Strain-specific duffy binding protein antibodies correlate with protection against infection with homologous compared to heterologous plasmodium vivax strains in Papua New Guinean children.

Individuals repeatedly infected with malaria acquire protection from infection and disease; immunity is thought to be primarily antibody-mediated and directed to blood-stage infection. Merozoite surface proteins involved in the invasion of host erythrocytes are likely targets of protective antibodies. We hypothesized that Papua New Guinean children (n = 206) who acquire high antibody levels to two Plasmodium vivax merozoite proteins, Duffy binding protein region II (PvDBPII) and the 19-kDa C-terminal region of P. vivax merozoite surface protein 1 (PvMSP1(19)), would have a delay in the time to reinfection following treatment to clear all blood-stage malaria infections. Ninety-four percent of the children were reinfected with P. vivax during biweekly follow-ups for 6 months. Since PvDBPII is polymorphic, we examined whether individuals acquired strain-specific immunity to PvDBPII. Children with high antibody levels to a prevalent PvDBPII allele (O) were associated with a delay in the time to reinfection with the same variant of P. vivax by 25% compared to parasites expressing other PvDBPII alleles (age-adjusted hazard ratio, 0.75 [95% confidence interval, 0.56 to 1.00 by Cox regression]) and 39% lower incidence density parasitemia (P = 0.01). Two other prevalent alleles (AH and P) showed a similar trend of 16% and 18% protection, respectively, against parasites with the same PvDBPII allele and reduced incidence density parasitemia. Antibodies directed to PvDBPII PNG-P and -O were both associated with a 21 to 26% reduction in the risk of P. vivax infections with higher levels of parasitemia (>150 parasites/mul), respectively. There was no association with high antibody levels to PvMSP1(19) and a delay in the time to P. vivax reinfection. Thus, anti-PvDBPII antibodies are associated with strain-specific immunity to P. vivax and support the use of PvDBPII for a vaccine against P. vivax.

High complexity of Plasmodium vivax infections in Papua New Guinean children.

Although genetically distinct malaria parasites have been shown to simultaneously infect an individual, the total number of unique parasites has not been systematically studied. We examined multiple clones (8-38) from individual blood samples collected from Papua New Guinean children for polymorphisms in the Plasmodium vivax Duffy binding protein (dbpII) and the merozoite surface protein 3alpha (msp3alpha). We found a median of 4 (range = 2-6) and 12 (range = 2-23) unique genotypes based on dbpII and msp3alpha, respectively, per person at one time point and at least 12-33 unique genotypes per person over a four-month period. Control polymerase chain reactions (PCRs) detected 0-31% of clones with haplotypes that arose from PCR artifacts, indicating that caution must be taken when using PCR-based analysis to examine complex infections. To reduce artifacts from clones, analysis was based on haplotypes unlikely to have been generated by PCR artifacts or had been previously identified. Plasmodium vivax infections can be highly complex in disease-endemic areas, suggesting continual genetic mixing that could have significant implications for the use of antimalarial drugs and malaria vaccines.