A component of the side tail fiber of Escherichia coli bacteriophage lambda can functionally replace the receptor-recognizing part of a long tail fiber protein of the unrelated bacteriophage T4.

The distal part of the long tail fiber of Escherichia coli bacteriophage T4 consists of a dimer of protein 37. Dimerization requires the catalytic action of protein 38, which is encoded by T4 and is not present in the virion. It had previously been shown that gene tfa of the otherwise entirely unrelated phage lambda can functionally replace gene 38. Open reading frame (ORF) 314, which encodes a protein that exhibits homology to a COOH-terminal area of protein 37, is located immediately upstream of tfa. The gene was cloned and expressed in E. coli. An antiserum against the corresponding polypeptide showed that it was present in phage lambda. The serum also reacted with the long tail fibers of phage T4 near their free ends. An area of the gene encoding a COOH-terminal region of ORF 314 was recombined, together with tfa, into the genome of T4, thus replacing gene 38 and a part of gene 37 that codes for a COOH-terminal part of protein 37. Such T4-lambda hybrids, unlike T4, required the presence of outer membrane protein OmpC for infection of E. coli B. An ompC missense mutant of E. coli K-12, which was still sensitive to T4, was resistant to these hybrids. We conclude that the ORF 314 protein represents a subunit of the side tail fibers of phage lambda which probably recognize the OmpC protein. ORF 314 was designated stf (side tail fiber). The results also offer an explanation for the very unusual fact that, despite identical genomic organizations, T4 and T2 produce totally different proteins 38. An ancestor of T4 from the T2 lineage may have picked up tfa and stf from a lambdoid phase, thus possibly demonstrating horizontal gene transfer between unrelated phage species.     

DNA sequences of the tail fiber genes of bacteriophage P2: evidence for horizontal transfer of tail fiber genes among unrelated bacteriophages.

We have determined the DNA sequence of the bacteriophage P2 tail genes G and H, which code for polypeptides of 175 and 669 residues, respectively. Gene H probably codes for the distal part of the P2 tail fiber, since the deduced sequence of its product contains regions similar to tail fiber proteins from phages Mu, P1, lambda, K3, and T2. The similarities of the carboxy-terminal portions of the P2, Mu, ann P1 tail fiber proteins may explain the observation that these phages in general have the same host range. The P2 H gene product is similar to the products of both lambda open reading frame (ORF) 401 (stf, side tail fiber) and its downstream ORF, ORF 314. If 1 bp is inserted near the end of ORF 401, this reading frame becomes fused with ORF 314, creating an ORF that may represent the complete stf gene that encodes a 774-amino-acid-long side tail fiber protein. Thus, a frameshift mutation seems to be present in the common laboratory strain of lambda. Gene G of P2 probably codes for a protein required for assembly of the tail fibers of the virion. The entire G gene product is very similar to the products of genes U and U' of phage Mu; a region of these proteins is also found in the tail fiber assembly proteins of phages TuIa, TuIb, T4, and lambda. The similarities in the tail fiber genes of phages of different families provide evidence that illegitimate recombination occurs at previously unappreciated levels and that phages are taking advantage of the gene pool available to them to alter their host ranges under selective pressures.     

Localization of the T4 phage ribonucleotide reductase B1 subunit gene and the nucleotide sequence of its upstream and 5' coding regions

The nucleotide (nt) sequence in a 757-bp [corrected] segment downstream from the intron-containing T4 phage thymidylate synthase gene (td) has been determined. This region was found to contain two open reading frames (ORFs). The first ORF(ORF2) [corrected] 261 bp [corrected] in length, is 24 [corrected] nt downstream from the td gene. The second ORF(ORF3) [corrected]) is 200 bp long at 558 [corrected] nt from the td gene and extends to the end of the Eco RI fragment. The amino acid (aa) sequence (66 aa residues) deduced from the second truncated ORF shows 59% homology to the sequence of the N-terminal portion of the ribonucleotide reductase large subunit of either Escherichia coli (B1 subunit) or mouse (M1 subunit). This tentatively identifies the truncated gene to be the 5' end of the T4 phage ribonucleotide reductase subunit B1 (nrdA) gene and pinpoints its exact location on the T4 phage genomic map. Southern hybridization analysis suggests good sequence homology among the nrdA genes of various T-even phages.     

