Your search keyword '"Leiman PG"' showing total 72 results

1. Microscopic Molecular Machines Help Bacteriophages to Package Their Genomes and Infect Their Hosts

Author

Leiman, PG, primary, Fokine, A, additional, Chipman, PR, additional, Kostyuchenko, VA, additional, Kanamaru, S, additional, Arisaka, F, additional, Mesyanzhinov, VV, additional, and Rossmann, MG, additional

Published

2006

2. T6SS-associated Rhs toxin-encapsulating shells: Structural and bioinformatical insights into bacterial weaponry and self-protection.

Author

Kielkopf CS, Shneider MM, Leiman PG, and Taylor NMI

Subjects

Bacterial Toxins chemistry, Bacterial Toxins metabolism, Bacterial Toxins genetics, Models, Molecular, Salmonella metabolism, Computational Biology, Protein Conformation, beta-Strand, Amino Acid Sequence, Type VI Secretion Systems metabolism, Type VI Secretion Systems chemistry, Bacterial Proteins chemistry, Bacterial Proteins metabolism

Abstract

Bacteria use the type VI secretion system (T6SS) to secrete toxins into pro- and eukaryotic cells via machinery consisting of a contractile sheath and a rigid tube. Rearrangement hotspot (Rhs) proteins represent one of the most common T6SS effectors. The Rhs C-terminal toxin domain displays great functional diversity, while the Rhs core is characterized by YD repeats. We elucidate the Rhs core structures of PAAR- and VgrG-linked Rhs proteins from Salmonella bongori and Advenella mimigardefordensis, respectively. The Rhs core forms a large shell of β-sheets with a negatively charged interior and encloses a large volume. The S. bongori Rhs toxin does not lead to ordered density in the Rhs shell, suggesting the toxin is unfolded. Together with bioinformatics analysis showing that Rhs toxins predominantly act intracellularly, this suggests that the Rhs core functions two-fold, as a safety feature for the producer cell and as delivery mechanism for the toxin., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

3. An extensive disulfide bond network prevents tail contraction in Agrobacterium tumefaciens phage Milano.

Author

Sonani RR, Palmer LK, Esteves NC, Horton AA, Sebastian AL, Kelly RJ, Wang F, Kreutzberger MAB, Russell WK, Leiman PG, Scharf BE, and Egelman EH

Subjects

Agrobacterium tumefaciens genetics, Cell Membrane metabolism, Bacteriophages genetics, Type VI Secretion Systems metabolism

Abstract

A contractile sheath and rigid tube assembly is a widespread apparatus used by bacteriophages, tailocins, and the bacterial type VI secretion system to penetrate cell membranes. In this mechanism, contraction of an external sheath powers the motion of an inner tube through the membrane. The structure, energetics, and mechanism of the machinery imply rigidity and straightness. The contractile tail of Agrobacterium tumefaciens bacteriophage Milano is flexible and bent to varying degrees, which sets it apart from other contractile tail-like systems. Here, we report structures of the Milano tail including the sheath-tube complex, baseplate, and putative receptor-binding proteins. The flexible-to-rigid transformation of the Milano tail upon contraction can be explained by unique electrostatic properties of the tail tube and sheath. All components of the Milano tail, including sheath subunits, are crosslinked by disulfides, some of which must be reduced for contraction to occur. The putative receptor-binding complex of Milano contains a tailspike, a tail fiber, and at least two small proteins that form a garland around the distal ends of the tailspikes and tail fibers. Despite being flagellotropic, Milano lacks thread-like tail filaments that can wrap around the flagellum, and is thus likely to employ a different binding mechanism., (© 2024. The Author(s).)

Published

2024

4. Neck and capsid architecture of the robust Agrobacterium phage Milano.

Author

Sonani RR, Esteves NC, Horton AA, Kelly RJ, Sebastian AL, Wang F, Kreutzberger MAB, Leiman PG, Scharf BE, and Egelman EH

Subjects

Capsid Proteins, Dendritic Spines, Agrobacterium, Capsid, Bacteriophages genetics

Abstract

Large gaps exist in our understanding of how bacteriophages, the most abundant biological entities on Earth, assemble and function. The structure of the "neck" region, where the DNA-filled capsid is connected to the host-recognizing tail remains poorly understood. We describe cryo-EM structures of the neck, the neck-capsid and neck-tail junctions, and capsid of the Agrobacterium phage Milano. The Milano neck 1 protein connects the 12-fold symmetrical neck to a 5-fold vertex of the icosahedral capsid. Comparison of Milano neck 1 homologs leads to four proposed classes, likely evolved from the simplest one in siphophages to more complex ones in myo- and podophages. Milano neck is surrounded by the atypical collar, which covalently crosslinks the tail sheath to neck 1. The Milano capsid is decorated with three types of proteins, a minor capsid protein (mCP) and two linking proteins crosslinking the mCP to the major capsid protein. The extensive network of disulfide bonds within and between neck, collar, capsid and tail provides an exceptional structural stability to Milano., (© 2023. Springer Nature Limited.)

Published

2023

5. Function of the bacteriophage P2 baseplate central spike Apex domain in the infection process.

Author

Miller JM, Knyazhanskaya ES, Buth SA, Prokhorov NS, and Leiman PG

Abstract

The contractile tail of bacteriophage P2 functions to drive the tail tube across the outer membrane of its host bacterium, a prerequisite event for subsequent translocation of phage genomic DNA into the host cell. The tube is equipped with a spike-shaped protein (product of P2 gene V , gpV or Spike) that contains a membrane-attacking Apex domain carrying a centrally positioned Fe ion. The ion is enclosed in a histidine cage that is formed by three symmetry-related copies of a conserved HxH (histidine, any residue, histidine) sequence motif. Here, we used solution biophysics and X-ray crystallography to characterize the structure and properties of Spike mutants in which the Apex domain was either deleted or its histidine cage was either destroyed or replaced with a hydrophobic core. We found that the Apex domain is not required for the folding of full-length gpV or its middle intertwined β-helical domain. Furthermore, despite its high conservation, the Apex domain is dispensable for infection in laboratory conditions. Collectively, our results show that the diameter of the Spike but not the nature of its Apex domain determines the efficiency of infection, which further strengthens the earlier hypothesis of a drill bit-like function of the Spike in host envelope disruption.

Published

2023

6. Structural basis of template strand deoxyuridine promoter recognition by a viral RNA polymerase.

Author

Fraser A, Sokolova ML, Drobysheva AV, Gordeeva JV, Borukhov S, Jumper J, Severinov KV, and Leiman PG

Subjects

DNA-Directed RNA Polymerases metabolism, Deoxyuridine, Promoter Regions, Genetic genetics, Sigma Factor metabolism, Transcription, Genetic, RNA, Viral, Viral Replicase Complex Proteins

Abstract

Recognition of promoters in bacterial RNA polymerases (RNAPs) is controlled by sigma subunits. The key sequence motif recognized by the sigma, the -10 promoter element, is located in the non-template strand of the double-stranded DNA molecule ~10 nucleotides upstream of the transcription start site. Here, we explain the mechanism by which the phage AR9 non-virion RNAP (nvRNAP), a bacterial RNAP homolog, recognizes the -10 element of its deoxyuridine-containing promoter in the template strand. The AR9 sigma-like subunit, the nvRNAP enzyme core, and the template strand together form two nucleotide base-accepting pockets whose shapes dictate the requirement for the conserved deoxyuridines. A single amino acid substitution in the AR9 sigma-like subunit allows one of these pockets to accept a thymine thus expanding the promoter consensus. Our work demonstrates the extent to which viruses can evolve host-derived multisubunit enzymes to make transcription of their own genes independent of the host., (© 2022. The Author(s).)

Published

2022

7. Computational models in the service of X-ray and cryo-electron microscopy structure determination.

Author

Kryshtafovych A, Moult J, Albrecht R, Chang GA, Chao K, Fraser A, Greenfield J, Hartmann MD, Herzberg O, Josts I, Leiman PG, Linden SB, Lupas AN, Nelson DC, Rees SD, Shang X, Sokolova ML, and Tidow H

Subjects

Protein Conformation, Software, Computational Biology methods, Cryoelectron Microscopy, Crystallography, X-Ray, Models, Molecular, Proteins chemistry

Abstract

Critical assessment of structure prediction (CASP) conducts community experiments to determine the state of the art in computing protein structure from amino acid sequence. The process relies on the experimental community providing information about not yet public or about to be solved structures, for use as targets. For some targets, the experimental structure is not solved in time for use in CASP. Calculated structure accuracy improved dramatically in this round, implying that models should now be much more useful for resolving many sorts of experimental difficulties. To test this, selected models for seven unsolved targets were provided to the experimental groups. These models were from the AlphaFold2 group, who overall submitted the most accurate predictions in CASP14. Four targets were solved with the aid of the models, and, additionally, the structure of an already solved target was improved. An a posteriori analysis showed that, in some cases, models from other groups would also be effective. This paper provides accounts of the successful application of models to structure determination, including molecular replacement for X-ray crystallography, backbone tracing and sequence positioning in a cryo-electron microscopy structure, and correction of local features. The results suggest that, in future, there will be greatly increased synergy between computational and experimental approaches to structure determination., (© 2021 Wiley Periodicals LLC.)

