Evaluation of anhydrous processing and storage methods of the temperate bacteriophage ɸV10 for integration into foodborne pathogen detection methodologies

Due to the nascency of bacteriophage-based pathogen detection technologies, several practical hurdles stand in the way between providing promising proof-of-concept data and development of robust detection platforms. One such hurdle, and the focus of this work, is the development of methods for trans...

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Bibliographic Details
Published in:PloS one 2021, Vol.16 (4), p.e0249473
Main Authors: Kanach, Andrew, Bottorff, Theresa, Zhao, Min, Wang, Jun, Chiu, George T C, Applegate, Bruce
Format: Article
Language:English
Subjects:
Agricultural technology
Assaying
Bacteria
Bacteriophages - physiology
Biology and Life Sciences
Data analysis
E coli
Editing
Escherichia coli O157 - virology
Food
Food contamination
Food industry
Food Microbiology - methods
Food processing
Food processing industry
Food science
Foodborne diseases
Foodborne pathogens
Freeze Drying - methods
Genomes
Infections
Integration
Mechanical engineering
Medicine and Health Sciences
Methodology
Methods
Packaging
Pathogens
Phages
Physical Sciences
Refrigeration
Reporters
Research and Analysis Methods
Reviews
Science and technology
Storage
Target detection
Virulence
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Summary:Due to the nascency of bacteriophage-based pathogen detection technologies, several practical hurdles stand in the way between providing promising proof-of-concept data and development of robust detection platforms. One such hurdle, and the focus of this work, is the development of methods for transitioning laboratory stocks of bacteriophage into functional, consistent, and shelf-stable delivery methods in commercial detection kits. Research described here was undertaken to evaluate two methods for their ability to store the bacteriophage ɸV10 at ambient temperature without aqueous storage solutions while limiting loss of viability. ɸV10 is a temperate bacteriophage which solely infects the zero-tolerance food adulterant Escherichia coli O157:H7 and has been genetically modified to generate a detectable phenotype in host cells. In order to integrate this reporter bacteriophage into food-borne pathogen detection methodologies, two methods of processing phage suspensions for long-term, ambient storage were evaluated: printing solutions onto pieces of dissolvable paper and lyophilizing suspensions with sucrose. Applying phage to dissolvable paper yielded key attributes to consider when addressing phage viability, however, optimized methodology still resulted in an approximate five-log reduction in titer of viable phage. Lyophilization of ɸV10 with various concentrations of the cryoprotectant molecule, sucrose, yielded losses of approximately 0.3-log after 120 days of storage at 23°C. Liquid storage buffer samples with and without sucrose saw a reduction of viable phage of at least 3.9-log in the same period. Additionally, the ability for ɸV10 to form lysogens in an E. coli O157:H7 host was not negatively affected by lyophilization. Drying ɸV10 at ambient temperature drastically reduces the viability of the phage. However, lyophilizing ɸV10 in the presence of sucrose is an effective method for dehydration and storage of the phage in ambient environmental conditions for an extended time lending to commercial application and integration into foodborne pathogen detection methodologies.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0249473