Morphogenesis of the T4 tail and tail fibers

Remarkable progress has been made during the past ten years in elucidating the structure of the bacteriophage T4 tail by a combination of three-dimensional image reconstruction from electron micrographs and X-ray crystallography of the components. Partial and complete structures of nine out of twenty tail structural proteins have been determined by X-ray crystallography and have been fitted into the 3D-reconstituted structure of the "extended" tail. The 3D structure of the "contracted" tail was also determined and interpreted in terms of component proteins. Given the pseudo-atomic tail structures both before and after contraction, it is now possible to understand the gross conformational change of the baseplate in terms of the change in the relative positions of the subunit proteins. These studies have explained how the conformational change of the baseplate and contraction of the tail are related to the tail's host cell recognition and membrane penetration function. On the other hand, the baseplate assembly process has been recently reexamined in detail in a precise system involving recombinant proteins (unlike the earlier studies with phage mutants). These experiments showed that the sequential association of the subunits of the baseplate wedge is based on the induced-fit upon association of each subunit. It was also found that, upon association of gp53 (gene product 53), the penultimate subunit of the wedge, six of the wedge intermediates spontaneously associate to form a baseplate-like structure in the absence of the central hub. Structure determination of the rest of the subunits and intermediate complexes and the assembly of the hub still require further study.     

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.     

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.     

Assembly of the tail of bacteriophage T4

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

Structure of the central hub of bacteriophage Mu baseplate determined by X-ray crystallography of gp44

Bacteriophage Mu is a double-stranded DNA phage that consists of an icosahedral head, a contractile tail with baseplate and six tail fibers, similar to the well-studied T-even phages. The baseplate of bacteriophage Mu, which recognizes and attaches to a host cell during infection, consists of at least eight different proteins. The baseplate protein, gp44, is essential for bacteriophage Mu assembly and the generation of viable phages. To investigate the role of gp44 in baseplate assembly and infection, the crystal structure of gp44 was determined at 2.1A resolution by the multiple isomorphous replacement method. The overall structure of the gp44 trimer is similar to that of the T4 phage gp27 trimer, which forms the central hub of the T4 baseplate, although these proteins share very little primary sequence homology. Based on these data, we confirm that gp44 exists as a trimer exhibiting a hub-like structure with an inner diameter of 25A through which DNA can presumably pass during infection. The molecular surface of the gp44 trimer that abuts the host cell membrane is positively charged, and it is likely that Mu phage interacts with the membrane through electrostatic interactions mediated by gp44.     

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

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

Construction and characterization of hybrids containing genes coding for proteins of the central part of bacteriophage T4 baseplate.

The central part (hub or plug) of bacteriophage T4 baseplate consist of several proteins which are present in only few copies per phage particle. The presence of these minor baseplate components was inferred from the genetic data but only some of them were identified as distinct proteins species by biochemical analysis. We have constructed a number of plasmids containing segments of bacteriophage T4 genome coding for baseplate proteins. The following genes were cloned into expression vectors: 54, 48, 29, 28, 27, 51, 26 and 25. The presence of a particular gene product was confirmed by in vivo complementation test. On the basis of these results we could more precisely localize the position of a particular gene on T4 phage genetic map. The hybrids contain sets of genes which make aggregation impossible, so bacteria harbouring these plasmids are convenient starting point for the purification of baseplate proteins.     

Analysis of near-neighbor contacts in bacteriophage T4 wedges and hubless baseplates by using a cleavable chemical cross-linker.

