Receptor-binding protein of Lactococcus lactis phages: identification and characterization of the saccharide receptor-binding site

Phage p2, a member of the lactococcal 936 phage species, infects Lactococcus lactis strains by binding initially to specific carbohydrate receptors using its receptor-binding protein (RBP). The structures of p2 RBP, a homotrimeric protein composed of three domains, and of its complex with a neutralizing llama VH domain (VHH5) have been determined (S. Spinelli, A. Desmyter, C. T. Verrips, H. J. de Haard, S. Moineau, and C. Cambillau, Nat. Struct. Mol. Biol. 13:85-89, 2006). Here, we show that VHH5 was able to neutralize 12 of 50 lactococcal phages belonging to the 936 species. Moreover, escape phage mutants no longer neutralized by VHH5 were isolated from 11 of these phages. All of the mutations (but one) cluster in the RBP/VHH5 interaction surface that delineates the receptor-binding area. A glycerol molecule, observed in the 1.7-A resolution structure of RBP, was found to bind tightly (Kd= 0.26 microM) in a crevice located in this area. Other saccharides bind RBP with comparable high affinity. These data prove the saccharidic nature of the bacterial receptor recognized by phage p2 and identify the position of its binding site in the RBP head domain.     

Modular structure of the receptor binding proteins of Lactococcus lactis phages. The RBP structure of the temperate phage TP901-1

Lactococcus lactis is a gram-positive bacterium widely used by the dairy industry. Several industrial L. lactis strains are sensitive to various distinct bacteriophages. Most of them belong to the Siphoviridae family and comprise several species, among which the 936 and P335 are prominent. Members of these two phage species recognize their hosts through the interaction of their receptor-binding protein (RBP) with external cell wall saccharidices of the host, the "receptors." We report here the 1.65 A resolution crystal structure of the RBP from phage TP901-1, a member of the P335 species. This RBP of 163 amino acids is a homotrimer comprising three domains: a helical N terminus, an interlaced beta-prism, and a beta-barrel, the head domain (residues 64-163), which binds a glycerol molecule. Fluorescence quenching experiments indicated that the RBP exhibits high affinity for glycerol, muramyl-dipeptide, and other saccharides in solution. The structural comparison of this RBP with that of lactococcal phage p2 RBP, a member of the 936 species (Spinelli, S., Desmyter, A., Verrips, C. T., de Haard, J. W., Moineau, S., and Cambillau, C. (2006) Nat. Struct. Mol. Biol. 13, 85-89) suggests a large extent of modularity in RBPs of lactococcal phages.     

Genome sequence and global gene expression of Q54, a new phage species linking the 936 and c2 phage species of Lactococcus lactis

The lytic lactococcal phage Q54 was previously isolated from a failed sour cream production. Its complete genomic sequence (26,537 bp) is reported here, and the analysis indicated that it represents a new Lactococcus lactis phage species. A striking feature of phage Q54 is the low level of similarity of its proteome (47 open reading frames) with proteins in databases. A global gene expression study confirmed the presence of two early gene modules in Q54. The unusual configuration of these modules, combined with results of comparative analysis with other lactococcal phage genomes, suggests that one of these modules was acquired through recombination events between c2- and 936-like phages. Proteolytic cleavage and cross-linking of the major capsid protein were demonstrated through structural protein analyses. A programmed translational frameshift between the major tail protein (MTP) and the receptor-binding protein (RBP) was also discovered. A "shifty stop" signal followed by putative secondary structures is likely involved in frameshifting. To our knowledge, this is only the second report of translational frameshifting (+1) in double-stranded DNA bacteriophages and the first case of translational coupling between an MTP and an RBP. Thus, phage Q54 represents a fascinating member of a new species with unusual characteristics that brings new insights into lactococcal phage evolution.     

Crystal structure of the receptor-binding protein head domain from Lactococcus lactis phage bIL170

Lactococcus lactis, a gram-positive bacterium widely used by the dairy industry, is subject to lytic phage infections. In the first step of infection, phages recognize the host saccharidic receptor using their receptor binding protein (RBP). Here, we report the 2.30-A-resolution crystal structure of the RBP head domain from phage bIL170. The structure of the head monomer is remarkably close to those of other lactococcal phages, p2 and TP901-1, despite any sequence identity with them. The knowledge of the three-dimensional structures of three RBPs gives a better insight into the module exchanges which have occurred among phages.     

