Your search keyword '"Grose JH"' showing total 15 results

1. Genome sequences of two Klebsiella phages isolated from wastewater treatment samples that infect a clinical Klebsiella isolate.

Author

Lewis JM, Arens DK, Quaye A, Calvopina-Chavez DG, Jensen KT, Miller AK, Moss MM, Warren ME, Tavana JP, Johnson SM, and Grose JH

Abstract

We announce the complete genomes of Klebsiella phages ValerieMcCarty03 and ValerieMcCarty04 isolated from wastewater treatment plant samples that infect a multidrug-resistant Klebsiella oxytoca clinical isolate. These phages belong to the T4-like cluster and fall within the Jiaodavirus genus., Competing Interests: The authors declare a conflict of interest.

Published

2025

2. Complete genome sequences of five Ackermannviridae that infect Enterobacteriaceae hosts.

Author

Harris EB, Anthony LB, Ali S, Atkin H, Bowden LC, Brugger SW, Carr EL, Eberhard N, Flor S, Gaertner RK, Gleave A, Hess D, Hoggan T, Lazaro EC, Leonard K, Lewis T, Newey CR, Ramsey J, Sajous KR, Schaeffer D, Stoker T, Stump S, Thompson DW, Weyland R, and Grose JH

Abstract

This announcement contains the whole genome sequences of five Ackermannviridae that infect members of the Enterobacteriaceae family of bacteria. Four of the five phages were isolated using Salmonella enterica serovar Typhimurium as a bacterial host: AR2819, Sajous1, SilasIsHot, and FrontPhageNews. ChubbyThor was isolated using Shigella boydii ., Competing Interests: The authors declare no conflict of interest.

Published

2024

3. Genomic and Proteomic Analysis of Six Vi01-like Phages Reveals Wide Host Range and Multiple Tail Spike Proteins.

Author

Harris EB, Ewool KKK, Bowden LC, Fierro J, Johnson D, Meinzer M, Tayler S, and Grose JH

Subjects

Proteomics, Spike Glycoprotein, Coronavirus genetics, Wastewater, Genomics, Enterobacteriaceae, Genome, Viral, Host Specificity, Bacteriophages genetics, Salmonella Phages genetics

Abstract

Enterobacteriaceae is a large family of Gram-negative bacteria composed of many pathogens, including Salmonella and Shigella . Here, we characterize six bacteriophages that infect Enterobacteriaceae, which were isolated from wastewater plants in the Wasatch front (Utah, United States). These phages are highly similar to the Kuttervirus vB_SenM_Vi01 (Vi01), which was isolated using wastewater from Kiel, Germany. The phages vary little in genome size and are between 157 kb and 164 kb, which is consistent with the sizes of other phages in the Vi01-like phage family. These six phages were characterized through genomic and proteomic comparison, mass spectrometry, and both laboratory and clinical host range studies. While their proteomes are largely unstudied, mass spectrometry analysis confirmed the production of five hypothetical proteins, several of which unveiled a potential operon that suggests a ferritin-mediated entry system on the Vi01-like phage family tail. However, no dependence on this pathway was observed for the single host tested herein. While unable to infect every genus of Enterobacteriaceae tested, these phages are extraordinarily broad ranged, with several demonstrating the ability to infect Salmonella enterica and Citrobacter freundii strains with generally high efficiency, as well as several clinical Salmonella enterica isolates, most likely due to their multiple tail fibers.

Published

2024

4. Genomic Analyses of Major SARS-CoV-2 Variants Predicting Multiple Regions of Pathogenic and Transmissive Importance.

Author

Brugger SW, Grose JH, Decker CH, Pickett BE, and Davis MF

Subjects

Humans, Phylogeny, Genome, Viral, Genomics, Codon, SARS-CoV-2 genetics, COVID-19 genetics

Abstract

The rapid evolution of SARS-CoV-2 has fueled its global proliferation since its discovery in 2019, with several notable variants having been responsible for increases in cases of coronavirus disease 2019 (COVID-19). Analyses of codon bias and usage in these variants between phylogenetic clades or lineages may grant insights into the evolution of SARS-CoV-2 and identify target codons indicative of evolutionary or mutative trends that may prove useful in tracking or defending oneself against emerging strains. We processed a cohort of 120 SARS-CoV-2 genome sequences through a statistical and bioinformatic pipeline to identify codons presenting evidence of selective pressure as well as codon coevolution. We report the identification of two codon sites in the orf8 and N genes demonstrating such evidence with real-world impacts on pathogenicity and transmissivity.