Although bacteriophage T4 baseplate morphogenesis has been analyzed in some detail, there is little information available on the spatial arrangement and associations of its 150 subunits. We have therefore carried out the first analysis of its near-neighbor interactions by using the cleavable chemical cross-linker ethylene glycolbis(succinimidylsuccinate). In this report, we describe the cross-linked complexes that have been identified in the one-sixth arms or wedges and also in baseplatelike structures called rings consisting of six wedges but lacking the central hub, both of which are purified from T4 gene 5- -infected cells. Thirty different complexes were identified, of which about half contain multimers of a single species and half contain two different species. In general, the complexes reflect and support the assembly pathway derived by Kikuchi and King (Y. Kikuchi and J. King, J. Mol. Biol. 99:695-716, 1975) but broaden its scope to include such complexes as gp25-gp53, gp25-gp48, and gp48-gp53, which locate the gp48 binding site over the inner edge of the ring but outside the central hub. The data also supports the view that wedges are assembled from the outer edge inward toward the central hub. Wedge-wedge contact in rings was mediated primarily by gp12 and gp9, the absence of which dramatically destabilized the ring----wedge equilibrium in favor of wedges. Although no heterologous complexes containing gp9 were identified, gp12 contacts unique to rings were observed with both gp10 and gp11.     

Isolation and characterization of precursors in bacteriophage T4 baseplate assembly. II. Purification of the protein products of genes 10 and 11 and the in vitro formation of the P(10/11) complex

Two bacteriophage T4 proteins which are precursors to the phage baseplate have been purified to homogeneity. These proteins, P10 and P11, are components of the P(10/11) complex, which is the first intermediate in the assembly of T4 baseplate 1/6th arms. Each protein was isolated from cells infected with a T4 amber mutant defective in the production of the other protein. Thus these purified proteins have never been assembled into the P(10/11) complex in vivo. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis and the ability of these proteins to block the phage killing activity of specific antisera were used to monitor the purification steps. Sedimentation equilibrium experiments reveal a molecular weight of 188,000 g/mol for P10 and 60,000 g/mol for P11. These data together with the previously determined molecular weights of the gene 10 and gene 11 polypeptide chains (King & Mykolajewycz, 1973) and the in vivo assembled P(10/11) complex (Berget & King, 1978b) are consistent with P10 being a dimer of the product of gene 10, P11 being a dimer of the product of gene 11, and P(10/11) being a tetramer containing one of each of these dimers. Purified P10 and P11 are active in assembly because they complement 10- and 11- defective extracts, respectively, to form viable bacteriophage in vitro. Furthermore, these proteins assemble in vitro to form a protein structure identical to the P(10/11) complex formed in vivo as determined by non-denaturing gel electrophoresis. This P(10/11) complex formed in vitro complements 10-/11- defective extracts to form viable phage. The overall extent of this in vitro assembly reaction is not affected by NaCl to 1.5 M or 2% Triton X-100. The reaction is, however, prevented by the denaturing effects of urea and sodium dodecyl sulfate.     

Functional Role of the N-Terminal Domain of Bacteriophage T4-Gene Product 11

Bacteriophage T4 late gene product 11 (gp11), the three-dimensional structure of which has been solved by us to 2.0 A resolution, is a part of the virus' baseplate. The gp11 polypeptide chain consists of 219 amino acid residues and the functionally active protein is a three-domain homotrimer. In this work, we have studied the role of gp11 N-terminal domain in the formation of a functionally active trimer. Deletion variants of gp11 and monoclonal antibodies recognizing the native conformation of gp11 trimer have been selected. Long deletions up to a complete removal of the N-terminal domain, containing 64 residues, do not affect the gp11 trimerization, but considerably change the protein structure and lead to the loss of its ability to incorporate into the baseplate. However, the deletion of the first 17 N-terminal residues results in functionally active protein that can complete the 11(-)-defective phage particles in in vitro complementation assay. This region of the polypeptide chain is probably essential for gp11-gp10 stable complex formation at the early stages of phage baseplate assembly in vivo. A study of the gp10 deletion variants suggests that the central domain of gp10 trimer is responsible for the interaction with gp11.     