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.     

Identification of the receptor-binding protein in 936-species lactococcal bacteriophages

The aim of this work was to identify genes responsible for host recognition in the lactococcal phages sk1 and bIL170 belonging to species 936. These phages have a high level of DNA identity but different host ranges. Bioinformatic analysis indicated that homologous genes, orf18 in sk1 and orf20 in bIL170, could be the receptor-binding protein (RBP) genes, since the resulting proteins were unrelated in the C-terminal part and showed homology to different groups of proteins hypothetically involved in host recognition. Consequently, chimeric bIL170 phages carrying orf18 from sk1 were generated. The recombinant phages were able to form plaques on the sk1 host Lactococcus lactis MG1614, and recombination was verified by PCR analysis directly with the plaques. A polyclonal antiserum raised against the C-terminal part of phage sk1 ORF18 was used in immunogold electron microscopy to demonstrate that ORF18 is located at the tip of the tail. Sequence analysis of corresponding proteins from other lactococcal phages belonging to species 936 showed that the N-terminal parts of the RBPs were very similar, while the C-terminal parts varied, suggesting that the C-terminal part plays a role in receptor binding. The phages investigated could be grouped into sk1-like phages (p2, fd13, jj50, and phi 7) and bIL170-like phages (P008, P113G, P272, and bIL66) on the basis of the homology of their RBPs to the C-terminal part of ORF18 in sk1 and ORF20 in bIL170, respectively. Interestingly, sk1-like phages bind to and infect a defined group of L. lactis subsp. cremoris strains, while bIL170-like phages bind to and infect a defined group of L. lactis subsp. lactis strains.     

Detection of lactococcal 936-species bacteriophages in whey by magnetic capture hybridization PCR targeting a variable region of receptor-binding protein genes

AIMS: To develop PCR assays able to distinguish between groups within lactococcal 936-species bacteriophages, as defined by their different receptor-binding protein (RBP) genes. METHODS AND RESULTS: DNA sequences of RBP genes from 17 lactococcal bacteriophages of the 936-species were compared, and six phage groups were identified. For each phage group a specific primer pair targeting a variable region of the RBP genes was designed. In nine of 20 whey samples, from dairies with recorded phage problems, between one and six phage groups were identified by conventional PCR. The sensitivity and specificity of the method was improved by magnetic capture hybridization (MCH)-PCR using a capture probe targeting an 80-bp highly conserved region just upstream from the RBP gene in all the investigated phages. The MCH-PCR was performed on 100 microl whey samples and the detection limit of the assay was 10(2)-10(3) PFU ml(-1) as opposed to the detection limit of 10(4) PFU ml(-1) for conventional PCR performed on 1-microl whey samples. CONCLUSIONS: In this study, PCR assays have been developed to detect six different types of RBP genes in lactococcal 936-species bacteriophages. SIGNIFICANCE AND IMPACT OF THE STUDY: The PCR assays have practical applications at cheese plants for detection of 936-species phages with different RBP and thereby potentially with different host ranges. This knowledge will make it possible to improve starter culture rotation systems in the dairy industry.     

Assessing the Conformational Changes of pb5, the Receptor-binding Protein of Phage T5, upon Binding to Its Escherichia coli Receptor FhuA

Within tailed bacteriophages, interaction of the receptor-binding protein (RBP) with the target cell triggers viral DNA ejection into the host cytoplasm. In the case of phage T5, the RBP pb5 and the receptor FhuA, an outer membrane protein of Escherichia coli, have been identified. Here, we use small angle neutron scattering and electron microscopy to investigate the FhuA-pb5 complex. Specific deuteration of one of the partners allows the complete masking in small angle neutron scattering of the surfactant and unlabeled proteins when the complex is solubilized in the fluorinated surfactant F₆-DigluM. Thus, individual structures within a membrane protein complex can be described. The solution structure of FhuA agrees with its crystal structure; that of pb5 shows an elongated shape. Neither displays significant conformational changes upon interaction. The mechanism of signal transduction within phage T5 thus appears different from that of phages binding cell wall saccharides, for which structural information is available.     

