Selection and Characterization of Bacteriophages Specific to Choleraesuis in Swine

Overview

Journal Vet World

Specialty Veterinary Medicine

Date 2023 Jan 31

PMID 36718326

Authors

Pattaraporn Sriprasong

Napakhwan Imklin

Rujikan Nasanit

Affiliations

Soon will be listed here.

Abstract

Background And Aim: Choleraesuis is the most common serotype that causes salmonellosis in swine. Recently, the use of bacteriophages as a potential biocontrol strategy has increased. Therefore, this study aimed to isolate and characterize bacteriophages specific to . Choleraesuis associated with swine infection and to evaluate the efficacy of individual phages and a phage cocktail against . Choleraesuis strains in simulated intestinal fluid (SIF).

Materials And Methods: Three strains of . Choleraesuis isolated from pig intestines served as host strains for phage isolation. The other 10 serovars were also used for the phage host range test. The antibiotic susceptibility of the bacterial strains was investigated. Water samples from natural sources and drain liquid from slaughterhouses were collected for phage isolation. The isolated phages were characterized by determining the efficiency of plating against all Salmonella strains and the stability at a temperature range (4°C-65°C) and at low pH (2.5-4.0) in simulated gastric fluids (SGFs). Furthermore, morphology and genomic restriction analyses were performed for phage classification phages. Finally, . Choleraesuis reduction in the SIF by the selected individual phages and a phage cocktail was investigated.

Results: The antibiotic susceptibility results revealed that most strains were sensitive to all tested drugs. Choleraesuis KPS615 was multidrug-resistant, showing resistance to three antibiotics. Nine phages were isolated. Most of them could infect four strains. Phages vB_SCh-RP5i3B and vB_SCh-RP61i4 showed high efficiency in infecting . Choleraesuis and Rissen. The phages were stable for 1 h at 4°C-45°C. However, their viability decreased when the temperature increased to 65°C. In addition, most phages remained viable at a low pH (pH 2.5-4.0) for 2 h in SGF. The efficiency of phage treatment against . Choleraesuis in SIF showed that individual phages and a phage cocktail with three phages effectively reduced . Choleraesuis in SIF. However, the phage cocktails were more effective than the individual phages.

Conclusion: These results suggest that the newly isolated phages could be promising biocontrol agents against S. Choleraesuis infection in pigs and could be orally administered. However, further studies should be conducted.

Citing Articles

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