Molecular reorganization in the hexagon to star transition of the baseplate of bacteriophage T4

The baseplate of bacteriophage T4 is a complex structure containing at least 14 different structural proteins. It undergoes a transition from a hexagonal to a star-shaped configuration during infection of the host bacterial cell. We have used a combination of genetics and image processing of electron micrographs to analyse both the wild-type structure and a series of mutant structures lacking specific gene products. Besides describing the basic anatomy of the hexagon and star configurations, we have been able to locate the products of genes 9, 11 and 12.Gene 9 product occupies a peripheral position in hexagons and stars consistent with its providing a binding site for the long tail fibres. Gene 11 product in the hexagon forms the distal part of the tail pin, which folds out to form the point of the hexagram in the star configuration. Gene 12 product is visualized as an extended 350 Å fibre in stars and broken baseplates but appears to have a more compact configuration in hexagons and intact phage.We demonstrate the structural relationship between the hexagonal and starshaped configurations and show how the positions of the specific gene products alter as a result of the structural transition. We suggest a speculative model for the role of gene 9 and gene 12 products in triggering the rearrangement of the baseplate and tail contraction.     

Structure and location of gene product 8 in the bacteriophage T4 baseplate

Many bacteriophages, such as T4, T7, RB49, and phi29, have complex, sometimes multilayered, tails that facilitate an almost 100% success rate for the viral particles to infect host cells. In bacteriophage T4, there is a baseplate, which is a multiprotein assembly, at the distal end of the contractile tail. The baseplate communicates to the tail that the phage fibers have attached to the host cell, thereby initiating the infection process. Gene product 8 (gp8), whose amino acid sequence consists of 334 residues, is one of at least 16 different structural proteins that constitute the T4 baseplate and is the sixth baseplate protein whose structure has been determined. A 2.0A resolution X-ray structure of gp8 shows that the two-domain protein forms a dimer, in which each monomer consists of a three-layered beta-sandwich with two loops, each containing an alpha-helix at the opposite sides of the sandwich. The crystals of gp8 were produced in the presence of concentrated chloride and bromide ions, resulting in at least 11 halide-binding sites per monomer. Five halide sites, situated at the N termini of alpha-helices, have a protein environment observed in other halide-containing protein crystal structures. The computer programs EMfit and SITUS were used to determine the positions of six gp8 dimers within the 12A resolution cryo-electron microscopy image reconstruction of the baseplate-tail tube complex. The gp8 dimers were found to be located in the upper part of the baseplate outer rim. About 20% of the gp8 surface is involved in contacts with other baseplate proteins, presumed to be gp6, gp7, and gp10. With the structure determination of gp8, a total of 53% of the volume of the baseplate has now been interpreted in terms of its atomic structure.     

Structural characterization and assembly of the distal tail structure of the temperate lactococcal bacteriophage TP901-1

The tail structures of bacteriophages infecting gram-positive bacteria are largely unexplored, although the phage tail mediates the initial interaction with the host cell. The temperate Lactococcus lactis phage TP901-1 of the Siphoviridae family has a long noncontractile tail with a distal baseplate. In the present study, we investigated the distal tail structures and tail assembly of phage TP901-1 by introducing nonsense mutations into the late transcribed genes dit (orf46), tal(TP901-1) (orf47), bppU (orf48), bppL (orf49), and orf50. Transmission electron microscopy examination of mutant and wild-type TP901-1 phages showed that the baseplate consisted of two different disks and that a central tail fiber is protruding below the baseplate. Evaluation of the mutant tail morphologies with protein profiles and Western blots revealed that the upper and lower baseplate disks consist of the proteins BppU and BppL, respectively. Likewise, Dit and Tal(TP901-1) were shown to be structural tail proteins essential for tail formation, and Tal(TP901-1) was furthermore identified as the tail fiber protein by immunogold labeling experiments. Determination of infection efficiencies of the mutant phages showed that the baseplate is fundamental for host infection and the lower disk protein, BppL, is suggested to interact with the host receptor. In contrast, ORF50 was found to be nonessential for tail assembly and host infection. A model for TP901-1 tail assembly, in which the function of eight specific proteins is considered, is presented.     