The dilemma of phage taxonomy illustrated by comparative genomics of Sfi21-like Siphoviridae in lactic acid bacteria

The complete genome sequences of two dairy phages, Streptococcus thermophilus phage 7201 and Lactobacillus casei phage A2, are reported. Comparative genomics reveals that both phages are members of the recently proposed Sfi21-like genus of Siphoviridae, a widely distributed phage type in low-GC-content gram-positive bacteria. Graded relatedness, the hallmark of evolving biological systems, was observed when different Sfi21-like phages were compared. Across the structural module, the graded relatedness was represented by a high level of DNA sequence similarity or protein sequence similarity, or a shared gene map in the absence of sequence relatedness. This varying range of relatedness was found within Sfi21-like phages from a single species as demonstrated by the different prophages harbored by Lactococcus lactis strain IL1403. A systematic dot plot analysis with 11 complete L. lactis phage genome sequences revealed a clear separation of all temperate phages from two classes of virulent phages. The temperate lactococcal phages share DNA sequence homology in a patchwise fashion over the nonstructural gene cluster. With respect to structural genes, four DNA homology groups could be defined within temperate L. lactis phages. Closely related structural modules for all four DNA homology groups were detected in phages from Streptococcus or Listeria, suggesting that they represent distinct evolutionary lineages that have not uniquely evolved in L. lactis. It seems reasonable to base phage taxonomy on data from comparative genomics. However, the peculiar modular nature of phage evolution creates ambiguities in the definition of phage taxa by comparative genomics. For example, depending on the module on which the classification is based, temperate lactococcal phages can be classified as a single phage species, as four distinct phage species, or as two if not three different phage genera. We propose to base phage taxonomy on comparative genomics of a single structural gene module (head or tail genes). This partially phylogeny-based taxonomical system still mirrors some aspects of the current International Committee on Taxonomy in Virology classification system. In this system the currently sequenced lactococcal phages would be grouped into five genera: c2-, sk1, Sfi11-, r1t-, and Sfi21-like phages.     

Revisiting the host adhesion determinants of Streptococcus thermophilus siphophages

Available 3D structures of bacteriophage modules combined with predictive bioinformatic algorithms enabled the identification of adhesion modules in 57 siphophages infecting Streptococcus thermophilus (St). We identified several carbohydrate-binding modules (CBMs) in so-called evolved distal tail (Dit) and tail-associated lysozyme (Tal) proteins of St phage baseplates. We examined the open reading frame (ORF) downstream of the Tal-encoding ORF and uncovered the presence of a putative p2-like receptor-binding protein (RBP). A 21 Å resolution electron microscopy structure of the baseplate of cos-phage STP1 revealed the presence of six elongated electron densities, surrounding the core of the baseplate, that harbour the p2-like RBPs at their tip. To verify the functionality of these modules, we expressed GFP- or mCherry-coupled Tal and putative RBP CBMs and observed by fluorescence microscopy that both modules bind to their corresponding St host, the putative RBP CBM with higher affinity than the Tal-associated one. The large number of CBM functional domains in St phages suggests that they play a contributory role in the infection process, a feature that we previously described in lactococcal phages and beyond, possibly representing a universal feature of the siphophage host-recognition apparatus.     

Crystal Structure and Function of a DARPin Neutralizing Inhibitor of Lactococcal Phage TP901-1: COMPARISON OF DARPin AND CAMELID VHH BINDING MODE*

