Quantitation of viable Coxiella burnetii in milk using an integrated cell culture-polymerase chain reaction (ICC-PCR) assay

The obligate intracellular pathogen Coxiella burnetii has long been considered the most heat resistant pathogen in raw milk, making it the reference pathogen for determining pasteurisation conditions for milk products. New milk formulations and novel non-thermal processes require validation of effec...

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Bibliographic Details
Published in:Journal of dairy research 2015-11, Vol.82 (4), p.478-484
Main Authors: Stewart, Diana, Shieh, Y-Carol, Tortorello, Mary, Kukreja, Ankush, Shazer, Arlette, Schlesser, Joseph
Format: Article
Language:English
Subjects:
Animal models
Animals
Bacteriological Techniques - veterinary
Cattle
Cattle Diseases - diagnosis
cell culture
Cercopithecus aethiops
Coxiella burnetii
Coxiella burnetii - isolation & purification
genes
guinea pigs
heat inactivation
heat tolerance
Inactivation
Milk
Milk - microbiology
pasteurization
Pathogens
Polymerase Chain Reaction - veterinary
Q Fever - microbiology
Q Fever - veterinary
raw milk
Vero Cells
viability
whole milk
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Summary:The obligate intracellular pathogen Coxiella burnetii has long been considered the most heat resistant pathogen in raw milk, making it the reference pathogen for determining pasteurisation conditions for milk products. New milk formulations and novel non-thermal processes require validation of effectiveness which requires a more practical method for analysis than using the currently used animal model for assessing Coxiella survival. Also, there is an interest in better characterising thermal inactivation of Coxiella in various milk formulations. To avoid the use of the guinea pig model for evaluating Coxiella survival, an Integrated Cell Culture-PCR (ICC-PCR) method was developed for determining Coxiella viability in milk. Vero cell cultures were directly infected from Coxiella-contaminated milk in duplicate 24-well plates. Viability of the Coxiella in milk was shown by a ≥0·5 log genome equivalent (ge)/ml increase in the quantity of IS111a gene from the baseline post-infection (day 0) level after 9–11 d propagation. Coxiella in skim, 2%, and whole milk, and half and half successfully infected Vero cells and increased in number by at least 2 logs using a 48-h infection period followed by 9-d propagation time. As few as 125 Coxiella ge/ml in whole milk was shown to infect and propagate at least 2 logs in the optimised ICC-PCR assay, though variable confirmation of propagation was shown for as low as 25 Coxiella ge/ml. Applicability of the ICC-PCR method was further proven in an MPN format to quantitate the number of viable Coxiella remaining in whole milk after 60 °C thermal treatment at 0, 20, 40, 60 and 90 min.
ISSN:1469-7629
0022-0299
1469-7629
DOI:10.1017/S0022029915000400