Evidence of interactions between Gp27 and Gp28 constituents of the central part of bacteriophage T4 baseplate

The central part of the bacteriophage T4 baseplate consists of several proteins. However, for a number of the constituents the manner of incorporation are not convincingly established. Recently, we have presented evidence that gp28 is the structural component of the central part of the baseplate, which possesses a hydrophobic region and is membrane bound [Nieradko et al., 1998]. By utilizing extracts prepared from Escherichia coli cells that overexpressed genes 27 and 28 of phage T4, we proved that gp28 forms a complex with an another baseplate structural components: gp27. This complex was located in the membrane fraction. Its affinity to the inner membrane indicates that the identified complex may function as an initiator of the central hub assembly. It was subsequently established that these products interact in the ratio 1:1. We have also demonstrated that the particular components of the complex can be separated by action of SDS and to a lesser extent by Triton X-100.     

Exposing the Secrets of Two Well-Known Lactobacillus casei Phages,J-1 and PL-1, by Genomic and Structural Analysis

Bacteriophage J-1 was isolated in 1965 from an abnormal fermentation of Yakult using Lactobacillus casei strain Shirota, and a related phage, PL-1, was subsequently recovered from a strain resistant to J-1. Complete genome sequencing shows that J-1 and PL-1 are almost identical, but PL-1 has a deletion of 1.9 kbp relative to J-1, resulting in the loss of four predicted gene products involved in immunity regulation. The structural proteins were identified by mass spectrometry analysis. Similarly to phage A2, two capsid proteins are generated by a translational frameshift and undergo proteolytic processing. The structure of gene product 16 (gp16), a putative tail protein, was modeled based on the crystal structure of baseplate distal tail proteins (Dit) that form the baseplate hub in other Siphoviridae. However, two regions of the C terminus of gp16 could not be modeled using this template. The first region accounts for the differences between J-1 and PL-1 gp16 and showed sequence similarity to carbohydrate-binding modules (CBMs). J-1 and PL-1 GFP-gp16 fusions bind specifically to Lactobacillus casei/paracasei cells, and the addition of l-rhamnose inhibits binding. J-1 gp16 exhibited a higher affinity than PL-1 gp16 for cell walls of L. casei ATCC 27139 in phage adsorption inhibition assays, in agreement with differential adsorption kinetics observed for both phages in this strain. The data presented here provide insights into how Lactobacillus phages interact with their hosts at the first steps of infection.     

The Type VI Secretion TssEFGK-VgrG Phage-Like Baseplate Is Recruited to the TssJLM Membrane Complex via Multiple Contacts and Serves As Assembly Platform for Tail Tube/Sheath Polymerization

The Type VI secretion system (T6SS) is a widespread weapon dedicated to the delivery of toxin proteins into eukaryotic and prokaryotic cells. The 13 T6SS subunits assemble a cytoplasmic contractile structure anchored to the cell envelope by a membrane-spanning complex. This structure is evolutionarily, structurally and functionally related to the tail of contractile bacteriophages. In bacteriophages, the tail assembles onto a protein complex, referred to as the baseplate, that not only serves as a platform during assembly of the tube and sheath, but also triggers the contraction of the sheath. Although progress has been made in understanding T6SS assembly and function, the composition of the T6SS baseplate remains mostly unknown. Here, we report that six T6SS proteins–TssA, TssE, TssF, TssG, TssK and VgrG–are required for proper assembly of the T6SS tail tube, and a complex between VgrG, TssE,-F and-G could be isolated. In addition, we demonstrate that TssF and TssG share limited sequence homologies with known phage components, and we report the interaction network between these subunits and other baseplate and tail components. In agreement with the baseplate being the assembly platform for the tail, fluorescence microscopy analyses of functional GFP-TssF and TssK-GFP fusion proteins show that these proteins assemble stable and static clusters on which the sheath polymerizes. Finally, we show that recruitment of the baseplate to the apparatus requires initial positioning of the membrane complex and contacts between TssG and the inner membrane TssM protein.     

Structure of the bacteriophage T4 baseplate as determined by chemical cross-linking.