Unexpected relationships between bacteriophage lambda hypothetical proteins and bacteriophage T4 tail-fiber proteins

Hypothetical lambda protein ORF314 shows significant homology with the carboxyl end of phage T4 tail-fiber protein gp37. Homology can also be demonstrated between hypothetical lambda protein ORF194 and a fragment of bacteriophage T4 protein gp38. This sequence homology is also reflected in the genomic sequences of these two phages.     

An open reading frame in the Escherichia coli bacteriophage lambda genome encodes a protein that functions in assembly of the long tail fibers of bacteriophage T4.

Assembly of the long tail fibers of the Escherichia coli bacteriophage T4 requires the catalytic action of two auxiliary proteins. It was found that a gene of the entirely unrelated phage lambda codes for a protein which can substitute for one of these T4 polypeptides, protein 38. The lambda gene was designated tfa (tail fiber assembly). Protein 38 consists of 183 residues, and the Tfa protein consists of 194 residues; the two polypeptides are about 40% homologous. Although the tfa gene is dispensable for the growth of phage lambda, these results indicate that it may have a function in lambda morphogenesis.     

Llama antibodies against a lactococcal protein located at the tip of the phage tail prevent phage infection

Bacteriophage p2 belongs to the most prevalent lactococcal phage group (936) responsible for considerable losses in industrial production of cheese. Immunization of a llama with bacteriophage p2 led to higher titers of neutralizing heavy-chain antibodies (i.e., devoid of light chains) than of the classical type of immunoglobulins. A panel of p2-specific single-domain antibody fragments was obtained using phage display technology, from which a group of potent neutralizing antibodies were identified. The antigen bound by these antibodies was identified as a protein with a molecular mass of 30 kDa, homologous to open reading frame 18 (ORF18) of phage sk1, another 936-like phage for which the complete genomic sequence is available. By the use of immunoelectron microscopy, the protein is located at the tip of the tail of the phage particle. The addition of purified ORF18 protein to a bacterial culture suppressed phage infection. This result and the inhibition of cell lysis by anti-ORF18 protein antibodies support the conclusion that the ORF18 protein plays a crucial role in the interaction of bacteriophage p2 with the surface receptors of Lactococcus lactis.     

DNA sequence of the tail fibre genes 36 and 37 of bacteriophage T4

We present here the DNA sequence of the tail fibre genes 36 and 37 of bacteriophage T4. The products of these genes form the major part of the 800 Å long distal half tail fibre of the phage. Restriction fragments of the DNA were subcloned in M13 phage and sequenced by the dideoxy sequencing method. A marker rescue technique was developed to allow rapid genetic identification of the particular T4 fragment carried by a given M13 clone, using the many T4 mutants available in the tail fibre region. This ensured little duplication in sequencing the M13 clones, and also allowed us to correlate the sequence with the genetic map. Predicted protein sequences are given for genes 36 and 37. Secondary structure prediction rules, when applied to the gene 37 protein, indicate the likely presence of regions of alternating β-strand and β-turn. This is consistent with previous structural analysis of the distal half fibre, which proposed an antiparallel β-structure running normal to the fibre axis, although the folding appears much less regular than anticipated.     

Structural conservation of the myoviridae phage tail sheath protein fold

Bacteriophage phiKZ is a giant phage that infects Pseudomonas aeruginosa, a human pathogen. The phiKZ virion consists of a 1450?? diameter icosahedral head and a 2000??-long contractile tail. The structure of the whole virus was previously reported, showing that its tail organization in the extended state is similar to the well-studied Myovirus bacteriophage T4 tail. The crystal structure of a tail sheath protein fragment of phiKZ was determined to 2.4?? resolution. Furthermore, crystal structures of two prophage tail sheath proteins were determined to 1.9 and 3.3?? resolution. Despite low sequence identity between these proteins, all of these structures have a similar fold. The crystal structure of the phiKZ tail sheath protein has been fitted into cryo-electron-microscopy reconstructions of the extended tail sheath and of a polysheath. The structural rearrangement of the phiKZ tail sheath contraction was found to be similar to that of phage T4.     

