The Atomic Structure of the Phage Tuc2009 Baseplate Tripod Suggests that Host Recognition Involves Two Different Carbohydrate Binding Modules

ABSTRACT The Gram-positive bacterium Lactococcus lactis, used for the production of cheeses and other fermented dairy products, falls victim frequently to fortuitous infection by tailed phages. The accompanying risk of dairy fermentation failures in industrial facilities has prompted in-depth investigations of these phages. Lactococcal phage Tuc2009 possesses extensive genomic homology to phage TP901-1. However, striking differences in the baseplate-encoding genes stimulated our interest in solving the structure of this host’s adhesion device. We report here the X-ray structures of phage Tuc2009 receptor binding protein (RBP) and of a “tripod” assembly of three baseplate components, BppU, BppA, and BppL (the RBP). These structures made it possible to generate a realistic atomic model of the complete Tuc2009 baseplate that consists of an 84-protein complex: 18 BppU, 12 BppA, and 54 BppL proteins. The RBP head domain possesses a different fold than those of phages p2, TP901-1, and 1358, while the so-called “stem” and “neck” domains share structural features with their equivalents in phage TP901-1. The BppA module interacts strongly with the BppU N-terminal domain. Unlike other characterized lactococcal phages, Tuc2009 baseplate harbors two different carbohydrate recognition sites: one in the bona fide RBP head domain and the other in BppA. These findings represent a major step forward in deciphering the molecular mechanism by which Tuc2009 recognizes its saccharidic receptor(s) on its host. IMPORTANCE Understanding how siphophages infect Lactococcus lactis is of commercial importance as they cause milk fermentation failures in the dairy industry. In addition, such knowledge is crucial in a general sense in order to understand how viruses recognize their host through protein-glycan interactions. We report here the lactococcal phage Tuc2009 receptor binding protein (RBP) structure as well as that of its baseplate. The RBP head domain has a different fold than those of phages p2, TP901-1, and 1358, while the so-called “stem” and “neck” share the fold characteristics also found in the equivalent baseplate proteins of phage TP901-1. The baseplate structure contains, in contrast to other characterized lactococcal phages, two different carbohydrate binding modules that may bind different motifs of the host’s surface polysaccharide. Understanding how siphophages infect Lactococcus lactis is of commercial importance as they cause milk fermentation failures in the dairy industry. In addition, such knowledge is crucial in a general sense in order to understand how viruses recognize their host through protein-glycan interactions. We report here the lactococcal phage Tuc2009 receptor binding protein (RBP) structure as well as that of its baseplate. The RBP head domain has a different fold than those of phages p2, TP901-1, and 1358, while the so-called “stem” and “neck” share the fold characteristics also found in the equivalent baseplate proteins of phage TP901-1. The baseplate structure contains, in contrast to other characterized lactococcal phages, two different carbohydrate binding modules that may bind different motifs of the host’s surface polysaccharide.

[1]  A. Desmyter,et al.  Camelid nanobodies: killing two birds with one stone. , 2015, Current opinion in structural biology.

[2]  D. van Sinderen,et al.  Investigating the requirement for calcium during lactococcal phage infection. , 2015, International journal of food microbiology.

[3]  C. Cambillau,et al.  The targeted recognition of Lactococcus lactis phages to their polysaccharide receptors , 2015, Molecular microbiology.

[4]  D. van Sinderen,et al.  Gram-positive phage-host interactions , 2015, Front. Microbiol..

[5]  Charles A. Bowman,et al.  Exposing the Secrets of Two Well-Known Lactobacillus casei Phages, J-1 and PL-1, by Genomic and Structural Analysis , 2014, Applied and Environmental Microbiology.

[6]  C. Cambillau,et al.  Differences in Lactococcal Cell Wall Polysaccharide Structure Are Major Determining Factors in Bacteriophage Sensitivity , 2014, mBio.

[7]  C. Cambillau,et al.  Molecular Insights on the Recognition of a Lactococcus lactis Cell Wall Pellicle by the Phage 1358 Receptor Binding Protein , 2014, Journal of Virology.