Published

2021

8. Quantitative description of a contractile macromolecular machine.

Author

Fraser A, Prokhorov NS, Jiao F, Pettitt BM, Scheuring S, and Leiman PG

Abstract

Contractile injection systems (CISs) [type VI secretion system (T6SS), phage tails, and tailocins] use a contractile sheath-rigid tube machinery to breach cell walls and lipid membranes. The structures of the pre- and postcontraction states of several CISs are known, but the mechanism of contraction remains poorly understood. Combining structural information of the end states of the 12-megadalton R-type pyocin sheath-tube complex with thermodynamic and force spectroscopy analyses and an original modeling procedure, we describe the mechanism of pyocin contraction. We show that this nanomachine has an activation energy of 160 kilocalories/mole (kcal/mol), and it releases 2160 kcal/mol of heat and develops a force greater than 500 piconewtons. Our combined approach provides a quantitative and experimental description of the membrane penetration process by a CIS., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution License 4.0 (CC BY).)

Published

2021

9. Reprogramming bacteriophage host range: design principles and strategies for engineering receptor binding proteins.

Author

Dunne M, Prokhorov NS, Loessner MJ, and Leiman PG

Subjects

Carrier Proteins, Host Specificity, Protein Binding, Protein Engineering, Bacteriophages genetics

Abstract

Bacteriophages (phages) use specialized tail machinery to deliver proteins and genetic material into a bacterial cell during infection. Attached at the distal ends of their tails are receptor binding proteins (RBPs) that recognize specific molecules exposed on host bacteria surfaces. Since the therapeutic capacity of naturally occurring phages is often limited by narrow host ranges, there is significant interest in expanding their host range via directed evolution or structure-guided engineering of their RBPs. Here, we describe the design principles of different RBP engineering platforms and draw attention to the mechanisms linking RBP binding and the correct spatial and temporal attachment of the phage to the bacterial surface. A deeper understanding of these mechanisms will directly benefit future engineering of more effective phage-based therapeutics., (Copyright © 2021 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2021

10. Structure and function of virion RNA polymerase of a crAss-like phage.

Author

Drobysheva AV, Panafidina SA, Kolesnik MV, Klimuk EI, Minakhin L, Yakunina MV, Borukhov S, Nilsson E, Holmfeldt K, Yutin N, Makarova KS, Koonin EV, Severinov KV, Leiman PG, and Sokolova ML

Subjects

Bacteriophages genetics, Catalytic Domain, Cell-Free System, Crystallography, X-Ray, DNA, Single-Stranded biosynthesis, DNA, Single-Stranded genetics, DNA-Directed RNA Polymerases genetics, Evolution, Molecular, Gene Expression Regulation, Viral, Genes, Viral genetics, Models, Biological, Models, Molecular, Protein Domains, Protein Subunits chemistry, Protein Subunits metabolism, RNA Interference, Transcription, Genetic, Bacteriophages classification, Bacteriophages enzymology, DNA-Directed RNA Polymerases chemistry, DNA-Directed RNA Polymerases metabolism, Flavobacteriaceae virology

Abstract

CrAss-like phages are a recently described expansive group of viruses that includes the most abundant virus in the human gut 1-3 . The genomes of all crAss-like phages encode a large virion-packaged protein 2,4 that contains a DFDxD sequence motif, which forms the catalytic site in cellular multisubunit RNA polymerases (RNAPs) 5 . Here, using Cellulophaga baltica crAss-like phage phi14:2 as a model system, we show that this protein is a DNA-dependent RNAP that is translocated into the host cell along with the phage DNA and transcribes early phage genes. We determined the crystal structure of this 2,180-residue enzyme in a self-inhibited state, which probably occurs before virion packaging. This conformation is attained with the help of a cleft-blocking domain that interacts with the active site and occupies the cavity in which the RNA-DNA hybrid binds. Structurally, phi14:2 RNAP is most similar to eukaryotic RNAPs that are involved in RNA interference 6,7 , although most of the phi14:2 RNAP structure (nearly 1,600 residues) maps to a new region of the protein fold space. Considering this structural similarity, we propose that eukaryal RNA interference polymerases have their origins in phage, which parallels the emergence of the mitochondrial transcription apparatus 8 .

Published

2021

11. Editorial overview: Virus structure and expression.

Author

Taylor NMI and Leiman PG

Subjects

Humans, Virus Diseases virology, Viral Structures, Viruses chemistry, Viruses genetics

Published

2020

12. Structural basis for recognition of bacterial cell wall teichoic acid by pseudo-symmetric SH3b-like repeats of a viral peptidoglycan hydrolase.

Author

Shen Y, Kalograiaki I, Prunotto A, Dunne M, Boulos S, Taylor NMI, Sumrall ET, Eugster MR, Martin R, Julian-Rodero A, Gerber B, Leiman PG, Menéndez M, Peraro MD, Cañada FJ, and Loessner MJ

Abstract

Endolysins are bacteriophage-encoded peptidoglycan hydrolases targeting the cell wall of host bacteria via their cell wall-binding domains (CBDs). The molecular basis for selective recognition of surface carbohydrate ligands by CBDs remains elusive. Here, we describe, in atomic detail, the interaction between the Listeria phage endolysin domain CBD500 and its cell wall teichoic acid (WTA) ligands. We show that 3' O -acetylated GlcNAc residues integrated into the WTA polymer chain are the key epitope recognized by a CBD binding cavity located at the interface of tandem copies of beta-barrel, pseudo-symmetric SH3b-like repeats. This cavity consists of multiple aromatic residues making extensive interactions with two GlcNAc acetyl groups via hydrogen bonds and van der Waals contacts, while permitting the docking of the diastereomorphic ligands. Our multidisciplinary approach tackled an extremely challenging protein-glycopolymer complex and delineated a previously unknown recognition mechanism by which a phage endolysin specifically recognizes and targets WTA, suggesting an adaptable model for regulation of endolysin specificity., Competing Interests: The authors declare no conflicts of interest., (This journal is © The Royal Society of Chemistry.)

Published

2020

13. The Central Spike Complex of Bacteriophage T4 Contacts PpiD in the Periplasm of Escherichia coli .

Author

Wenzel S, Shneider MM, Leiman PG, Kuhn A, and Kiefer D

Subjects

Cell Membrane metabolism, Escherichia coli Proteins genetics, Glycoside Hydrolases, Peptidylprolyl Isomerase genetics, Periplasm virology, Viral Envelope Proteins metabolism, Virus Attachment, Virus Internalization, Bacteriophage T4 metabolism, Escherichia coli virology, Escherichia coli Proteins metabolism, Peptidylprolyl Isomerase metabolism, Viral Tail Proteins metabolism

Abstract

Infecting bacteriophage T4 uses a contractile tail structure to breach the envelope of the Escherichia coli host cell. During contraction, the tail tube headed with the "central spike complex" is thought to mechanically puncture the outer membrane. We show here that a purified tip fragment of the central spike complex interacts with periplasmic chaperone PpiD, which is anchored to the cytoplasmic membrane. PpiD may be involved in the penetration of the inner membrane by the T4 injection machinery, resulting in a DNA-conducting channel to translocate the phage DNA into the interior of the cell. Host cells with the ppiD gene deleted showed partial reduction in the plating efficiency of T4, suggesting a supporting role of PpiD to improve the efficiency of the infection process.

