Biology of malarial liver stages: implications for vaccine design.

The molecular events controlling sporozoite invasion and exo-erythrocytic (EE) development within hepatocytes are largely not understood, and EE parasites are probably better defined immunologically than biologically. The observation that the Plasmodium falciparum sporozoite antigen TRAP (thrombospondin-related anonymous protein) contains multiple adhesive domains that recognize endothelial and hepatocyte receptors indicates that, like leucocyte passage across capillaries, sporozoite invasion probably involves a co-ordinated interaction between sporozoite and hepatic molecules. The parallel with leucocyte extravasation is strengthened by the finding that TRAP contains a functional, integrin-like, I domain. EE parasites are an important target of immunity elicited by irradiated sporozoites, and much current effort is focused on developing malaria vaccines targeting EE parasites. Only one EE-specific antigen, liver-stage antigen 1 (LSA-1), is known to be expressed during EE development and may contribute to protective immunity elicited by irradiated P. falciparum sporozoites. In a study in Papua New Guinea, resistance to P. falciparum infection correlated with CD8+ T-cell interferon-gamma responses to an LSA-1 epitope that contains an HLA A11-restricted sequence. Since A11 is > 40% frequent in this population it is reasonable to suggest that, as with B53 responses to LSA-1 in The Gambia, P. falciparum has driven genetic selection of certain HLA haplotypes, as proposed by Haldane nearly 50 years ago. LSA-1 is thus an important vaccine candidate, and is being expressed in bacterial and phage vectors.