Combinatorial libraries of designed ankyrin repeat proteins (DARPins) have been proven to be a valuable source of specific binding proteins, as they can be expressed at very high levels and are very stable. We report here the selection of DARPins directed against a macromolecular multiprotein complex, the baseplate BppU·BppL complex of the lactococcal phage TP901-1. Using ribosome display, we selected several DARPins that bound specifically to the tip of the receptor-binding protein (RBP, the BppL trimer). The three selected DARPins display high specificity and affinity in the low nanomolar range and bind with a stoichiometry of one DARPin per BppL trimer. The crystal structure of a DARPin complexed with the RBP was solved at 2.1 Å resolution. The DARPin·RBP interface is of the concave (DARPin)-convex (RBP) type, typical of other DARPin protein complexes and different from what is observed with a camelid VHH domain, which penetrates the phage p2 RBP inter-monomer interface. Finally, phage infection assays demonstrated that TP901-1 infection of Lactococcus lactis cells was inhibited by each of the three selected DARPins. This study provides proof of concept for the possible use of DARPins to circumvent viral infection. It also provides support for the use of DARPins in co-crystallization, due to their rigidity and their ability to provide multiple crystal contacts.Lactococcus lactis is a Gram-positive bacterium widely used by the dairy industry for the production of an array of fermented milk products. Several industrial strains are sensitive to various distinct bacteriophages, mostly belonging to the Siphoviridae family. The lactococcal phage population is divided in at least 10 genetically distinct groups, of which the 936, c2, and P335 groups are prominent (1, 2). These L. lactis-infecting phages are considerably problematic in causing milk fermentation failures and resulting in decreased yields as well as low quality products (3). Preventing these infections has proven to be difficult because of lactococcal phage ubiquity, biodiversity, and genomic plasticity (4).Phage infection is initiated by binding of the phage receptor-binding protein (RBP),⁵ located within the baseplate at the distal part of the tail, to its receptor on the host cell surface (5). We have previously solved the crystal structures of the three RBPs of the lactococcal phages p2 (936) (6), bIL170 (936) (7), TP901-1 (P335) (8), and their chimera (9) as well as characterized their saccharide binding sites (10). The RBPs of these phages have a similar homotrimeric architecture related by a 3-fold axis. They comprise three domains: the N terminus shoulder domain, the interlaced β-prism neck domain, and the jellyroll head domain at the C terminus. The head domain has a saccharide binding site likely involved in host recognition. The lactococcal phage TP901-1 contains a double-disk-shaped baseplate at the tip of its tail which is made of a lower baseplate protein (BppL) and an upper baseplate protein (BppU) (11).One strategy to minimize bacteriophage infections is to competitively block phage adsorption by adding a protein that specifically binds to the phage RBP. A neutralizing llama VHH domain recognizing the head domain of the phage p2 RBP has been used to block L. lactis phage infection in milk fermentation (12). Lactococcal phages could readily escape neutralization by generating mutations interfering with VHH binding over the large interaction surface while keeping the central polysaccharide receptor binding pocket intact (10). Designed ankyrin repeat proteins (DARPins) may be another tool to neutralize viral infection, as they display distinct characteristics from VHHs and contain the required properties in terms of stability and facility of expression (13).Ankyrin repeat proteins are found in virtually all phyla and mediate specific protein-protein interactions in all cell compartments (14). The ankyrin elementary module is composed of 33 amino acids structured as a β-turn followed by two antiparallel α-helices and a loop connected to the β-turn of the next repeat. The repeats are stacked in a rigid manner. In creating a DARPin library, residues in each repeat were subdivided in two groups; (i) randomized residues constituting potential target interaction points and (ii) framework residues, important for maintaining the ankyrin fold (13). Libraries with varying repeat numbers were assembled and named according to the constituent repeat number; N2C and N3C libraries were used in this study, with two and three internal repeats inserted between the N and C capping repeats, respectively. DARPins are a powerful alternative to the use of antibodies, notably because of their very high expression rates in Escherichia coli, their high stability paired with high affinity, and successful reports of their use in co-crystallization (15–19). Their architecture results in a very rigid structure that facilitates multiple crystal contacts and may promote crystal formation of the protein of interest by providing additional surfaces for such crystal contacts.We report here the selection and analysis of DARPin binders directed against a macromolecular multiprotein ensemble, the TP901-1 baseplate BppU·BppL protein complex. Ribosome display selection, ELISA screening, and surface plasmon resonance (SPR) measurements allowed us to isolate and characterize three N2C DARPins that recognized the RBP (BppL of the BppU·BppL complex) with high specificity and affinity. Further studies showed that the three DARPins bound to a unique area of the RBP at the tip of the head domain. QELS, MALS, UV, and refractometry coupled online with a size exclusion chromatography (SEC) column allowed us to monitor complex formation in solution as well as to estimate DARPin binding stoichiometry. Crystals of one of these selected DARPins in complex with the RBP were obtained, and the x-ray structure was solved at 2.1 Å resolution. This constitutes the first structure of a DARPin complex originating from the N2C library and the highest resolution for a DARPin complex structure reported to date. Finally, phage adsorption inhibition experiments demonstrated that the three N2C DARPins strongly inhibited L. lactis infection by TP901-1. We describe the DARPin·RBP interface and compare it to other DARPin interfaces. We also compare it to the p2 RBP·VHH5 complex, a previously selected llama VHH domain inhibiting p2 phage adsorption (12), to highlight the different binding mode of these two types of binders.     