Mutational analysis of the phage T4 morphogenetic 31 gene, whose product interacts with the Escherichia coli GroEL protein

The phage T4 morphogenetic gene 31 has been sequenced. Its deduced gene product is a polypeptide of 111 aa, with a predicted Mr of 12064 and a pI of 4.88. The proof that the assigned open reading frame (ORF) encodes Gp31 rests on the sequencing of two known gene 31 amber mutations, amN54 and NG71, demonstrating that these mutations result in translational termination within the assigned ORF. Furthermore, the sequencing of four different T4 epsilon mutations, isolated on the basis of allowing the phage to propagate on Escherichia coli groEL- hosts, showed that they are either missense mutations or 3-bp deletions in the gene 31 reading frame. The sequencing of neighboring DNA revealed the presence of five other ORFs, one of which overlaps gene 31 substantially, but in the opposite orientation.     

Programmed translational frameshift in the bacteriophage P2 FETUD tail gene operon

The major structural components of the P2 contractile tail are encoded in the FETUD tail gene operon. The sequences of genes F(I) and F(II), encoding the major tail sheath and tail tube proteins, have been reported previously (L. M. Temple, S. L. Forsburg, R. Calendar, and G. E. Christie, Virology 181:353-358, 1991). Sequence analysis of the remainder of this operon and the locations of amber mutations Eam30, Tam5, Tam64, Tam215, Uam25, Uam77, Uam92, and Dam6 and missense mutation Ets55 identified the coding regions for genes E, T, U, and D, completing the sequence determination of the P2 genome. Inspection of the DNA sequence revealed a new open reading frame overlapping the end of the essential tail gene E. Lack of an apparent translation initiation site and identification of a putative sequence for a programmed translational frameshift within the E gene suggested that this new reading frame (E') might be translated as an extension of gene E, following a -1 translational frameshift. Complementation analysis demonstrated that E' was essential for P2 lytic growth. Analysis of fusion polypeptides verified that this reading frame was translated as a -1 frameshift extension of gpE, with a frequency of approximately 10%. The arrangement of these two genes within the tail gene cluster of phage P2 and their coupling via a translational frameshift appears to be conserved among P2-related phages. This arrangement shows a striking parallel to the organization in the tail gene cluster of phage lambda, despite a lack of amino acid sequence similarity between the tail gene products of these phage families.     

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.     

Crystal structure of Bacillus subtilis SPP1 phage gp22 shares fold similarity with a domain of lactococcal phage p2 RBP

SPP1 is a siphophage infecting the gram‐positive bacterium Bacillus subtilis. It is constituted by an icosahedric head and a long non‐contractile tail formed by gene products (gp) 17–21. A group of 5 small genes (gp 22–24.1) follows in the genome those coding for the main tail components. However, the belonging of the corresponding gp to the tail or to other parts of the phage is not documented. Among these, gp22 lacks sequence identity to any known protein. We report here the gp22 structure solved by X‐ray crystallography at 2.35 Å resolution. We found that gp22 is a monomer in solution and possesses a significant structural similarity with lactococcal phage p2 ORF 18 N‐terminal “shoulder” domain.     

Receptor-recognizing proteins of T-even type bacteriophages. The receptor-recognizing area of proteins 37 of phages T4 TuIa and TuIb

Escherichia coli phages of the T4 family (T4, TuIa, TuIb) recognize their cellular receptors by means of a C-terminal region of protein 37; a dimer of this polypeptide (1026 residues in T4) is located at the distal part of the long tail fibers. Virions of the T2 family use protein 38 (which is attached to the free end of protein 37) for this purpose. The corresponding areas of genes 37 belonging to TuIa and TuIb were cloned and sequenced. Comparison of the deduced protein primary structures, including those of T4 and lambda Stf (Stf most likely representing a subunit of the side tail fibers of phage lambda) showed that an area of 70 to 100 residues is characterized by very variable sequences, while the sequences of the adjacent 43 to 44 C-terminal residues as well as those upstream from the variable region are highly homologous. The variable regions are flanked and interrupted seven or eight times by the motif His-x-His-y, with x and y most often being Ser or Thr; furthermore, the locations of these repeated tetrapeptides are conserved. Using hybrid phages obtained by recombination of one phage with cloned fragments of gene 37 of another, it could be shown that the area of this gene encoding receptor specificity includes the variable area. The situation is analogous to the known receptor-recognizing region of proteins 38 belonging to the T2-type family, except that the repeating sequence is of a different nature. In T4, receptor specificity is coded for by 382 base-pairs of the 3'-end of the gene, starting exactly at the variable area. It was found that T4 can use the outer membrane protein OmpC or lipopolysaccharide as receptors with the same efficiency, and it is proposed that the 70 residues of the variable part of the protein serve to bind to both ligands.     

