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References (14)
-
R. Davey (1981)
Effects of Babesia bovis on the Ovipositional Success of the Southern Cattle Tick, Boophilus microplusAnnals of The Entomological Society of America, 74
-
M. Levy, M. Ristic (1980)
Babesia bovis: continuous cultivation in a microaerophilous stationary phase culture.Science, 207 4436
-
S. Deem, A. Noss, R. Villarroel, M. Uhart, W. Karesh (2004)
Disease Survey of Free-ranging Grey Brocket Deer (Mazama gouazoubira) in the Gran Chaco, Bolivia, 40
-
Vega Ca, G. Buening, T. Green, C. Carson (1985)
In vitro cultivation of Babesia bigemina.American journal of veterinary research, 46 2
-
D. Mahoney, G. Mirre (1977)
The selection of larvae of Boophilus microplus infected with Babesia bovis (syn B argentina).Research in veterinary science, 23 1
-
J. Figueroa, L. Chieves, G. Johnson, G. Buening (1993)
Multiplex polymerase chain reaction based assay for the detection of Babesia bigemina, Babesia bovis and Anaplasma marginale DNA in bovine blood.Veterinary parasitology, 50 1-2
-
D. Duh, M. Petrovec, A. Bidovec, T. Avšič-Županc (2005)
Cervids as Babesiae Hosts, SloveniaEmerging Infectious Diseases, 11
-
T. Oliveira-Sequeira, M. Oliveira, J. Araújo, A. Amarante (2005)
PCR-based detection of Babesia bovis and Babesia bigemina in their natural host Boophilus microplus and cattle.International journal for parasitology, 35 1
-
A. Kjemtrup, P. Conrad (2000)
Human babesiosis: an emerging tick-borne disease.International journal for parasitology, 30 12-13
-
L. Hamilton (1990)
Statistics with Stata -
N. Barré, M. Bianchi, L. Chardonnet (2004)
Role of Rusa deer Cervus timorensis russa in the cycle of the cattle tick Boophilus microplus in New CaledoniaExperimental & Applied Acarology, 25
-
A. Cantú, J. Ortega-S., J. Mosqueda, Z. García-Vázquez, S. Henke, J. George, Caesar Kleberg (2007)
Immunologic and Molecular Identification of Babesia bovis and Babesia bigemina in Free-Ranging White-Tailed Deer in Northern Mexico, 43
-
F. Amerasinghe, N. Breisch, A. Azad, W. Gimpel, M. Greco, K. Neidhardt, B. Pagac, J. Piesman, J. Sandt, T. Scott (1992)
Distribution, density, and Lyme disease spirochete infection in Ixodes dammini (Acari: Ixodidae) on white-tailed deer in Maryland.Journal of medical entomology, 29 1
-
P. Holman, K. Waldrup, R. Droleskey, D. Corrier, G. Wagner (1993)
In vitro growth of Babesia bovis in white-tailed deer (Odocoileus virginianus) erythrocytes.The Journal of parasitology, 79 2
- Publisher
- Allen Press
- Copyright
- American Society of Parasitologists
- Subject
- Ectoparasitology
- ISSN
- 0022-3395
- eISSN
- 1937-2345
- DOI
- 10.1645/GE-1648.1
- pmid
- 19642800
- Publisher site
- See Article on Publisher Site
Abstract
Species of Rhipicephalus ( Boophilus ) ticks are the vectors of babesiosis (cattle fever tick), which are distributed worldwide. White-tailed deer ( Odocoileus virginianus ) are important secondary hosts for the cattle fever ticks, Rhipicephalus ( B .) annulatus and Rhipicephalus ( B .) microplus . White-tailed deer are capable of sustaining Boophilus spp. tick populations in the presence or absence of cattle. The objectives of this study were to determine the frequency of Babesia bovis and Babesia bigemina and the prevalence of antibodies to them and identify possible risk factors for bovine babesiosis in white-tailed deer in 3 northeastern states of México. Whole blood and serum samples (n = 457) were collected from white-tailed deer in the states of Coahuila, Nuevo Leon, and Tamaulipas during the spring of 2004. Samples were tested for B. bovis and B. bigemina by nested polymerase chain reaction (n-PCR) (the primers for B. bovis identified the gene Rap-1 and B. bigemina were specific primers) and by an indirect immunofluorescence antibody test (IFAT). A questionnaire was given to each ranch to obtain information about management practices. Logistic regression methods were used to test the association between management factors and the dependent variable of positive n-PCR or IFAT. Nineteen (4.2%) samples were positive to B. bigemina and 6 (1.7%) were positive to B. bovis by n-PCR. Serological testing showed 59.9% (n = 274) of deer sampled were positive to B. bovis and 5.4% (n = 25) were positive to B. bigemina antibodies. The logistic model varied with different dependent variables. With positive n-PCR and B. bigemina as the dependent variable, 3 factors were associated: habitat (presence of brush and exotic grasses; odds ratio (OR), 3.3; 95% confidence interval (CI), 1.3–8.5), grazing system (continuous grazing OR 4.0; CI, 1.3–12.2), and tick treatment frequency (3–4 mo; OR 7.0, CI 1.4–34.3; 5–6 mo; OR, 11.0; CI, 1.9–62.7; >6 mo; OR, 4.6; CI, 0.9–23.3). These findings suggest that white-tailed deer may act as a reservoir for the 2 bovine Babesia spp. and that white-tailed deer may be important in the epidemiology of babesiosis. However, evidence is not available to support whether white-tailed deer are, or are not, likely to be a host that could complete the transmission cycle of Babesia spp. These results suggest that additional research is needed to demonstrate the importance of white-tailed deer as a Babesia spp. infection source for ticks.
Journal
Journal of Parasitology – Allen Press
Published: Jun 1, 2009