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1. ORACLE reveals a bright future to fight bacteria.

Author

Coyote-Maestas, Willow and Fraser, James S

Subjects
Humans, Bacteria, Bacteriophages, bacteriophage, biochemistry, chemical biology, deep mutational scanning, phage, synthetic biology, tail fiber, virus, virus engineering, Biochemistry and Cell Biology
Abstract

A new way to alter the genome of bacteriophages helps produce large libraries of variants, allowing these bacteria-killing viruses to be designed to target species harmful to human health.

Published
2021

2. Extracellular Polysaccharide Receptor and Receptor-Binding Proteins of the Rhodobacter capsulatus Bacteriophage-like Gene Transfer Agent RcGTA.

Author

Alim, Nawshin T. B., Koppenhöfer, Sonja, Lang, Andrew S., and Beatty, J. Thomas

Subjects
*GENETIC transformation, *POLYSACCHARIDES, *PROTEIN receptors, *HORIZONTAL gene transfer, *MICROSCOPY
Abstract

A variety of prokaryotes produce a bacteriophage-like gene transfer agent (GTA), and the alphaproteobacterial Rhodobacter capsulatus RcGTA is a model GTA. Some environmental isolates of R. capsulatus lack the ability to acquire genes transferred by the RcGTA (recipient capability). In this work, we investigated the reason why R. capsulatus strain 37b4 lacks recipient capability. The RcGTA head spike fiber and tail fiber proteins have been proposed to bind extracellular oligosaccharide receptors, and strain 37b4 lacks a capsular polysaccharide (CPS). The reason why strain 37b4 lacks a CPS was unknown, as was whether the provision of a CPS to 37b4 would result in recipient capability. To address these questions, we sequenced and annotated the strain 37b4 genome and used BLAST interrogations of this genome sequence to search for homologs of genes known to be needed for R. capsulatus recipient capability. We also created a cosmid-borne genome library from a wild-type strain, mobilized the library into 37b4, and used the cosmid-complemented strain 37b4 to identify genes needed for a gain of function, allowing for the acquisition of RcGTA-borne genes. The relative presence of CPS around a wild-type strain, 37b4, and cosmid-complemented 37b4 cells was visualized using light microscopy of stained cells. Fluorescently tagged head spike fiber and tail fiber proteins of the RcGTA particle were created and used to measure the relative binding to wild-type and 37b4 cells. We found that strain 37b4 lacks recipient capability because of an inability to bind RcGTA; the reason it is incapable of binding is that it lacks CPS, and the absence of CPS is due to the absence of genes previously shown to be needed for CPS production in another strain. In addition to the head spike fiber, we found that the tail fiber protein also binds to the CPS. [ABSTRACT FROM AUTHOR]

Published
2023
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3. Isolation, Characterization, Genome Analysis and Host Resistance Development of Two Novel Lastavirus Phages Active against Pandrug-Resistant Klebsiella pneumoniae.

Author

Obradović, Mina, Malešević, Milka, Di Luca, Mariagrazia, Kekić, Dušan, Gajić, Ina, McAuliffe, Olivia, Neve, Horst, Stanisavljević, Nemanja, Vukotić, Goran, and Kojić, Milan

Subjects
*KLEBSIELLA pneumoniae, *DISEASE resistance of plants, *BACTERIOPHAGES, *BASE pairs, *SEQUENCE analysis
Abstract

Klebsiella pneumoniae is a global health threat and bacteriophages are a potential solution in combating pandrug-resistant K. pneumoniae infections. Two lytic phages, LASTA and SJM3, active against several pandrug-resistant, nosocomial strains of K. pneumoniae were isolated and characterized. Their host range is narrow and latent period is particularly long; however, their lysogenic nature was refuted using both bioinformatic and experimental approaches. Genome sequence analysis clustered them with only two other phages into the new genus Lastavirus. Genomes of LASTA and SJM3 differ in only 13 base pairs, mainly located in tail fiber genes. Individual phages, as well as their cocktail, demonstrated significant bacterial reduction capacity in a time-dependent manner, yielding up to 4 log reduction against planktonic, and up to 2.59 log on biofilm-embedded, cells. Bacteria emerging from the contact with the phages developed resistance and achieved numbers comparable to the growth control after 24 h. The resistance to the phage seems to be of a transient nature and varies significantly between the two phages, as resistance to LASTA remained constant while resensitization to SJM3 was more prominent. Albeit with very few differences, SJM3 performed better than LASTA overall; however, more investigation is needed in order to consider them for therapeutic application. [ABSTRACT FROM AUTHOR]

Published
2023
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4. Predictable Molecular Adaptation of Coevolving Enterococcus faecium and Lytic Phage EfV12-phi1

Author

Wandro, Stephen, Oliver, Andrew, Gallagher, Tara, Weihe, Claudia, England, Whitney, Martiny, Jennifer BH, and Whiteson, Katrine

Subjects
Microbiology, Medical Microbiology, Biomedical and Clinical Sciences, Biological Sciences, Genetics, Antimicrobial Resistance, Human Genome, Infectious Diseases, Biotechnology, Aetiology, 2.1 Biological and endogenous factors, Infection, phage, Enterococcus, experimental evolution, phage therapy, tail fiber, exopolysaccharide, coevolution, Environmental Science and Management, Soil Sciences, Medical microbiology
Abstract

Bacteriophages are highly abundant in human microbiota where they coevolve with resident bacteria. Phage predation can drive the evolution of bacterial resistance, which can then drive reciprocal evolution in the phage to overcome that resistance. Such coevolutionary dynamics have not been extensively studied in human gut bacteria, and are of particular interest for both understanding and eventually manipulating the human gut microbiome. We performed experimental evolution of an Enterococcus faecium isolate from healthy human stool in the absence and presence of a single infecting Myoviridae bacteriophage, EfV12-phi1. Four replicates of E. faecium and phage were grown with twice daily serial transfers for 8 days. Genome sequencing revealed that E. faecium evolved resistance to phage through mutations in the yqwD2 gene involved in exopolysaccharide biogenesis and export, and the rpoC gene which encodes the RNA polymerase β' subunit. In response to bacterial resistance, phage EfV12-phi1 evolved varying numbers of 1.8 kb tandem duplications within a putative tail fiber gene. Host range assays indicated that coevolution of this phage-host pair resulted in arms race dynamics in which bacterial resistance and phage infectivity increased over time. Tracking mutations from population sequencing of experimental coevolution can quickly illuminate phage entry points along with resistance strategies in both phage and host - critical information for using phage to manipulate microbial communities.

Published
2019

5. A Novel Aeromonas popoffii Phage AerP_220 Proposed to Be a Member of a New Tolavirus Genus in the Autographiviridae Family.

Author

Morozova, Vera, Kozlova, Yuliya, Jdeed, Ghadeer, Tikunov, Artem, Ushakova, Tatyana, Bardasheva, Alevtina, Zhirakovskaia, Elena, Poletaeva, Yuliya, Ryabchikova, Elena, and Tikunova, Nina V.

Subjects
*AEROMONAS, *URINARY tract infections, *BACTERIOPHAGES, *GENOMICS, *AEROMONAS hydrophila, *DRUG resistance in bacteria
Abstract

Aeromonas popoffii is one of the environmental Aeromonas species. A number of factors of virulence have been described for this species and it has been reported as a causative agent of urinary tract infection. The first A. popoffii bacteriophage AerP_220 along with its host strain A. popoffii CEMTC 4062 were isolated from river water. The phage has a podovirus morphotype, shows a narrow host range and is lytic against the host strain. The AerP_220 genome comprises 45,207 bp and does not contain genes responsible for antibiotic resistance and toxin production. Fifty-nine co-directional putative ORFs were found in the AerP_220 genome. Thirty-three ORFs encoded proteins with predicted functions; the products of 26 ORFs were hypothetical proteins. AerP_220 genome analysis revealed that this phage can be considered a novel species within the Autographiviridae family. Comparative genomic and proteomic analysis revealed that AerP_220 along with the Aeromonas phage vB_AspA_Tola (OM913599) are members of a new putative Tolavirus genus in the family Autographiviridae. The Gajwadongvirus and proposed Tolavirus genera along with Pantoea phage Nufs112 and phage Reminis could form a new Tolavirinae subfamily within the Autographiviridae family. [ABSTRACT FROM AUTHOR]

Published
2022
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6. T7 噬菌体尾丝蛋白随机进化文库的构建.

