RTS,S vaccination is associated with serologic evidence of decreased exposure to plasmodium falciparum liver- and blood-stage parasites

Abstract

The leading malaria vaccine candidate, RTS,S, targets the sporozoite and liver stages of the Plasmodium falciparum life cycle, yet it provides partial protection against disease associated with the subsequent blood stage of infection. Antibodies against the vaccine target, the circumsporo- zoite protein, have not shown sufficient correlation with risk of clinical malaria to serve as a surrogate for protec- tion. The mechanism by which a vaccine that targets the asymptomatic sporozoite and liver stages protects against disease caused by blood-stage parasites remains unclear. We hypothesized that vaccination with RTS,S protects from blood-stage disease by reducing the num- ber of parasites emerging from the liver, leading to pro- longed exposure to subclinical levels of blood-stage par- asites that go undetected and untreated, which in turn boosts pre-existing antibody-mediated blood-stage im- munity. To test this hypothesis, we compared antibody responses to 824 P. falciparum antigens by protein array in Mozambican children 6 months after receiving a full course of RTS,S (n ⴝ 291) versus comparator vaccine (n ⴝ 297) in a Phase IIb trial. Moreover, we used a nested case-control design to compare antibody responses of children who did or did not experience febrile malaria. Unexpectedly, we found that the breadth and magnitude of the antibody response to both liver and asexual bloodstage antigens was significantly lower in RTS,S vaccin- ees, with the exception of only four antigens, including the RTS,S circumsporozoite antigen. Contrary to our initial hypothesis, these findings suggest that RTS,S confers protection against clinical malaria by blocking sporozoite invasion of hepatocytes, thereby reducing exposure to the blood-stage parasites that cause disease. We also found that antibody profiles 6 months after vaccination did not distinguish protected and susceptible children during the subsequent 12-month follow-up period but were strongly associated with exposure. Together, these data provide insight into the mechanism by which RTS,S protects from malaria. Molecular & Cellular Proteomics 14: 10.1074/ mcp.M114.044677, 519–531, 2015