Published

2024

5. Genome sequences of 13 Bacillus anthracis Sterne bacteriophages isolated from soil in the western United States .

Author

Fairholm JD, James R, Lavering ED, Ogilvie BH, Thurgood TL, Robison RA, and Grose JH

Abstract

Bacillus anthracis, classified as a Tier 1 Select Agent by the Centers for Disease Control and Prevention (CDC), is the causative agent of anthrax in both humans and livestock. Herein, we report the full genome sequences of 13 bacteriophages that infect B. anthracis Sterne. These phages are grouped into four clusters and are similar to previously described Bacillus phages., Competing Interests: The authors declare no conflict of interest.

Published

2024

6. Diversity and conservation of the genome architecture of phages infecting the Alphaproteobacteria.

Author

Hyde JR, Armond T, Herring JA, Hope S, Grose JH, Breakwell DP, and Pickett BE

Subjects

Phylogeny, Genomics, Genome, Viral, Whole Genome Sequencing, Bacteriophages genetics

Abstract

Importance: This study reports the results of the largest analysis of genome sequences from phages that infect the Alphaproteobacteria class of bacterial hosts. We analyzed over 100 whole genome sequences of phages to construct dotplots, categorize them into genetically distinct clusters, generate a bootstrapped phylogenetic tree, compute protein orthologs, and predict packaging strategies. We determined that the phage sequences primarily cluster by the bacterial host family, phage morphotype, and genome size. We expect that the findings reported in this seminal study will facilitate future analyses that will improve our knowledge of the phages that infect these hosts., Competing Interests: The authors declare no conflict of interest.

Published

2024

7. Characterization of the Attachment of Three New Coliphages onto the Ferrichrome Transporter FhuA.

Author

Lewis JM, Janda KE, Kotter DB, Grose JH, and McCleary WR

Subjects

Humans, Bacterial Proteins metabolism, Ferrichrome metabolism, Ferrichrome pharmacology, Bacterial Outer Membrane Proteins metabolism, Lipopolysaccharides metabolism, Receptors, Virus metabolism, Membrane Transport Proteins metabolism, Coliphages genetics, Coliphages metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Bacteriophages genetics, Bacteriophages metabolism

Abstract

Receptor-binding proteins (RBPs) allow phages to dock onto their host and initiate infection through the recognition of proteinaceous or saccharidic receptors located on the cell surface. FhuA is the ferrichrome hydroxamate transporter in Escherichia coli and serves as a receptor for the well-characterized phages T1, T5, and phi80. To further characterize how other FhuA-dependent phages attach to FhuA, we isolated and published the genomes of three new FhuA-dependent coliphages: JLBYU37, JLBYU41, and JLBYU60. We identified the egions of FhuA involved in phage attachment by testing the effect of mutant fhuA alleles containing single-loop deletions of extracellular loops (L3, L4, L5, L8, L10, and L11) on phage infectivity. Deletion of loop 8 resulted in complete resistance to SO1-like phages JLBYU37 and JLBYU60 and the previously isolated vB_EcoD_Teewinot phage, but no single-loop deletions significantly altered the infection of T1-like JLBYU41. Additionally, lipopolysaccharide (LPS) truncation coupled with the L5 mutant significantly impaired the infectivity of JLBYU37 and JLBYU60. Moreover, significant reductions in the infectivity of JLBYU41 were observed upon LPS truncation in the L8 mutant strain. Analysis of the evolutionary relationships among FhuA-dependent phage RBPs highlights the conservation of L8 dependence in JLBYU37, JLBYU60, Teewinot, T5, and phi80, but also showcases how positive selective pressure and/or homologous recombination also selected for L4 dependence in T1 and even the lack of complete loop dependence in JLBYU41. IMPORTANCE Phage attachment is the first step of phage infection and plays a role in governing host specificity. Characterizing the interactions taking place between phage tail fibers and bacterial receptors that better equip bacteria to survive within the human body may provide insights to aid the development of phage therapeutics., Competing Interests: The authors declare no conflict of interest.

Published

2023

8. Identifying the core genome of the nucleus-forming bacteriophage family and characterization of Erwinia phage RAY.

Author

Prichard A, Lee J, Laughlin TG, Lee A, Thomas KP, Sy AE, Spencer T, Asavavimol A, Cafferata A, Cameron M, Chiu N, Davydov D, Desai I, Diaz G, Guereca M, Hearst K, Huang L, Jacobs E, Johnson A, Kahn S, Koch R, Martinez A, Norquist M, Pau T, Prasad G, Saam K, Sandhu M, Sarabia AJ, Schumaker S, Sonin A, Uyeno A, Zhao A, Corbett KD, Pogliano K, Meyer J, Grose JH, Villa E, Dutton R, and Pogliano J