Author

洪伟鸣, 李睿婷, 郭子杰, 徐海, 左伟勇, 张亮, and 宋亮

Subjects
DNA sequencing, LIVESTOCK breeding, LIVESTOCK breeds, GENE libraries, BACTERIOPHAGES, PLASMID genetics, PLASMIDS, GENE amplification
Abstract

Copyright of Acta Agriculturae Zhejiangensis is the property of Acta Agriculturae Zhejiangensis Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2022
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7. Understanding Bacteriophage Tail Fiber Interaction with Host Surface Receptor: The Key "Blueprint" for Reprogramming Phage Host Range.

Author

Taslem Mourosi, Jarin, Awe, Ayobami, Guo, Wenzheng, Batra, Himanshu, Ganesh, Harrish, Wu, Xiaorong, and Zhu, Jingen

Subjects
*BACTERIOPHAGES, *BACTERIOPHAGE T4, *SURFACE interactions, *FIBERS, *ANTIBACTERIAL agents
Abstract

Bacteriophages (phages), as natural antibacterial agents, are being rediscovered because of the growing threat of multi- and pan-drug-resistant bacterial pathogens globally. However, with an estimated 1031 phages on the planet, finding the right phage to recognize a specific bacterial host is like looking for a needle in a trillion haystacks. The host range of a phage is primarily determined by phage tail fibers (or spikes), which initially mediate reversible and specific recognition and adsorption by susceptible bacteria. Recent significant advances at single-molecule and atomic levels have begun to unravel the structural organization of tail fibers and underlying mechanisms of phage–host interactions. Here, we discuss the molecular mechanisms and models of the tail fibers of the well-characterized T4 phage's interaction with host surface receptors. Structure–function knowledge of tail fibers will pave the way for reprogramming phage host range and will bring future benefits through more-effective phage therapy in medicine. Furthermore, the design strategies of tail fiber engineering are briefly summarized, including machine-learning-assisted engineering inspired by the increasingly enormous amount of phage genetic information. [ABSTRACT FROM AUTHOR]

Published
2022
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8. Pectobacterium versatile Bacteriophage Possum: A Complex Polysaccharide-Deacetylating Tail Fiber as a Tool for Host Recognition in Pectobacterial Schitoviridae.

Author

Lukianova, Anna A., Evseev, Peter V., Shneider, Mikhail M., Dvoryakova, Elena A., Tokmakova, Anna D., Shpirt, Anna M., Kabilov, Marsel R., Obraztsova, Ekaterina A., Shashkov, Alexander S., Ignatov, Alexander N., Knirel, Yuriy A., Dzhalilov, Fevzi S.-U., and Miroshnikov, Konstantin A.

Subjects
*BACTERIOPHAGES, *ERWINIA, *ADAPTOR proteins, *SURFACE strains, *FIBERS, *POLYSACCHARIDES
Abstract

Novel, closely related phages Possum and Horatius infect Pectobacterium versatile, a phytopathogen causing soft rot in potatoes and other essential plants. Their properties and genomic composition define them as N4-like bacteriophages of the genus Cbunavirus, a part of a recently formed family Schitoviridae. It is proposed that the adsorption apparatus of these phages consists of tail fibers connected to the virion through an adapter protein. Tail fibers possess an enzymatic domain. Phage Possum uses it to deacetylate O-polysaccharide on the surface of the host strain to provide viral attachment. Such an infection mechanism is supposed to be common for all Cbunavirus phages and this feature should be considered when designing cocktails for phage control of soft rot. [ABSTRACT FROM AUTHOR]

Published
2022
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9. Predictable Molecular Adaptation of Coevolving Enterococcus faecium and Lytic Phage EfV12-phi1.

Author

Wandro, Stephen, Oliver, Andrew, Gallagher, Tara, Weihe, Claudia, England, Whitney, Martiny, Jennifer BH, and Whiteson, Katrine

Subjects
Enterococcus, coevolution, exopolysaccharide, experimental evolution, phage, phage therapy, tail fiber, Environmental Science and Management, Soil Sciences, Microbiology
Abstract

Bacteriophages are highly abundant in human microbiota where they coevolve with resident bacteria. Phage predation can drive the evolution of bacterial resistance, which can then drive reciprocal evolution in the phage to overcome that resistance. Such coevolutionary dynamics have not been extensively studied in human gut bacteria, and are of particular interest for both understanding and eventually manipulating the human gut microbiome. We performed experimental evolution of an Enterococcus faecium isolate from healthy human stool in the absence and presence of a single infecting Myoviridae bacteriophage, EfV12-phi1. Four replicates of E. faecium and phage were grown with twice daily serial transfers for 8 days. Genome sequencing revealed that E. faecium evolved resistance to phage through mutations in the yqwD2 gene involved in exopolysaccharide biogenesis and export, and the rpoC gene which encodes the RNA polymerase β' subunit. In response to bacterial resistance, phage EfV12-phi1 evolved varying numbers of 1.8 kb tandem duplications within a putative tail fiber gene. Host range assays indicated that coevolution of this phage-host pair resulted in arms race dynamics in which bacterial resistance and phage infectivity increased over time. Tracking mutations from population sequencing of experimental coevolution can quickly illuminate phage entry points along with resistance strategies in both phage and host - critical information for using phage to manipulate microbial communities.

Published
2018

10. Discovery and characterisation of new phage targeting uropathogenic Escherichia coli.

Author

Asgharzadeh Kangachar, Shahla, Logel, Dominic Y., Trofimova, Ellina, Zhu, Hannah X., Zaugg, Julian, Schembri, Mark A., Weynberg, Karen D., and Jaschke, Paul R.

Subjects
*ESCHERICHIA coli, *URINARY tract infections, *BACTERIOPHAGES, *ESCHERICHIA coli O157:H7, *DRUG resistance in microorganisms, *BACTERIAL diseases
Abstract

Antimicrobial resistance is an escalating threat with few new therapeutic options in the pipeline. Urinary tract infections (UTIs) are one of the most prevalent bacterial infections globally and are prone to becoming recurrent and antibiotic resistant. We discovered and characterized six novel Autographiviridae and Guernseyvirinae bacterial viruses (phage) against uropathogenic Escherichia coli (UPEC), a leading cause of UTIs. The phage genomes were between 39,471 bp - 45,233 bp, with 45.0%–51.0% GC%, and 57–84 predicted coding sequences per genome. We show that tail fiber domain structure, predicted host capsule type, and host antiphage repertoire correlate with phage host range. In vitro characterisation of phage cocktails showed synergistic improvement against a mixed UPEC strain population and when sequentially dosed. Together, these phage are a new set extending available treatments for UTI from UPEC, and phage vM_EcoM_SHAK9454 represents a promising candidate for further improvement through engineering. • UTIs from antibiotic resistant uropathogenic E. coli (UPEC) are recurrent and difficult to eliminate. • Six novel Autographiviridae and Guernseyvirinae phages were isolated from UPEC hosts. • Phage cocktails showed synergistic improvement against a mixed UPEC strain population. • Sequential phage treatment was improvement over single phage treatment. • Host range differences were explained by predicted tail fiber/spike structure, LPS/capsules, and host antiphage repertoire. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Structural and functional characterization of the receptor binding proteins of Escherichia coli O157 phages EP75 and EP335

