In the 1960s, it was demonstrated that X-irradiated sporozoites confer protective immunity in mice [3]; and the cloning of the gene encoding CSP from the monkey malaria parasite P. knowlesi [4] led to hopes that the homologous protein might form the basis of a vaccine against human malaria parasites. The pace of clinical trials of vaccines based on CSP and other malaria surface Libraries proteins from the two most see more widespread human malaria parasites, P. falciparum and P. vivax, has increased dramatically in the past decade, but so far the results have been mixed [2]. One of the major challenges

facing vaccine developers is the high level of naturally occurring polymorphism at several of the loci encoding surface proteins of P.

falciparum and P. vivax [5]. In the case of the CSP of P. falciparum, polymorphic variants in epitopes for host CD4+ T cell recognition have been shown not to be cross-reactive [6], implying that vaccines which rely on the use of these epitopes selleck compound to stimulate an immune response will fail to provide protection against all naturally occurring parasite variants [5]. At the CSP locus of P. falciparum, there is evidence that the polymorphism in T-cell epitopes is maintained by balancing selection driven by host T cell recognition [7], [8], [9] and [10]. Adenylyl cyclase Likewise, several other loci encoding malaria cell surface proteins show evidence of selectively maintained polymorphism [8], [11], [12] and [13]. Even under balancing selection, because of the role of genetic drift, the level of polymorphism that can be maintained is expected to be a function of the effective population size [14] and [15]. Consistent with theoretical expectations, there is evidence that population bottlenecks can effect the level of polymorphism at antigen-encoding loci of malaria parasites. For example, the

locus encoding apical membrane antigen-1 (AMA-1) of P. vivax shows considerably reduced polymorphism in Brazil in comparison to the Old World, reflecting a bottleneck in colonization of the New World [10] and [16]. Likewise, studies of P. falciparum populations on Pacific islands have revealed relatively low levels of polymorphism at several antigen loci, as expected in the case of founder effects in the colonization of islands by the parasite [17] and [18]. On the other hand, local populations in Old World mainland areas where malaria has long been present, such as Southeast Asia, have revealed substantial levels of polymorphism at antigen-encoding loci [9], [10], [12] and [19]. Given these high levels of polymorphism, the design of a locality-specific vaccine that provides immunity against all locally occurring variants seems problematic.