Effect of a phase I Coxiella burnetii inactivated vaccine on body temperature and milk yield in dairy cows.

Q fever is a zoonotic disease caused by Coxiella burnetii. The pathogen is prevalent in ruminants (goats, sheep, cows), which are the main sources of human infection. In the cattle industry around the world, animal (15 to 20%) and herd (38 to 72%) level prevalences of C. burnetii are high. Vaccination of ruminants against Q fever is considered important to prevent spreading of the disease and risk of infection in humans. However, published information on side effects of the Q fever vaccination under field conditions is limited for cows. The objective of this study was to investigate the effect of the phase I C. burnetii inactivated vaccine Coxevac on body temperature and milk yield in dairy cows. In 2 experiments, a total of 508 cows were randomly divided into 2 groups to determine the effect of first vaccination on body temperature and milk yield. The C. burnetii serostatus of all cows was tested before vaccination with an indirect ELISA. The first experiment took place in the teaching and research barn of the Clinic of Animal Reproduction at the Freie Universität Berlin. Temperature was measured vaginally in 10 cows in a crossover design. The second experiment was conducted on a commercial dairy farm. Milk yield of 498 cows was measured 1 wk before and 1 wk after vaccination. In a subset of 41 cows, temperature was measured rectally. In both experiments, body temperature increased significantly after vaccination (1.0 ± 0.9°C and 0.7 ± 0.8°C). A significant difference was also found in body temperature between vaccinated and control cows. Thirty percent of the vaccinated animals in experiment 1 showed reversible swelling at the injection site as a reaction to the vaccination. The results indicate that vaccination against Q fever causes a transient increase of body temperature that peaks in the first 12 to 24h and declines after that. In experiment 2, vaccinated cows (26.8 ± 0.39 kg/d) produced significantly less milk than did control cows (28.2 ± 0.44 kg/d) 7d after first vaccination. The cumulative milk loss after first vaccination was influenced by an interaction between C. burnetii serostatus and average milk yield 7d before first vaccination. This was considered as part of the physiological immune response. Three out of 10 vaccinated animals in experiment 1 showed painful swelling of the skin at the injection site, which had a maximum size of 14.0 × 14.0 × 1.1cm. In conclusion, a transient increase of body temperature and a decrease in milk yield is prevalent after Coxevac vaccination.

[1]  F. López-Gatius,et al.  Does Coxiella burnetii affect reproduction in cattle? A clinical update. , 2014, Reproduction in domestic animals = Zuchthygiene.

[2]  W. Heuwieser,et al.  Prediction of parturition in bitches utilizing continuous vaginal temperature measurement. , 2014, Reproduction in domestic animals = Zuchthygiene.

[3]  F. Beaudeau,et al.  Vaccination using phase I vaccine is effective to control Coxiella burnetii shedding in infected dairy cattle herds. , 2014, Comparative immunology, microbiology and infectious diseases.

[4]  R. Berkelman,et al.  Survey of laboratory animal technicians in the United States for Coxiella burnetii antibodies and exploration of risk factors for exposure. , 2013, Journal of the American Association for Laboratory Animal Science : JAALAS.

[5]  F. López-Gatius,et al.  Reproductive performance of high producing lactating cows in Coxiella-infected herds following vaccination with phase-I Coxiella burnetii vaccine during advanced pregnancy. , 2013, Vaccine.

[6]  T. Mirski,et al.  Q fever--selected issues. , 2013, Annals of agricultural and environmental medicine : AAEM.

[7]  E. Monleón,et al.  Coxiella burnetii shedding during the peripartum period and subsequent fertility in dairy cattle. , 2013, Reproduction in domestic animals = Zuchthygiene.

[8]  W. Heuwieser,et al.  Agreement between rectal and vaginal temperature measured with temperature loggers in dairy cows , 2013, Journal of Dairy Research.

[9]  F. Beaudeau,et al.  Effectiveness of vaccination and antibiotics to control Coxiella burnetii shedding around calving in dairy cows. , 2012, Veterinary microbiology.

[10]  F. López-Gatius,et al.  Serological screening for Coxiella burnetii infection and related reproductive performance in high producing dairy cows. , 2012, Research in veterinary science.

[11]  C. Wagner-Wiening,et al.  High seroprevalence of Coxiella burnetii antibodies in veterinarians associated with cattle obstetrics, Bavaria, 2009. , 2012, Vector borne and zoonotic diseases.

[12]  W. Heuwieser,et al.  Validity of prepartum changes in vaginal and rectal temperature to predict calving in dairy cows. , 2011, Journal of dairy science.

[13]  A. Vossen,et al.  Insights into the dynamics of endemic Coxiella burnetii infection in cattle by application of phase-specific ELISAs in an infected dairy herd. , 2011, Veterinary microbiology.