Author

Sander Witte, Léa V. Zinsli, Rafael Gonzalez-Serrano, Cassandra I. Matter, Martin J. Loessner, Joël T. van Mierlo, and Matthew Dunne

Subjects
Bacteriophage, STEC, Escherichia coli O157, Salmonella, Tail fiber, Tailspike, Biotechnology, TP248.13-248.65
Abstract

Bacteriophages (phages) are widely used as biocontrol agents in food and as antibacterial agents for treatment of food production plant surfaces. An important feature of such phages is broad infectivity towards a given pathogenic species. Phages attach to the surfaces of bacterial cells using receptor binding proteins (RBPs), namely tail fibers or tailspikes (TSPs). The binding range of RBPs is the primary determinant of phage host range and infectivity, and therefore dictates a phage’s suitability as an antibacterial agent. Phages EP75 and EP335 broadly infect strains of E. coli serotype O157. To better understand host recognition by both phages, here we focused on characterizing the structures and functions of their RBPs. We identified two distinct tail fibers in the genome of the podovirus EP335: gp12 and gp13. Using fluorescence microscopy, we reveal how gp13 recognizes strains of E. coli serotypes O157 and O26. Phage EP75 belongs to the Kuttervirus genus within the Ackermannviridae family and features a four TSP complex (TSPs 1–4) that is universal among such phages. We demonstrate enzymatic activity of TSP1 (gp167) and TSP2 (gp168) toward the O18A and O157 O-antigens of E. coli, respectively, as well as TSP3 activity (gp169.1) against O4, O7, and O9 Salmonella O-antigens. TSPs of EP75 present high similarity to TSPs from E. coli phages CBA120 (TSP2) and HK620 (TSP1) and Salmonella myovirus Det7 (TSP3), which helps explain the cross-genus infectivity observed for EP75.

Published
2021
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12. Characterization of Three Novel Virulent Aeromonas Phages Provides Insights into the Diversity of the Autographiviridae Family.

Author

Bujak, Katarzyna, Decewicz, Przemyslaw, Kitowicz, Michal, and Radlinska, Monika

Subjects
*AEROMONAS, *AMINO acid sequence, *BACTERIOPHAGES, *MICROBIAL mats, *GENOMICS, *NUCLEOTIDE sequence
Abstract

In this study, we isolated and characterized three novel virulent Autographiviridae bacteriophages, vB_AspA_Bolek, vB_AspA_Lolek, and vB_AspA_Tola, which infect different Aeromonas strains. These three host–pathogen pairs were derived from the same sampling location—the arsenic-containing microbial mats of the Zloty Stok gold mine. Functional analysis showed they are psychrotolerant (4–25 °C), albeit with a much wider temperature range of propagation for the hosts (≤37 °C). Comparative genomic analyses revealed a high nucleotide and amino acid sequence similarity of vB_AspA_Bolek and vB_AspA_Lolek, with significant differences exclusively in the C-terminal region of their tail fibers, which might explain their host range discrimination. The protein-based phage network, together with a phylogenetic analysis of the marker proteins, allowed us to assign vB_AspA_Bolek and vB_AspA_Lolek to the Beijerinckvirinae and vB_AspA_Tola to the Colwellvirinae subfamilies, but as three novel species, due to their low nucleotide sequence coverage and identity with other known phage genomes. Global comparative analysis showed that the studied phages are also markedly different from most of the 24 Aeromonas autographiviruses known so far. Finally, this study provides in-depth insight into the diversity of the Autographiviridae phages and reveals genomic similarities between selected groups of this family as well as between autographiviruses and their relatives of other Caudoviricetes families. [ABSTRACT FROM AUTHOR]

Published
2022
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13. Rapid Clinical Screening of Burkholderia pseudomallei Colonies by a Bacteriophage Tail Fiber-Based Latex Agglutination Assay.

Author

Muangsombut, Veerachat, Withatanung, Patoo, Chantratita, Narisara, Chareonsudjai, Sorujsiri, Lim, Jiali, Galyov, Edouard E., Ottiwet, Orawan, Sengyee, Sineenart, Janesomboon, Sujintana, Loessner, Martin J., Dunne, Matthew, and Korbsrisate, Sunee

Subjects
*BURKHOLDERIA pseudomallei, *LATEX, *AGGLUTINATION, *MELIOIDOSIS, *BACTERIOPHAGES, *PADDY fields
Abstract

Melioidosis is a life-threatening disease in humans caused by the Gramnegative bacterium Burkholderia pseudomallei. As severe septicemic melioidosis can lead to death within 24 to 48 h, a rapid diagnosis of melioidosis is critical for ensuring that an optimal antibiotic course is prescribed to patients. Here, we report the development and evaluation of a bacteriophage tail fiber-based latex agglutination assay for rapid detection of B. pseudomallei infection. Burkholderia phage E094 was isolated from rice paddy fields in northeast Thailand, and the whole genome was sequenced to identify its tail fiber (94TF). The 94TF complex was structurally characterized, which involved identification of a tail assembly protein that forms an essential component of the mature fiber. Recombinant 94TF was conjugated to latex beads and developed into an agglutination-based assay (94TF-LAA). 94TF-LAA was initially tested against a large library of Burkholderia and other bacterial strains before a field evaluation was performed during routine clinical testing. The sensitivity and specificity of the 94TF-LAA were assessed alongside standard biochemical analyses on 300 patient specimens collected from an area of melioidosis endemicity over 11months. The 94TF-LAA took less than 5 min to produce positive agglutination, demonstrating 98% (95% confidence interval [CI] of 94.2% to 99.59%) sensitivity and 83% (95% CI of 75.64% to 88.35%) specificity compared to biochemical-based detection. Overall, we show how a Burkholderiaspecific phage tail fiber can be exploited for rapid detection of B. pseudomallei. The 94TF-LAA has the potential for further development as a supplementary diagnostic to assist in clinical identification of this life-threatening pathogen. [ABSTRACT FROM AUTHOR]

Published
2021
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14. ORACLE reveals a bright future to fight bacteria

Author

Willow Coyote-Maestas and James S Fraser

Subjects
bacteriophage, phage, virus engineering, deep mutational scanning, synthetic biology, tail fiber, Medicine, Science, Biology (General), QH301-705.5
Abstract

A new way to alter the genome of bacteriophages helps produce large libraries of variants, allowing these bacteria-killing viruses to be designed to target species harmful to human health.

Published
2021
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15. Mapping the functional landscape of the receptor binding domain of T7 bacteriophage by deep mutational scanning

Author

Phil Huss, Anthony Meger, Megan Leander, Kyle Nishikawa, and Srivatsan Raman

Subjects
Bacteriophage, phage, virus, deep mutational scanning, synthetic biology, tail fiber, Medicine, Science, Biology (General), QH301-705.5
Abstract

The interaction between a bacteriophage and its host is mediated by the phage's receptor binding protein (RBP). Despite its fundamental role in governing phage activity and host range, molecular rules of RBP function remain a mystery. Here, we systematically dissect the functional role of every residue in the tip domain of T7 phage RBP (1660 variants) by developing a high-throughput, locus-specific, phage engineering method. This rich dataset allowed us to cross compare functional profiles across hosts to precisely identify regions of functional importance, many of which were previously unknown. Substitution patterns showed host-specific differences in position and physicochemical properties of mutations, revealing molecular adaptation to individual hosts. We discovered gain-of-function variants against resistant hosts and host-constricting variants that eliminated certain hosts. To demonstrate therapeutic utility, we engineered highly active T7 variants against a urinary tract pathogen. Our approach presents a generalized framework for characterizing sequence–function relationships in many phage–bacterial systems.

