Purification, characterization and reassembly of the bacteriophage T4D tail sheath protein P18

Self-Assembly of Tail Tube Protein of Bacteriophage vB_EcoS_NBD2 into Extremely Long Polytubes in E. coli and S. cerevisiae

Nucleotides, peptides and proteins serve as a scaffold material for self-assembling nanostructures. In this study, the production of siphovirus vB_EcoS_NBD2 (NBD2) recombinant tail tube protein gp39 reached approximately 33% and 27% of the total cell protein level in Escherichia coli and Saccharomyces cerevisiae expression systems, respectively. A simple purification protocol allowed us to produce a recombinant gp39 protein with 85%⁻90% purity. The yield of gp39 was 2.9 ± 0.36 mg/g of wet E. coli cells and 0.85 ± 0.33 mg/g for S. cerevisiae cells. The recombinant gp39 self-assembled into well-ordered tubular structures (polytubes) in vivo in the absence of other phage proteins. The diameter of these structures was the same as the diameter of the tail of phage NBD2 (~12 nm). The length of these structures varied from 0.1 µm to >3.95 µm, which is 23-fold the normal NBD2 tail length. Stability analysis demonstrated that the polytubes could withstand various chemical and physical conditions. These polytubes show the potential to be used as a nanomaterial in various fields of science.

The Robust Self-Assembling Tubular Nanostructures Formed by gp053 from Phage vB_EcoM_FV3

The recombinant phage tail sheath protein, gp053, from Escherichia coli infecting myovirus vB_EcoM_FV3 (FV3) was able to self-assemble into long, ordered and extremely stable tubular structures (polysheaths) in the absence of other viral proteins. TEM observations revealed that those protein nanotubes varied in length (~10–1000 nm). Meanwhile, the width of the polysheaths (~28 nm) corresponded to the width of the contracted tail sheath of phage FV3. The formed protein nanotubes could withstand various extreme treatments including heating up to 100 °C and high concentrations of urea. To determine the shortest variant of gp053 capable of forming protein nanotubes, a set of N- or/and C-truncated as well as poly-His-tagged variants of gp053 were constructed. The TEM analysis of these mutants showed that up to 25 and 100 amino acid residues could be removed from the N and C termini, respectively, without disturbing the process of self-assembly. In addition, two to six copies of the gp053 encoding gene were fused into one open reading frame. All the constructed oligomers of gp053 self-assembled in vitro forming structures of different regularity. By using the modification of cysteines with biotin, the polysheaths were tested for exposed thiol groups. Polysheaths formed by the wild-type gp053 or its mutants possess physicochemical properties, which are very attractive for the construction of self-assembling nanostructures with potential applications in different fields of nanosciences.

Foreword to 'Multiscale structural biology: biophysical principles and mechanisms underlying the action of bio-nanomachines', a special issue in Honour of Fumio Arisaka's 70th birthday

This issue of Biophysical Reviews, titled 'Multiscale structural biology: biophysical principles and mechanisms underlying the action of bio-nanomachines', is a collection of articles dedicated in honour of Professor Fumio Arisaka's 70th birthday. Initially, working in the fields of haemocyanin and actin filament assembly, Fumio went on to publish important work on the elucidation of structural and functional aspects of T4 phage biology. As his career has transitioned levels of complexity from proteins (hemocyanin) to large protein complexes (actin) to even more massive bio-nanomachinery (phage), it is fitting that the subject of this special issue is similarly reflective of his multiscale approach to structural biology. This festschrift contains articles spanning biophysical structure and function from the bio-molecular through to the bio-nanomachine level.

Contractile injection systems of bacteriophages and related systems

Contractile tail bacteriophages, or myobacteriophages, use a sophisticated biomolecular structure to inject their genome into the bacterial host cell. This structure consists of a contractile sheath enveloping a rigid tube that is sharpened by a spike-shaped protein complex at its tip. The spike complex forms the centerpiece of a baseplate complex that terminates the sheath and the tube. The baseplate anchors the tail to the target cell membrane with the help of fibrous proteins emanating from it and triggers contraction of the sheath. The contracting sheath drives the tube with its spiky tip through the target cell membrane. Subsequently, the bacteriophage genome is injected through the tube. The structural transformation of the bacteriophage T4 baseplate upon binding to the host cell has been recently described in near-atomic detail. In this review we discuss structural elements and features of this mechanism that are likely to be conserved in all contractile injection systems (systems evolutionary and structurally related to contractile bacteriophage tails). These include the type VI secretion system (T6SS), which is used by bacteria to transfer effectors into other bacteria and into eukaryotic cells, and tailocins, a large family of contractile bacteriophage tail-like compounds that includes the P. aeruginosa R-type pyocins.

