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1. Complete Genome Sequences of Paenibacillus larvae Phages BN12, Dragolir, Kiel007, Leyra, Likha, Pagassa, PBL1c, and Tadhana

   https://doi.org/10.1128/genomeA.01602-17  

   Walker, Jamison K.; Merrill, Bryan D.; Berg, Jordan A.; Dhalai, Aziza; Dingman, Douglas W.; Fajardo, Chris P.; Graves, Kiel; Hill, Hunter L.; Hilton, Jared A.; Imahara, Cameron; et al (June 2018, Genome Announcements)

   ABSTRACT We present here the complete genomes of eight phages that infect Paenibacillus larvae , the causative agent of American foulbrood in honeybees. Phage PBL1c was originally isolated in 1984 from a P. larvae lysogen, while the remaining phages were isolated in 2014 from bee debris, honeycomb, and lysogens from three states in the USA. 

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2. More’s the Same—Multiple Hosts Do Not Select for Broader Host Range Phages

   https://doi.org/10.3390/v15020518  

   Myers, Jupiter; Davis II, Joshua; Lollo, Megan; Hudec, Gabriella; Hyman, Paul (February 2023, Viruses)

   Bacteriophage host range is a result of the interactions between phages and their hosts. For phage therapy, phages with a broader host range are desired so that a phage can infect and kill the broadest range of pathogen strains or related species possible. A common, but not well-tested, belief is that using multiple hosts during the phage isolation will make the isolation of broader host range phage more likely. Using a Bacillus cereus group system, we compared the host ranges of phages isolated on one or four hosts and found that there was no difference in the breadth of host ranges of the isolated phages. Both narrow and broader host range phage were also equally likely to be isolated from either isolation procedure. While there are methods that reliably isolate broader host range phages, such as sequential host isolation, and there are other reasons to use multiple hosts during isolation, multiple hosts are not a consistent way to obtain broader host range phages. 

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3. The Missing Tailed Phages: Prediction of Small Capsid Candidates

   https://doi.org/10.3390/microorganisms8121944  

   Luque, Antoni; Benler, Sean; Lee, Diana Y.; Brown, Colin; White, Simon (December 2020, Microorganisms)

   null (Ed.)

   Tailed phages are the most abundant and diverse group of viruses on the planet. Yet, the smallest tailed phages display relatively complex capsids and large genomes compared to other viruses. The lack of tailed phages forming the common icosahedral capsid architectures T = 1 and T = 3 is puzzling. Here, we extracted geometrical features from high-resolution tailed phage capsid reconstructions and built a statistical model based on physical principles to predict the capsid diameter and genome length of the missing small-tailed phage capsids. We applied the model to 3348 isolated tailed phage genomes and 1496 gut metagenome-assembled tailed phage genomes. Four isolated tailed phages were predicted to form T = 3 icosahedral capsids, and twenty-one metagenome-assembled tailed phages were predicted to form T < 3 capsids. The smallest capsid predicted was a T = 4/3 ≈ 1.33 architecture. No tailed phages were predicted to form the smallest icosahedral architecture, T = 1. We discuss the feasibility of the missing T = 1 tailed phage capsids and the implications of isolating and characterizing small-tailed phages for viral evolution and phage therapy. 

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4. Genome Sequences of Gordonia rubripertincta Phages LilyPad and PokyPuppy

   https://doi.org/10.1128/mra.00958-22  

   Eleven, Ella; Esparza, Casia; Abernathy, Alivia; Bradshaw, Ashley; Garcia, Marisa; Jobe, Nathaniel; Pyper, Kennedi; Skaar, Cassandra; Goncz, Kaarin; Sharbrough, Joel; et al (November 2022, Microbiology Resource Announcements)

   Stedman, Kenneth M (Ed.)

   Two lytic phages infectingGordonia rubripertinctawere isolated from irrigated desert soil. Phage LilyPad and PokyPuppy have 64,158-bp and 77,065-bp genomes, respectively. Based on gene content similarity to phages in the Actinobacteriophage database, LilyPad is assigned to phage subcluster DG1 and PokyPuppy to subcluster CS2. 

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5. Mutant and Recombinant Phages Selected from In Vitro Coevolution Conditions Overcome Phage-Resistant Listeria monocytogenes

   https://doi.org/10.1128/AEM.02138-20  

   Peters, Tracey Lee; Song, Yaxiong; Bryan, Daniel W.; Hudson, Lauren K.; Denes, Thomas G. (October 2020, Applied and Environmental Microbiology)

   Dudley, Edward G. (Ed.)

   ABSTRACT Bacteriophages (phages) are currently available for use by the food industry to control the foodborne pathogen Listeria monocytogenes . Although phage biocontrols are effective under specific conditions, their use can select for phage-resistant bacteria that repopulate phage-treated environments. Here, we performed short-term coevolution experiments to investigate the impact of single phages and a two-phage cocktail on the regrowth of phage-resistant L. monocytogenes and the adaptation of the phages to overcome this resistance. We used whole-genome sequencing to identify mutations in the target host that confer phage resistance and in the phages that alter host range. We found that infections with Listeria phages LP-048, LP-125, or a combination of both select for different populations of phage-resistant L. monocytogenes bacteria with different regrowth times. Phages isolated from the end of the coevolution experiments were found to have gained the ability to infect phage-resistant mutants of L. monocytogenes and L. monocytogenes strains previously found to be broadly resistant to phage infection. Phages isolated from coinfected cultures were identified as recombinants of LP-048 and LP-125. Interestingly, recombination events occurred twice independently in a locus encoding two proteins putatively involved in DNA binding. We show that short-term coevolution of phages and their hosts can be utilized to obtain mutant and recombinant phages with adapted host ranges. These laboratory-evolved phages may be useful for limiting the emergence of phage resistance and for targeting strains that show general resistance to wild-type (WT) phages. IMPORTANCE Listeria monocytogenes is a life-threatening bacterial foodborne pathogen that can persist in food processing facilities for years. Phages can be used to control L. monocytogenes in food production, but phage-resistant bacterial subpopulations can regrow in phage-treated environments. Coevolution experiments were conducted on a Listeria phage-host system to provide insight into the genetic variation that emerges in both the phage and bacterial host under reciprocal selective pressure. As expected, mutations were identified in both phage and host, but additionally, recombination events were shown to have repeatedly occurred between closely related phages that coinfected L. monocytogenes . This study demonstrates that in vitro evolution of phages can be utilized to expand the host range and improve the long-term efficacy of phage-based control of L. monocytogenes . This approach may also be applied to other phage-host systems for applications in biocontrol, detection, and phage therapy. 

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