Published
2021
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16. Alteromonas Myovirus V22 Represents a New Genus of Marine Bacteriophages Requiring a Tail Fiber Chaperone for Host Recognition

Author

Rafael Gonzalez-Serrano, Matthew Dunne, Riccardo Rosselli, Ana-Belen Martin-Cuadrado, Virginie Grosboillot, Léa V. Zinsli, Juan J. Roda-Garcia, Martin J. Loessner, and Francisco Rodriguez-Valera

Subjects
Alteromonas, phage V22, receptor binding protein, tail fiber, tail fiber chaperone, Myoalterovirus, Microbiology, QR1-502
Abstract

ABSTRACT Marine phages play a variety of critical roles in regulating the microbial composition of our oceans. Despite constituting the majority of genetic diversity within these environments, there are relatively few isolates with complete genome sequences or in-depth analyses of their host interaction mechanisms, such as characterization of their receptor binding proteins (RBPs). Here, we present the 92,760-bp genome of the Alteromonas-targeting phage V22. Genomic and morphological analyses identify V22 as a myovirus; however, due to a lack of sequence similarity to any other known myoviruses, we propose that V22 be classified as the type phage of a new Myoalterovirus genus within the Myoviridae family. V22 shows gene homology and synteny with two different subfamilies of phages infecting enterobacteria, specifically within the structural region of its genome. To improve our understanding of the V22 adsorption process, we identified putative RBPs (gp23, gp24, and gp26) and tested their ability to decorate the V22 propagation strain, Alteromonas mediterranea PT11, as recombinant green fluorescent protein (GFP)-tagged constructs. Only GFP-gp26 was capable of bacterial recognition and identified as the V22 RBP. Interestingly, production of functional GFP-gp26 required coexpression with the downstream protein gp27. GFP-gp26 could be expressed alone but was incapable of host recognition. By combining size-exclusion chromatography with fluorescence microscopy, we reveal how gp27 is not a component of the final RBP complex but instead is identified as a new type of phage-encoded intermolecular chaperone that is essential for maturation of the gp26 RBP. IMPORTANCE Host recognition by phage-encoded receptor binding proteins (RBPs) constitutes the first step in all phage infections and the most critical determinant of host specificity. By characterizing new types of RBPs and identifying their essential chaperones, we hope to expand the repertoire of known phage-host recognition machineries. Due to their genetic plasticity, studying RBPs and their associated chaperones can shed new light onto viral evolution affecting phage-host interactions, which is essential for fields such as phage therapy or biotechnology. In addition, since marine phages constitute one of the most important reservoirs of noncharacterized genetic diversity on the planet, their genomic and functional characterization may be of paramount importance for the discovery of novel genes with potential applications.

Published
2020
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17. Supplementary data for the article: Obradović, M., Malešević, M., Di Luca, M., Kekić, D., Gajić, I., McAuliffe, O., Neve, H., Stanisavljević, N., Vukotić, G.,& Kojić, M.. (2023). Isolation, Characterization, Genome Analysis and Host Resistance Development of Two Novel Lastavirus Phages Active against Pandrug-Resistant Klebsiella pneumoniae. in Viruses, 15(3), 628. https://doi.org/10.3390/v15030628

Author

Obradović, Mina, Malešević, Milka, Di Luca, Mariagrazia, Kekić, Dušan, Gajić, Ina, McAuliffe, Olivia, Neve, Horst, Stanisavljević, Nemanja, Vukotić, Goran, Kojić, Milan, Obradović, Mina, Malešević, Milka, Di Luca, Mariagrazia, Kekić, Dušan, Gajić, Ina, McAuliffe, Olivia, Neve, Horst, Stanisavljević, Nemanja, Vukotić, Goran, and Kojić, Milan

Published
2023

18. Cryo-EM analysis of Pseudomonas phage Pa193 structural components.

Author

Cingolani G, Iglesias S, Hou CF, Lemire S, Soriaga A, and Kyme P

Abstract

The World Health Organization has designated Pseudomonas aeruginosa as a critical pathogen for the development of new antimicrobials. Bacterial viruses, or bacteriophages, have been used in various clinical settings, commonly called phage therapy, to address this growing public health crisis. Here, we describe a high-resolution structural atlas of a therapeutic, contractile-tailed Pseudomonas phage, Pa193. We used bioinformatics, proteomics, and cryogenic electron microscopy single particle analysis to identify, annotate, and build atomic models for 21 distinct structural polypeptide chains forming the icosahedral capsid, neck, contractile tail, and baseplate. We identified a putative scaffolding protein stabilizing the interior of the capsid 5-fold vertex. We also visualized a large portion of Pa193 ~ 500 Å long tail fibers and resolved the interface between the baseplate and tail fibers. The work presented here provides a framework to support a better understanding of phages as biomedicines for phage therapy and inform engineering opportunities., Competing Interests: COMPETING INTERESTS STATEMENT J.R., E.S., R.G., A.S., L.S., P.K., D.B., and S.L. are employees of Armata Pharmaceuticals Inc., a company involved in the development of bacteriophage therapies. LG and JW were contracted by Armata under a fee-for-service agreement. The other authors declare that the research was conducted in a way that is free of financial or commercial relationship that could be construed as conflict of interest.

Published
2024
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19. T4-like Bacteriophages Isolated from Pig Stools Infect Yersinia pseudotuberculosis and Yersinia pestis Using LPS and OmpF as Receptors

Author

Mabruka Salem, Maria I. Pajunen, Jin Woo Jun, and Mikael Skurnik

Subjects
Y. pseudotuberculosis, bacteriophage, receptor, Myoviridae, lipopolysaccharide, tail fiber, Microbiology, QR1-502
Abstract

The Yersinia bacteriophages fPS-2, fPS-65, and fPS-90, isolated from pig stools, have long contractile tails and elongated heads, and they belong to genus Tequatroviruses in the order Caudovirales. The phages exhibited relatively wide host ranges among Yersinia pseudotuberculosis and related species. One-step growth curve experiments revealed that the phages have latent periods of 50–80 min with burst sizes of 44–65 virions per infected cell. The phage genomes consist of circularly permuted dsDNA of 169,060, 167,058, and 167,132 bp in size, respectively, with a G + C content 35.3%. The number of predicted genes range from 267 to 271. The phage genomes are 84–92% identical to each other and ca 85% identical to phage T4. The phage receptors were identified by whole genome sequencing of spontaneous phage-resistant mutants. The phage-resistant strains had mutations in the ompF, galU, hldD, or hldE genes. OmpF is a porin, and the other genes encode lipopolysaccharide (LPS) biosynthetic enzymes. The ompF, galU, and hldE mutants were successfully complemented in trans with respective wild-type genes. The host recognition was assigned to long tail fiber tip protein Gp38, analogous to that of T-even phages such as Salmonella phage S16, specifically to the distal β-helices connecting loops.

Published
2021
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20. Predictable Molecular Adaptation of Coevolving Enterococcus faecium and Lytic Phage EfV12-phi1

Author

Stephen Wandro, Andrew Oliver, Tara Gallagher, Claudia Weihe, Whitney England, Jennifer B. H. Martiny, and Katrine Whiteson

Subjects
phage (bacteriophage), Enterococcus, experimental evolution, phage therapy, tail fiber, exopolysaccharide, Microbiology, QR1-502
Abstract

Bacteriophages are highly abundant in human microbiota where they coevolve with resident bacteria. Phage predation can drive the evolution of bacterial resistance, which can then drive reciprocal evolution in the phage to overcome that resistance. Such coevolutionary dynamics have not been extensively studied in human gut bacteria, and are of particular interest for both understanding and eventually manipulating the human gut microbiome. We performed experimental evolution of an Enterococcus faecium isolate from healthy human stool in the absence and presence of a single infecting Myoviridae bacteriophage, EfV12-phi1. Four replicates of E. faecium and phage were grown with twice daily serial transfers for 8 days. Genome sequencing revealed that E. faecium evolved resistance to phage through mutations in the yqwD2 gene involved in exopolysaccharide biogenesis and export, and the rpoC gene which encodes the RNA polymerase β’ subunit. In response to bacterial resistance, phage EfV12-phi1 evolved varying numbers of 1.8 kb tandem duplications within a putative tail fiber gene. Host range assays indicated that coevolution of this phage-host pair resulted in arms race dynamics in which bacterial resistance and phage infectivity increased over time. Tracking mutations from population sequencing of experimental coevolution can quickly illuminate phage entry points along with resistance strategies in both phage and host – critical information for using phage to manipulate microbial communities.