Type VI secretion system sheath inter-subunit interactions modulate its contraction

Secretion systems are essential for bacteria to survive and manipulate their environment. The bacterial type VI secretion system (T6SS) generates the force needed for protein translocation by the contraction of a long polymer called sheath. The sheath is a six-start helical assembly of interconnected VipA/VipB subunits. The mechanism of T6SS sheath contraction is unknown. Here, we show that elongating the N-terminal VipA linker or eliminating charge of a specific VipB residue abolishes sheath contraction and delivery of effectors into target cells. Mass spectrometry analysis identified the inner tube protein Hcp, spike protein VgrG, and other components of the T6SS baseplate significantly enriched in samples of the stable non-contractile sheaths. The ability to lock the T6SS in the pre-firing state opens new possibilities for understanding its mode of action.

Most of it started with T4 phage and was then taken over

Professor Fumio Arisaka is one of the famous leaders in bacteriophage research, especially in the areas of protein biophysics and structural biology. Autonomous phage morphogenesis is a self-assembly process controlled by subunit-subunit interaction. Under this principle, Fumio has studied T4 tail assembly and morphology. He has also contributed structural information about T4 phage through a combination of X-ray structural analysis and three-dimensional image reconstruction using cryo-electron microscopy. Most of the development of ultracentrifugation applications for molecular assembly and phage morphogenesis research was also performed in Fumio's laboratory. Fumio is a pioneer of supramolecular protein assembly study, and his science continues in the research work of the approximately 150 people who had attended his final lecture at the Tokyo Institute of Technology.

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.

Type VI secretion system: secretion by a contractile nanomachine

The type VI secretion systems (T6SS) are present in about a quarter of all Gram-negative bacteria. Several key components of T6SS are evolutionarily related to components of contractile nanomachines such as phages and R-type pyocins. The T6SS assembly is initiated by formation of a membrane complex that binds a phage-like baseplate with a sharp spike, and this is followed by polymerization of a long rigid inner tube and an outer contractile sheath. Effectors are preloaded onto the spike or into the tube during the assembly by various mechanisms. Contraction of the sheath releases an unprecedented amount of energy, which is used to thrust the spike and tube with the associated effectors out of the effector cell and across membranes of both bacterial and eukaryotic target cells. Subunits of the contracted sheath are recycled by T6SS-specific unfoldase to allow for a new round of assembly. Live-cell imaging has shown that the assembly is highly dynamic and its subcellular localization is in certain bacteria regulated with a remarkable precision. Through the action of effectors, T6SS has mainly been shown to contribute to pathogenicity and competition between bacteria. This review summarizes the knowledge that has contributed to our current understanding of T6SS mode of action.

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.

Contractile tail machines of bacteriophages

Bacteriophages with contractile tails epitomize the concepts of "virus" and "phage" for many because the tails of these phages undergo a large conformational change - resembling the action of a syringe - upon the attachment to the host cell. The contractile tails belong to the recently recognized class of "contractile systems," which includes phage tails, their close relatives R-type pyocins, the bacterial type VI secretion system, and the virulence cassette of Photorhabdus. Their function is to deliver large proteins and/or DNA into the cytoplasm of a bacterial or eukaryotic cell. The structure of the core components of all contractile tail-like systems is conserved, but the corresponding genes have diverged to such a degree that the common ancestry can no longer be easily detected at the level of amino acid sequence. At present, it is unclear, whether the contractile systems originated in bacteria or in phages. This chapter describes the structure and function of phage contractile tails and compares them with other phage tails and with other known contractile systems.