Structure,Adsorption to Host,and Infection Mechanism of Virulent Lactococcal Phage p2

Lactococcal siphophages from the 936 and P335 groups infect the Gram-positive bacterium Lactococcus lactis using receptor binding proteins (RBPs) attached to their baseplate, a large multiprotein complex at the distal part of the tail. We have previously reported the crystal and electron microscopy (EM) structures of the baseplates of phages p2 (936 group) and TP901-1 (P335 group) as well as the full EM structure of the TP901-1 virion. Here, we report the complete EM structure of siphophage p2, including its capsid, connector complex, tail, and baseplate. Furthermore, we show that the p2 tail is characterized by the presence of protruding decorations, which are related to adhesins and are likely contributed by the major tail protein C-terminal domains. This feature is reminiscent of the tail of Escherichia coli phage λ and Bacillus subtilis phage SPP1 and might point to a common mechanism for establishing initial interactions with their bacterial hosts. Comparative analyses showed that the architecture of the phage p2 baseplate differs largely from that of lactococcal phage TP901-1. We quantified the interaction of its RBP with the saccharidic receptor and determined that specificity is due to lower k_off values of the RBP/saccharidic dissociation. Taken together, these results suggest that the infection of L. lactis strains by phage p2 is a multistep process that involves reversible attachment, followed by baseplate activation, specific attachment of the RBPs to the saccharidic receptor, and DNA ejection.     

New insights into pb5, the receptor binding protein of bacteriophage T5, and its interaction with its Escherichia coli receptor FhuA

The majority of bacterial viruses are bacteriophages bearing a tail that serves to recognise the bacterial surface and deliver the genome into the host cell. Infection is initiated by the irreversible interaction between the viral receptor binding protein (RBP) and a receptor at the surface of the bacterium. This interaction results ultimately in the phage DNA release in the host cytoplasm. Phage T5 infects Escherichia coli after binding of its RBP pb5 to the outer membrane ferrichrome transporter FhuA. Here, we have studied the complex formed by pb5 and FhuA by a variety of biophysical and biochemical techniques. We show that unlike RBPs of known structures, pb5 probably folds as a unique domain fulfilling both functions of binding to the host receptor and interaction with the rest of the phage. Pb5 likely binds to the domain occluding the β-barrel of FhuA as well as to external loops of the barrel. Furthermore, upon binding to FhuA, pb5 undergoes conformational changes, at the secondary and tertiary structure level that would be the key to the transmission of the signal through the tail to the capsid, triggering DNA release. This is the first structural information regarding the binding of a RBP to a proteic receptor.     

Molecular characterization of a second abortive phage resistance gene present in Lactococcus lactis subsp. lactis ME2.

The fifth phage resistance factor from the prototype phage-insensitive strain Lactococcus lactis subsp. lactis ME2 has been characterized and sequenced. The genetic determinant for Prf (phage resistance five) was subcloned from the conjugative plasmid pTN20, which also encodes a restriction and modification system. Typical of other abortive resistance mechanisms, Prf reduces the efficiency of plaquing to 10(-2) to 10(-3) and decreases the plaque size and burst size of the small isometric-headed phage p2 in L. lactis subsp. lactis LM0230. However, normal-size plaques occurred at a frequency of 10(-4) and contained mutant phages that were resistant to Prf, even after repeated propagation through a sensitive host. Prf does not prevent phage adsorption or promote restriction and modification activities, but 90% of Prf+ cells infected with phage p2 die. Thus, phage infections in Prf+ cells are aborted. Prf is effective in both L. lactis subsp. lactis and L. lactis subsp. cremoris strains against several small isometric-headed phages but not against prolate-headed phages. The Prf determinant was localized by Tn5 mutagenesis and subcloning. DNA sequencing identified a 1,056-nucleotide structural gene designated abiC. Prf+ expression was obtained when abiC was subcloned into the lactococcal expression vector pMG36e. abiC is distinct from two other lactococcal abortive phage resistance genes, abiA (Hsp+, from L. lactis subsp. lactis ME2) and abi416 (Abi+, from L. lactis subsp. lactis IL416). Unlike abiA, the action of abiC does not appear to affect DNA replication. Thus, abiC represents a second abortive system found in ME2 that acts at a different point of the phage lytic cycle.     