Published
2019
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21. Characterization and Genomic Analysis of SFPH2, a Novel T7virus Infecting Shigella

Author

Chaojie Yang, Haiying Wang, Hui Ma, Renlong Bao, Hongbo Liu, Lang Yang, Beibei Liang, Leili Jia, Jing Xie, Ying Xiang, Nian Dong, Shaofu Qiu, and Hongbin Song

Subjects
bacteriophage, Shigella flexneri, T7virus, genome analysis, tail fiber, Microbiology, QR1-502
Abstract

Shigellosis, caused by Shigella, is a major global health concern, with nearly 164.7 million cases and over a million deaths occurring annually worldwide. Shigella flexneri is one of the most common subgroups of Shigella with a high incidence of multidrug-resistance. The phage therapy approach is an effective method for controlling multidrug-resistant bacteria. However, only a few Shigella phages have been described to date. In this study, a novel lytic bacteriophage SFPH2 was isolated from a sewage sample obtained from a hospital in Beijing, China, using a multidrug-resistant S. flexneri 2a strain (SF2) isolated from the fecal sample of a dysentery patient. SFPH2 is a member of the Podoviridae virus family with an icosahedral capsid and a short, non-contractile tail. It was found to be stable over a wide range of temperatures (4–50°C) and pH values (pH 3–11). Moreover, SFPH2 could infect two other S. flexneri serotypes (serotypes 2 variant and Y). High-throughput sequencing revealed that SFPH2 has a linear double-stranded DNA genome of 40,387 bp with 50 open reading frames. No tRNA genes were identified in the genome. Comparative analysis of the genome revealed that the SFPH2 belongs to the subfamily Autographivirinae and genus T7virus. The genome shows high similarity with other enterobacterial T7virus bacteriophages such as Citrobacter phage SH4 (95% identity and 89% coverage) and Cronobacter phage Dev2 (94% identity and 92% coverage). A comparison of the fiber proteins showed that minor differences in the amino acid residues might specify different protein binding regions and determine host species. In conclusion, this is the first report of a T7virus that can infect Shigella; SFPH2 has a functional stability under a wide range of temperatures and pH values, showing the potential to be widely applied to control Shigella–associated clinical infections and reduce the transmission rates of S. flexneri serotype 2a and its variants in the environment.

Published
2018
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25. Asymmetric Structure of Podophage GP4 Reveals a Novel Architecture of Three Types of Tail Fibers.

Author

Zheng, Jing, Chen, Wenyuan, Xiao, Hao, Yang, Fan, Song, Jingdong, Cheng, Lingpeng, and Liu, Hongrong

Subjects
*FIBERS, *BACTERIAL cell surfaces, *BACTERIOPHAGE typing, *BACTERIAL diseases
Abstract

[Display omitted] • The tail flank is decorated by a 15-fold symmetrical fiber-tail adaptor and three types of tail fibers, including 5-fold symmetrical fibers I and II, and 6-fold symmetrical fiber III. • The fiber-tail adaptor acts as a platform for anchoring fibers I and II. • Five fibers I, each consisting of five protein gp80 dimers linked in turn by an elongated rope protein to form a chain-like structure, are attached to the five edges of the tail vertex of the icosahedral head. Bacteriophage tail fibers (or called tail spikes) play a critical role in the early stage of infection by binding to the bacterial surface. Podophages with known structures usually possess one or two types of fibers. Here, we resolved an asymmetric structure of the podophage GP4 to near-atomic resolution by cryo-EM. Our structure revealed a symmetry-mismatch relationship between the components of the GP4 tail with previously unseen topologies. In detail, two dodecameric adaptors (adaptors I and II), a hexameric nozzle, and a tail needle form a conserved tail body connected to a dodecameric portal occupying a unique vertex of the icosahedral head. However, five chain-like extended fibers (fiber I) and five tulip-like short fibers (fiber II) are anchored to a 15-fold symmetric fiber-tail adaptor, encircling the adaptor I, and six bamboo-like trimeric fibers (fiber III) are connected to the nozzle. Five fibers I, each composed of five dimers of the protein gp80 linked by an elongated rope protein, are attached to the five edges of the tail vertex of the icosahedral head. In this study, we identified a new structure of the podophage with three types of tail fibers, and such phages with different types of fibers may have a broad host range and/or infect host cells with considerably high efficiency, providing evolutionary advantages in harsh environments. [ABSTRACT FROM AUTHOR]

Published
2023
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30. Isolation and genomic analysis of a type IV pili-independent Thermus thermophilus phage, φMN1 from a Japanese hot spring.

Author

Tamakoshi M, Hijikata A, Yura K, Oshima K, Toh H, Mitsuoka K, Oshima T, and Bessho Y

Subjects
Thermus thermophilus genetics, Proteomics, Japan, Open Reading Frames, Bacteriophages genetics, Hot Springs
Abstract

A Thermus thermophilus lytic phage was isolated from a Japanese hot spring using a type IV pili-deficient strain as an indicator host, and designated as φMN1. Electron microscopic (EM) examination revealed that φMN1 had an icosahedral head and a contractile tail, suggesting that φMN1 belonged to Myoviridae. An EM analysis focused on φMN1 adsorption to the Thermus host cell showed that the receptor molecules for the phage were uniformly distributed on the outer surface of the cells. The circular double-stranded DNA of φMN1 was 76,659 base pairs in length, and the guanine and cytosine content was 61.8%. It was predicted to contain 99 open reading frames, and its putative distal tail fiber protein, which is essential for non-piliated host cell surface receptor recognition, was dissimilar in terms of sequence and length with its counterpart in the type IV pili-dependent φYS40. A phage proteomic tree revealed that φMN1 and φYS40 are in the same cluster, but many genes had low sequence similarities and some seemed to be derived from both mesophilic and thermophilic organisms. The gene organization suggested that φMN1 evolved from a non-Thermus phage through large-scale recombination events of the genes determining the host specificity, followed by gradual evolution by recombination of both the thermophilic and mesophilic DNAs assimilated by the host Thermus cells. This newly isolated phage will provide evolutionary insights into thermophilic phages.

Published
2023
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34. Bacteriophage Mu

Author

Howe, Martha M., Busby, Stephen J. W., editor, Thomas, Christopher M., editor, and Brown, Nigel L., editor

Published
1998
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37. Synthetic phage tail-like bacteriocins targeting Shiga toxin-producing Escherichia coli

Author

Pas, Célia, Dams, Dorien, Łątka, Agnieszka, Fieseler, Lars, and Briers, Yves

Subjects
STEC, tail fiber, RBP, PTLB, tailspike, Biology and Life Sciences, receptor-binding protein, Phage tail-like bacteriocins, tailocins, R2-pyocins
Abstract

Next to pandemics and wars, antibiotic resistance is a drastically increasing problem the world must prepare for. Shiga-toxin producing Escherichia coli (STEC), belonging to the critical priority pathogen list defined by the World Health Organization, is a severe foodborne disease with an estimated 2.2 reported cases per 100,000 population in 2019. The use of broad-spectrum antibiotics does not only disrupt the microbiome and contribute to the spread of antibiotic resistance, but in the case of this specific pathogen also induces the release of the Shiga-toxin, which causes bloody diarrhea and can even lead to the life-threatening haemolytic uraemic syndrome (HUS). Phage tail-like bacteriocins (PTLBs), more specifically R2-pyocins, are antimicrobial compounds that are morphologically similar to head-less myoviruses. R2-pyocins are produced by Pseudomonas aeruginosa to protect themselves from their competitors. Here we show that the natural receptor-binding proteins of R2-pyocins, necessary to initiate contact with their host, can successfully be swapped with those of bacteriophages targeting STEC serovars, resulting in highly specific, antimicrobial compounds to combat STEC pathogens. Synthetic PTLBs rely on a simple and efficient killing mechanism, conserve the high specificity of bacteriophages, and may have a regulatory advantage since they do not multiply or carry DNA and thus, do not evolve. Therefore, synthetic PTLB cocktails may provide a valuable alternative for antibiotics, inspired by phages.