Bacteriophage assembly

Bacteriophages have been a model system to study assembly processes for over half a century. Formation of infectious phage particles involves specific protein-protein and protein-nucleic acid interactions, as well as large conformational changes of assembly precursors. The sequence and molecular mechanisms of phage assembly have been elucidated by a variety of methods. Differences and similarities of assembly processes in several different groups of bacteriophages are discussed in this review. The general principles of phage assembly are applicable to many macromolecular complexes.

The tail sheath structure of bacteriophage T4: a molecular machine for infecting bacteria

The contractile tail of bacteriophage T4 is a molecular machine that facilitates very high viral infection efficiency. Its major component is a tail sheath, which contracts during infection to less than half of its initial length. The sheath consists of 138 copies of the tail sheath protein, gene product (gp) 18, which surrounds the central non-contractile tail tube. The contraction of the sheath drives the tail tube through the outer membrane, creating a channel for the viral genome delivery. A crystal structure of about three quarters of gp18 has been determined and was fitted into cryo-electron microscopy reconstructions of the tail sheath before and after contraction. It was shown that during contraction, gp18 subunits slide over each other with no apparent change in their structure.

Cell-free co-synthesis of protein nanoassemblies: tubes, rings, and doughnuts

We used a cell-free transcription/translation system to synthesize structural proteins of the T4 bacteriophage. We focused on two proteins that participate in the formation of the virus tail tube assembly. Synthesized separately, the proteins assembled into their in vivo forms, namely one polymerized into rigid hollow nanotubes approximately 20 nm thick and hundreds of nanometers long, the other assembled into 10 nm tube-capping hexameric rings. Co-synthesis of the two proteins, however, revealed a novel structure of a nanodoughnut with an outer diameter of approximately 50 nm and thickness of approximately 20 nm. Cell-free co-synthesis and assembly of T4 structural proteins can be extended in a combinatorial fashion. The addition of other structural genes offers control of native nanoassemblies and may reveal ones not observable by mixing purified components.

Processing of the tail lysozyme (gp5) of bacteriophage T4

The processing site of gp5 has been determined to be between residues Val-390 and His-391, instead of Ser-351 and Ala-352 as previously reported (H. Kanamaru, N. C. Gassner, N. Ye, S. Takeda, and F. Arisaka, J. Bacteriol. 181:2739-2744). Moreover, the maturation of gp5 is abolished by null mutations in other hub genes, indicating that cleavage requires the interactions of several baseplate proteins.

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

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

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Pulse-chase analysis of the in vivo assembly of the bacteriophage T4 tail

The in vivo assembly pathway of the complex tail of bacteriophage T4 virus was determined using pulse-chase analysis as a non-invasive alternative to the in vitro experiments previously used to map assembly. Bacteriophage T4 mutants defective in head assembly were used to infect cultures of Escherichia coli in order to study tail assembly in isolation. Beginning with the onset of late protein synthesis, the cultures were labeled continuously with [(3)H]leucine to normalize against subsequent sample losses. After completed tails had begun to accumulate at a constant rate, the cultures were pulsed with [(35)S]methionine, and then chased. Completed tails were purified at one minute intervals for the next 30 minutes and their proteins separated electrophoretically and counted by liquid scintillation. Total (35)S incorporation into each protein rose and then leveled off as the chase of unlabeled methionine flushed the label through the pools of soluble proteins and assembly intermediates and into completed tails. The inflection point in the sigmoidal (35)S-incorporation curve of each protein marks the maximal uptake of (35)S within that pool just before the effect of the chase becomes apparent and the curve begins to level off. The length of the delay in the apparent chase time reflects the position of that protein in the pathway. The closer the assembly point to the end of the pathway, the sooner the chase appears, revealing the relative order of assembly. As predicted, tail completion proteins such as gp18 (tail sheath) and 19 (tail tube) show the earliest inflection, while those earlier in the pathway take longer to chase. Of the 17 tail proteins analyzed, 14 are in agreement with the established in vitro pathway. The other three, gp15, gp10 and gp53, have helped us to develop a model that offers a plausible explanation for their altered chase times.