Subjects

Phylogeny, Genome, Viral, DNA, Viral genetics, DNA, Viral metabolism, Bacteriophages genetics, Bacteriophages metabolism, Erwinia genetics, Erwinia metabolism

Abstract

We recently discovered that some bacteriophages establish a nucleus-like replication compartment (phage nucleus), but the core genes that define nucleus-based phage replication and their phylogenetic distribution were still to be determined. Here, we show that phages encoding the major phage nucleus protein chimallin share 72 conserved genes encoded within seven gene blocks. Of these, 21 core genes are unique to nucleus-forming phage, and all but one of these genes encode proteins of unknown function. We propose that these phages comprise a novel viral family we term Chimalliviridae. Fluorescence microscopy and cryoelectron tomography studies of Erwinia phage vB_EamM_RAY confirm that many of the key steps of nucleus-based replication are conserved among diverse chimalliviruses and reveal variations on this replication mechanism. This work expands our understanding of phage nucleus and PhuZ spindle diversity and function, providing a roadmap for identifying key mechanisms underlying nucleus-based phage replication., Competing Interests: Declaration of interests K.P. and J.P. have an equity interest in Linnaeus Bioscience Incorporated and receive income. The terms of this arrangement have been reviewed and approved by the University of California, San Diego, in accordance with its conflict-of-interest policies., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

9. Identifying the core genome of the nucleus-forming bacteriophage family and characterization of Erwinia phage RAY.

Author

Prichard A, Lee J, Laughlin TG, Lee A, Thomas KP, Sy A, Spencer T, Asavavimol A, Cafferata A, Cameron M, Chiu N, Davydov D, Desai I, Diaz G, Guereca M, Hearst K, Huang L, Jacobs E, Johnson A, Kahn S, Koch R, Martinez A, Norquist M, Pau T, Prasad G, Saam K, Sandhu M, Sarabia AJ, Schumaker S, Sonin A, Uyeno A, Zhao A, Corbett K, Pogliano K, Meyer J, Grose JH, Villa E, Dutton R, and Pogliano J

Abstract

We recently discovered that some bacteriophages establish a nucleus-like replication compartment (phage nucleus), but the core genes that define nucleus-based phage replication and their phylogenetic distribution were unknown. By studying phages that encode the major phage nucleus protein chimallin, including previously sequenced yet uncharacterized phages, we discovered that chimallin-encoding phages share a set of 72 highly conserved genes encoded within seven distinct gene blocks. Of these, 21 core genes are unique to this group, and all but one of these unique genes encode proteins of unknown function. We propose that phages with this core genome comprise a novel viral family we term Chimalliviridae. Fluorescence microscopy and cryo-electron tomography studies of Erwinia phage vB_EamM_RAY confirm that many of the key steps of nucleus-based replication encoded in the core genome are conserved among diverse chimalliviruses, and reveal that non-core components can confer intriguing variations on this replication mechanism. For instance, unlike previously studied nucleus-forming phages, RAY doesn't degrade the host genome, and its PhuZ homolog appears to form a five-stranded filament with a lumen. This work expands our understanding of phage nucleus and PhuZ spindle diversity and function, providing a roadmap for identifying key mechanisms underlying nucleus-based phage replication.

Published

2023

10. The small genome, virulent, non-contractile tailed bacteriophages that infect Enterobacteriales hosts.

Author

Casjens SR, Davidson AR, and Grose JH

Subjects

Genome, Viral, Host Specificity, Phylogeny, Bacteriophages genetics, Caudovirales genetics

Abstract

Tailed bacteriophages are abundant and extremely diverse. Understanding this diversity is a challenge, and here we examine a small slice of that diversity in some detail. We contrast and compare the small genome, virulent, non-contractile tailed phages that infect the bacterial order Enterobacteriales. These phages, with genomes in the 35-60 kbp range, have very similar virions that are often difficult to distinguish by negative stain electron microscopy. There are currently 651 genome sequences of such phages in the public database. We show that these can be robustly parsed into fifteen well-defined clusters that have very different nucleotide sequences. We examine the similarities and differences among these clusters, as well as genetic exchange among clusters and the relationships between host species and phage clusters., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

11. Genome Sequences of 14 Siphophages That Infect Serratia marcescens.

Author

Carr EL, Wilson ME, Adams ST, Arens DK, Ayala M, Ayers H, Barker A, Beecroft V, Bishop E, Brundage B, Carroll MJ, Chow J, Cobbley H, Davis R, Fajardo C, Flor S, Fuhriman D, Tullis RG, Gleave A, Green C, Hanis T, Hoggan T, Johnson L, Kruger JL, Lambert A, Lazaro EC, Loertscher E, Marshall N, Melhado E, Sarabia R, Sharma R, Steffensen A, Stewart JB, Stoker T, Swain A, Toronto S, Thompson DW, Todd JZ, Walker J, Wilkey A, Wilson D, Hallen CL, Casjens SR, and Grose JH

Abstract

We announce the complete genome sequences of 14 Serratia bacteriophages isolated from wastewater treatment plants. These phages define two previously undescribed types which we call the Carrot-like phage cluster (phages Carrot, BigDog, LittleDog, Niamh, Opt-148, Opt-169, PhooPhighters, Rovert, Serratianator, Stoker, Swain, and Ulliraptor) and Tlacuache-like phage cluster (Tlacuache and Opt-155).