Published
2022

38. A blueprint of tail fiber modularity and its relationship with host specificity for STEC serovars

Author

Pas, Célia, Łątka, Agnieszka, Fieseler, Lars, and Briers, Yves

Subjects
STEC, tail fiber, RBP, tailspike, Biology and Life Sciences, Horizontal gene transfer, receptor-binding protein, Shiga toxin
Abstract

Shiga toxin-producing E. coli (STEC) is a foodborne pathogen causing around 2.8 million annual infections worldwide. Antimicrobial treatment is debated as treatment for STEC infections as the activated SOS response may lead to increased toxin production. Phages, as the natural predator of bacteria, therefore offer great potential in STEC treatment. The phage-host relationship is very specific and complex, where tail fibers or tailspikes of the phages are the first phage proteins initiating the infection process. These proteins bind to various outer membrane structures including O-antigen, a serovar specific sugar-based component on the outer lipopolysaccharide layer. Here we introduce a bio-informatics pipeline to find and investigate this phage-host relationship, namely the tail fiber and O-antigen interaction, using public databases and online tools. Both temperate and lytic phages were screened for the presence of tail fiber O-antigen specific genes. The O-antigen specificity of the tail fibers was confirmed for multiple phage groups, such as genera Uetake-, Lederberg- and kutterviruses. Tail fibers specific for O-antigen types O26, O103, O104, O111, O145, O146 and O157 were identified. Additionally, the current hurdles of this pipeline are disclosed. This method of screening for new O-antigen-specific tail fibers is highly interesting to develop serotype-targeting microbials, especially in current times where antimicrobial resistance is a serious threat to global health and development.

Published
2022

42. Host recognition strategies and evolution in phages infecting the marine bacterium Alteromonas sp.

Author

Rodriguez-Valera, Francisco, Rosselli, Riccardo, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Gonzalez-Serrano, Rafael, Rodriguez-Valera, Francisco, Rosselli, Riccardo, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, and Gonzalez-Serrano, Rafael

Abstract

Viruses constitute the vast majority of all biological entities in the biosphere and represent one of the biggest reservoirs of undetected genetic diversity on Earth. Of all the viral particles inhabiting the ocean, phages are the most abundant and can affect the overall microbial composition of marine ecosystems and the dynamics of global biogeochemical cycles. The interaction between prokaryotic cells and their phages is among the oldest and most intertwined host-parasite relationships on the planet. It has been extensively studied by culture, molecular biology, and experimental evolution. However, due to the difficulties of culture with environmental samples, only a few studies have analyzed the mechanisms of phage-host interaction in the marine environment. Here, we have studied the genes involved in viral host recognition and their evolutionary dynamics by focusing on two species of the marine copiotrophic bacterium Alteromonas and several phages infecting them. We described the genomic and morphological characterization of the first Alteromonas phage belonging to the Myoviridae family (Alteromonas myovirus V22) that was isolated in coastal waters of the Mediterranean Sea, and we identified its receptor-binding protein (RBP) used for host recognition by combining fluorescence microscopy and spectrometry. In addition, using size-exclusion chromatography, we showed how this protein required co-expression with a downstream protein to be functional, which later was identified as a new type of intermolecular chaperone crucial for RBP maturation. We also identified a conserved host recognition module in V22 and other unrelated alterophages belonging to different viral families and with completely different morphologies, suggesting horizontal gene transfer between the ancestors of these phages. Furthermore, we described the first coevolution study of a host-parasite system performed with Alteromonas using a metagenomics-like approach. Finally, we analyzed the micro- a

Published
2021

43. Engineering the Modular Receptor-Binding Proteins ofKlebsiellaPhages Switches Their Capsule Serotype Specificity

Author

Yves Briers, Agnieszka Latka, Barbara Maciejewska, Zuzanna Drulis-Kawa, Sebastien Lemire, Timothy K. Lu, Dorien Dams, and Dennis Grimon

Subjects
Serotype, BACTERIAL, Klebsiella, Klebsiella pneumoniae, viruses, BACTERIOPHAGES, receptor-binding protein, Genome, Viral, Computational biology, receptor binding protein, Serogroup, DEPOLYMERASES, Microbiology, Narrow spectrum, Bacteriophage, bacteriophage, Virology, phage, CRYSTAL-STRUCTURE, Bacteriophages, ENCODES, horizontal transfer, Bacterial Capsules, TAILSPIKE PROTEIN, Modular structure, IDENTIFICATION, biology, Biology and Life Sciences, Viral Tail Proteins, biology.organism_classification, QR1-502, Bacteriophage Therapy, tail fiber, PNEUMONIAE, Horizontal gene transfer, depolymerase, HOST-RANGE, Carrier Proteins, RESISTANCE, Research Article, Protein Binding
Abstract

The high specificity of bacteriophages is driven by their receptor-binding proteins (RBPs). Many Klebsiella bacteriophages target the capsular exopolysaccharide as the receptor and encode RBPs with depolymerase activity. The modular structure of these RBPs with an N-terminal structural module to attach the RBP to the phage tail, and a C-terminal specificity module for exopolysaccharide degradation, supports horizontal transfer as a major evolutionary driver for Klebsiella phage RBPs. We mimicked this natural evolutionary process by the construction of modular RBP chimeras, exchanging N-terminal structural modules and C-terminal specificity modules. All chimeras strictly follow the capsular serotype specificity of the C-terminal module. Transplanting chimeras with a K11 N-terminal structural RBP module in a Klebsiella phage K11 scaffold results in a capsular serotype switch and corresponding host range modification of the synthetic phages, demonstrating that horizontal transfer of C-terminal specificity modules offers Klebsiella phages an evolutionary highway for rapid adaptation to new capsular serotypes. IMPORTANCE The antimicrobial resistance crisis has rekindled interest in bacteriophage therapy. Phages have been studied over a century as therapeutics to treat bacterial infections, but one of the biggest challenges for the use of phages in therapeutic interventions remains their high specificity. In particular, many Klebsiella phages have a narrow spectrum constrained by the high diversity of exopolysaccharide capsules that shield access to the cells. In this work, we have elaborated how Klebsiella phages deal with this high diversity by exchanging building blocks of their receptor-binding proteins.