Published

2020

14. Structure and Function of the T4 Spackle Protein Gp61.3.

Author

Kanamaru S, Uchida K, Nemoto M, Fraser A, Arisaka F, and Leiman PG

Subjects

Bacteriophage T4 genetics, Crystallography, X-Ray, Escherichia coli virology, Genome, Viral genetics, Protein Conformation, Viral Proteins genetics, Bacteriophage T4 enzymology, Muramidase antagonists & inhibitors, Viral Proteins metabolism

Abstract

The bacteriophage T4 genome contains two genes that code for proteins with lysozyme activity- e and 5 . Gene e encodes the well-known T4 lysozyme (commonly called T4L) that functions to break the peptidoglycan layer late in the infection cycle, which is required for liberating newly assembled phage progeny. Gene product 5 (gp5) is the tail-associated lysozyme, a component of the phage particle. It forms a spike at the tip of the tail tube and functions to pierce the outer membrane of the Escherichia coli host cell after the phage has attached to the cell surface. Gp5 contains a T4L-like lysozyme domain that locally digests the peptidoglycan layer upon infection. The T4 Spackle protein (encoded by gene 61.3 ) has been thought to play a role in the inhibition of gp5 lysozyme activity and, as a consequence, in making cells infected by bacteriophage T4 resistant to later infection by T4 and closely related phages. Here we show that (1) gp61.3 is secreted into the periplasm where its N-terminal periplasm-targeting peptide is cleaved off; (2) gp61.3 forms a 1:1 complex with the lysozyme domain of gp5 (gp5Lys); (3) gp61.3 selectively inhibits the activity of gp5, but not that of T4L; (4) overexpression of gp5 causes cell lysis. We also report a crystal structure of the gp61.3-gp5Lys complex that demonstrates that unlike other known lysozyme inhibitors, gp61.3 does not interact with the active site cleft. Instead, it forms a "wall" that blocks access of an extended polysaccharide substrate to the cleft and, possibly, locks the enzyme in an "open-jaw"-like conformation making catalysis impossible.

Published

2020

15. Structure and function of bacteriophage CBA120 ORF211 (TSP2), the determinant of phage specificity towards E. coli O157:H7.

Author

Greenfield J, Shang X, Luo H, Zhou Y, Linden SB, Heselpoth RD, Leiman PG, Nelson DC, and Herzberg O

Subjects

Bacteriophages metabolism, Bacteriophages pathogenicity, Catalytic Domain, Escherichia coli O157 metabolism, Glycoside Hydrolases, Species Specificity, Viral Tail Proteins genetics, Viral Tail Proteins metabolism, Virion, Bacteriophages genetics, Escherichia coli O157 genetics, Viral Tail Proteins ultrastructure

Abstract

The genome of Escherichia coli O157:H7 bacteriophage vB_EcoM_CBA120 encodes four distinct tailspike proteins (TSPs). The four TSPs, TSP1-4, attach to the phage baseplate forming a branched structure. We report the 1.9 Å resolution crystal structure of TSP2 (ORF211), the TSP that confers phage specificity towards E. coli O157:H7. The structure shows that the N-terminal 168 residues involved in TSPs complex assembly are disordered in the absence of partner proteins. The ensuing head domain contains only the first of two fold modules seen in other phage vB_EcoM_CBA120 TSPs. The catalytic site resides in a cleft at the interface between adjacent trimer subunits, where Asp506, Glu568, and Asp571 are located in close proximity. Replacement of Asp506 and Asp571 for alanine residues abolishes enzyme activity, thus identifying the acid/base catalytic machinery. However, activity remains intact when Asp506 and Asp571 are mutated into asparagine residues. Analysis of additional site-directed mutants in the background of the D506N:D571N mutant suggests engagement of an alternative catalytic apparatus comprising Glu568 and Tyr623. Finally, we demonstrate the catalytic role of two interacting glutamate residues of TSP1, located in a cleft between two trimer subunits, Glu456 and Glu483, underscoring the diversity of the catalytic apparatus employed by phage vB_EcoM_CBA120 TSPs.

Published

2020

16. Action of a minimal contractile bactericidal nanomachine.

Author

Ge P, Scholl D, Prokhorov NS, Avaylon J, Shneider MM, Browning C, Buth SA, Plattner M, Chakraborty U, Ding K, Leiman PG, Miller JF, and Zhou ZH

Subjects

Bacteriophage T4 chemistry, Bacteriophage T4 metabolism, Cryoelectron Microscopy, Crystallography, X-Ray, Genes, Bacterial genetics, Models, Molecular, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Substrate Specificity, Type VI Secretion Systems chemistry, Type VI Secretion Systems metabolism, Pseudomonas aeruginosa chemistry, Pseudomonas aeruginosa genetics, Pseudomonas aeruginosa metabolism, Pyocins chemistry, Pyocins metabolism

Abstract

R-type bacteriocins are minimal contractile nanomachines that hold promise as precision antibiotics 1-4 . Each bactericidal complex uses a collar to bridge a hollow tube with a contractile sheath loaded in a metastable state by a baseplate scaffold 1,2 . Fine-tuning of such nucleic acid-free protein machines for precision medicine calls for an atomic description of the entire complex and contraction mechanism, which is not available from baseplate structures of the (DNA-containing) T4 bacteriophage 5 . Here we report the atomic model of the complete R2 pyocin in its pre-contraction and post-contraction states, each containing 384 subunits of 11 unique atomic models of 10 gene products. Comparison of these structures suggests the following sequence of events during pyocin contraction: tail fibres trigger lateral dissociation of baseplate triplexes; the dissociation then initiates a cascade of events leading to sheath contraction; and this contraction converts chemical energy into mechanical force to drive the iron-tipped tube across the bacterial cell surface, killing the bacterium.

Published

2020

17. Target highlights in CASP13: Experimental target structures through the eyes of their authors.

Author

Lepore R, Kryshtafovych A, Alahuhta M, Veraszto HA, Bomble YJ, Bufton JC, Bullock AN, Caba C, Cao H, Davies OR, Desfosses A, Dunne M, Fidelis K, Goulding CW, Gurusaran M, Gutsche I, Harding CJ, Hartmann MD, Hayes CS, Joachimiak A, Leiman PG, Loppnau P, Lovering AL, Lunin VV, Michalska K, Mir-Sanchis I, Mitra AK, Moult J, Phillips GN Jr, Pinkas DM, Rice PA, Tong Y, Topf M, Walton JD, and Schwede T

Subjects

Arabidopsis chemistry, Arabidopsis ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Crystallography, X-Ray, Humans, Models, Molecular, Proteins chemistry, Proteins genetics, Computational Biology, Protein Conformation, Proteins ultrastructure

Abstract

The functional and biological significance of selected CASP13 targets are described by the authors of the structures. The structural biologists discuss the most interesting structural features of the target proteins and assess whether these features were correctly reproduced in the predictions submitted to the CASP13 experiment., (© 2019 The Authors. Proteins: Structure, Function, and Bioinformatics published by Wiley Periodicals, Inc.)

Published

2019

18. Modeling the Architecture of Depolymerase-Containing Receptor Binding Proteins in Klebsiella Phages.

Author

Latka A, Leiman PG, Drulis-Kawa Z, and Briers Y

Abstract

Klebsiella pneumoniae carries a thick polysaccharide capsule. This highly variable chemical structure plays an important role in its virulence. Many Klebsiella bacteriophages recognize this capsule with a receptor binding protein (RBP) that contains a depolymerase domain. This domain degrades the capsule to initiate phage infection. RBPs are highly specific and thus largely determine the host spectrum of the phage. A majority of known Klebsiella phages have only one or two RBPs, but phages with up to 11 RBPs with depolymerase activity and a broad host spectrum have been identified. A detailed bioinformatic analysis shows that similar RBP domains repeatedly occur in K. pneumoniae phages with structural RBP domains for attachment of an RBP to the phage tail (anchor domain) or for branching of RBPs (T4gp10-like domain). Structural domains determining the RBP architecture are located at the N-terminus, while the depolymerase is located in the center of protein. Occasionally, the RBP is complemented with an autocleavable chaperone domain at the distal end serving for folding and multimerization. The enzymatic domain is subjected to an intense horizontal transfer to rapidly shift the phage host spectrum without affecting the RBP architecture. These analyses allowed to model a set of conserved RBP architectures, indicating evolutionary linkages., (Copyright © 2019 Latka, Leiman, Drulis-Kawa and Briers.)

