Biological control of rodents using Sarcocystis singaporensis

Parasites have been identified as an important factor in regulating vertebrate populations. In replicated field experiments (plots up to 4 ha) performed in Thailand we tested whether commensal and field rodents could be artificially infected and controlled with the host-restricted apicomplexan protozoon Sarcocystis singaporensis which is endemic in Southeast Asia. When bait-pellets containing high numbers of these parasites were consumed by rodents of three species (Rattus norvegicus, Rattus tiomanicus, Bandicota indica) in different agricultural habitats (chicken farm, oil palm plantation, ricefield), we observed a parasite-induced mortality ranging from 58% to 92%. Detection of merozoites of S. singaporensis in lung tissue samples of rats collected dead at the experimental sites using a species-specific monoclonal antibody confirmed that S. singaporensis was the causative agent of mortality. As observed with brown rats, the parasite's effect on the host was not related to sex. These experiments demonstrate for the first time that artificial infection of rodents with an endemic protozoon has the potential for effective population control.     

Immunoglobulin subclass responses of wild brown rats to Sarcocystis singaporensis

Immunoglobulin subclass responses of wild brown rats (Rattus norvegicus) from southeastern Asia to the endemic cyst-forming coccidian Sarcocystis singaporensis were characterised. The antibody response of brown rats to wild-type parasites (high reproductive capacity) showed a Th1 profile during acute infection, namely elevated concentrations of parasite-specific IgG2b and IgG2c and absence of IgG1. Chronic infection (bradyzoite development) resulted in a mixed Th1/Th2 pattern whereby significant concentrations of IgG1 appeared. A primary infection with 1000 sporocysts eight days before challenge induced protection, accompanied by significant concentrations of IgA and IgG2, particularly IgG2a. Western blot analysis of rat sera, using sporozoite and bradyzoite-extracts as antigen, revealed that IgG1, IgG2a, and IgG2b predominantly recognised molecules between 70-80 kDa in one or the other stage. Some of the antibodies were possibly directed against a 79 kDa heat shock protein of sporozoites. An apparent unresponsiveness to molecules in the low molecular weight range, particularly of bradyzoite antigens, was observed. This was abrogated by infection of rats with an avirulent strain of S. singaporensis (low reproductive capacity) indicating that a parasite that was less adapted to its host provoked a stronger immune response. These results suggest the existence of an immune evasion strategy used by Sarcocystis and show that wild rodents may be suitable as immunological research objects, reflecting the natural situation.     

Reduction of transmission stages concomitant with increased host immune responses to hypervirulent Sarcocystis singaporensis, and natural selection for intermediate virulence.

Parasite virulence (pathogenicity depending on inoculum size) and host immune reactions were examined for the apicomplexan protozoan Sarcocystis singaporensis. This parasite is endemic in southeastern Asia and multiplies as a proliferation (merozoite) and transmission stage (bradyzoite) in rats. Virulence in wild brown rats of parasites freshly isolated in the wild (wild-type) was surprisingly constant within the endemic area and showed an intermediate level. In contrast, serially passaged parasites either became avirulent or virulence increased markedly (hypervirulence). Production of transmission stages was maximal for the wild-type whereas numbers were significantly reduced for hypervirulent and avirulent (shown in a previous study) parasites. Analyses of B and T cell immunity revealed that immune responses of WKY rats to the transmission stage were significantly higher for hypervirulent than for wild-type parasites. These results suggest that it is the immune system of the host that is not only responsible for reduction of transmission stages in individual rats, but also could act as a selective force that maintains intermediate virulence at the population level because reduction of muscle stages challenges transmission of S. singaporensis to the definitive host. Collectively, the presented data support evolutionary theory, which predicts intermediate rates of parasite growth in nature and an ‘arms race’ between host immunity and parasite proliferation.     

Reduction of transmission stages concomitant with increased host immune responses to hypervirulent Sarcocystis singaporensis, and natural selection for intermediate virulence

Parasite virulence (pathogenicity depending on inoculum size) and host immune reactions were examined for the apicomplexan protozoan Sarcocystis singaporensis. This parasite is endemic in southeastern Asia and multiplies as a proliferation (merozoite) and transmission stage (bradyzoite) in rats. Virulence in wild brown rats of parasites freshly isolated in the wild (wild-type) was surprisingly constant within the endemic area and showed an intermediate level. In contrast, serially passaged parasites either became avirulent or virulence increased markedly (hypervirulence). Production of transmission stages was maximal for the wild-type whereas numbers were significantly reduced for hypervirulent and avirulent (shown in a previous study) parasites. Analyses of B and T cell immunity revealed that immune responses of WKY rats to the transmission stage were significantly higher for hypervirulent than for wild-type parasites. These results suggest that it is the immune system of the host that is not only responsible for reduction of transmission stages in individual rats, but also could act as a selective force that maintains intermediate virulence at the population level because reduction of muscle stages challenges transmission of S. singaporensis to the definitive host. Collectively, the presented data support evolutionary theory, which predicts intermediate rates of parasite growth in nature and an ‘arms race’ between host immunity and parasite proliferation.