitro assembled baseplate through the three-dimensional reconstruction of cryo-electron microscopy images to a resolution of 3.8 Å from electron micrographs. The atomic structure was fitted to the baseplate structure before and after sheath contraction in order to elucidate the conformational changes that occur after bacteriophage T4 has attached itself to a cell surface. The structure was also used to investigate the protease digestion of the assembly intermediates and the mutation sites of the tail genes, resulting in a number of phenotypes.     

Bacteriophage T4 self-assembly: localization of gp3 and its role in determining tail length

Gene 3 of bacteriophage T4 participates at a late stage in the T4 tail assembly pathway, but the hypothetical protein product, gp3, has never been identified in extracts of infected cells or in any tail assembly intermediate. In order to overcome this difficulty, we expressed gp3 in a high-efficiency plasmid expression vector and subsequently purified it for further analysis. The N-terminal sequence of the purified protein showed that the initial methionine had been removed. Variant C-terminal amino acid sequences were resolved by determining the cysteine content of the protein. The molecular mass of 20.6 kDa for the pure protein was confirmed by Western blotting, using a specific anti-gp3 serum for which the purified protein was the immunogen. We also demonstrated, for the first time, the physical presence of gp3 in the mature T4 phage particle and localized it to the tail tube. By finding a nonleaky, nonpermissive host for a gene 3 mutant, we could clearly demonstrate a new phenotype: the slow, aberrant elongation of the tail tube in the absence of gp3.     

Characterization of the helper proteins for the assembly of tail fibers of coliphages T4 and lambda.

Assembly of tail fibers of coliphage T4 requires the action of helper proteins. In the absence of one of these, protein 38 (p38), p37, constituting the distal part of the long tail fiber, fails to oligomerize. In the absence of the other, p57, p34 (another component of the long tail fiber), p37, and p12 (the subunit of the short tail fiber) remain unassembled. p38 can be replaced by the Tfa (tail fiber assembly) protein (pTfa) of phage lambda, which has the advantage of remaining soluble even when produced in massive amounts. The mechanisms of action of the helpers are unknown. As a first step towards elucidation of these mechanisms, p57 and pTfa have been purified to homogeneity and have been crystallized. The identity of gene 57 (g57), not known with certainty previously, has been established. The 79-residue protein p57 represents a very exotic polypeptide. It is oligomeric and acidic (an excess of nine negative charges). It does not contain Phe, Trp, Tyr, His, Pro, and Cys. Only 25 N-terminal residues were still able to complement a g57 amber mutant, although with a reduced efficiency. In cells overproducing the protein, it assumed a quasi-crystalline structure in the form of highly ordered fibers. They traversed the cells longitudinally (and thus blocked cell division) with a diameter approaching that of the cell and with a hexagonal appearance. The 194-residue pTfa is also acidic (an excess of 13 negative charges) and is likely to be dimeric.     

Letter: Bacteriophage T4D-induced proteinase

The change of trypsin-like proteolytic activity in Eacherichia coli cells infected with bacteriophage T4D has been investigated. Synthetic α,N-benzoyl-d,l-arginine p-nitroanilide was used as an enzyme substrate. Proteinase activity of the host cell was inhibited 30% eight minutes after infection. Later, the activity of the phage-induced proteinase increased and a maximum (40%) increment was reached 18 minutes after infection. It was demonstrated that the newly formed enzyme had a pH optimum (6.7) which differed from the optima of proteolytic enzymes of the host cell.     