DNA sequence heterogeneity in the genes of T-even type Escherichia coli phages encoding the receptor recognizing protein of the long tail fibers

Summary Genes (g) 36 and 37 code for the proteins of the distal half of the long tail fibers of phage T4, gene product (gp) 35 links the distal half to the proximal half of this fiber. The receptor, lipopolysaccharide, most likely is recognized by gp37. Using as probe a restriction fragment consisting of most of g36 and g37 of phage T4 the genes corresponding to g35, g36, and g37 of phages T2 and K3 (using the E. coli outer membrane proteins OmpF and OmpA, respectively, as receptors) have been cloned into plasmid pUC8. Partial DNA sequences of g37 of phage K3 have been determined. One area, corresponding to residues 157 to 210 of the 1026 residue gp37 of phage T4, codes for an identical sequence in phage K3. Another area corresponds to residues 767 to 832 of the phage T4 sequence. Amino acid residues 767 to 832 of the phage T4 sequence are almost identical in both phage proteins while the remainder is rather different. DNAs of T2, T4, T6, another T-even type phage using protein Tsx as a receptor, and 10 different T-even type phages using the OmpA protein as a receptor have been hybridized with restriction fragments covering various parts of the g37 area of phage K3. With probably only one exception all of the 13 phages tested possess unique genes 37 and within the majority of these, sequences highly homologous to parts of g37 of K3 are present in a mosaic type fashion. Other regions of these genes 37 did not show any homology with the K3 probes; in case of the OmpA specific phage M1 absence of homology was evident in most of its g37 even including the area that should serve for recognition of the cellular receptor. In sharp contrast to this situation it was found that a major part of the gene (g23) coding for the major capsid protein is rather highly conserved in all phages studied. The extreme variability in sequences existing in genes 37 might be a consequence of phages during evolution being able to more or less drastically change their receptor specifities.     

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.     

Characterization and cloning of gene 5 of Bacillus subtilis phage phi 29

Sequencing of the phi 29 DNA region [open reading frames (ORFs) 12, 11 and 10] between genes 6 and 4 of the mutant ts5(219) showed that a G in the wild-type phage had been changed to an A in the mutant at position 218 of ORF 10 indicating that this ORF corresponds to gene 5. ORF 10 was cloned in plasmid pPLc28 under the control of the PL promoter of phage lambda and, after heat induction of the Escherichia coli cells carrying the recombinant plasmid pGM26, a 12-kDa protein was overproduced, accounting for about 5% of the de novo synthesized protein. Introduction of a nonsense mutation in ORF 10 indicated that the latter codes for the 12-kDa protein. The predicted secondary structure, the hydrophilicity values and the antigenic regions of protein p5 are discussed.     

Identification of related genes in phages phi 80 and P22 whose products are inhibitory for phage growth in Escherichia coli IHF mutants.

Bacteriophage lambda grows in both IHF+ and IHF- host strains, but the lambdoid phage phi 80 and hybrid phage lambda (QSRrha+)80 fail to grow in IHF- host strains. We have identified a gene, rha, in the phi80 region of the lambda(QSRrha+)80 genome whose product, Rha, inhibits phage growth in an IHF- host. A search of the GenBank database identified a homolog of rha, ORF201, a previously identified gene in phage P22, which similarly inhibits phage growth in IHF- hosts. Both rha and ORF201 contain two possible translation start sites and two IHF binding site consensus sequences flanking the translation start sites. Mutations allowing lambda (QSRrha+)80 and P22 to grow in IHF- hosts map in rha and ORF201, respectively. We present evidence suggesting that, in an IHF+ host, lambda(QSRrha+)80 expresses Rha only late in infection but in an IHF- host the phage expresses Rha at low levels early in infection and at levels higher than those in an IHF+ host late in infection. We suspect that the deregulation of rha expression and, by analogy, ORF201 expression, is responsible for the failure of phi80, lambda(QSRrha+)80, and P22 to grow in IHF mutants.