[8]  Kristin N. Parent,et al.  OmpA and OmpC are critical host factors for bacteriophage Sf6 entry in Shigella , 2014, Molecular microbiology.

[9]  S. Muyldermans,et al.  A general protocol for the generation of Nanobodies for structural biology , 2014, Nature Protocols.

[10]  Christian Cambillau,et al.  Structures and host-adhesion mechanisms of lactococcal siphophages , 2014, Front. Microbiol..

[11]  M. van Heel,et al.  Structure, Adsorption to Host, and Infection Mechanism of Virulent Lactococcal Phage p2 , 2013, Journal of Virology.

[12]  H. Neve,et al.  Biodiversity of lactococcal bacteriophages isolated from 3 Gouda-type cheese-producing plants. , 2013, Journal of dairy science.

[13]  D. Veesler,et al.  Structure and Functional Analysis of the Host Recognition Device of Lactococcal Phage Tuc2009 , 2013, Journal of Virology.

[14]  A. Desmyter,et al.  Viral infection modulation and neutralization by camelid nanobodies , 2013, Proceedings of the National Academy of Sciences.

[15]  Bo Hu,et al.  The Bacteriophage T7 Virion Undergoes Extensive Structural Remodeling During Infection , 2013, Science.

[16]  Aldert L. Zomer,et al.  Complete Genome of Lactococcus lactis subsp. cremoris UC509.9, Host for a Model Lactococcal P335 Bacteriophage , 2013, Genome Announcements.

[17]  D. Veesler,et al.  Structure of the phage TP901-1 1.8 MDa baseplate suggests an alternative host adhesion mechanism , 2012, Proceedings of the National Academy of Sciences.

[18]  E. Castro-Nallar,et al.  Population Genomics and Phylogeography of an Australian Dairy Factory Derived Lytic Bacteriophage , 2012, Genome biology and evolution.

[19]  I. Nes,et al.  Bacteriophages in milk fermentations: Diversity fluctuations of normal and failed fermentations , 2011 .

[20]  D. Veesler,et al.  Unraveling Lactococcal Phage Baseplate Assembly by Mass Spectrometry , 2011, Molecular & Cellular Proteomics.

[21]  N. Pannu,et al.  REFMAC5 for the refinement of macromolecular crystal structures , 2011, Acta crystallographica. Section D, Biological crystallography.

[22]  M. Rossmann,et al.  Structure of bacteriophage ϕ29 head fibers has a supercoiled triple repeating helix-turn-helix motif , 2011, Proceedings of the National Academy of Sciences.

[23]  M. Rossmann,et al.  Morphogenesis of the T4 tail and tail fibers , 2010, Virology Journal.

[24]  J. Otero,et al.  Structure of the bacteriophage T4 long tail fiber receptor-binding tip , 2010, Proceedings of the National Academy of Sciences.

[25]  A. Davidson,et al.  The solution structure of the C-terminal Ig-like domain of the bacteriophage λ tail tube protein. , 2010, Journal of Molecular Biology.

[26]  M. van Heel,et al.  Structure and Molecular Assignment of Lactococcal Phage TP901-1 Baseplate* , 2010, The Journal of Biological Chemistry.

[27]  G. Sciara,et al.  Solution and electron microscopy characterization of lactococcal phage baseplates expressed in Escherichia coli. , 2010, Journal of structural biology.

[28]  G. Sciara,et al.  Structure of lactococcal phage p2 baseplate and its mechanism of activation , 2010, Proceedings of the National Academy of Sciences.

[29]  Kevin Cowtan,et al.  Recent developments in classical density modification , 2010, Acta crystallographica. Section D, Biological crystallography.

[30]  P. Emsley,et al.  Features and development of Coot , 2010, Acta crystallographica. Section D, Biological crystallography.

[31]  C. Péchoux,et al.  Cell Surface of Lactococcus lactis Is Covered by a Protective Polysaccharide Pellicle* , 2010, The Journal of Biological Chemistry.

