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Bacteriophage Volume 2, 2012 - Issue 3

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Research Paper

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

Mohammed H. Rashid Emerging Pathogens Institute; University of Florida; Gainesville, FL USA

Tamara Revazishvili Emerging Pathogens Institute; University of Florida; Gainesville, FL USA

Timothy Dean United States Environmental Protection Agency; Research Triangle Park; NC USA

Amy Butani Henry M. Jackson Foundation and Biological Defense Research Directorate; Naval Medical Research Center-Frederick; Ft. Detrick, MD USA

Kathleen Verratti Henry M. Jackson Foundation and Biological Defense Research Directorate; Naval Medical Research Center-Frederick; Ft. Detrick, MD USA

Kimberly A. Bishop-Lilly Henry M. Jackson Foundation and Biological Defense Research Directorate; Naval Medical Research Center-Frederick; Ft. Detrick, MD USA

Shanmuga Sozhamannan Henry M. Jackson Foundation and Biological Defense Research Directorate; Naval Medical Research Center-Frederick; Ft. Detrick, MD USA

Alexander Sulakvelidze Emerging Pathogens Institute; University of Florida; Gainesville, FL USA; Intralytix Inc.; Baltimore, MD USA

Chythanya Rajanna Emerging Pathogens Institute; University of Florida; Gainesville, FL USACorrespondence[email protected]

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Pages 168-177 | Published online: 19 Dec 2012

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https://doi.org/10.4161/bact.22240

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Joelle Woolston, Adam R. Parks, Tamar Abuladze, Bradley Anderson, Manrong Li, Chandi Carter, Leigh Farris Hanna, Serena Heyse, Duane Charbonneau & Alexander Sulakvelidze. (2013) Bacteriophages lytic for rapidly reduce contamination on glass and stainless steel surfaces. Bacteriophage 3:3.
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Tamar Suladze, Ekaterine Jaiani, Marina Darsavelidze, Maia Elizbarashvili, Olivier Gorge, Ia Kusradze, Tamar Kokashvili, Nino Lashkhi, George Tsertsvadze, Nino Janelidze, Svetlana Chubinidze, Marina Grdzelidze, Shota Tsanava, Eric Valade & Marina Tediashvili. (2023) New Bacteriophages with Podoviridal Morphotypes Active against Yersinia pestis: Characterization and Application Potential. Viruses 15:7, pages 1484.
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Haixiao Jin, Youhong Zhong, Yiting Wang, Chuanyu Zhang, Jin Guo, Xiaona Shen, Cunxiang Li, Ying Huang, Haoming Xiong, Peng Wang & Wei Li. (2022) Two Novel Yersinia pestis Bacteriophages with a Broad Host Range: Potential as Biocontrol Agents in Plague Natural Foci. Viruses 14:12, pages 2740.
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Jens Andre Hammerl, Andrea Barac, Anja Bienert, Aslihan Demir, Niklas Drüke, Claudia Jäckel, Nina Matthies, Jin Woo Jun, Mikael Skurnik, Juliane Ulrich & Stefan Hertwig. (2022) Birds Kept in the German Zoo “Tierpark Berlin” Are a Common Source for Polyvalent Yersinia pseudotuberculosis Phages. Frontiers in Microbiology 12.
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Sonika Sharma, Sibnarayan Datta, Soumya Chatterjee, Moumita Dutta, Jhuma Samanta, Mohan G. Vairale, Rajeev Gupta, Vijay Veer & Sanjai K. Dwivedi. (2021) Isolation and characterization of a lytic bacteriophage against Pseudomonas aeruginosa. Scientific Reports 11:1.
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Yuriy A. Knirel, Andrey P. Anisimov, Angelina A. Kislichkina, Anna N. Kondakova, Olga V. Bystrova, Anastasia S. Vagaiskaya, Konstantin Y. Shatalin, Alexander S. Shashkov & Svetlana V. Dentovskaya. (2021) Lipopolysaccharide of the Yersinia pseudotuberculosis Complex. Biomolecules 11:10, pages 1410.
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Jing Xu, Ruiyang Zhang, Xinyan Yu, Xuesen Zhang, Genyan Liu & Xiaoqiu Liu. (2021) Molecular Characteristics of Novel Phage vB_ShiP-A7 Infecting Multidrug-Resistant Shigella flexneri and Escherichia coli, and Its Bactericidal Effect in vitro and in vivo. Frontiers in Microbiology 12.
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Junrong Liang, Shuai Qin, Ran Duan, Haoran Zhang, Weiwei Wu, Xu Li, Deming Tang, Guoming Fu, Xinmin Lu, Dongyue Lv, Zhaokai He, Hui Mu, Meng Xiao, Jinchuan Yang, Huaiqi Jing & Xin Wang. (2021) A Lytic Yersina pestis Bacteriophage Obtained From the Bone Marrow of Marmota himalayana in a Plague-Focus Area in China. Frontiers in Cellular and Infection Microbiology 11.
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L. G. Dudina, O. D. Novikova, O. Yu. Portnyagina, V. A. Khomenko, I. V. Konyshev & A. A. Byvalov. (2021) Role of Lipopolysaccharide and Nonspecific Porins of Yersinia pseudotuberculosis in the Reception of Pseudotuberculous Diagnostic Bacteriophage. Applied Biochemistry and Microbiology 57:4, pages 426-433.
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Qiaoli Yang, Sangsang Deng, Jingjing Xu, Umer Farooq, Taotao Yang, Wei Chen, Lei Zhou, Meiying Gao & Shenqi Wang. (2021) Poly(indole-5-carboxylic acid)/reduced graphene oxide/gold nanoparticles/phage-based electrochemical biosensor for highly specific detection of Yersinia pseudotuberculosis. Microchimica Acta 188:4.
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Sudhakar Bhandare & Lawrence Goodridge. 2021. Bacteriophages. Bacteriophages 769 788 .