The C-terminal fragment of the precursor tail lysozyme of bacteriophage T4 stays as a structural component of the baseplate after cleavage

Tail-associated lysozyme of bacteriophage T4 (tail lysozyme), the product of gene 5 (gp 5), is an essential structural component of the hub of the phage baseplate. It is synthesized as a 63-kDa precursor, which later cleaves to form mature gp 5 with a molecular weight of 43,000. To elucidate the role of the C-terminal region of the precursor protein, gene 5 was cloned and overexpressed and the product was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoblotting, analytical ultracentrifugation, and circular dichroism. It was shown that the precursor protein tends to be cleaved into two fragments during expression and that the cleavage site is close to or perhaps identical to the cleavage site in the infected cell. The two fragments, however, remained associated. The lysozyme activity of the precursor or the nicked protein is about 10% of that of mature gp 5. Both the N-terminal mature tail lysozyme and the C-terminal fragment were then isolated and characterized by far-UV circular dichroism and analytical ultracentrifugation. The latter remained trimeric after dissociation from the N-terminal fragment and is rich in beta-structure as predicted by an empirical method. To trace the fate of the C-terminal fragment, antiserum was raised against a synthesized peptide of the last 12 C-terminal residues. Surprisingly, the C-terminal fragment was found in the tail and the phage particle by immunoblotting. The significance of this finding is discussed in relation to the molecular assembly and infection process.

Atomic force microscopy of bacteriophage T4 and its tube-baseplate complex

Bacteriophage T4 was imaged by atomic force microscopy with the finest resolution to date with a clear image of tail fibers of an estimated diameter of 2-3 nm. T4 phages were spread on a clean surface of silicon wafer and dried under air before observation with an atomic force microscope. The head, tail and tail fibers were routinely imaged with somewhat distorted dimensions. The ease of imaging isolated phage particles with a good resolution raised our expectation for the further use of AFM in biomedical applications.

GTPase activity of bacteriophage T4 sheath protein

We show by nuclear magnetic resonance studies that, following GTP hydrolysis during phage T4 sheath contraction, GDP remains bound to the sheath protein (gp18), whereas orthophosphate is released. gp18 in the contracted state has GTPase activity and can hydrolyse exogenous GTP; the reaction is calcium-dependent and displays high substrate specificity. The process comprises two steps: (1) displacement of GDP from gp18 by exogenous GTP, and (2) GTP hydrolysis proper. The first step appears to be rate-limiting and to be accelerated when the nucleotide-protein interaction is mechanically disrupted by sonication.

Physiological, morphological, and physicochemical characterization of a novel Escherichia coli bacteriophage, phage MM

A double-stranded DNA containing, T even-like, Escherichia coli bacteriophage, called MM, has been isolated from the local sewage and purified by polyethylene glycol precipitation followed by banding on a cesium chloride three-step gradient. It yields a burst size of 75 particles per infected cell, and has an adsorption coefficient of 3.3 x 10(-10) cm3/min and a latent period of 45 min. Electron microscopy of phage MM reveals an isometric icosahedral head, 92 nm long and 81 nm wide, and a 112-nm-long contractile tail with six pairs of 40-nm-long fibers attached to its baseplate. Phage MM appears similar to E. coli phage T4 or Salmonella phage O1. The density of phage MM in cesium chloride is 1.515 g/ml, and its total mass is 144 MDa. Gel electrophoresis of purified MM capsids displays two major capsid proteins in approximately equimolar amounts and with apparent molecular masses of 38 and 15 kDa. Similarly, purified MM tails yield two major polypeptides with apparent molecular masses of 55 and 16 kDa, most likely representing the major tail sheath and tail tube polypeptides. Its double-stranded DNA has a G-C content of 50%, a length of 131 kilobases (kb), and a mass of 89 MDa.