The trypanosome homolog of human p32 interacts with RBP16 and stimulates its gRNA binding activity

RBP16 is a guide RNA (gRNA)-binding protein that was shown through immunoprecipitation experiments to interact with ~30% of total gRNAs in Trypanosoma brucei mitochondria. To gain insight into the biochemical function of RBP16, we used affinity chromatography and immunoprecipitation to identify RBP16 protein binding partners. By these methods, RBP16 does not appear to stably interact with the core editing machinery. However, fractionation of mitochondrial extracts on MBP–RBP16 affinity columns consistently isolated proteins of 12, 16, 18 and 22 kDa that were absent from MBP control columns. We describe here our analysis of one RBP16-associated protein, p22. The predicted p22 protein has significant sequence similarity to a family of multimeric, acidic proteins that includes human p32 and Saccharomyces cerevisiae mam33p. Glutaraldehyde crosslinking of recombinant p22 identified homo-multimeric forms of the protein, further substantiating its homology to p32. We confirmed the p22–RBP16 interaction and demonstrated that the two proteins bind each other directly by ELISA utilizing recombinant p22 and RBP16. p32 family members have been reported to modulate viral and cellular pre-mRNA splicing, in some cases by perturbing interaction of their binding partners with RNA. To determine whether p22 similarly affects the gRNA binding properties of RBP16, we titrated recombinant p22 into UV crosslinking assays. These experiments revealed that p22 significantly stimulates the gRNA binding capacity of RBP16. Thus, p22 has the potential to be a regulatory factor in T.brucei mitochondrial gene expression by modulating the RNA binding properties of RBP16.     

Cloning of genomic DNA of Lactococcus lactis that restores phage sensitivity to an unusual bacteriophage sk1-resistant mutant

An unusual, spontaneous, phage sk1-resistant mutant (RMSK1/1) of Lactococcus lactis C2 apparently blocks phage DNA entry into the host. Although no visible plaques formed on RMSK1/1, this host propagated phage at a reduced efficiency. This was evident from center-of-infection experiments, which showed that 21% of infected RMSK1/1 formed plaques when plated on its phage-sensitive parental strain, C2. Moreover, viable cell counts 0 and 4 h after infection were not significantly different from those of an uninfected culture. Further characterization showed that phage adsorption was normal, but burst size was reduced fivefold and the latent period was increased from 28.5 to 36 min. RMSK1/1 was resistant to other, but not all, similar phages. Phage sensitivity was restored to RMSK1/1 by transformation with a cloned DNA fragment from a genomic library of a phage-sensitive strain. Characterization of the DNA that restored phage sensitivity revealed an open reading frame with similarity to sequences encoding lysozymes (beta-1,4-N-acetylmuramidase) and lysins from various bacteria, a fungus, and phages of Lactobacillus and Streptococcus and also revealed DNA homologous to noncoding sequences of temperate phage of L. lactis, DNA similar to a region of phage sk1, a gene with similarity to tRNA genes, a prophage attachment site, and open reading frames with similarities to sun and to sequences encoding phosphoprotein phosphatases and protein kinases. Mutational analyses of the cloned DNA showed that the region of homology with lactococcal temperate phage was responsible for restoring the phage-sensitive phenotype. The region of homology with DNA of lactococcal temperate phage was similar to DNA from a previously characterized lactococcal phage that suppresses an abortive infection mechanism of phage resistance. The region of homology with lactococcal temperate phage was deleted from a phage-sensitive strain, but the strain was not phage resistant. The results suggest that the cloned DNA with homology to lactococcal temperate phage was not mutated in the phage-resistant strain. The cloned DNA apparently suppressed the mechanism of resistance, and it may do so by mimicking a region of phage DNA that interacts with components of the resistance mechanism.     