Published

2019

19. Structure and Function of the Branched Receptor-Binding Complex of Bacteriophage CBA120.

Author

Plattner M, Shneider MM, Arbatsky NP, Shashkov AS, Chizhov AO, Nazarov S, Prokhorov NS, Taylor NMI, Buth SA, Gambino M, Gencay YE, Brøndsted L, Kutter EM, Knirel YA, and Leiman PG

Subjects

Crystallography, X-Ray, Escherichia coli O157 metabolism, Escherichia coli Proteins metabolism, Host Specificity, Models, Molecular, Peptides chemistry, Peptides metabolism, Protein Binding, Protein Domains, Proteolysis, Salmonella enterica virology, Static Electricity, Structure-Activity Relationship, Substrate Specificity, Bacteriophages metabolism, Viral Proteins chemistry, Viral Proteins metabolism

Abstract

Bacteriophages recognize their host cells with the help of tail fiber and tailspike proteins that bind, cleave, or modify certain structures on the cell surface. The spectrum of ligands to which the tail fibers and tailspikes can bind is the primary determinant of the host range. Bacteriophages with multiple tailspike/tail fibers are thought to have a wider host range than their less endowed relatives but the function of these proteins remains poorly understood. Here, we describe the structure, function, and substrate specificity of three tailspike proteins of bacteriophage CBA120-TSP2, TSP3 and TSP4 (orf211 through orf213, respectively). We show that tailspikes TSP2, TSP3 and TSP4 are hydrolases that digest the O157, O77, and O78 Escherichia coli O-antigens, respectively. We demonstrate that recognition of the E. coli O157:H7 host by CBA120 involves binding to and digesting the O157 O-antigen by TSP2. We report the crystal structure of TSP2 in complex with a repeating unit of the O157 O-antigen. We demonstrate that according to the specificity of its tailspikes TSP2, TSP3, and TSP4, CBA120 can infect E. coli O157, O77, and O78, respectively. We also show that CBA120 infects Salmonella enterica serovar Minnesota, and this host range expansion is likely due to the function of TSP1. Finally, we describe the assembly pathway and the architecture of the TSP1-TSP2-TSP3-TSP4 branched complex in CBA120 and its related ViI-like phages., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

20. Structure and transformation of bacteriophage A511 baseplate and tail upon infection of Listeria  cells.

Author

Guerrero-Ferreira RC, Hupfeld M, Nazarov S, Taylor NM, Shneider MM, Obbineni JM, Loessner MJ, Ishikawa T, Klumpp J, and Leiman PG

Subjects

Cryoelectron Microscopy, Crystallography, X-Ray, Infections, Listeria growth & development, Models, Molecular, Viral Tail Proteins metabolism, Bacteriophages physiology, Bacteriophages ultrastructure, Listeria virology, Protein Conformation, Viral Tail Proteins chemistry

Abstract

Contractile injection systems (bacteriophage tails, type VI secretions system, R-type pyocins, etc.) utilize a rigid tube/contractile sheath assembly for breaching the envelope of bacterial and eukaryotic cells. Among contractile injection systems, bacteriophages that infect Gram-positive bacteria represent the least understood members. Here, we describe the structure of Listeria bacteriophage A511 tail in its pre- and post-host attachment states (extended and contracted, respectively) using cryo-electron microscopy, cryo-electron tomography, and X-ray crystallography. We show that the structure of the tube-baseplate complex of A511 is similar to that of phage T4, but the A511 baseplate is decorated with different receptor-binding proteins, which undergo a large structural transformation upon host attachment and switch the symmetry of the baseplate-tail fiber assembly from threefold to sixfold. For the first time under native conditions, we show that contraction of the phage tail sheath assembly starts at the baseplate and propagates through the sheath in a domino-like motion., (© 2019 The Authors.)

Published

2019

21. Salmonella Phage S16 Tail Fiber Adhesin Features a Rare Polyglycine Rich Domain for Host Recognition.

Author

Dunne M, Denyes JM, Arndt H, Loessner MJ, Leiman PG, and Klumpp J

Subjects

Binding Sites, Computer Simulation, Crystallography, X-Ray, Hydrophobic and Hydrophilic Interactions, Models, Molecular, Peptides chemistry, Protein Conformation, Protein Domains, Salmonella Phages chemistry, Peptides metabolism, Salmonella Phages metabolism, Viral Tail Proteins chemistry, Viral Tail Proteins metabolism

Abstract

The ability of phages to infect specific bacteria has led to their exploitation as bio-tools for bacterial remediation and detection. Many phages recognize bacterial hosts via adhesin tips of their long tail fibers (LTFs). Adhesin sequence plasticity modulates receptor specificity, and thus primarily defines a phage's host range. Here we present the crystal structure of an adhesin (gp38) attached to a trimeric β-helical tip (gp37) from the Salmonella phage S16 LTF. Gp38 contains rare polyglycine type II helices folded into a packed lattice, herein designated "PG II sandwich." Sequence variability within the domain is limited to surface-exposed helices and distal loops that form putative receptor-binding sites. In silico analyses revealed a prevalence of the adhesin architecture among T-even phages, excluding the archetypal T4 phage. Overall, S16 LTF provides a valuable model for understanding binding mechanisms of phage adhesins, and for engineering of phage adhesins with expandable or modulated host ranges., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

22. Structure and Analysis of R1 and R2 Pyocin Receptor-Binding Fibers.

Author

Buth SA, Shneider MM, Scholl D, and Leiman PG

Subjects

Binding Sites, Calcium chemistry, Calcium metabolism, Cations, Cloning, Molecular, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Iron chemistry, Iron metabolism, Magnesium chemistry, Magnesium metabolism, Models, Molecular, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Pseudomonas aeruginosa genetics, Pseudomonas aeruginosa metabolism, Pyocins metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sodium chemistry, Sodium metabolism, Substrate Specificity, Thermodynamics, Pseudomonas aeruginosa chemistry, Pyocins chemistry

Abstract

The R-type pyocins are high-molecular weight bacteriocins produced by some strains of Pseudomonas aeruginosa to specifically kill other strains of the same species. Structurally, the R-type pyocins are similar to "simple" contractile tails, such as those of phage P2 and Mu. The pyocin recognizes and binds to its target with the help of fibers that emanate from the baseplate structure at one end of the particle. Subsequently, the pyocin contracts its sheath and drives the rigid tube through the host cell envelope. This causes depolarization of the cytoplasmic membrane and cell death. The host cell surface-binding fiber is ~340 Å-long and is attached to the baseplate with its N-terminal domain. Here, we report the crystal structures of C-terminal fragments of the R1 and R2 pyocin fibers that comprise the distal, receptor-binding part of the protein. Both proteins are ~240 Å-long homotrimers in which slender rod-like domains are interspersed with more globular domains-two tandem knob domains in the N-terminal part of the fragment and a lectin-like domain at its C-terminus. The putative substrate binding sites are separated by about 100 Å, suggesting that binding of the fiber to the cell surface causes the fiber to adopt a certain orientation relative to the baseplate and this then triggers sheath contraction.

Published

2018

23. Contractile injection systems of bacteriophages and related systems.

Author

Taylor NMI, van Raaij MJ, and Leiman PG

Subjects

Bacteriophage T4 genetics, Biological Evolution, Cell Membrane chemistry, Cell Membrane metabolism, Genome, Viral, Gram-Negative Bacteria chemistry, Gram-Negative Bacteria genetics, Gram-Negative Bacteria physiology, Pyocins chemistry, Pyocins metabolism, Type VI Secretion Systems chemistry, Type VI Secretion Systems genetics, Type VI Secretion Systems physiology, Viral Tail Proteins genetics, X-Ray Diffraction, Bacteriophage T4 chemistry, Bacteriophage T4 physiology, Viral Tail Proteins chemistry, Viral Tail Proteins physiology

Abstract

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., (© 2018 John Wiley & Sons Ltd.)

Published

2018

24. Stretching the arms of the type VI secretion sheath protein.

Author

Leiman PG

Subjects

Bacterial Proteins, Bacterial Secretion Systems, Type VI Secretion Systems

Published

2018

25. The O-specific polysaccharide lyase from the phage LKA1 tailspike reduces Pseudomonas virulence.

Author

Olszak T, Shneider MM, Latka A, Maciejewska B, Browning C, Sycheva LV, Cornelissen A, Danis-Wlodarczyk K, Senchenkova SN, Shashkov AS, Gula G, Arabski M, Wasik S, Miroshnikov KA, Lavigne R, Leiman PG, Knirel YA, and Drulis-Kawa Z

Subjects

Biofilms, Virulence, Bacteriophages enzymology, O Antigens metabolism, Polysaccharide-Lyases metabolism, Pseudomonas virology

Abstract

Pseudomonas phage LKA1 of the subfamily Autographivirinae encodes a tailspike protein (LKA1gp49) which binds and cleaves B-band LPS (O-specific antigen, OSA) of Pseudomonas aeruginosa PAO1. The crystal structure of LKA1gp49 catalytic domain consists of a beta-helix, an insertion domain and a C-terminal discoidin-like domain. The putative substrate binding and processing site is located on the face of the beta-helix whereas the C-terminal domain is likely involved in carbohydrates binding. NMR spectroscopy and mass spectrometry analyses of degraded LPS (OSA) fragments show an O5 serotype-specific polysaccharide lyase specificity. LKA1gp49 reduces virulence in an in vivo Galleria mellonella infection model and sensitizes P. aeruginosa to serum complement activity. This enzyme causes biofilm degradation and does not affect the activity of ciprofloxacin and gentamicin. This is the first comprehensive report on LPS-degrading lyase derived from a Pseudomonas phage. Biological properties reveal a potential towards its applications in antimicrobial design and as a microbiological or biotechnological tool.