Published

2022

12. Genome Sequences of 22 T1-like Bacteriophages That Infect Enterobacteriales .

Author

Cranston A, Danielson P, Arens DK, Barker A, Birch EK, Brown H, Carr E, Cero P, Chow J, Correa E, Dean J, Dunn M, Eberhard N, Egbert A, Foster K, Gaertner R, Gleave A, Gomez A, Gordon JB, Harris EB, Heaps C, Hyer M, Johnson A, Johnson L, Kim M, Kruger JL, Leonard T, LeSueur A, Lima S, Marshall N, Moulton R, Newey CR, Owen D, Packard A, Rolfson A, Suorsa AR, Rodriguez W, Sandoval C, Sharma R, Smith A, Sork C, Soule C, Soule S, Stewart J, Stoker T, Thompson DW, Thurgood T, Walker J, Zaugg E, Casjens SR, and Grose JH

Abstract

Here, the full genome sequences of 22 T1-like bacteriophages isolated from wastewater are reported. Eight (BlueShadow, Brooksby, Devorator, ElisaCorrea, Reinasaurus, SorkZaugg, Supreme284, ZeroToHero) were isolated on Citrobacter , six on Klebsiella (Chell, FairDinkum, HazelMika, Opt-817, P528, PeteCarol), and eight on Escherichia (Fulano1, Mishu, Opt-719, PhleaSolo, Punny, Poky, Phunderstruck, Sadiya).

Published

2022

13. Complete Genome Sequences of Six Chi-Like Bacteriophages That Infect Proteus and Klebsiella.

Author

Cobbley HK, Evans SI, Brown HMF, Eberhard B, Eberhard N, Kim M, Moe HM, Schaeffer D, Sharma R, Thompson DW, Casjens SR, and Grose JH

Abstract

Proteus mirabilis and Klebsiella aerogenes are Gram-negative opportunistic pathogens that are responsible for nosocomial and health care-associated infections, including urinary tract infections. Here, the full genome sequences of six Chi-like Proteus (DanisaurMW, DoubleBarrel, Inception, Jing313, and NotEvenPhaged) or Klebsiella (Phraden) bacteriophages are announced, contributing to the understanding of Chi-like phages.

Published

2022

14. Complete Genome Sequences of Five SO-1-Like Siphoviridae Bacteriophages That Infect Enterobacteriales .

Author

Purnell MG, Andersen K, Bell A, Briscoe JT, Brown HMF, Carr EL, Doney J, Folsom PF, Green C, Harris EH, Huhem E, Jensen RM, Johnson L, Jones C, Lambert AS, Loertscher E, Newey CR, Porter M, Rallison J, Sharma R, Sork C, Soule S, Stewart JB, Stoker T, Tayler S, Thompson DW, Thurgood TL, Walker J, Breakwell DP, Casjens SR, and Grose JH

Abstract

The Enterobacteriales order is composed of Gram-negative bacteria that range from harmless symbionts to well-studied pathogens. We announce complete genome sequences of five related SO-1-like Enterobacteriales bacteriophages (also known as the Dhillonvirus genus) isolated from wastewater that infect Escherichia coli (Opt-212, Over9000, Pubbukkers, and Teewinot) or Shigella boydii (StarDew).

Published

2022

15. Complete Genome Sequences of Five Bacteriophages That Infect Enterobacteriales Hosts.

Author

Evans S, Cobbley H, Davis K, Divis T, Eberhard N, Flor S, Harris EB, Gordon JB, Hyer M, Larson W, Suorsa AR, Sharma R, Sork C, Thompson DW, Wells L, Casjens SR, and Grose JH

Abstract

Full genome sequences of five bacteriophages that were isolated from raw sewage samples and infect Enterobacteriales hosts are presented. Brookers is a P22-like Proteus phage, OddieOddie is a 9g-like Escherichia coli phage, Diencephelon is a Kp3-like Klebsiella phage, and Rgz1 and Lilpapawes are classic T4-like and T7-like virulent Proteus phages, respectively.

Published

2022