Cleavage of head and tail proteins during bacteriophage T5 assembly: selective host involvement in the cleavage of a tail protein

Electrophoresis studies showed that at least three phage-specified proteins undergo proteolytic cleavage during the development of bacteriophage T5. One of these proteins has a molecular weight of about 135,000 and the product of this cleavage reaction is a minor component of the T5 tail, having a molecular weight of about 128,000. All of the tail-defective T5 mutants studied in this report failed to induce this cleavage reaction under restrictive conditions. This reaction also failed to occur in Escherichia coli groEA639 and groEA36 infected with wild type T5. Examination of lysates of infected groE cells in the electron microscope revealed the presence of filled and empty heads as well as tubular head structures, but no tails were detected. The filled heads were able to combine with separately prepared T5 tails in vitro to form infectious phage particles. Therefore, propagation of T5 in these groE mutants is prevented primarily by a specific block in tail assembly. A T5 mutant, T5?6, was isolated, which has the capacity to propagate in these groE hosts. The gene locus in T5?6 was mapped.The second T5 protein which is cleaved has a molecular weight of 50,000 and is related to head morphogenesis. Treatment of infected cells with l-canavanine (50 μg/ml) inhibited cleavage of this polypeptide. Only small quantities of the major head protein (32,000 mol. wt) were produced in these treated cells. Treatment with canavanine lead to production of tubular heads. The major protein component of partially purified tubular heads has a molecular weight of 50,000. Cells infected with T5 amber H30b, a mutant defective in head gene D20, does not produce the 50,000 and 32,000 molecular weight proteins. These findings suggest that the 50,000 molecular weight protein undergoes cleavage to form the major head polypeptide. A third T5 protein is cleaved to form a minor head component with a molecular weight of 43,000 and its cleavage is linked to that involving the major head protein.     

Protein interactions in the assembly of the tail of bacteriophage T4

Protein interactions in the assembly of the baseplate have been investigated. The baseplate of the phage T4 tail consists of a hub and six wedges which surround the former. Both reversible and irreversible interactions were found. Reversible association includes gp5 and gp27 (gp: gene product) which form a complex in a pH-dependent manner and gp18 polymerization, i.e. the tail sheath formation depends on the ionic strength. These reversible interactions were followed by irreversible or tight binding which pulls the whole association reaction to complete the assembly. The wedge assembly is strictly ordered which means that if one of the seven wedge proteins is missing, the assembly proceeds to that point and the remaining molecules stay non-associated. The strictly sequential assembly pathway is suggested to be materialized by successive conformational change upon binding, which can be shown by proteolytic probe.     

Topology of the structural proteins of long tail fibers of phages T4D, DDVIh+ and DDVIh

Topology of the products of the genes 34, 35, 36 and 37 of the bacteriophage T4D long tail fibers were determined with the aid of monospecific antibodies. The antibodies against gene product 34 were the only to interact with the proximal part of long tail fibers, but the distal part bound the antibodies against 35, 36 and 37. Product of the gene 35 is located at the joint-site with the distal part and binds the distance not more than 75 A long. Gene product 36 is located between these of 35 and 37 and occupy the region about 150 A. The capability of the antibodies obtained against the above-mentioned proteins were tested ot bind with long tail fibers diagnostic phages DDVIh+ and DDVIh Shigella disentheriae. We could'nt mark any difference in binding of the antibodies against gene 34, 35 and 36 product with DDVI phages and T4D. The distal part of the fibers of DDVIh bound the antibodies against product of gene 37 as T4D. Nevertheless DDVIh+ possesses only few antigenic sites relative to product of gene 37 of T4. The changes in the distal part of long tail fibers of h-strain DDVI may lead to the broadening of the host specifity of this virus.     

Multiple-Tailed T4 Bacteriophage.

Smith, Kendall O. (Baylor University College of Medicine, Houston, Tex.), and Melvin Trousdale. Multiple-tailed T4 bacteriophage. J. Bacteriol. 90:796-802. 1965.-T4 phage particles which appeared to have multiple-tails were observed. Experiments were designed to minimize the possibility that superimposed particles might account for this appearance. Double-tailed particles occurred at a frequency as high as 10%. Triple- and quadruple-tailed particles were extremely rare. All attempts to isolate pure lines of multiple-tailed phage have failed. Multiple-tailed phage particles were produced in highest frequency by Escherichia coli cells in the logarithmic growth phase which had been inoculated at a multiplicity of about 2.