Published

2017

26. Refined Cryo-EM Structure of the T4 Tail Tube: Exploring the Lowest Dose Limit.

Author

Zheng W, Wang F, Taylor NMI, Guerrero-Ferreira RC, Leiman PG, and Egelman EH

Subjects

Bacteriophage T4 chemistry, Models, Molecular, Molecular Conformation, Software, Bacteriophage T4 ultrastructure, Cryoelectron Microscopy methods

Abstract

The bacteriophage T4 contractile tail (containing a tube and sheath) was the first biological assembly reconstructed in three dimensions by electron microscopy at a resolution of ∼35 Å in 1968. A single-particle reconstruction of the T4 baseplate was able to generate a 4.1 Å resolution map for the first two rings of the tube using the overall baseplate for alignment. We have now reconstructed the T4 tail tube at a resolution of 3.4 Å, more than a 1,000-fold increase in information content for the tube from 1968. We have used legacy software (Spider) to show that we can do better than the typical 2/3 Nyquist frequency. A reasonable map can be generated with only 1.5 electrons/Å 2 using the higher dose images for alignment, but increasing the dose results in a better map, consistent with other reports that electron dose does not represent the main limitation on resolution in cryo-electron microscopy., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

27. Function of bacteriophage G7C esterase tailspike in host cell adsorption.

Author

Prokhorov NS, Riccio C, Zdorovenko EL, Shneider MM, Browning C, Knirel YA, Leiman PG, and Letarov AV

Subjects

Adsorption physiology, Animals, Bacteriophage P22 chemistry, Bacteriophages physiology, Crystallography, X-Ray, Escherichia coli metabolism, Esterases genetics, Horses microbiology, Models, Molecular, Polysaccharides, Bacterial metabolism, Protein Binding, Protein Conformation, Viral Tail Proteins metabolism, Bacteriophage P22 physiology, Esterases metabolism

Abstract

Bacteriophages recognize and bind to their hosts with the help of receptor-binding proteins (RBPs) that emanate from the phage particle in the form of fibers or tailspikes. RBPs show a great variability in their shapes, sizes, and location on the particle. Some RBPs are known to depolymerize surface polysaccharides of the host while others show no enzymatic activity. Here we report that both RBPs of podovirus G7C - tailspikes gp63.1 and gp66 - are essential for infection of its natural host bacterium E. coli 4s that populates the equine intestinal tract. We characterize the structure and function of gp63.1 and show that unlike any previously described RPB, gp63.1 deacetylates surface polysaccharides of E. coli 4s leaving the backbone of the polysaccharide intact. We demonstrate that gp63.1 and gp66 form a stable complex, in which the N-terminal part of gp66 serves as an attachment site for gp63.1 and anchors the gp63.1-gp66 complex to the G7C tail. The esterase domain of gp63.1 as well as domains mediating the gp63.1-gp66 interaction is widespread among all three families of tailed bacteriophages., (© 2017 John Wiley & Sons Ltd.)

Published

2017

28. Genetic, Structural, and Phenotypic Properties of MS2 Coliphage with Resistance to ClO 2 Disinfection.

Author

Zhong Q, Carratalà A, Nazarov S, Guerrero-Ferreira RC, Piccinini L, Bachmann V, Leiman PG, and Kohn T

Subjects

Chlorine, Coliphages, Disinfectants, Oxides, Chlorine Compounds, Disinfection

Abstract

Common water disinfectants like chlorine have been reported to select for resistant viruses, yet little attention has been devoted to characterizing disinfection resistance. Here, we investigated the resistance of MS2 coliphage to inactivation by chlorine dioxide (ClO 2 ). ClO 2 inactivates MS2 by degrading its structural proteins, thereby disrupting the ability of MS2 to attach to and infect its host. ClO 2 -resistant virus populations emerged not only after repeated cycles of ClO 2 disinfection followed by regrowth but also after dilution-regrowth cycles in the absence of ClO 2 . The resistant populations exhibited several fixed mutations which caused the substitution of ClO 2 -labile by ClO 2 -stable amino acids. On a phenotypic level, these mutations resulted in a more stable host binding during inactivation compared to the wild-type, thus resulting in a greater ability to maintain infectivity. This conclusion was supported by cryo-electron microscopy reconstruction of the virus particle, which demonstrated that most structural modification occurred in the putative A protein, an important binding factor. Resistance was specific to the inactivation mechanism of ClO 2 and did not result in significant cross-resistance to genome-damaging disinfectants. Overall, our data indicate that resistant viruses may emerge even in the absence of ClO 2 pressure but that they can be inactivated by other common disinfectants.

Published

2016

29. Structure of the T4 baseplate and its function in triggering sheath contraction.

Author

Taylor NM, Prokhorov NS, Guerrero-Ferreira RC, Shneider MM, Browning C, Goldie KN, Stahlberg H, and Leiman PG

Subjects

Cryoelectron Microscopy, Crystallography, X-Ray, Models, Molecular, Protein Conformation, Bacteriophage T4 chemistry, Bacteriophage T4 ultrastructure, Viral Structural Proteins chemistry, Viral Structural Proteins ultrastructure

Abstract

Several systems, including contractile tail bacteriophages, the type VI secretion system and R-type pyocins, use a multiprotein tubular apparatus to attach to and penetrate host cell membranes. This macromolecular machine resembles a stretched, coiled spring (or sheath) wound around a rigid tube with a spike-shaped protein at its tip. A baseplate structure, which is arguably the most complex part of this assembly, relays the contraction signal to the sheath. Here we present the atomic structure of the approximately 6-megadalton bacteriophage T4 baseplate in its pre- and post-host attachment states and explain the events that lead to sheath contraction in atomic detail. We establish the identity and function of a minimal set of components that is conserved in all contractile injection systems and show that the triggering mechanism is universally conserved.

Published

2016

30. Structure and Biophysical Properties of a Triple-Stranded Beta-Helix Comprising the Central Spike of Bacteriophage T4.

Author

Buth SA, Menin L, Shneider MM, Engel J, Boudko SP, and Leiman PG

Subjects

Bacteriophage T4 metabolism, Biophysical Phenomena, Crystallography, X-Ray, Fatty Acids analysis, Mass Spectrometry, Models, Molecular, Protein Binding, Protein Conformation, Protein Folding, Bacteriophage T4 chemistry, Viral Proteins chemistry

Abstract

Gene product 5 (gp5) of bacteriophage T4 is a spike-shaped protein that functions to disrupt the membrane of the target cell during phage infection. Its C-terminal domain is a long and slender β-helix that is formed by three polypeptide chains wrapped around a common symmetry axis akin to three interdigitated corkscrews. The folding and biophysical properties of such triple-stranded β-helices, which are topologically related to amyloid fibers, represent an unsolved biophysical problem. Here, we report structural and biophysical characterization of T4 gp5 β-helix and its truncated mutants of different lengths. A soluble fragment that forms a dimer of trimers and that could comprise a minimal self-folding unit has been identified. Surprisingly, the hydrophobic core of the β-helix is small. It is located near the C-terminal end of the β-helix and contains a centrally positioned and hydrated magnesium ion. A large part of the β-helix interior comprises a large elongated cavity that binds palmitic, stearic, and oleic acids in an extended conformation suggesting that these molecules might participate in the folding of the complete β-helix.

Published

2015

31. Atomic structures of a bactericidal contractile nanotube in its pre- and postcontraction states.

Author

Ge P, Scholl D, Leiman PG, Yu X, Miller JF, and Zhou ZH

Subjects

Bacterial Proteins chemistry, Bacterial Secretion Systems, Bacteriophages chemistry, Cell Membrane metabolism, Contractile Proteins chemistry, Crystallography, X-Ray, Microscopy, Electron, Models, Molecular, Protein Structure, Secondary, Anti-Bacterial Agents chemistry, Contractile Proteins ultrastructure, Nanotubes chemistry, Pseudomonas aeruginosa pathogenicity, Pyocins chemistry

Abstract

R-type pyocins are representatives of contractile ejection systems, a class of biological nanomachines that includes, among others, the bacterial type VI secretion system (T6SS) and contractile bacteriophage tails. We report atomic models of the Pseudomonas aeruginosa precontraction pyocin sheath and tube, and the postcontraction sheath, obtained by cryo-EM at 3.5-Å and 3.9-Å resolutions, respectively. The central channel of the tube is negatively charged, in contrast to the neutral and positive counterparts in T6SSs and phage tails. The sheath is interwoven by long N- and C-terminal extension arms emanating from each subunit, which create an extensive two-dimensional mesh that has the same connectivity in the extended and contracted state of the sheath. We propose that the contraction process draws energy from electrostatic and shape complementarities to insert the inner tube through bacterial cell membranes to eventually kill the bacteria.