Genome and proteome of Campylobacter jejuni bacteriophage NCTC 12673

Campylobacter jejuni continues to be the leading cause of bacterial food-borne illness worldwide, so improvements to current methods used for bacterial detection and disease prevention are needed. We describe here the genome and proteome of C. jejuni bacteriophage NCTC 12673 and the exploitation of its receptor-binding protein for specific bacterial detection. Remarkably, the 135-kb Myoviridae genome of NCTC 12673 differs greatly from any other proteobacterial phage genome described (including C. jejuni phages CP220 and CPt10) and instead shows closest homology to the cyanobacterial T4-related myophages. The phage genome contains 172 putative open reading frames, including 12 homing endonucleases, no visible means of packaging, and a putative trans-splicing intein. The phage DNA appears to be strongly associated with a protein that interfered with PCR amplification and estimation of the phage genome mass by pulsed-field gel electrophoresis. Identification and analyses of the receptor-binding protein (Gp48) revealed features common to the Salmonella enterica P22 phage tailspike protein, including the ability to specifically recognize a host organism. Bacteriophage receptor-binding proteins may offer promising alternatives for use in pathogen detection platforms.     

Crystal Structure of a Chimeric Receptor Binding Protein Constructed from Two Lactococcal Phages

Lactococcus lactis, a gram-positive bacterium widely used by the dairy industry to manufacture cheeses, is subject to infection by a diverse population of virulent phages. We have previously determined the structures of three receptor binding proteins (RBPs) from lactococcal phages TP901-1, p2, and bIL170, each of them having a distinct host range. Virulent phages p2 and bIL170 are classified within the 936 group, while the temperate phage TP901-1 is a member of the genetically distinct P335 polythetic group. These RBPs comprise three domains: the N-terminal domain, binding to the virion particle; a β-helical linker domain; and the C-terminal domain, bearing the receptor binding site used for host recognition. Here, we have designed, expressed, and determined the structure of an RBP chimera in which the N-terminal and linker RBP domains of phage TP901-1 (P335) are fused to the C-terminal RBP domain of phage p2 (936). This chimera exhibits a stable structure that closely resembles the parental structures, while a slight displacement of the linker made RBP domain adaptation efficient. The receptor binding site is structurally indistinguishable from that of native p2 RBP and binds glycerol with excellent affinity.A broad number of products are manufactured by large-scale bacterial fermentation, including the value-added fermented dairy products. Most bacterial fermentation industries have experienced problems with phage contamination. Phage outbreaks are costly and time-consuming because they can slow or arrest the fermentation process and adversely affect product quality (15). For decades, the dairy industry has relied on an array of strategies to control this natural phenomenon, including rotation of their bacterial cultures (11, 24, 25). However, in spite of these efforts, new virulent lactococcal phages keep emerging. A better understanding of the various mechanisms affecting the genetic diversity of the phage population is necessary for optimal phage control strategies (18).Lactococcal phages are among the most studied bacterial viruses because of the economic importance of their hosts. Hundreds of lactococcal phages have been isolated, and the vast majority of them have a long, contractile tail, thereby belonging to the Siphoviridae family (1). Lactococcus lactis phages are currently classified into 10 genetically distinct groups (10), but only members of 3 of them are highly adapted to multiply in milk, namely, the 936, c2, and P335 groups (11, 24, 25). The first step for such an effective viral infection is host recognition, which necessitates the interaction between the adsorption device located at the distal tail end of the phage and the cell surface receptor (32). Members of the 936 and P335 groups recognize their host through an interaction between their receptor binding protein (RBP) (13) and receptors, probably lipoteichoic acids, at the host cell surface (27, 29-31).We have previously determined the crystal structures of three RBPs, from the virulent lactococcal phages p2 (30, 31) and bIL170 (936 group) (27) and from the temperate phage TP901-1 (P335 group) (29). The RBPs of these phages have a similar architecture of three protomers related by a threefold axis. Each protomer comprises three domains: the N terminus (named shoulders in p2), the interlaced β-prism linker (the “neck” domain), and the jelly-roll domain (2) at the C terminus (the “head” domain). This last domain harbors a saccharide binding site likely involved in host recognition, as it binds with high affinity to