Polymorphism in the gene encoding the Pfs48/45 antigen of Plasmodium falciparum. XI. Asembo Bay Cohort Project.

We have investigated the genetic diversity of the gene encoding the transmission-blocking vaccine antigen Pfs48/45 of Plasmodium falciparum parasites from western Kenya and compared it with parasite populations from Thailand, India, and Venezuela. We report 44 complete new sequences. Overall, the antigen is less polymorphic as compared with other pre-erythrocytic and blood stage antigens. Contrary to other P. falciparum antigens, the number of synonymous substitutions per synonymous site exceeds the number of non-synonymous substitutions per non-synonymous site. We have found that the Pfs48/45 gene of Kenyan parasites is more polymorphic than parasites from other geographic origins. Our analysis reveals that positive natural selection is involved in the maintenance of the observed polymorphism. No evidence of intragenic recombination was found. F(st) values reveal high levels of gene flow between India and Thailand, however, there are strong constraints in gene flow among Kenyan, Southeast Asian, and Venezuelan parasites. No alleles could be linked to a specific geographic region. The results of this study suggest that this gametocyte antigen, like other asexual blood stage antigens, is under selection pressure.

A study of genetic diversity in the gene encoding the circumsporozoite protein (CSP) of Plasmodium falciparum from different transmission areas--XVI. Asembo Bay Cohort Project.

We have investigated the genetic diversity of the gene encoding the CS protein. A total of 75 complete and 96 partial sequences are studied. We find high levels of genetic polymorphisms as evidenced by 50 and 24 alleles at the Th2R and Th3R epitopes, respectively. Overall, we find that African isolates are more polymorphic as compared with parasites from other geographic regions. We conclude that the uneven geographic polymorphism may have an adverse impact on the effectiveness of vaccines based on this antigen alone. We find extensive polymorphism in the repeat allotypes, or RATs. In order to explore how the protein structure may impose restrictions in the number of repeats, we have simulated the stability of the structure of the tandem repeat region. Our analysis suggests that the protein structure may play an important role in the observed polymorphism in the number of CS repeats in Plasmodium falciparum. We explored the linkage and recombination events among the polymorphic sites. We found that putative recombination events overlap with linked sites. We discuss how this pattern is explained by the action of positive natural selection, where the recombination events detected are convergent mutations. We conclude that it is inappropriate to use linkage-recombination patterns on genes under positive selection for assessing the structure of parasite populations.