151. Shiga Toxin-Producing Escherichia coli O157 Shedding Dynamics in an Australian Beef Herd
- Author
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Geraldine Lammers, Petra Muellner, Jane Heller, Christina Ahlstrom, Meghan Jones, Ruiting Lan, and Sophie Octavia
- Subjects
0301 basic medicine ,Whole genome sequencing ,Genetics ,lcsh:Veterinary medicine ,Molecular epidemiology ,General Veterinary ,Strain (biology) ,030106 microbiology ,MLVA typing ,Multiple Loci VNTR Analysis ,Biology ,Beef cattle ,medicine.disease_cause ,molecular epidemiology ,03 medical and health sciences ,food safety ,030104 developmental biology ,Herd ,medicine ,Escherichia coli ,lcsh:SF600-1100 ,Shiga toxin-producing Escherichia coli O157 ,Feces - Abstract
Shiga-toxin producing Escherichia coli (STEC) O157 is an important foodborne pathogen that can be transmitted to humans both directly and indirectly from the feces of beef cattle, its primary reservoir. Numerous studies have investigated the shedding dynamics of E. coli O157 by beef cattle, however the spatiotemporal trends of shedding are still not well understood. Molecular tools can increase the resolution through the use of strain typing to explore transmission dynamics within and between herds and identify strain-specific characteristics that may influence pathogenicity and spread. Previously, the shedding dynamics and molecular diversity, through the use of multilocus variable number of tandem repeat analysis (MLVA) of STEC O157, were separately investigated in an Australian beef herd over a 9-month study period. Variation in shedding was observed over time and 33 MLVA types were identified. The study presented here combines the two datasets previously published with an aim to clarify the relationship between epidemiological variables and strain types. Three major genetic clusters were identified that were significantly associated with the location of the cattle in different paddocks. No significant association between genetic clusters and individual cow was observed. Results from this molecular epidemiological study provide evidence for herd-level clonal replacement over time that may have been triggered by movement to a new paddock. In conclusion, this study has provided further insight into STEC O157 shedding dynamics and pathogen transmission. Knowledge gaps remain regarding the relationship of strain types and the shedding dynamics of STEC O157 by beef cattle that could be further clarified through the use of whole genome sequencing.
- Published
- 2017