Published

2015

32. Introduction to “Viruses of Microbes III” special section of Virology.

Author

Leiman PG and Molineux IJ

Subjects

Virology trends, Viruses classification, Viruses genetics, Biodiversity, Virus Physiological Phenomena, Viruses isolation & purification

Published

2015

33. Structure and biochemical characterization of bacteriophage phi92 endosialidase.

Author

Schwarzer D, Browning C, Stummeyer K, Oberbeck A, Mühlenhoff M, Gerardy-Schahn R, and Leiman PG

Subjects

Crystallography, X-Ray, N-Acetylneuraminic Acid chemistry, N-Acetylneuraminic Acid metabolism, Protein Binding, Protein Conformation, Coliphages enzymology, Escherichia coli virology, Neuraminidase chemistry, Neuraminidase metabolism

Abstract

Surface-associated capsular polysaccharides (CPSs) protect bacteria against phage infection and enhance pathogenicity by interfering with the function of the host innate immune system. The CPS of enteropathogenic Escherichia coli K92 is a unique sialic acid polymer (polySia) with alternating α2,8- and α2,9-linkages. This CPS can be digested by the gene 143 encoded endosialidase of bacteriophage phi92. Here we report the crystal structure of the phi92 endosialidase in complex with a dimer of α2,9-linked sialic acid and analyze its catalytic functions. Unlike the well characterized and homologous endosialidase of phage K1F, the phi92 endosialidase is a bifunctional enzyme with high activity against α2,8- and low activity against α2,9-linkages in a polySia chain. Moreover, in contrast to the processive K1F endosialidase, the phi92 endosialidase degrades the polymer in a non-processive mode. Beyond describing the first endosialidase with α2,9-specificity, our data introduce a novel platform for studies of endosialidase regioselectivity and for engineering highly active α2,9-specific enzymes., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2015

34. Listeria phage A511, a model for the contractile tail machineries of SPO1-related bacteriophages.

Author

Habann M, Leiman PG, Vandersteegen K, Van den Bossche A, Lavigne R, Shneider MM, Bielmann R, Eugster MR, Loessner MJ, and Klumpp J

Subjects

Cell Wall metabolism, Genome, Viral, Microscopy, Electron, Transmission, Myoviridae classification, Rhamnose metabolism, Teichoic Acids metabolism, Bacterial Proteins metabolism, Listeria virology, Myoviridae physiology, Viral Proteins metabolism

Abstract

Recognition of the bacterial host and attachment to its surface are two critical steps in phage infection. Here we report the identification of Gp108 as the host receptor-binding protein of the broad host-range, virulent Listeria phage A511. The ligands for Gp108 were found to be N-acetylglucosamine and rhamnose substituents of the wall teichoic acids of the bacterial cell wall. Transmission electron microscopy and immunogold-labelling allowed us to create a model of the A511 baseplate in which Gp108 forms emanating short tail fibres. Data obtained for related phages, such as Staphylococcus phages ISP and Twort, demonstrate the evolutionary conservation of baseplate components and receptor-binding proteins within the Spounavirinae subfamily, and contractile tail machineries in general. Our data reveal key elements in the infection process of large phages infecting Gram-positive bacteria and generate insights into the complex adsorption process of phage A511 to its bacterial host., (© 2014 John Wiley & Sons Ltd.)

Published

2014

35. Structure and properties of the C-terminal β-helical domain of VgrG protein from Escherichia coli O157.

Author

Uchida K, Leiman PG, Arisaka F, and Kanamaru S

Subjects

Amino Acid Sequence, Crystallography, X-Ray, Escherichia coli O157 isolation & purification, Hydrogen Bonding, Models, Molecular, Molecular Sequence Data, Protein Multimerization, Protein Structure, Secondary, Protein Structure, Tertiary, Proteolysis, Salts metabolism, Solutions, Structure-Activity Relationship, Trypsin metabolism, Escherichia coli O157 metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism

Abstract

The bacterial Type 6 secretion system (T6SS) translocates protein toxins (also called effectors) from the cytosol of a T6SS-carrying cell to a target cell by a syringe-like supramolecular complex resembling a contractile tail of bacteriophages. Valine-glycine repeat protein G (VgrG) proteins, which are the homologues of the gp27-gp5 (gene product) cell puncturing complex of bacteriophage T4, are considered to be located at the attacking tip of the bacterial T6SS apparatus. Here, we over-expressed six VgrG proteins from pathogenic Escherichia coli O157 and CFT073 strains. Purified VgrG1 of E. coli O157 and c3393 of E. coli CFT073 form trimer in solution and are rich in β-structure. We also solved the crystal structure of a trypsin-resistant C-terminal fragment of E. coli O157 VgrG1 (VgrG1C(G561)) at 1.95 Å resolution. VgrG1C(G561) forms a three-stranded antiparallel β-helix which is structurally similar to the β-helix domain of the central spike protein (gp138) of phi92 phage, indicating a possible evolutional relationship. Comparison of four different three-stranded β-helix proteins shows how their amino acid composition determines the protein fold.

Published

2014

36. PAAR-repeat proteins sharpen and diversify the type VI secretion system spike.

Author

Shneider MM, Buth SA, Ho BT, Basler M, Mekalanos JJ, and Leiman PG

Subjects

Acinetobacter genetics, Acinetobacter metabolism, Protein Binding, Vibrio cholerae genetics, Vibrio cholerae metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Secretion Systems genetics, Microsatellite Repeats physiology

Abstract

The bacterial type VI secretion system (T6SS) is a large multicomponent, dynamic macromolecular machine that has an important role in the ecology of many Gram-negative bacteria. T6SS is responsible for translocation of a wide range of toxic effector molecules, allowing predatory cells to kill both prokaryotic as well as eukaryotic prey cells. The T6SS organelle is functionally analogous to contractile tails of bacteriophages and is thought to attack cells by initially penetrating them with a trimeric protein complex called the VgrG spike. Neither the exact protein composition of the T6SS organelle nor the mechanisms of effector selection and delivery are known. Here we report that proteins from the PAAR (proline-alanine-alanine-arginine) repeat superfamily form a sharp conical extension on the VgrG spike, which is further involved in attaching effector domains to the spike. The crystal structures of two PAAR-repeat proteins bound to VgrG-like partners show that these proteins sharpen the tip of the T6SS spike complex. We demonstrate that PAAR proteins are essential for T6SS-mediated secretion and target cell killing by Vibrio cholerae and Acinetobacter baylyi. Our results indicate a new model of the T6SS organelle in which the VgrG-PAAR spike complex is decorated with multiple effectors that are delivered simultaneously into target cells in a single contraction-driven translocation event.

Published

2013

37. Improving binding affinity and stability of peptide ligands by substituting glycines with D-amino acids.

Author

Chen S, Gfeller D, Buth SA, Michielin O, Leiman PG, and Heinis C

Subjects

Binding Sites, Catalytic Domain, Crystallography, X-Ray, Databases, Protein, Enzyme Inhibitors chemical synthesis, Enzyme Inhibitors chemistry, Enzyme Inhibitors metabolism, Humans, Kinetics, Ligands, Mutagenesis, Site-Directed, Peptide Library, Peptides chemistry, Peptides genetics, Protein Binding, Protein Stability, Proteolysis, Substrate Specificity, Urokinase-Type Plasminogen Activator antagonists & inhibitors, Urokinase-Type Plasminogen Activator metabolism, Amino Acids metabolism, Glycine metabolism, Peptides metabolism

Abstract

Improving the binding affinity and/or stability of peptide ligands often requires testing of large numbers of variants to identify beneficial mutations. Herein we propose a type of mutation that promises a high success rate. In a bicyclic peptide inhibitor of the cancer-related protease urokinase-type plasminogen activator (uPA), we observed a glycine residue that has a positive ϕ dihedral angle when bound to the target. We hypothesized that replacing it with a D-amino acid, which favors positive ϕ angles, could enhance the binding affinity and/or proteolytic resistance. Mutation of this specific glycine to D-serine in the bicyclic peptide indeed improved inhibitory activity (1.75-fold) and stability (fourfold). X-ray-structure analysis of the inhibitors in complex with uPA showed that the peptide backbone conformation was conserved. Analysis of known cyclic peptide ligands showed that glycine is one of the most frequent amino acids, and that glycines with positive ϕ angles are found in many protein-bound peptides. These results suggest that the glycine-to-D-amino acid mutagenesis strategy could be broadly applied., (Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2013

