Background Malaria vaccine efficacy may be compromised if the frequency of non-target alleles increases following vaccination with a genetically polymorphic target. Methods are needed to monitor genetic diversity in polymorphic vaccine antigens, but determining which genetic variants of such antigens are present in infected individuals is complicated by the frequent occurrence of mixed infections. Methods Pyrosequencing was used to determine allele frequencies at each of six single nucleotide polymorphisms in the Plasmodium falciparum blood-stage vaccine antigen merozoite surface protein 1 19 kDa (MSP-1 19 ) in field samples from a vaccine-testing site in Mali. Mixtures of MSP-1 19 clones were created to validate a haplotype-estimating algorithm that uses maximum likelihood methods to determine the most probable combination of haplotypes given the allele frequencies for an infection and the haplotypes known to be circulating in the population. Results Fourteen unique MSP-1 19 haplotypes were identified among 351 genotyped infections. After adjustment to a standard curve, Pyrosequencing provided accurate and precise estimates of allele frequencies in mixed infections. The haplotype-estimating algorithm provided accurate estimates of haplotypes in mixed infections containing up to three haplotypes. Based on the MSP-1 19 locus, approximately 90% of the 351 infections contained two or fewer haplotypes. Conclusion Pyrosequencing in conjunction with a haplotype-estimating algorithm provides accurate estimates of haplotypes present in infections with up to 3 haplotypes, and can be used to monitor genetic diversity in parasite populations prior to and following introduction of MSP-1-based malaria vaccines.
A high-throughput method for quantifying alleles and haplotypes of the malaria vaccine candidate Plasmodium falciparum merozoite surface protein-1 19 kDa
말라리아 백신 후보인 플라스모디움 팔시파룸 메로조이트 표면 단백질-1 19 kDa의 대량 처리 방법을 통한 대립유전자 및 해플로타입 정량화
[Category] 말라리아,
[Article Type] Methodology
[Source] PMC
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