Julie Stenberg PedersenAlexander Byth CarstensAmaru Miranda DjurhuusWitold KotHorst NeveLars Hestbjerg Hansen. (2020) Pectobacterium Phage Jarilo Displays Broad Host Range and Represents a Novel Genus of Bacteriophages Within the Family Autographiviridae . PHAGE 1:4, pages 237-244.
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Md. Sharifull Islam, Yang Hu, Md. Furkanur Rahaman Mizan, Ting Yan, Ishatur Nime, Yang Zhou & Jinquan Li. (2020) Characterization of Salmonella Phage LPST153 That Effectively Targets Most Prevalent Salmonella Serovars. Microorganisms 8:7, pages 1089.
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Sudhakar Bhandare & Lawrence Goodridge. 2020. Bacteriophages. Bacteriophages 1 20 .

Junrong Liang, Zengqiang Kou, Shuai Qin, Yuhuang Chen, Zhenpeng Li, Chuchu Li, Ran Duan, Huijing Hao, Tao Zha, Wenpeng Gu, Yuanming Huang, Meng Xiao, Huaiqi Jing & Xin Wang. (2019) Novel Yersinia enterocolitica Prophages and a Comparative Analysis of Genomic Diversity. Frontiers in Microbiology 10.
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Paul Hyman. (2019) Phages for Phage Therapy: Isolation, Characterization, and Host Range Breadth. Pharmaceuticals 12:1, pages 35.
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Ana Rodríguez, Beatriz Martínez, Pilar García, Patricia Ruas-Madiedo & Borja Sánchez. 2017. Starter Cultures in Food Production. Starter Cultures in Food Production 299 323 .

Xiangna Zhao & Mikael Skurnik. 2016. Yersinia pestis: Retrospective and Perspective. Yersinia pestis: Retrospective and Perspective 361 375 .

Neha Bhardwaj, Sanjeev K. Bhardwa, Akash Deep, Swati Dahiya & Sanjay Kapoor. (2015) Lytic Bacteriophages as Biocontrol Agents of Foodborne Pathogens. Asian Journal of Animal and Veterinary Advances 10:11, pages 708-723.
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Hiroki Ando, Sebastien Lemire, Diana P. Pires & Timothy K. Lu. (2015) Engineering Modular Viral Scaffolds for Targeted Bacterial Population Editing. Cell Systems 1:3, pages 187-196.
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Kyle C. Jensen, Bryan B. Hair, Trevor M. Wienclaw, Mark H. Murdock, Jacob B. Hatch, Aaron T. Trent, Tyler D. White, Kyler J. Haskell & Bradford K. Berges. (2015) Isolation and Host Range of Bacteriophage with Lytic Activity against Methicillin-Resistant Staphylococcus aureus and Potential Use as a Fomite Decontaminant. PLOS ONE 10:7, pages e0131714.
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Andrea I. Moreno Switt, Alexander Sulakvelidze, Martin Wiedmann, Andrew M. Kropinski, David S. Wishart, Cornelis Poppe & Yongjie Liang. 2015. Salmonella. Salmonella 237 287 .

Geevika J Ganegama Arachchi, Andrew G Cridge, Beatrice M Dias-Wanigasekera, Cristina D Cruz, Lynn McIntyre, Rachel Liu, Steve H Flint & Anthony N Mutukumira. (2013) Effectiveness of phages in the decontamination of Listeria monocytogenes adhered to clean stainless steel, stainless steel coated with fish protein, and as a biofilm . Journal of Industrial Microbiology and Biotechnology 40:10, pages 1105-1116.
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Alexander Sulakvelidze. (2013) Using lytic bacteriophages to eliminate or significantly reduce contamination of food by foodborne bacterial pathogens. Journal of the Science of Food and Agriculture 93:13, pages 3137-3146.
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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

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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

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