We have carried out a series of reversible chemical cross-linking experiments using the reagent ethylene glycol-bis(succinimidylsuccinate) with the goal of determining the three-dimensional structure of the bacteriophage T4 baseplate. In a previous report, we investigated the near-neighbor contacts in baseplate precursors and substructures (N.R.M. Watts and D.H. Coombs, J. Virol. 63:2427-2436, 1989). Here we report completion of the analysis by examining finished baseplates and tails. Most of the previous contacts were confirmed, and we report several new contacts, including those within the central hub (gp5-gptd2, gp26-gptd), between the hub and the outer wedges (gp6-gp27(2], between baseplate and sheath (gp54-gp18), and between sheath and core (gp19-gp18). On the basis of this and other available information, a partial three-dimensional model of the baseplate is proposed.     

Three-dimensional structure of bacteriophage T4 baseplate

The baseplate of bacteriophage T4 is a multiprotein molecular machine that controls host cell recognition, attachment, tail sheath contraction and viral DNA ejection. We report here the three-dimensional structure of the baseplate-tail tube complex determined to a resolution of 12 A by cryoelectron microscopy. The baseplate has a six-fold symmetric, dome-like structure approximately 520 A in diameter and approximately 270 A long, assembled around a central hub. A 940 A-long and 96 A-diameter tail tube, coaxial with the hub, is connected to the top of the baseplate. At the center of the dome is a needle-like structure that was previously identified as a cell puncturing device. We have identified the locations of six proteins with known atomic structures, and established the position and shape of several other baseplate proteins. The baseplate structure suggests a mechanism of baseplate triggering and structural transition during the initial stages of T4 infection.     

A topological model of the baseplate of lactococcal phage Tuc2009

Phages infecting Lactococcus lactis, a Gram-positive bacterium, are a recurrent problem in the dairy industry. Despite their economical importance, the knowledge on these phages, belonging mostly to Siphoviridae, lags behind that accumulated for members of Myoviridae. The three-dimensional structures of the receptor-binding proteins (RBP) of three lactococcal phages have been determined recently, illustrating their modular assembly and assigning the nature of their bacterial receptor. These RBPs are attached to the baseplate, a large phage organelle, located at the tip of the tail. Tuc2009 baseplate is formed by the products of 6 open read frames, including the RBP. Because phage binding to its receptor induces DNA release, it has been postulated that the baseplate might be the trigger for DNA injection. We embarked on a structural study of the lactococcal phages baseplate, ultimately to gain insight into the triggering mechanism following receptor binding. Structural features of the Tuc2009 baseplate were established using size exclusion chromatography coupled to on-line UV-visible absorbance, light scattering, and refractive index detection (MALS/UV/RI). Combining the results of this approach with literature data led us to propose a "low resolution" model of Tuc2009 baseplate. This model will serve as a knowledge base to submit relevant complexes to crystallization trials.     

Structure, stability, and biological activity of bacteriophage T4 gene product 9 probed with mutagenesis and monoclonal antibodies

Gene product (gp) 9 connects the long tail fibers and triggers the structural transition of T4 phage baseplate at the beginning of infection process. Gp9 is a parallel homotrimer with 288 amino acid residues per chain that forms three domains. To investigate the role of the gp9 amino terminus, we have engineered a set of mutants with deletions and random substitutions in this part. The structure of the mutants was probed using monoclonal antibodies that bind to either N-terminal, middle, or C-terminal domains. Deletions of up to 12 N-terminal residues as well as random substitutions of the second, third and fourth residues yielded trimers that failed to incorporate in vitro into the T4 9(-)-particles and were not able to convert them into infectious virions. As detected using monoclonal antibodies, these mutants undergo structural changes in both N-terminal and middle domains. Furthermore, deletion of the first twenty residues caused profound structural changes in all three gp9 domains. In addition, N-terminally truncated proteins and randomized mutants formed SDS-resistant "conformers" due to unwinding of the N-terminal region. Co-expression of the full-length gp9 and the mutant lacking first 20 residues clearly shows the assembly of heterotrimers, suggesting that the gp9 trimerization in vivo occurs post-translationally. Collectively, our data indicate that the aminoterminal sequence of gp9 is important to maintain a competent structure capable of incorporating into the baseplate, and may be also required at intermediate stages of gp9 folding and assembly.