38. Bicyclic peptide ligands pulled out of cysteine-rich peptide libraries.

Author

Chen S, Rentero Rebollo I, Buth SA, Morales-Sanfrutos J, Touati J, Leiman PG, and Heinis C

Subjects

Alkylation, Amino Acid Sequence, Amino Acids chemistry, Combinatorial Chemistry Techniques, Crystallization, Disulfides, Electrophoresis, Polyacrylamide Gel, Ligands, Models, Molecular, Molecular Sequence Data, Oxidation-Reduction, Peptide Library, X-Ray Diffraction, Bridged Bicyclo Compounds chemistry, Cysteine chemistry, Peptides chemistry

Abstract

Bicyclic peptide ligands were found to have good binding affinity and target specificity. However, the method applied to generate bicyclic ligands based on phage-peptide alkylation is technically complex and limits its application to specialized laboratories. Herein, we report a method that involves a simpler and more robust procedure that additionally allows screening of structurally more diverse bicyclic peptide libraries. In brief, phage-encoded combinatorial peptide libraries of the format X(m)CX(n)CX(o)CX(p) are oxidized to connect two pairs of cysteines (C). This allows the generation of 3 × (m + n + o + p) different peptide topologies because the fourth cysteine can appear in any of the (m + n + o + p) randomized amino acid positions (X). Panning of such libraries enriched strongly peptides with four cysteines and yielded tight binders to protein targets. X-ray structure analysis revealed an important structural role of the disulfide bridges. In summary, the presented approach offers facile access to bicyclic peptide ligands with good binding affinities.

Published

2013

39. Crystal structure and location of gp131 in the bacteriophage phiKZ virion.

Author

Sycheva LV, Shneider MM, Sykilinda NN, Ivanova MA, Miroshnikov KA, and Leiman PG

Subjects

Amino Acid Sequence, Crystallography, X-Ray, Microscopy, Immunoelectron, Models, Molecular, Molecular Sequence Data, Protein Structure, Tertiary, Pseudomonas ultrastructure, Virion ultrastructure, Pseudomonas virology, Pseudomonas Phages chemistry, Viral Structural Proteins analysis, Virion chemistry

Abstract

Pseudomonas phage ϕKZ and its two close relatives ϕPA3 and 201ϕ2-1 are very large bacteriophages that form a separate branch in phage classification because their genomes are very different from the rest of GenBank sequence data. The contractile tail of ϕKZ is built from at least 32 different proteins, but a definitive structural function is assigned to only one of them-the tail sheath protein. Here, we report the crystal structure of the C-terminal domain of another phiKZ tail protein, gene product 131 (gp131C). We show that gp131 is located at the periphery of the baseplate and possibly associates with fibers that emanate from the baseplate. Gp131C is a seven-bladed β-propeller that has a shape of a skewed toroid. A small but highly conserved and negatively charged patch on the surface of gp131C might be important for substrate binding or for interaction with a different tail protein., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

40. A multivalent adsorption apparatus explains the broad host range of phage phi92: a comprehensive genomic and structural analysis.

Author

Schwarzer D, Buettner FF, Browning C, Nazarov S, Rabsch W, Bethe A, Oberbeck A, Bowman VD, Stummeyer K, Mühlenhoff M, Leiman PG, and Gerardy-Schahn R

Subjects

Adsorption, Algorithms, Computational Biology methods, Cryoelectron Microscopy methods, Escherichia coli metabolism, Escherichia coli virology, Genome, Genome, Bacterial, Genomics, Host Specificity, Models, Genetic, Molecular Conformation, Molecular Sequence Data, Open Reading Frames, RNA, Transfer metabolism, Salmonella metabolism, Salmonella virology, Sequence Analysis, DNA, Tandem Mass Spectrometry methods, Bacteriophages genetics, Bacteriophages metabolism

Abstract

Bacteriophage phi92 is a large, lytic myovirus isolated in 1983 from pathogenic Escherichia coli strains that carry a polysialic acid capsule. Here we report the genome organization of phi92, the cryoelectron microscopy reconstruction of its virion, and the reinvestigation of its host specificity. The genome consists of a linear, double-stranded 148,612-bp DNA sequence containing 248 potential open reading frames and 11 putative tRNA genes. Orthologs were found for 130 of the predicted proteins. Most of the virion proteins showed significant sequence similarities to proteins of myoviruses rv5 and PVP-SE1, indicating that phi92 is a new member of the novel genus of rv5-like phages. Reinvestigation of phi92 host specificity showed that the host range is not limited to polysialic acid-encapsulated Escherichia coli but includes most laboratory strains of Escherichia coli and many Salmonella strains. Structure analysis of the phi92 virion demonstrated the presence of four different types of tail fibers and/or tailspikes, which enable the phage to use attachment sites on encapsulated and nonencapsulated bacteria. With this report, we provide the first detailed description of a multivalent, multispecies phage armed with a host cell adsorption apparatus resembling a nanosized Swiss army knife. The genome, structure, and, in particular, the organization of the baseplate of phi92 demonstrate how a bacteriophage can evolve into a multi-pathogen-killing agent.

Published

2012

41. Phage pierces the host cell membrane with the iron-loaded spike.

Author

Browning C, Shneider MM, Bowman VD, Schwarzer D, and Leiman PG

Subjects

Amino Acid Sequence, Binding Sites, Coordination Complexes chemistry, Crystallography, X-Ray, Hydrophobic and Hydrophilic Interactions, Iron chemistry, Microscopy, Electron, Models, Molecular, Molecular Sequence Data, Multiprotein Complexes chemistry, Protein Structure, Quaternary, Protein Structure, Secondary, Sequence Homology, Amino Acid, Bacteriophage P2, Iron-Binding Proteins chemistry, Viral Structural Proteins chemistry

Abstract

Bacteriophages with contractile tails and the bacterial type VI secretion system have been proposed to use a special protein to create an opening in the host cell membrane during infection. These proteins have a modular architecture but invariably contain an oligonucleotide/oligosaccharide-binding (OB-fold) domain and a long β-helical C-terminal domain, which initiates the contact with the host cell membrane. Using X-ray crystallography and electron microscopy, we report the atomic structure of the membrane-piercing proteins from bacteriophages P2 and ϕ92 and identify the residues that constitute the membrane-attacking apex. Both proteins form compact spikes with a ∼10Å diameter tip that is stabilized by a centrally positioned iron ion bound by six histidine residues. The accumulated data strongly suggest that, in the process of membrane penetration, the spikes are translocated through the lipid bilayer without undergoing major unfolding., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

42. Contractile tail machines of bacteriophages.

Author

Leiman PG and Shneider MM

Subjects

Models, Molecular, Viral Proteins genetics, Bacteriophages ultrastructure, Protein Conformation, Viral Proteins chemistry

Abstract

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.

Published

2012

43. Morphogenesis of the T4 tail and tail fibers.

Author

Leiman PG, Arisaka F, van Raaij MJ, Kostyuchenko VA, Aksyuk AA, Kanamaru S, and Rossmann MG

Subjects

Crystallography, X-Ray, Imaging, Three-Dimensional, Microscopy, Electron, Models, Biological, Models, Molecular, Myoviridae chemistry, Myoviridae ultrastructure, Bacteriophage T4 chemistry, Bacteriophage T4 ultrastructure, Macromolecular Substances chemistry, Macromolecular Substances ultrastructure, Viral Tail Proteins chemistry, Viral Tail Proteins ultrastructure

Abstract

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.