phosphoglycerol, a component of teichoic acid (8, 19, 27, 29-31). We have previously shown that the shoulder and neck domains are highly conserved in the RBPs of 936-like phages (8, 19, 27, 29-31). The individuality of the RBP C-terminal domain sequence likely dictates phage specificity for the receptor, which may specifically recognize different substitutions (H, GlcNAc, or d-Ala) of the phosphoglycerol moieties of the L. lactis teichoic acid polymers. Recently, the complete genomic sequence of the reference virulent phage P335 was determined, and comparative analysis revealed that the C terminus of its RBP showed homology to the RBP of the virulent lactococcal phage P475 of the 936 group (17). Such homology between RBP head domains was surprising because the two lactococcal phage groups rarely shared common genes or domains. This observation suggested that modular shuffling of domains can occur between these otherwise genetically distinct phage groups.The overall fold of the N-terminal RBP domain is different in 936- and P335-like phages. In the P335 group, the N-terminal domain comprises a unique helix that fits into the rest of the phage baseplate (28, 29) (Fig. ​(Fig.1A),1A), while in the 936 group, this 140-residue domain is a large β-sandwich with an external α-helix (30) (Fig. ​(Fig.1B).1B). Nonetheless, the N-terminal domains of the two RBPs may still be, related because both appear to be built using a coiled coil, although the 936-like phages have an additional β-sandwich. The β-prism linkers (neck domain) of the two phage groups also differ in sequence and in radius, but they have a similar fold, the latter being also close to that of T4 phage short fiber (33). The linker domain of phage TP901-1 is wider than that of p2 and exhibits a repeated motif (G-X-Y-X-Y, where X is polar and Y nonpolar). Finally, the C-terminal domains of both species share the same fold, a jelly-roll motif (2) also found in adenovirus (5) and reovirus (3, 4, 6).Open in a separate windowFIG. 1.Structures and sequences of RBPs from lactococcal phages. (A) Three-dimensional structure of the RBP from phage TP901-1 (P335 group; blue). (B) Three-dimensional structure of the RBP from phage p2 (936 group; magenta). (C) View of a model associating domains of TP901-1 (N terminus and linker domain, below red line, blue) and p2 (head, above red line, magenta) RBPs. (D) Three-dimensional crystal structure of chimera form 1 (yellow) assembled according to the model in panel C. (E) Sequence alignment of the RBPs of p2 (part) and TP901-1. The secondary structure is described above the alignment. The binding residues are shown with blue dots. The hinge proline (Pro 162/63) is identified by a red arrow. The chimera is composed of the N-terminal domain (residues 17 to 33) and the linker domain residues (residues 34 to 63) from phage TP901-1 RBP and the C-terminal domain (residues 163 to 264) from phage p2 RBP.The question addressed here was whether exchange between the C-terminal domains of two phage groups would lead to a stable protein with conserved binding capacity. To answer this question, we have generated an RBP chimera comprising the N-terminal and linker domains of phage TP901-1 fused to the C-terminal domain of phage p2. We have produced this chimera and determined its crystal structure and its sugar binding capacity. These results indicate that straightforward domain exchange produced a stable chimera with a conserved binding capacity and a structure close to that of each of the parental parts.     

Structure and function of phage p2 ORF34p2, a new type of single-stranded DNA binding protein

Lactococcus lactis , a Gram-positive bacterium widely used by the dairy industry, is subject to infection by a diverse population of virulent phages, predominantly by those of the 936 group, including the siphovirus phage p2. Confronted with the negative impact of phage infection on milk fermentation, the study of the biology of lactococcal provides insight from applied and fundamental perspectives. We decided to characterize the product of the orf34 gene from lactococcus phage p2, which was considered as a candidate single-stranded DNA binding protein (SSB) due to its localization downstream of a gene coding for a single-strand annealing protein. Two-dimensional gel electrophoresis showed that ORF34_p2 is expressed in large amounts during the early phases of phage infection, suggesting an important role in this process. Gel-shift assays, surface plasmon resonance and atomic force microscopy demonstrated that ORF34_p2 interacts with single-strand DNA with nanomolar affinity. We also determined the crystal structure of ORF34_p2 and showed that it bears a variation of the typical oligonucleotide/oligosaccharide binding-fold of SSBs. Finally, we found that ORF34_p2 is able to stimulate Escherichia coli RecA-mediated homologous recombination. The specific structural and biochemical properties that distinguish ORF34_p2 from other SSB proteins are discussed.