Effect of diminazene block treatment on live redwater vaccine reactions

Co-transmission of the non-transmissible South African Babesia bovis S24 vaccine strain during mixed infection with a field isolate

The South African Babesia bovis live blood vaccine, originating from a field isolate attenuated by 23 serial syringe passages in splenectomized calves, has lost the ability to infect the natural vector Rhipicephalus (Boophilus) microplus. In this study, infection with mixed parasites from the vaccine strain and a field isolate, resulted in transmission of both genotype populations. Comparing the field isolate and transmitted combination indicated no significant difference in their virulence, while challenge of vaccinated cattle with these isolates showed the ability of the vaccine to protect against both. Limiting dilution of the transmitted combination, followed by infection of splenectomized cattle (n=34) yielded no single infections for the vaccine strain genotype, seven clonal lines of the field isolate and one mixture of vaccine strain and field isolate. Only one of two field isolate clonal lines selected for vector transmission study was transmitted. Showing that B. bovis isolates can contain both tick transmissible and non-transmissible subpopulations. The findings of this study also indicate the probability of vaccine co-infection transmission occurring in the field, which may result in new genotype populations of B. bovis. However, the impact of this recombination with field isolates is considered negligible since a genotypically diverse population of B. bovis is already present in South Africa.

Serological responses to Babesia bovis vaccination in cattle previously infected with Babesia bigemina

Serological responses of field cattle (260) on a farm in KwaZulu-Natal, South Africa were determined before and after vaccination with the commercial Babesia bovis live-blood vaccine, using the indirect fluorescent antibody test (IFAT). All the cattle tested negative for B. bovis antibodies before vaccination while 83% of them had significant antibody titres (>or=1/80) to Babesia bigemina, indicating a high degree of natural exposure to the latter parasite. By Day 60 post-vaccination only 53% of the cattle had seroconverted to B. bovis. This raised the question as to why only half of the vaccinated cattle had seroconverted. The possibility of previous exposure to B. bigemina infection interfering with the development of detectable antibodies to B. bovis was therefore investigated under controlled conditions. It was found that simultaneous vaccination with B. bigemina and B. bovis (n=6), and B. bigemina vaccination followed by B. bovis vaccination (n=12), had no effect on the animals' immune responses to B. bovis vaccination. All of these cattle developed a significant antibody response. However, only 58% of cattle (n=12) which had previously been inoculated with the B. bigemina field isolate, obtained from the trial farm, seroconverted (>or=1/80) after B. bovis vaccination, yet parasites for B. bovis could be demonstrated microscopically in all of the animals in this group. These findings confirmed the serology results from the field trial. When challenged with a B. bovis field isolate, cattle in this group did not show clinical reactions compared with an unvaccinated control group. The judicious use of IFAT to establish vaccination success obtained with the current South African B. bovis vaccine is indicated.

Live vaccines against bovine babesiosis

Bovine babesiosis is an important tick-borne disease caused by Babesia bovis, B. bigemina and B. divergens. The first steps taken in the development of an effective vaccination strategy against bovine babesiosis followed the observations that animals, recovered from natural infection with Babesia were strongly protected against subsequent challenge. Further investigation indicated that the use of donor blood from recovered animals to infect recipient animals did not produce the severe form of the disease. The past century has seen a refinement of this original carrier-donor system to one using attenuated less virulent strains with standardized doses of known parasite concentration to ensure reliability. With the implementation of good manufacturing practices further changes were necessary in the production of these vaccines, such as freezing for long-term storage to allow sufficient time for pre-release safety and effectivity testing. Regardless of these improvements the vaccines are not without problems and breakdowns and breakthroughs occur from time to time. Despite considerable research efforts into the development of alternative more consumer friendly vaccines, none is immediately forthcoming and the live attenuated babesiosis vaccines are still used in many countries.