Structural studies of the contractile tail sheath protein of bacteriophage T4. 2. Structural analyses of the tail sheath protein, Gp18, by limited proteolysis, immunoblotting, and immunoelectron microscopy

The molecular structure of the T4 phage tail sheath protein, gp18, was studied by limited proteolysis, immunoblotting, and immunoelectron microscopy. Gp18 is extremely resistant to proteolysis in the assembled form of either extended or contracted sheaths, but it is readily cleaved by proteases in the monomeric form, giving rise to stable protease-resistant fragments. Limited proteolysis with trypsin gave rise to a trypsin-resistant fragment, Ala82-Lys316, with a molecular weight of 27K. Chymotrypsin- and thermolysin-resistant fragments were also mapped close to the trypsin-resistant region. The time course of trypsin digestion of the monomeric gp18 as monitored by SDS-polyacrylamide gel electrophoresis and immunoblotting of the gel revealed that the polypeptide chain consisting of 658 amino acid residues is sequentially cleaved at several positions from the C terminus. The N-terminal portion, Thr1-Arg81, was then removed to form the trypsin-resistant fragment. Immunoelectron microscopy revealed that the polyclonal antibodies against the trypsin-resistant fragment bound to the tail sheath. This supported the idea that at least part of the protease-resistant region of gp18 constitutes the protruding part of the sheath protein as previously revealed with three-dimensional image reconstruction from electron micrographs by Amos and Klug [Amos, L. A., & Klug, A. (1975) J. Mol. Biol. 99, 51-73].

Structural studies of the contractile tail sheath protein of bacteriophage T4. 1. Conformational change of the tail sheath upon contraction as probed by differential chemical modification

Differential chemical modifications of tyrosine residues of the tail sheath protein, gp18, were performed to elucidate the structural change of the tail sheath upon contraction. Tyrosine residues of monomeric gp18, extended tail sheath, and contracted tail sheath were nitrated by tetranitromethane, and the modified tyrosine residues in each state of the sheath protein were identified by peptide mapping and amino acid sequence analyses of the isolated peptides. Of 31 tyrosine residues in gp18 monomer or in the extended sheath, 12 or 13 residues (Tyr63 and/or -73, -225, -254, -270, -304, -455, -460, -493, -532, -535, -569, and -590) were modified. When photo-CIDNP difference spectra were measured with monomeric gp18, two peaks, which are due to highly exposed tyrosine residues on the molecular surface of gp18, were observed. These two peaks disappeared when the monomeric gp18 was nitrated. With contracted sheath, however, only eight tyrosine residues (Tyr225, -254, -270, -455, -460, -493, -532, and -535) were nitrated on the contracted sheath. Chemical modification of cysteine residues by sulfhydryl group specific reagent ABD-F [(4-aminosulfonyl)-7-fluoro-2,1,3-benzoxadiazole] revealed that, among five cysteine residues, Cys377, Cys477, and Cys607 have a sulfhydryl group. Cys402 and Cys406 were modified only under reducing conditions, which strongly suggested the presence of a disulfide bond between these two residues.

Nucleotide sequence of the tail sheath gene of bacteriophage T4 and amino acid sequence of its product

The nucleotide sequence of gene 18 of bacteriophage T4 was determined by the Maxam-Gilbert method, partially aided by the dideoxy method. To confirm the deduced amino acid sequence of the tail sheath protein (gp18) that is encoded by gene 18, gp18 was extensively digested by trypsin or lysyl endopeptidase and subjected to reverse-phase high-performance liquid chromatography. Approximately 40 peptides, which cover 88% of the primary structure, were fractionated, the amino acid compositions were determined, and the corresponding sequences in DNA were identified. Furthermore, the amino acid sequences of 10 of the 40 peptides were determined by a gas phase protein sequencer, including N- and C-terminal sequences. Thus, the complete amino acid sequence of gp18, which consists of 658 amino acids with a molecular weight of 71,160, was determined.

A novel method for selective isolation of C-terminal peptides from tryptic digests of proteins by immobilized anhydrotrypsin: application to structural analyses of the tail sheath and tube proteins from bacteriophage T4

A novel method useful for selective isolation of the C-terminal peptide from a tryptic digestion mixture of a protein has been developed by taking advantage of a unique property of anhydrotrypsin, which has a strong specific affinity for the peptides containing arginine or lysine at their C-termini. Briefly, peptides produced by tryptic digestion of a protein are fractionated by affinity chromatography on a column of immobilized anhydrotrypsin. The C-terminal peptide is recovered in a breakthrough fraction, while the remainders are adsorbed on the column (unless the protein ends in arginine or lysine). The breakthrough fraction is then subjected to reversed-phase high-performance liquid chromatography in order to purify the C-terminal peptide. Using this method, we have successfully isolated the C-terminal peptides from tryptic digests of the sheath protein (gp 18) and the tube protein (gp 19) of bacteriophage T4. The analytical results on these peptides, together with the information on the N-terminal structures of the original proteins and on the nucleotide sequences of genes 18 and 19, allowed us to establish the complete primary structures of the two proteins.