[14]  H. Seegers,et al.  Prevalence of Coxiella burnetii infection in domestic ruminants: a critical review. , 2011, Veterinary microbiology.

[15]  Y. V. van Duynhoven,et al.  Q fever in the Netherlands: an update on the epidemiology and control measures. , 2010, Euro surveillance : bulletin Europeen sur les maladies transmissibles = European communicable disease bulletin.

[16]  D. Weary,et al.  Short communication: repeatability of measures of rectal temperature in dairy cows. , 2010, Journal of dairy science.

[17]  F. Conraths,et al.  Comparative safety study of three inactivated BTV-8 vaccines in sheep and cattle under field conditions. , 2009, Vaccine.

[18]  S. Martin,et al.  Veterinary Epidemiologic Research , 2009 .

[19]  B. Kullberg,et al.  Q fever in the Netherlands: a concise overview and implications of the largest ongoing outbreak. , 2008, The Netherlands journal of medicine.

[20]  P. E. Kendall,et al.  Milking frequency affects the circadian body temperature rhythm in dairy cows , 2008 .

[21]  H. Seegers,et al.  Prevention of Coxiella burnetii shedding in infected dairy herds using a phase I C. burnetii inactivated vaccine. , 2008, Vaccine.

[22]  Y. Schukken,et al.  Association between Coxiella burnetii shedding in milk and subclinical mastitis in dairy cattle. , 2008, Veterinary research.

[23]  J. Elsener,et al.  Comparison of postvaccinal milk drop in dairy cattle vaccinated with one of two different commercial vaccines. , 2008, Veterinary therapeutics : research in applied veterinary medicine.

[24]  H. Seegers,et al.  Coxiella burnetii shedding by dairy cows. , 2007, Veterinary research.

[25]  P. E. Kendall,et al.  The effects of providing shade to lactating dairy cows in a temperate climate , 2006 .

[26]  T. Mader,et al.  Environmental factors influencing heat stress in feedlot cattle. , 2006, Journal of animal science.

[27]  Neil R Parker,et al.  Q fever. , 2006, Lancet.

[28]  P. Dufour,et al.  Effect of vaccination with phase I and phase II Coxiella burnetii vaccines in pregnant goats. , 2005, Vaccine.

[29]  A. Rodolakis,et al.  Is Q fever an emerging or re-emerging zoonosis? , 2005, Veterinary research.

[30]  B. Mullinix,et al.  Effects of hot, humid weather on milk temperature, dry matter intake, and milk yield of lactating dairy cows. , 2003, Journal of dairy science.

[31]  E. Maltz,et al.  Heat stress in lactating dairy cows: a review , 2002 .

[32]  M. Berri,et al.  Shedding of Coxiella burnetii in ewes in two pregnancies following an episode of Coxiella abortion in a sheep flock. , 2002, Veterinary microbiology.

[33]  G. Atkins,et al.  Effects of 2 commercially-available 9-way killed vaccines on milk production and rectal temperature in Holstein-Friesian dairy cows. , 2001, The Canadian veterinary journal = La revue veterinaire canadienne.

[34]  L. Petersen,et al.  Changing epidemiology of Q fever in Germany, 1947-1999. , 2001, Emerging infectious diseases.

[35]  D. Haines,et al.  Coxiella Burnetii Infection is Associated with Placentitis in Cases of Bovine Abortion , 2000, Journal of veterinary diagnostic investigation : official publication of the American Association of Veterinary Laboratory Diagnosticians, Inc.

[36]  G. Hahn Dynamic responses of cattle to thermal heat loads. , 1999, Journal of animal science.

[37]  B. Mallard,et al.  Effects of a core antigen vaccine against gram-negative bacteria on physiologic and yield parameters of dairy cows during late lactation and the dry period. , 1998, Journal of dairy science.

[38]  K. Frankena,et al.  Effect on milk production of vaccination with a bovine herpesvirus 1 gene-deleted vaccine , 1997, Veterinary Record.

[39]  K. Anderson,et al.  Effect of vaccination with an Escherichia coli bacterin-toxoid on milk production in dairy cattle. , 1996, Journal of the American Veterinary Medical Association.

[40]  Durand Mp [Lacteal and placental excretion of Coxiella burnetti, agent of Q fever, in the cow. Importance and prevention]. , 1993 .

[41]  M. Durand [Lacteal and placental excretion of Coxiella burnetti, agent of Q fever, in the cow. Importance and prevention]. , 1993, Bulletin de l'Academie nationale de medecine.

[42]  M. O. Igono,et al.  Environmental profile and critical temperature effects on milk production of Holstein cows in desert climate , 1992, International journal of biometeorology.

[43]  M. Shimizu,et al.  Physical dependence on meprobamate after repeated oral administration in rats. , 1983, Japanese journal of pharmacology.