Abstract
BackgroundAvian malaria (Plasmodium sp.) is globally widespread, but considerable variation exists in infection (presence/absence) patterns at small spatial scales. This variation can be driven by variation in ecology, demography, and phenotypic characters, in particular those that influence the host’s resistance. Generation of reactive oxygen species (ROS) is one of the host’s initial immune responses to combat parasitic invasion. However, long-term ROS exposure can harm the host and the redox response therefore needs to be adjusted according to infection stage and host phenotype. Here we use experimental and correlational approaches to assess the relative importance of host density, habitat composition, individual level variation and redox physiology for Plasmodium infection in a wild population of great tits, Parus major.ResultsWe found that 36% of the great tit population was infected with Plasmodium (22% P. relictum and 15% P. circumflexum prevalence) and that patterns of infection were Plasmodium species-specific. First, the infection of P. circumflexum was significantly higher in areas with experimental increased host density, whereas variation in P. relictum infection was mainly attributed to age, sex and reproduction. Second, great tit antioxidant responses – total and oxidizied glutathione - showed age- , sex- and Plasmodium species-specific patterns between infected and uninfected individuals, but reactive oxygen metabolites (ROM) showed only a weak explanatory power for patterns of P. relictum infection. Instead ROM significantly increased with Plasmodium parasitaemia.ConclusionsThese results identify some key factors that influence Plasmodium infection in wild birds, and provide a potential explanation for the underlying physiological basis of recently documented negative effects of chronic avian malaria on survival and reproductive success.
Highlights
Avian malaria (Plasmodium sp.) is globally widespread, but considerable variation exists in infection patterns at small spatial scales
Avian malaria (Plasmodium sp) is a globally widespread disease but considerable variation exists in both prevalence and parasitaemia at small spatial scales [1,2]
For example on the Hawaiian Islands there was an accidental introduction of Plasmodium relictum and one of its vectors which caused direct die-offs during the acute infection state which continues to play a significant role in species distribution and is a serious threat for endangered species [19,20,21,22]
Summary
Avian malaria (Plasmodium sp.) is globally widespread, but considerable variation exists in infection (presence/absence) patterns at small spatial scales This variation can be driven by variation in ecology, demography, and phenotypic characters, in particular those that influence the host’s resistance. Avian malaria (Plasmodium sp) is a globally widespread disease but considerable variation exists in both prevalence and parasitaemia at small spatial scales [1,2] This variation can be generated by several ecological, demographical and immunological mechanisms, including variation in vector and host densities and host susceptibility. Recent long-term and experimental studies have shown that there are effects on both survival and reproductive success [15,16,17,18] On naïve hosts such as island species and captive birds in zoo the impacts have been devastating [19]. For example on the Hawaiian Islands there was an accidental introduction of Plasmodium relictum and one of its vectors which caused direct die-offs during the acute infection state which continues to play a significant role in species distribution and is a serious threat for endangered species [19,20,21,22]
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