Published
2021
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44. Rapid Clinical Screening of Burkholderia pseudomallei Colonies by a Bacteriophage Tail Fiber-Based Latex Agglutination Assay

Author

Veerachat Muangsombut, Jiali Lim, Sineenart Sengyee, Edouard E. Galyov, Sorujsiri Chareonsudjai, Orawan Ottiwet, Narisara Chantratita, Patoo Withatanung, Martin J. Loessner, Sujintana Janesomboon, Matthew Dunne, and Sunee Korbsrisate

Subjects
rapid colony screening, Burkholderia pseudomallei, Melioidosis, medicine.disease_cause, Sensitivity and Specificity, Applied Microbiology and Biotechnology, Microbiology, Bacteriophage, 03 medical and health sciences, bacteriophage, tail assembly chaperone, Methods, medicine, Humans, Bacteriophages, Pathogen, 030304 developmental biology, Latex beads, 0303 health sciences, Ecology, biology, 030306 microbiology, Pathogenic bacteria, medicine.disease, biology.organism_classification, latex agglutination assay, Agglutination (biology), Burkholderia, tail fiber, Latex agglutination assay, Rapid colony screening, Tail fiber, Tail assembly chaperone, Capsid Proteins, Latex Fixation Tests, Food Science, Biotechnology
Abstract

Melioidosis is a life-threatening disease in humans caused by the Gram-negative bacterium Burkholderia pseudomallei. As severe septicemic melioidosis can lead to death within 24 to 48 h, a rapid diagnosis of melioidosis is critical for ensuring that an optimal antibiotic course is prescribed to patients. Here, we report the development and evaluation of a bacteriophage tail fiber-based latex agglutination assay for rapid detection of B. pseudomallei infection. Burkholderia phage E094 was isolated from rice paddy fields in northeast Thailand, and the whole genome was sequenced to identify its tail fiber (94TF). The 94TF complex was structurally characterized, which involved identification of a tail assembly protein that forms an essential component of the mature fiber. Recombinant 94TF was conjugated to latex beads and developed into an agglutination-based assay (94TF-LAA). 94TF-LAA was initially tested against a large library of Burkholderia and other bacterial strains before a field evaluation was performed during routine clinical testing. The sensitivity and specificity of the 94TF-LAA were assessed alongside standard biochemical analyses on 300 patient specimens collected from an area of melioidosis endemicity over 11 months. The 94TF-LAA took less than 5 min to produce positive agglutination, demonstrating 98% (95% confidence interval [CI] of 94.2% to 99.59%) sensitivity and 83% (95% CI of 75.64% to 88.35%) specificity compared to biochemical-based detection. Overall, we show how a Burkholderia-specific phage tail fiber can be exploited for rapid detection of B. pseudomallei. The 94TF-LAA has the potential for further development as a supplementary diagnostic to assist in clinical identification of this life-threatening pathogen. IMPORTANCE Rapid diagnosis of melioidosis is essential for ensuring that optimal antibiotic courses are prescribed to patients and thus warrants the development of cost-effective and easy-to-use tests for implementation in underresourced areas such as northeastern Thailand and other tropical regions. Phage tail fibers are an interesting alternative to antibodies for use in various diagnostic assays for different pathogenic bacteria. As exposed appendages of phages, tail fibers are physically robust and easy to manufacture, with many tail fibers (such as 94TF investigated here) capable of targeting a given bacterial species with remarkable specificity. Here, we demonstrate the effectiveness of a latex agglutination assay using a Burkholderia-specific tail fiber 94TF against biochemical-based detection methods that are the standard diagnostic in many areas where melioidosis is endemic., Applied and Environmental Microbiology, 87 (12), ISSN:0099-2240, ISSN:1098-5336

Published
2021
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45. Structural and functional characterization of the receptor binding proteins of Escherichia coli O157 phages EP75 and EP335

Author

Léa V. Zinsli, Martin J. Loessner, Cassandra I. Matter, Rafael Gonzalez-Serrano, Joël T. van Mierlo, Sander Witte, and Matthew Dunne

Subjects
Serotype, Salmonella, Bacteriophage, STEC, Escherichia coli O157, Tail fiber, Tailspike, Receptor binding protein, Lipopolysaccharide, O-antigen, Biophysics, Biology, medicine.disease_cause, Biochemistry, Genome, Microbiology, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Genetics, medicine, Escherichia coli, ComputingMethodologies_COMPUTERGRAPHICS, 030304 developmental biology, Antibacterial agent, chemistry.chemical_classification, Infectivity, 0303 health sciences, biology.organism_classification, Computer Science Applications, Enzyme, chemistry, 030220 oncology & carcinogenesis, TP248.13-248.65, Research Article, Biotechnology
Abstract

Graphical abstract, Highlights • Receptor binding proteins (RBPs) are the primary determinants of phage host range. • Tail fiber of phage EP335 (gp13) recognizes E. coli serotypes O157 and O26. • Phage EP75 tailspikes are active towards E. coli and Salmonella O-antigens. • Cross-genus tailspike activity is consistent with the broad host range of phage EP75., Bacteriophages (phages) are widely used as biocontrol agents in food and as antibacterial agents for treatment of food production plant surfaces. An important feature of such phages is broad infectivity towards a given pathogenic species. Phages attach to the surfaces of bacterial cells using receptor binding proteins (RBPs), namely tail fibers or tailspikes (TSPs). The binding range of RBPs is the primary determinant of phage host range and infectivity, and therefore dictates a phage’s suitability as an antibacterial agent. Phages EP75 and EP335 broadly infect strains of E. coli serotype O157. To better understand host recognition by both phages, here we focused on characterizing the structures and functions of their RBPs. We identified two distinct tail fibers in the genome of the podovirus EP335: gp12 and gp13. Using fluorescence microscopy, we reveal how gp13 recognizes strains of E. coli serotypes O157 and O26. Phage EP75 belongs to the Kuttervirus genus within the Ackermannviridae family and features a four TSP complex (TSPs 1–4) that is universal among such phages. We demonstrate enzymatic activity of TSP1 (gp167) and TSP2 (gp168) toward the O18A and O157 O-antigens of E. coli, respectively, as well as TSP3 activity (gp169.1) against O4, O7, and O9 Salmonella O-antigens. TSPs of EP75 present high similarity to TSPs from E. coli phages CBA120 (TSP2) and HK620 (TSP1) and Salmonella myovirus Det7 (TSP3), which helps explain the cross-genus infectivity observed for EP75.

Published
2021
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46. Specific Detection of Yersinia pestis Based on Receptor Binding Proteins of Phages

Author

Peter Braun, Gregor Grass, Holger C Scholz, and Friederike Born

Subjects
Microbiology (medical), Pneumonic plague, endocrine system, capsule, tailspike, Virulence, lcsh:Medicine, Biology, medicine.disease_cause, receptor binding protein, Microbiology, law.invention, Antigen, law, medicine, phage, Immunology and Allergy, Molecular Biology, Pathogen, Escherichia coli, General Immunology and Microbiology, lcsh:R, microscopic assay, medicine.disease, biology.organism_classification, Fusion protein, pathogen detection, plague, Yersinia pestis, Infectious Diseases, tail fiber, Recombinant DNA, fluorescent reporter
Abstract

The highly pathogenic bacterium Yersinia pestis is the causative agent of plague, a notorious infectious zoonotic disease. When transmitted from person to person as pneumonic plague via droplets, Y. pestis is highly contagious and in most cases is fatal if left untreated. Thus, when plague is suspected, rapid diagnosis is crucial, as a serious course of the infection is only averted by early antibiotic therapy. The bacterium is easy to cultivate, accessible and has a high potential for nefarious use such as bioterrorism. Highly specific, rapid and easy-to-use confirmatory diagnostic methods are required to reliably identify the pathogen independently from PCR-based methods or F1 antigen-based immunological detection. Yersinia pestis specific phages such as L-413C and &Phi, A1122 are already used for detection of Y. pestis in bacterial plaque or biosensor assays. Here, we made use of the host specificities conferred by phage receptor binding (or tail fiber/spike) proteins (RBP) for developing a specific, fast and simple fluorescence-microscopy-based detection method for Y. pestis. Genes of putative RBP of phages L-413C (gpH) and &Phi, A1122 (gp17) were fused with those of fluorescent proteins and recombinant receptor-reporter fusion proteins were produced heterologously in Escherichia coli. When first tested on attenuated Y. pestis strain EV76, RBP-reporters bound to the bacterial cell surface. This assay could be completed within a few minutes using live or formaldehyde-inactivated cells. Specificity tests using cultures of closely related Yersinia species and several inactivated fully virulent Y. pestis strains exhibited high specificities of the RBP-reporters against Y. pestis. The L-413C RBP proved to be especially specific, as it only detected Y. pestis at all temperatures tested, whereas the RBP of &Phi, A1122 also bound to Y. pseudotuberculosis strains at 37 &deg, C (but not at 28, 20 or 6 &deg, C). Finally, the Y. pestis-specific capsule, produced when grown at 37 &deg, C, significantly reduced binding of phage &Phi, A1122 RBP, whereas the capsule only slightly diminished binding of L-413C RBP.

