A Yersinia pestis-specific, lytic phage preparation significantly reduces viable Y. pestis on various hard surfaces experimentally contaminated with the bacterium

Rashid, Mohammed H.; Revazishvili, Tamara; Dean, Timothy R.; Butani, Amy; Verratti, Kathleen; Bishop‐Lilly, Kimberly A.; Sozhamannan, Shanmuga; Sulakvelidze, Alexander; Rajanna, Chythanya

doi:10.4161/bact.22240

Cited by 35 publications

(39 citation statements)

References 26 publications

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“…We hypothesized that these differences could be responsible for their divergent host ranges. Indeed, we were unable to detect productive T3 infection of Y. ptb strains IP2666 and YPIII, which are known hosts for phage R (Rashid et al, 2012). Because we did not have access to phage R, we introduced the desired mutations in T3 gene 17 by PCR so that it would encode the same tail fiber as phage R (Figure 4A).…”

Section: Resultsmentioning

confidence: 89%

Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing

Ando

Lemire

Pires

et al. 2015

Preprint

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15Bacteria are central to human health and disease, but the tools available for modulating and 16 editing bacterial communities are limited. New technologies for tuning microbial populations 17 would facilitate the targeted manipulation of the human microbiome and treatment of bacterial 18 infections. For example, antibiotics are often broad spectrum in nature and cannot be used to 19 accurately manipulate bacterial communities. Bacteriophages can provide highly specific 20 targeting of bacteria, but relying solely on natural phage isolation strategies to assemble well-21 defined and uniform phage cocktails that are amenable to engineering can be a time-consuming 22 and labor-intensive process. Here, we present a synthetic-biology strategy to modulate phage 23 host ranges by manipulating phage genomes in Saccharomyces cerevisiae. We used this 24 technology to swap multiple modular phage tail components and demonstrated that Escherichia 25 coli phage scaffolds can be redirected to target pathogenic Yersinia and Klebsiella bacteria, and 26 conversely, Klebsiella phage scaffolds can be redirected to target E. coli. The synthetic phages 27 achieved multiple orders-of-magnitude killing of their new target bacteria and were used to 28 selectively remove specific bacteria from multi-species bacterial communities. We envision that 29 this approach will accelerate the study of phage biology, facilitate the tuning of phage host 30 ranges, and enable new tools for microbiome engineering and the treatment of infectious diseases. 31 32 65 their manipulation within bacterial hosts. Finally, all existing approaches are limited in the 66 number of mutations that can be introduced simultaneously. Multiple rounds of mutations are 67 therefore often required, making the process inefficient. Here, we demonstrate a high-throughput 68 phage-engineering platform that leverages the tools of synthetic biology to overcome these 69 challenges and use this platform to engineer model phages with tunable host ranges. 70 71 RESULTS 72Yeast platform for bacteriophage genome engineering. 73 We used an efficient yeast-based platform (Jaschke et al., 2012; Lu et al., 2013) to create phages 74 with novel host ranges based on common viral scaffolds. Inspired by gap-repair cloning in yeast 75 (Ma et al., 1987) and the pioneering work of Gibson and co-workers (Gibson, 2012; Gibson et al., 76 2008; Gibson et al., 2009), we captured phage genomes into Saccharomyces cerevisiae, thus 77 enabling facile genetic manipulation of modified genomes that can be subsequently re-activated 78 or "rebooted" into functional phages after transformation of genomic DNA into bacteria (Figure 79 1A). The workflow is split into two parts. In the first part, the entirety of the viral genome to be 80 assembled in yeast is amplified by PCR in such a way that each adjacent fragment has homology 81 over at least 30 bp. The first and last fragments of the phage genome are amplified with primers 82 that carry "arms" that have homology with a yeast artificial chromosome (YA...

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Section: Resultsmentioning

confidence: 89%

Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing

Ando

Lemire

Pires

et al. 2015

Preprint

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“…We introduced these three mutations in T3 gene 17 by PCR so that it would encode the same tail fiber as phage R (Figure 4A). While T3 did not plaque on Y. ptb strains IP2666 and YPIII, which are known hosts for phage R (Rashid et al, 2012), synthetic T3 phage with the R tail fiber (T3 R(gp17) ) was able to infect Y. ptb IP2666 and YPIII (Figure 3 and Figure S2). The adsorption efficiencies of T3 WT and T3 R(gp17) against Y. ptb IP2666 were found to be 0.01±0.01% and 90.05±1.1%, respectively.…”

Section: Resultsmentioning

confidence: 99%

Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing

et al. 2015

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SUMMARY Bacteria are central to human health and disease, but existing tools to edit microbial consortia are limited. For example, broad-spectrum antibiotics are unable to accurately manipulate bacterial communities. Bacteriophages can provide highly specific targeting of bacteria, but assembling well-defined phage cocktails solely with natural phages can be a time-, labor- and cost-intensive process. Here, we present a synthetic-biology strategy to modulate phage host ranges by engineering phage genomes in Saccharomyces cerevisiae. We used this technology to redirect Escherichia coli phage scaffolds to target pathogenic Yersinia and Klebsiella bacteria, and conversely, Klebsiella phage scaffolds to target E. coli by modular swapping of phage tail components. The synthetic phages achieved efficient killing of their new target bacteria and were used to selectively remove bacteria from multi-species bacterial communities with cocktails based on common viral scaffolds. We envision that this approach will accelerate phage-biology studies and enable new technologies for bacterial population editing.

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“…Recently, using lytic bacteriophages to remove specifi c foodborne and non-foodborne bacterial pathogens from hard surfaces has been gaining increased attention. For example, some studies have focused on determining the efficacy of phages targeting some major foodborne bacterial pathogens, such as Listeria monocytogenes [ 235 , 236 ] and E. coli O157:H7 [ 237 , 238 ], as well as some non-foodborne pathogens of high bioterrorism concern [ 239 ]. Also, a phage-based preparation (ListShield™) was recently granted registration by the U.S. Environmental Protection Agency (EPA) as an antimicrobial for signifi cantly reducing L. monocytogenes contamination of nonfood-contact surfaces in food processing plants and food handling establishments (EPA Registration # 74234-1).…”

Section: Salmonella Phages For Preventing and Treating Salmonellosis mentioning

confidence: 99%

Salmonella Phages and Prophages: Genomics, Taxonomy, and Applied Aspects

Switt

Sulakvelidze

Wiedmann

et al. 2014

Methods in Molecular Biology

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Since this book was originally published in 2007 there has been a significant increase in the number of Salmonella bacteriophages, particularly lytic virus, and Salmonella strains which have been fully sequenced. In addition, new insights into phage taxonomy have resulted in new phage genera, some of which have been recognized by the International Committee of Taxonomy of Viruses (ICTV). The properties of each of these genera are discussed, along with the role of phage as agents of genetic exchange, as therapeutic agents, and their involvement in phage typing.

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A Yersinia pestis-specific, lytic phage preparation significantly reduces viable Y. pestis on various hard surfaces experimentally contaminated with the bacterium

Cited by 35 publications

References 26 publications

Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing

Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing

Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing

Salmonella Phages and Prophages: Genomics, Taxonomy, and Applied Aspects

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