Published

2010

44. The baseplate wedges of bacteriophage T4 spontaneously assemble into hubless baseplate-like structure in vitro.

Author

Yap ML, Mio K, Leiman PG, Kanamaru S, and Arisaka F

Subjects

Bacteriophage T4 chemistry, Bacteriophage T4 genetics, Bacteriophage T4 ultrastructure, In Vitro Techniques, Microscopy, Electron, Transmission, Models, Molecular, Multiprotein Complexes, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Recombinant Proteins ultrastructure, Viral Proteins chemistry, Viral Proteins genetics, Viral Proteins physiology, Viral Proteins ultrastructure, Virus Assembly genetics, Bacteriophage T4 physiology, Virus Assembly physiology

Abstract

The baseplate of phage T4 is an important model system in viral supramolecular assembly. The baseplate consists of six wedges surrounding the central hub. We report the first successful attempt at complete wedge assembly using an in vitro approach based on recombinant proteins. The cells expressing the individual wedge proteins were mixed in a combinatorial manner and then lysed. Using this approach, we could both reliably isolate the complete wedge along with a series of intermediate complexes as well as determine the exact sequence of assembly. The individual proteins and intermediate complexes at each step of the wedge assembly were successfully purified and characterized by sedimentation velocity and electron microscopy. Although our results mostly confirmed the hypothesized sequential wedge assembly pathway as established using phage mutants, interestingly, we also detected some protein interactions not following the specified order. It was found that association of gene product 53 to the immediate precursor complex induces spontaneous association of the wedges to form a six-fold star-shaped baseplate-like structure in the absence of the hub. The formation of the baseplate-like structure was facilitated by the addition of gene product 25. The complete wedge in the star-shaped supramolecular complex has a structure similar to the baseplate in the expanded "star" conformation found after infection. Based on the results of the present and previous studies, we assume that the strict order of wedge assembly is due to the induced conformational change caused by every new binding event. The significance of a 40-S star-shaped baseplate structure, which was previously reported and was also found in this study, is discussed in the light of a new paradigm for T4 baseplate assembly involving the star-shaped wedge ring and the central hub. Importantly, the methods described in this article suggest a novel methodology for future structural characterization of supramolecular protein assemblies., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

45. The structure of gene product 6 of bacteriophage T4, the hinge-pin of the baseplate.

Author

Aksyuk AA, Leiman PG, Shneider MM, Mesyanzhinov VV, and Rossmann MG

Subjects

Amino Acid Sequence, Cryoelectron Microscopy, Crystallization, Dimerization, Genes, Viral, Glycoproteins ultrastructure, Models, Molecular, Molecular Sequence Data, Protein Conformation, Protein Structure, Secondary, Protein Structure, Tertiary, Viral Proteins ultrastructure, Bacteriophage T4 genetics, Glycoproteins genetics, Glycoproteins physiology, Viral Proteins genetics, Viral Proteins physiology

Abstract

The baseplate of bacteriophage T4 is a multicomponent protein complex, which controls phage attachment to the host. It assembles from six wedges and a central hub. During infection the baseplate undergoes a large conformational change from a dome-shaped to a flat, star-shaped structure. We report the crystal structure of the C-terminal half of gene product (gp) 6 and investigate its motion with respect to the other proteins during the baseplate rearrangement. Six gp6 dimers interdigitate, forming a ring that maintains the integrity of the baseplate in both conformations. One baseplate wedge contains an N-terminal dimer of gp6, whereas neighboring wedges are tied together through the C-terminal dimer of gp6. The dimeric interactions are preserved throughout the rearrangement of the baseplate. However, the hinge angle between the N- and C-terminal parts of gp6 changes by approximately 15 degrees , accounting for a 10 A radial increase in the diameter of the gp6 ring.

Published

2009

46. Crystallographic insights into the autocatalytic assembly mechanism of a bacteriophage tail spike.

Author

Xiang Y, Leiman PG, Li L, Grimes S, Anderson DL, and Rossmann MG

Subjects

Adenosine Triphosphate metabolism, Amino Acid Sequence, Bacillus Phages chemistry, Catalytic Domain, Crystallography, X-Ray, Models, Molecular, Molecular Sequence Data, Sequence Alignment, Viral Structural Proteins genetics, Bacillus Phages ultrastructure, Protein Multimerization, Protein Processing, Post-Translational, Protein Structure, Quaternary, Viral Structural Proteins chemistry, Viral Structural Proteins metabolism

Abstract

The tailed bacteriophage phi29 has 12 "appendages" (gene product 12, gp12) attached to its neck region that participate in host cell recognition and entry. In the cell, monomeric gp12 undergoes proteolytic processing that releases the C-terminal domain during assembly into trimers. We report here crystal structures of the protein before and after catalytic processing and show that the C-terminal domain of gp12 is an "autochaperone" that aids trimerization. We also show that autocleavage of the C-terminal domain is a posttrimerization event that is followed by a unique ATP-dependent release. The posttranslationally modified N-terminal part has three domains that function to attach the appendages to the phage, digest the cell wall teichoic acids, and bind irreversibly to the host, respectively. Structural and sequence comparisons suggest that some eukaryotic and bacterial viruses as well as bacterial adhesins might have a similar maturation mechanism as is performed by phi29 gp12 for Bacillus subtilis.

Published

2009

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

Author

Aksyuk AA, Leiman PG, Kurochkina LP, Shneider MM, Kostyuchenko VA, Mesyanzhinov VV, and Rossmann MG

Subjects

Cloning, Molecular, Cryoelectron Microscopy, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Models, Molecular, Protein Structure, Tertiary, Viral Tail Proteins genetics, Viral Tail Proteins isolation & purification, Bacteriophage T4 metabolism, Viral Tail Proteins chemistry

Abstract

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.

Published

2009

48. Type VI secretion apparatus and phage tail-associated protein complexes share a common evolutionary origin.

Author

Leiman PG, Basler M, Ramagopal UA, Bonanno JB, Sauder JM, Pukatzki S, Burley SK, Almo SC, and Mekalanos JJ

Subjects

Bacterial Proteins metabolism, Bacteriophages chemistry, Gram-Negative Bacteria chemistry, Membrane Transport Proteins metabolism, Protein Conformation, Structural Homology, Protein, Bacterial Proteins chemistry, Biological Evolution, Caudovirales chemistry, Gram-Negative Bacteria pathogenicity, Membrane Transport Proteins physiology, Viral Proteins chemistry

Abstract

Protein secretion is a common property of pathogenic microbes. Gram-negative bacterial pathogens use at least 6 distinct extracellular protein secretion systems to export proteins through their multilayered cell envelope and in some cases into host cells. Among the most widespread is the newly recognized Type VI secretion system (T6SS) which is composed of 15-20 proteins whose biochemical functions are not well understood. Using crystallographic, biochemical, and bioinformatic analyses, we identified 3 T6SS components, which are homologous to bacteriophage tail proteins. These include the tail tube protein; the membrane-penetrating needle, situated at the distal end of the tube; and another protein associated with the needle and tube. We propose that T6SS is a multicomponent structure whose extracellular part resembles both structurally and functionally a bacteriophage tail, an efficient machine that translocates proteins and DNA across lipid membranes into cells.

Published

2009

49. Evolution of a new enzyme activity from the same motif fold.

Author

Leiman PG and Molineux IJ

Subjects

Binding Sites, Viral Tail Proteins metabolism, Coliphages chemistry, Coliphages enzymology, Escherichia coli virology, Protein Structure, Quaternary, Viral Tail Proteins chemistry

Abstract

The host cell recognition protein of the Escherichia coli bacteriophage HK620 is a large homotrimeric tailspike that cleaves the O18A1 type O antigen. The crystal structure of HK620 tailspike determined in the apo and substrate-bound form is reported by Barbirz et al. in this issue of Molecular Microbiology. Lacking detectable sequence similarity, the fold and overall organization of the HK620 tailspike are similar to those of the tailspikes of the related phages P22 and Sf6. The substrate-binding site is intrasubunit in P22 and HK620 tailspikes, but intersubunit in Sf6, demonstrating how phages can adapt the same protein fold to recognize different substrates.

Published

2008

50. The structures of bacteriophages K1E and K1-5 explain processive degradation of polysaccharide capsules and evolution of new host specificities.

Author

Leiman PG, Battisti AJ, Bowman VD, Stummeyer K, Mühlenhoff M, Gerardy-Schahn R, Scholl D, and Molineux IJ

Subjects

Bacteriophages genetics, Bacteriophages ultrastructure, Capsid chemistry, Cryoelectron Microscopy, DNA Packaging, DNA, Viral chemistry, Genome, Viral, Models, Molecular, Sequence Homology, Amino Acid, Species Specificity, Static Electricity, Viral Proteins chemistry, Viral Proteins ultrastructure, Virion chemistry, Bacterial Capsules metabolism, Bacteriophages chemistry, Biological Evolution, Escherichia coli virology

Abstract

External polysaccharides of many pathogenic bacteria form capsules protecting the bacteria from the animal immune system and phage infection. However, some bacteriophages can digest these capsules using glycosidases displayed on the phage particle. We have utilized cryo-electron microscopy to determine the structures of phages K1E and K1-5 and thereby establish the mechanism by which these phages attain and switch their host specificity. Using a specific glycosidase, both phages penetrate the capsule and infect the neuroinvasive human pathogen Escherichia coli K1. In addition to the K1-specific glycosidase, each K1-5 particle carries a second enzyme that allows it to infect E. coli K5, whose capsule is chemically different from that of K1. The enzymes are organized into a multiprotein complex attached via an adapter protein to the virus portal vertex, through which the DNA is ejected during infection. The structure of the complex suggests a mechanism for the apparent processivity of degradation that occurs as the phage drills through the polysaccharide capsule. The enzymes recognize the adapter protein by a conserved N-terminal sequence, providing a mechanism for phages to acquire different enzymes and thus to evolve new host specificities.

Published

2007