Modified Bacteriophage S16 Long Tail Fiber Proteins for Rapid and Specific Immobilization and Detection of Salmonella Cells

Denyes, Jenna; Dunne, Matthew; Steiner, Stanislava; Mittelviefhaus, Maximilian; Weiß, Agnes; Schmidt, Herbert; Klumpp, Jochen; Loessner, Martin J.

doi:10.1128/aem.00277-17

Cited by 63 publications

(50 citation statements)

References 63 publications

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“…Both phages are equipped with baseplate‐attached long tail fibers (LTFs) that mediate receptor‐binding through their distal tips . We recently exploited the Salmonella‐ specific binding of the S16 LTF as a tool for rapid, ELISA‐like detection of Salmonella contaminants in food …”

Section: Resultsmentioning

confidence: 99%

“…[64][65][66][67][68] We recently exploited the Salmonella-specific binding of the S16 LTF as a tool for rapid, ELISA-like detection of Salmonella contaminants in food. 69 The T4 and S16 LTFs are similar to each except for the structure of their distal tip that interacts with the host cell surface during host recognition. The distal tip of the T4 LTF is formed by the C-terminal domain of gene product 37 (gp37), whereas the S16 LTF carries an additional protein--gp38 that caps gp37.…”

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Target highlights in CASP13: Experimental target structures through the eyes of their authors

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Section: Resultsmentioning

confidence: 99%

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Target highlights in CASP13: Experimental target structures through the eyes of their authors

et al. 2019

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“…Phages directly enter eukaryotic host epithelial cells via active transcytosis . This phage uptake can be specific, ie, via eukaryotic cellular receptors or it can be nonspecific . It is said that during this internalization process, phages escape degradation in cellular lysosomal compartments and thus induce cellular immunity .…”

Section: Why Phage Therapy?mentioning

confidence: 99%

The dawn of phage therapy

Rehman

Ali

Khan

et al. 2019

Reviews in Medical Virology

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Bacteriophages or phages, being the most abundant entities on earth, represent a potential solution to a diverse range of problems. Phages are successful antibacterial agents whose use in therapeutics was hindered by the discovery of antibiotics. Eventually, because of the development and spread of antibiotic resistance among most bacterial species, interest in phage as therapeutic entities has returned, because their noninfectious nature to humans should make them safe for human nanomedicine.This review highlights the most recent advances and progress in phage therapy and bacterial hosts against which phage research is currently being conducted with respect to food, human, and marine pathogens. Bacterial immunity against phages and tactics of phage revenge to defeat bacterial defense systems are also summarized.We have also discussed approved phage-based products (whole phage-based products and phage proteins) and shed light on their influence on the eukaryotic host with respect to host safety and induction of immune response against phage preparations.Moreover, creation of phages with desirable qualities and their uses in cancer treatment, vaccine production, and other therapies are also reviewed to bring together evidence from the scientific literature about the potentials and possible utility of phage and phage encoded proteins in the field of therapeutics and industrial biotechnology.

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“…Microbead‐bound affinity proteins derived from phages incorporated into these enrichments increased the likelihood of capturing viable cells for further identification. Such is the case with a RBP of phage S16, which when immobilised onto microbeads, could recover Salmonella serovars in milk and chocolate milk from an initial inoculum of just 1–10 CFU/25 mL (Denyes et al ).…”

Section: Exploitation Of Phages and Phage Proteins For Pathogen Detecmentioning

confidence: 99%

The use of bacteriophages to control and detect pathogens in the dairy industry

O’Sullivan

Bolton

McAuliffe

et al. 2019

Int J of Dairy Tech

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Dairy products are susceptible to bacterial contamination during both primary production and the processing stages. Pasteurisation and high hydrostatic pressure are used to eliminate bacteria from milk; however, some heat‐tolerant pathogens and bacterial spores may survive these processes. Bacteriophages (phages) are viruses that infect and lyse specific bacteria. These or their encoded proteins may be exploited for pathogen biocontrol in milk products and for mastitis treatment during primary production. The host specificity of phages and their proteins may also be exploited for pathogen detection. Various examples of phage‐mediated pathogen biocontrol and detection in the dairy context are discussed in this review.

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Modified Bacteriophage S16 Long Tail Fiber Proteins for Rapid and Specific Immobilization and Detection of Salmonella Cells

Cited by 63 publications

References 63 publications

Target highlights in CASP13: Experimental target structures through the eyes of their authors

Target highlights in CASP13: Experimental target structures through the eyes of their authors

The dawn of phage therapy

The use of bacteriophages to control and detect pathogens in the dairy industry

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