[32]  A. Imberty,et al.  A TNF-like trimeric lectin domain from Burkholderia cenocepacia with specificity for fucosylated human histo-blood group antigens. , 2010, Structure.

[33]  Andreas Plückthun,et al.  Crystal Structure and Function of a DARPin Neutralizing Inhibitor of Lactococcal Phage TP901-1 , 2009, The Journal of Biological Chemistry.

[34]  Sylvain Moineau,et al.  Evolution of Lactococcus lactis Phages within a Cheese Factory , 2009, Applied and Environmental Microbiology.

[35]  Michael G Rossmann,et al.  The tail sheath structure of bacteriophage T4: a molecular machine for infecting bacteria , 2009, EMBO Journal.

[36]  A. Desmyter,et al.  Camelid nanobodies raised against an integral membrane enzyme, nitric oxide reductase , 2009, Protein science : a publication of the Protein Society.

[37]  Liisa Holm,et al.  Searching protein structure databases with DaliLite v.3 , 2008, Bioinform..

[38]  C. São-José,et al.  Phage SPP1 Reversible Adsorption to Bacillus subtilis Cell Wall Teichoic Acids Accelerates Virus Recognition of Membrane Receptor YueB , 2008, Journal of bacteriology.

[39]  G. Sciara,et al.  A Topological Model of the Baseplate of Lactococcal Phage Tuc2009* , 2008, Journal of Biological Chemistry.

[40]  K. Henrick,et al.  Inference of macromolecular assemblies from crystalline state. , 2007, Journal of molecular biology.

[41]  P. Leiman,et al.  The structures of bacteriophages K1E and K1-5 explain processive degradation of polysaccharide capsules and evolution of new host specificities. , 2007, Journal of molecular biology.

[42]  E. Orlova,et al.  Structure of bacteriophage SPP1 tail reveals trigger for DNA ejection , 2007, The EMBO journal.

[43]  Randy J. Read,et al.  Phaser crystallographic software , 2007, Journal of applied crystallography.

[44]  Olga Mayans,et al.  Molecular determinants for the recruitment of the ubiquitin‐ligase MuRF‐1 onto M‐line titin , 2007, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[45]  A. Szczepańska,et al.  Biodiversity of Lactococcus lactis bacteriophages in Polish dairy environment. , 2007, Acta biochimica Polonica.

[46]  Airlie J. McCoy,et al.  Solving structures of protein complexes by molecular replacement with Phaser , 2006, Acta crystallographica. Section D, Biological crystallography.

[47]  C. Cambillau,et al.  Crystal Structure of the Receptor-Binding Protein Head Domain from Lactococcus lactis Phage bIL170 , 2006, Journal of Virology.

[48]  Kevin Cowtan,et al.  The Buccaneer software for automated model building. 1. Tracing protein chains. , 2006, Acta crystallographica. Section D, Biological crystallography.

[49]  J. Conway,et al.  Bacteriophage T5 structure reveals similarities with HK97 and T4 suggesting evolutionary relationships. , 2006, Journal of molecular biology.

[50]  Kevin Cowtan,et al.  The Buccaneer software for automated model building , 2006 .

[51]  H. Deveau,et al.  Biodiversity and Classification of Lactococcal Phages , 2006, Applied and Environmental Microbiology.

[52]  Sylvain Moineau,et al.  Modular Structure of the Receptor Binding Proteins of Lactococcus lactis Phages , 2006, Journal of Biological Chemistry.

[53]  J. Lepault,et al.  The Ectodomain of the Viral Receptor YueB Forms a Fiber That Triggers Ejection of Bacteriophage SPP1 DNA* , 2006, Journal of Biological Chemistry.

[54]  R. Vincentelli,et al.  Automated expression and solubility screening of His-tagged proteins in 96-well format. , 2005, Analytical biochemistry.

[55]  M. Rossmann,et al.  Conservation of the capsid structure in tailed dsDNA bacteriophages: the pseudoatomic structure of phi29. , 2005, Molecular cell.