Potential length determiner and DNA injection protein is extruded from bacteriophage T4 tail tubes in vitro

Bacteriophage T4 tails contain a set of extended protein molecules in the central channel of the tail tube through which the DNA must exit during infection. Treatment of tails with guanidine hydrochloride separates the baseplates, leaving the tail tube and several specific tube-associated proteins. Methods were developed to purify these structures. Using specific antisera, immunoblotting, and electrophoretic analysis, these structures were shown to contain proteins gp19, 29, and 48. Electron microscopy showed specifically defined stain penetration into the tail tube, a bulge at one end, and a short fiber extruded from the tube. These structures could be removed by proteases but the gp19 tube itself was resistant. Structural studies of tails and intact phage show that the bulge and fiber are at the end of the tube that interacts with the cell membrane during infection. Since the fiber did not protrude from baseplates or from incomplete (short) tube-baseplates, we propose that it is first assembled as a compact structure formed of six copies of a tube-associated protein, which elongates during tail tube formation to fill the central channel, span the length of the tube, and regulate its length. We suggest that the exit of this fiber during infection signals DNA ejection.

Isolation and characterization of the bacteriophage T4 tail-associated lysozyme

Direct evidence has been obtained that the tail-associated lysozyme of bacteriophage T4 (tail-lysozyme) is gp5, which is a protein component of the hub of the baseplate. Tails were treated with 3 M guanidine hydrochloride containing 1% Triton X-100, and the tail-lysozyme was separated from other tail components by preparative isoelectric focusing electrophoresis as a peak with a pI of 8.4. The molecular weight as determined from sodium dodecyl sulfate electrophoresis was 42,000. The tail-lysozyme was unambiguously identified as gp5 when the position of the lysozyme was compared with that of gp5 of tube-baseplates from 5ts1/23amH11/eL1ainfected Escherichia coli cells by two-dimensional gel electrophoresis. The tail-lysozyme has N-acetylmuramidase activity and the same substrate specificity as gene e lysozyme; the optimum pH is around 5.8, about 1 pH unit lower than for the e lysozyme. We assume that the tail-lysozyme plays an essential role in locally digesting the peptidoglycan layer to let the tube penetrate into the periplasmic space. The tail-lysozyme is presumably also responsible for "lysis from without."

On the presence of guanosine phosphate in the tail of bacteriophage T4

Treatment of gp18, a biologically active monomer of the structural protein of the bacteriophage T4 contractile sheath, with 0.6 M-HClO4 leads to the release of GDP, GMP and inorganic phosphate. Each gp18 molecule is shown to carry three atoms of phosphorus. In the isolated protein preparation, gp18 and the nucleoside phosphate are in equimolar relation. It is suggested that in the native sheath-protein subunit, GDP and inorganic phosphate are united as GTP.

Gene 20 product of bacteriophage T4. II. Its structural organization in prehead and bacteriophage

The location of gene 20 product of bacteriophage T4 in phage and phage percursors has been determined by immunochemical analysis of polyacrylamide gels, immunoturbidimetry and immunoelectron microscopy. The protein is present at the membrane attachment site of the prehead, a head precursor, and is accessible to the antibodies in the solution. It is present at the tail attachment site of the capsid, partially buried in the structure. In complete phage particles it is totally buried in the structure. It is in contact with the major shell proteins, gp23 and gp23*, respectively, in preheads and capsids, as revealed by partial crosslinking experiments. It forms the upper collar of the neck in necked tails. The lower collar is constructed from other gene products. On the basis of these data a structural model of the neck region of the phage has been derived. This model is consistent with a number of events in phage assembly, such as the role of gp20 in head assembly and DNA packaging, prehead detachment from the bacterial membrane and head-tail attachment. The symmetry mismatch known to occur between head and tail has been localized at the gp20-gp23* contact area.

