Abstract
The var gene family of Plasmodium falciparum encodes the immunodominant variant surface antigens PfEMP1. These highly polymorphic proteins are important virulence factors that mediate cytoadhesion to a variety of host tissues, causing sequestration of parasitized red blood cells in vital organs, including the brain or placenta. Acquisition of variant-specific antibodies correlates with protection against severe malarial infections; however, understanding the relationship between gene expression and infection outcome is complicated by the modular genetic architectures of var genes that encode varying numbers of antigenic domains with differential binding specificities. By analyzing the domain architectures of fully sequenced var gene repertoires we reveal a significant, non-random association between the number of domains comprising a var gene and their sequence conservation. As such, var genes can be grouped into those that are short and diverse and genes that are long and conserved, suggesting gene length as an important characteristic in the classification of var genes. We then use an evolutionary framework to demonstrate how the same evolutionary forces acting on the level of an individual gene may have also shaped the parasite's gene repertoire. The observed associations between sequence conservation, gene architecture and repertoire structure can thus be explained by a trade-off between optimizing within-host fitness and minimizing between-host immune selection pressure. Our results demonstrate how simple evolutionary mechanisms can explain var gene structuring on multiple levels and have important implications for understanding the multifaceted epidemiology of P. falciparum malaria.
Highlights
The malaria parasite Plasmodium falciparum continues to be a major public health problem globally [1,2,3]
Plasmodium falciparum, the most severe of the human malarias, contains within its genome a family of,60 var genes which play an important role in disease pathology and maintenance of chronic infections
A classic example of this shared structure is the preservation of one or two copies of var2csa, which encodes a PfEMP1 variant that mediates binding to placental Chondroitin Sulfate A [26,27] and has been found in every parasite genome studied to date
Summary
The malaria parasite Plasmodium falciparum continues to be a major public health problem globally [1,2,3]. PfEMP1 mediates adhesion to a variety of host receptors on the endothelium as well as to uninfected red blood cells, leading to the sequestration of parasitized cells in peripheral blood vessels and organs [7,8,9,10,11]. This prevents the parasite from being cleared by the spleen [12,13], it is associated with a range of severe disease pathologies [14,15,16]. The relationship between mechanisms of acquired immunity, disease outcomes, and the evolution and structure of these antigens are still poorly understood, despite the critical role these interactions play in shaping the epidemiology of malaria
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