Published
2020
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47. Specific Detection of

Author

Friederike, Born, Peter, Braun, Holger C, Scholz, and Gregor, Grass

Subjects
endocrine system, tail fiber, Yersinia pestis, capsule, phage, tailspike, microscopic assay, fluorescent reporter, receptor binding protein, pathogen detection, Article, plague
Abstract

The highly pathogenic bacterium Yersinia pestis is the causative agent of plague, a notorious infectious zoonotic disease. When transmitted from person to person as pneumonic plague via droplets, Y. pestis is highly contagious and in most cases is fatal if left untreated. Thus, when plague is suspected, rapid diagnosis is crucial, as a serious course of the infection is only averted by early antibiotic therapy. The bacterium is easy to cultivate, accessible and has a high potential for nefarious use such as bioterrorism. Highly specific, rapid and easy-to-use confirmatory diagnostic methods are required to reliably identify the pathogen independently from PCR-based methods or F1 antigen-based immunological detection. Yersinia pestis specific phages such as L-413C and ΦA1122 are already used for detection of Y. pestis in bacterial plaque or biosensor assays. Here, we made use of the host specificities conferred by phage receptor binding (or tail fiber/spike) proteins (RBP) for developing a specific, fast and simple fluorescence-microscopy-based detection method for Y. pestis. Genes of putative RBP of phages L-413C (gpH) and ΦA1122 (gp17) were fused with those of fluorescent proteins and recombinant receptor-reporter fusion proteins were produced heterologously in Escherichia coli. When first tested on attenuated Y. pestis strain EV76, RBP-reporters bound to the bacterial cell surface. This assay could be completed within a few minutes using live or formaldehyde-inactivated cells. Specificity tests using cultures of closely related Yersinia species and several inactivated fully virulent Y. pestis strains exhibited high specificities of the RBP-reporters against Y. pestis. The L-413C RBP proved to be especially specific, as it only detected Y. pestis at all temperatures tested, whereas the RBP of ΦA1122 also bound to Y. pseudotuberculosis strains at 37 °C (but not at 28, 20 or 6 °C). Finally, the Y. pestis-specific capsule, produced when grown at 37 °C, significantly reduced binding of phage ΦA1122 RBP, whereas the capsule only slightly diminished binding of L-413C RBP.

Published
2020

48. Alteromonas Myovirus V22 Represents a New Genus of Marine Bacteriophages Requiring a Tail Fiber Chaperone for Host Recognition

Author

Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Gonzalez-Serrano, Rafael, Dunne, Matthew, Rosselli, Riccardo, Martín Cuadrado, Ana Belén, Grosboillot, Virginie, Zinsli, Léa V., Roda-Garcia, Juan J., Loessner, Martin J., Rodriguez-Valera, Francisco, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Gonzalez-Serrano, Rafael, Dunne, Matthew, Rosselli, Riccardo, Martín Cuadrado, Ana Belén, Grosboillot, Virginie, Zinsli, Léa V., Roda-Garcia, Juan J., Loessner, Martin J., and Rodriguez-Valera, Francisco

Abstract

Marine phages play a variety of critical roles in regulating the microbial composition of our oceans. Despite constituting the majority of genetic diversity within these environments, there are relatively few isolates with complete genome sequences or in-depth analyses of their host interaction mechanisms, such as characterization of their receptor binding proteins (RBPs). Here, we present the 92,760-bp genome of the Alteromonas-targeting phage V22. Genomic and morphological analyses identify V22 as a myovirus; however, due to a lack of sequence similarity to any other known myoviruses, we propose that V22 be classified as the type phage of a new Myoalterovirus genus within the Myoviridae family. V22 shows gene homology and synteny with two different subfamilies of phages infecting enterobacteria, specifically within the structural region of its genome. To improve our understanding of the V22 adsorption process, we identified putative RBPs (gp23, gp24, and gp26) and tested their ability to decorate the V22 propagation strain, Alteromonas mediterranea PT11, as recombinant green fluorescent protein (GFP)-tagged constructs. Only GFP-gp26 was capable of bacterial recognition and identified as the V22 RBP. Interestingly, production of functional GFP-gp26 required coexpression with the downstream protein gp27. GFP-gp26 could be expressed alone but was incapable of host recognition. By combining size-exclusion chromatography with fluorescence microscopy, we reveal how gp27 is not a component of the final RBP complex but instead is identified as a new type of phage-encoded intermolecular chaperone that is essential for maturation of the gp26 RBP.

Published
2020

49. PHENOTYPIC STOCHASTICITY PROTECTS LYTIC BACTERIOPHAGE POPULATIONS FROM EXTINCTION DURING THE BACTERIAL STATIONARY PHASE.

Author

Gallet, Romain, Lenormand, Thomas, and Wang, Ing-Nang

Subjects
*PHENOTYPES, *BACTERIOPHAGES, *BIOLOGICAL fitness, *BACTERIAL diseases, *ADSORPTION (Chemistry), *PROTEIN synthesis, *STOCHASTIC processes
Abstract

It is generally thought that the adsorption rate of a bacteriophage correlates positively with fitness, but this view neglects that most phages rely only on exponentially growing bacteria for productive infections. Thus, phages must cope with the environmental stochasticity that is their hosts' physiological state. If lysogeny is one alternative, it is unclear how strictly lytic phages can survive the host stationary phase. Three scenarios may explain their maintenance: (1) pseudolysogeny, (2) diversified, or (3) conservative bet hedging. To better understand how a strictly lytic phage survives the stationary phase of its host, and how phage adsorption rate impacts this survival, we challenged two strictly lytic phage λ, differing in their adsorption rates, with stationary phase Escherichia coli cells. Our results showed that, pseudolysogeny was not responsible for phage survival and that, contrary to our expectation, high adsorption rate was not more detrimental during stationary phase than low adsorption rate. Interestingly, this last observation was due to the presence of the 'residual fraction' (phages exhibiting extremely low adsorption rates), protecting phage populations from extinction. Whether this cryptic phenotypic variation is an adaptation (diversified bet hedging) or merely reflecting unavoidable defects during protein synthesis remains an open question. [ABSTRACT FROM AUTHOR]

Published
2012
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50. Isolation and characterization of a novel indigenous intestinal N4-related coliphage vB_EcoP_G7C.

Author

Kulikov, Eugene, Kropinski, Andrew M., Golomidova, Alla, Lingohr, Erika, Govorun, Vadim, Serebryakova, Marina, Prokhorov, Nikolai, Letarova, Maria, Manykin, Anatolij, Strotskaya, Alexandra, and Letarov, Andrey

Subjects
*BACTERIOPHAGES, *VIRUS isolation, *GUT microbiome, *FECES, *HORSES, *GENOMES, *HYDROLASES
Abstract

Abstract: Lytic coliphage vB_EcoP_G7C and several other highly related isolates were obtained repeatedly from the samples of horse feces held in the same stable thus representing a component of the normal indigenous intestinal communities in this population of animals. The genome of G7C consists of 71,759bp with terminal repeats of about 1160bp, yielding approximately 73 kbp packed DNA size. Seventy-eight potential open reading frames, most of them unique to N4-like viruses, were identified and annotated. The overall layout of functional gene groups was close to that of the original N4 phage, with some important changes in late gene area including new tail fiber proteins containing hydrolytic domains. Structural proteome analysis confirmed all the predicted subunits of the viral particle. Unlike N4 itself, phage G7C did not exhibit a lysis-inhibited phenotype. [Copyright &y& Elsevier]

Published
2012
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