Bacteriophage SPO1 structure and morphogenesis. III. SPO1 proteins and synthesis

The virion proteins of SPO1 have been determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis methods on purified phage components and on phage lysates. The phage head contains 16 proteins, and the connector or neck structure has an additional 3 proteins not found in the head. The proximal part of the tail, composed of sheath, tube and connecting components, contains six proteins. The distal baseplate is the most complex structure, with 28 proteins identifiable on sodium dodecyl sulfate gels. The maximum number of proteins found in phage subassemblies is 53, which would account for nearly half the coding capacity of the SPO1 genome.

Bacteriophage SPO1 structure and morphogenesis. I. Tail structure and length regulation

Bacteriophage SPO1, a structually complex phage with hydroxymethyl uracil replacing thymine, has been studied by structural and chemical methods with the aim of defining the virion organization. The contractile tail of SPO1 consists of a complex baseplate, a tail tube, and a 140-nm-long sheath composed of stacked disks (4.1 nm repeat), each containing six subunits of molecular weight 60,300. The subunits are arranged in six parallel helices, each with a helical screw angle (omega 0) of 22.5 degrees. The baseplate was shown to undergo a structural rearrangement during tail contraction into a hexameric pinwheel. A mutation in gene 8 which produced unattached heads and tails also produced tails of different lengths. The tail length distribution suggests that the smallest integral length increment is a single disk of subunits. The structural arrangement of subunits in long tails is identical to that of normal tails, and the tails can contract. Many of the long tails showed partial stain penetration within the tail tube to a point which coincides with the top of a unit-length tail. The implications of these findings with respect to tail length regulation are discussed.

Roles of cell surface components of Escherichia coli K-12 in bacteriophage T4 infection: interaction of tail core with phospholipids

The cell surface of Escherichia coli K-12, reconstituted from the OmpC protein, lipopolysaccharide, and the peptidoglycan layer, was active as a receptor for phage T4, resulting in the contraction of the tail sheath and the penetration of the core through the cell surface (Furukawa et al., J. Bacteriol. 140:1071--1080, 1979). In the present work the process of DNA ejection from the contracted T4 phage particle was studied. Contracted phage particles were adsorbed to phospholipid liposomes by the core tip. This adsorption resulted in ejection of phage DNA. Either phosphatidylglycerol or cardiolipin was active for the DNA ejection. A proton motive force across the liposome membrane was not required for these processes. The process of DNA ejection, however, was temperature dependent, whereas the adsorption of the core tip to liposomes took place at 4 degrees C. Based on these observations together with those in the previous paper, the process of T4 infection of E. coli K-12 cells is discussed with special reference to the roles of cell surface components.

Kinetics of the cooperative association of T4 tail sheath protein P18 to polysheaths

The polymerization of the monomeric sheath protein P18 to polysheath was followed by light scattering in 1 mM sodium phosphate buffer, pH 7 at a MgCl2 concentration of 5 mM. Sigmoidal kinetics were observed in the case of spontaneous nucleation. These were well fitted by a mechanism involving a slow nucleation step (rate constant kN = 10(-2) M-1 S-1) followed by propagation steps (k = 10(5) M-1 S-1) in which P18 protomers are added to the ends of the polysheath particles. When sonicated polysheaths or contracted sheaths were added as seeds exponential time courses were observed. From the pseudo first order rate constant and the concentration of seeds the above value for the rate constant of propagation was confirmed. The ability of contracted sheaths to nucleate polysheath formation lends support to the conclusion that polysheaths and contracted sheaths have identical structures and differ in their length distributions only. These were measured from electromicrographs and from the distribution of sedimentation coefficients. Poisson type, kinetically controlled size distributions were found after polymerization of polysheath. An extremely slow redistribution towards an exponential distribution was detected. The spontaneous slow formation of polysheaths is much slower than the formation of extended sheath are core baseplates. Extended sheath is a metastable assembly produce of P18 which either dissociates of contracts to form contracted sheath. Polysheaths and contracted sheaths are extremely stable products but their immediate formation is hindered by high nucleation difficulties.