[56]  G. Bricogne,et al.  Refinement of severely incomplete structures with maximum likelihood in BUSTER-TNT. , 2004, Acta crystallographica. Section D, Biological crystallography.

[57]  Conrad C. Huang,et al.  UCSF Chimera—A visualization system for exploratory research and analysis , 2004, J. Comput. Chem..

[58]  F. Vogensen,et al.  Identification of Lactococcus lactis Genes Required for Bacteriophage Adsorption , 2004, Applied and Environmental Microbiology.

[59]  Michael G Rossmann,et al.  Molecular architecture of the prolate head of bacteriophage T4. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[60]  Fumio Arisaka,et al.  The bacteriophage T4 DNA injection machine. , 2004, Current opinion in structural biology.

[61]  Fumio Arisaka,et al.  Three-dimensional structure of bacteriophage T4 baseplate , 2003, Nature Structural Biology.

[62]  Renaud Vincentelli,et al.  Medium-scale structural genomics: strategies for protein expression and crystallization. , 2003, Accounts of chemical research.

[63]  George M Sheldrick,et al.  Substructure solution with SHELXD. , 2002, Acta crystallographica. Section D, Biological crystallography.

[64]  Didier Nurizzo,et al.  Differential Oligosaccharide Recognition by Evolutionarily-related β-1,4 and β-1,3 Glucan-binding Modules , 2002 .

[65]  M. Desmadril,et al.  Characterization of a high-affinity complex between the bacterial outer membrane protein FhuA and the phage T5 protein pb5. , 2002, Journal of molecular biology.

[66]  Fumio Arisaka,et al.  Structure of the cell-puncturing device of bacteriophage T4 , 2002, Nature.

[67]  M. Hofnung,et al.  Cloning of the J gene of bacteriophage lambda, expression and solubilization of the J protein: first in vitro studies on the interactions between J and LamB, its cell surface receptor. , 1998, Research in microbiology.

[68]  S. Moineau,et al.  Isolation and Characterization of Lactococcal Bacteriophages from Cultured Buttermilk Plants in the United States , 1996 .

[69]  L. Letellier,et al.  Calcium controls phage T5 infection at the level of the Escherichia coli cytoplasmic membrane , 1995, FEBS letters.

[70]  W. Sandine,et al.  A membrane protein is required for bacteriophage c2 infection of Lactococcus lactis subsp. lactis C2 , 1991, Journal of bacteriology.

[71]  And,et al.  Roles of lipopolysaccharide and outer membrane protein OmpC of Escherichia coli K-12 in the receptor function for bacteriophage T4 , 1982, Journal of bacteriology.

[72]  L. Randall-Hazelbauer,et al.  Isolation of the Bacteriophage Lambda Receptor from Escherichia coli , 1973, Journal of bacteriology.

[73]  A. Davidson,et al.  Long noncontractile tail machines of bacteriophages. , 2012, Advances in experimental medicine and biology.

[74]  Alexei Vagin,et al.  Molecular replacement with MOLREP. , 2010, Acta crystallographica. Section D, Biological crystallography.

[75]  A. Plückthun,et al.  Crystal structure and function of a DARPin neutralizing inhibitor of lactococcal phage TP901-1: comparison of DARPin and camelid VHH binding mode , 2010 .

[76]  Sylvain Moineau,et al.  Lactococcal bacteriophage p2 receptor-binding protein structure suggests a common ancestor gene with bacterial and mammalian viruses , 2006, Nature Structural &Molecular Biology.

[77]  I. Riede Receptor specificity of the short tail fibres (gp12) of T-even type Escherichia coli phages , 2004, Molecular and General Genetics MGG.

[78]  Didier Nurizzo,et al.  Differential oligosaccharide recognition by evolutionarily-related beta-1,4 and beta-1,3 glucan-binding modules. , 2002, Journal of molecular biology.

[79]  Vincent B. Chen,et al.  PHENIX: a comprehensive Python-based system for macromolecular structure solution , 2010, Acta crystallographica. Section D, Biological crystallography.