Evolutionary analyses of the major variant surface antigen-encoding genes reveal population structure of Plasmodium falciparum within and between continents.

Gerry Tonkin-Hill,Lastenia Ruiz-Mesía,Oralee H Branch,Michael F Duffy,Yao-Ban Chan,Virginie Rougeron,Karen P Day,Anthony T Papenfuss,Sedigheh Zakeri,Shazia Ruybal-Pesántez,Kathryn E Tiedje,Franck Prugnolle,Tepanata Pumpaibool,Thomas S Rask,Pongchai Harnyuttanakorn,Carmen Buchrieser

doi:10.1371/journal.pgen.1009269

Abstract

Malaria remains a major public health problem in many countries. Unlike influenza and HIV, where diversity in immunodominant surface antigens is understood geographically to inform disease surveillance, relatively little is known about the global population structure of PfEMP1, the major variant surface antigen of the malaria parasite Plasmodium falciparum. The complexity of the var multigene family that encodes PfEMP1 and that diversifies by recombination, has so far precluded its use in malaria surveillance. Recent studies have demonstrated that cost-effective deep sequencing of the region of var genes encoding the PfEMP1 DBLα domain and subsequent classification of within host sequences at 96% identity to define unique DBLα types, can reveal structure and strain dynamics within countries. However, to date there has not been a comprehensive comparison of these DBLα types between countries. By leveraging a bioinformatic approach (jumping hidden Markov model) designed specifically for the analysis of recombination within var genes and applying it to a dataset of DBLα types from 10 countries, we are able to describe population structure of DBLα types at the global scale. The sensitivity of the approach allows for the comparison of the global dataset to ape samples of Plasmodium Laverania species. Our analyses show that the evolution of the parasite population emerging out of Africa underlies current patterns of DBLα type diversity. Most importantly, we can distinguish geographic population structure within Africa between Gabon and Ghana in West Africa and Uganda in East Africa. Our evolutionary findings have translational implications in the context of globalization. Firstly, DBLα type diversity can provide a simple diagnostic framework for geographic surveillance of the rapidly evolving transmission dynamics of P. falciparum. It can also inform efforts to understand the presence or absence of global, regional and local population immunity to major surface antigen variants. Additionally, we identify a number of highly conserved DBLα types that are present globally that may be of biological significance and warrant further characterization.

Highlights

Plasmodium falciparum continues to present a significant economic and public health burden globally
We developed a computational approach to explore the evolution of specific DNA sequences of the major variant surface antigens (VSA) gene of the human malaria parasite, Plasmodium falciparum
We can identify malaria parasites from countries within Africa, South America, and Asia/Oceania using a diverse region of VSA genes without having to sequence and assemble whole parasite genomes

Summary

Introduction

Plasmodium falciparum continues to present a significant economic and public health burden globally. Part of the pathogen’s success in remaining endemic, while highly prevalent in many regions, can be attributed to the extreme diversity of the major variant surface antigen of the blood stages, known as P. falciparum erythrocyte membrane protein 1 (PfEMP1). This molecule is encoded by the var multigene family [3] and each parasite possesses approximately 60 var genes [4,5]. Genome sequencing has shown that each parasite carries a different var gene repertoire [6]. Analysis of the population structure of the var genes encoding PfEMP1 is important for the control and prevention of the disease as well as for the design of any vaccine targeting PfEMP1 based on an understanding of variant-specific immunity [7]

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Discussion

Conclusion