Identification of a conserved var gene in different Plasmodium falciparum strains.

BACKGROUND: The multicopy var gene family of Plasmodium falciparum is of crucial importance for pathogenesis and antigenic variation. So far only var2csa, the var gene responsible for placental malaria, was found to be highly conserved among all P. falciparum strains. Here, a new conserved 3D7 var gene (PF3D7_0617400) is identified in several field isolates. METHODS: DNA sequencing, transcriptional analysis, Cluster of Differentiation (CD) 36-receptor binding, indirect immunofluorescence with PF3D7_0617400-antibodies and quantification of surface reactivity against semi-immune sera were used to characterize an NF54 clone and a Gabonese field isolate clone (MOA C3) transcribing the gene. A population of 714 whole genome sequenced parasites was analysed to characterize the conservation of the locus in African and Asian isolates. The genetic diversity of two var2csa fragments was compared with the genetic diversity of 57 microsatellites fragments in field isolates. RESULTS: PFGA01_060022400 was identified in a Gabonese parasite isolate (MOA) from a chronic infection and found to be 99% identical with PF3D7_0617400 of the 3D7 genome strain. Transcriptional analysis and immunofluorescence showed expression of the gene in an NF54 and a MOA clone but CD36 binding assays and surface reactivity to semi-immune sera differed markedly in the two clones. Long-read Pacific bioscience whole genome sequencing showed that PFGA01_060022400 is located in the internal cluster of chromosome 6. The full length PFGA01_060022400 was detected in 36 of 714 P. falciparum isolates and 500 bp fragments were identified in more than 100 isolates. var2csa was in parts highly conserved (He = 0) but in other parts as variable (He = 0.86) as the 57 microsatellites markers (He = 0.8). CONCLUSIONS: Individual var gene sequences exhibit conservation in the global parasite population suggesting that purifying selection may limit overall genetic diversity of some var genes. Notably, field and laboratory isolates expressing the same var gene exhibit markedly different phenotypes.

In Vitro Variant Surface Antigen Expression in Plasmodium falciparum Parasites from a Semi-Immune Individual Is Not Correlated with Var Gene Transcription.

Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1) is considered to be the main variant surface antigen (VSA) of Plasmodium falciparum and is mainly localized on electron-dense knobs in the membrane of the infected erythrocyte. Switches in PfEMP1 expression provide the basis for antigenic variation and are thought to be critical for parasite persistence during chronic infections. Recently, strain transcending anti-PfEMP1 immunity has been shown to develop early in life, challenging the role of PfEMP1 in antigenic variation during chronic infections. In this work we investigate how P. falciparum achieves persistence during a chronic asymptomatic infection. The infected individual (MOA) was parasitemic for 42 days and multilocus var gene genotyping showed persistence of the same parasite population throughout the infection. Parasites from the beginning of the infection were adapted to tissue culture and cloned by limiting dilution. Flow cytometry using convalescent serum detected a variable surface recognition signal on isogenic clonal parasites. Quantitative real-time PCR with a field isolate specific var gene primer set showed that the surface recognition signal was not correlated with transcription of individual var genes. Strain transcending anti-PfEMP1 immunity of the convalescent serum was demonstrated with CD36 selected and PfEMP1 knock-down NF54 clones. In contrast, knock-down of PfEMP1 did not have an effect on the antibody recognition signal in MOA clones. Trypsinisation of the membrane surface proteins abolished the surface recognition signal and immune electron microscopy revealed that antibodies from the convalescent serum bound to membrane areas without knobs and with knobs. Together the data indicate that PfEMP1 is not the main variable surface antigen during a chronic infection and suggest a role for trypsin sensitive non-PfEMP1 VSAs for parasite persistence in chronic infections.

Var Gene promoter activation in clonal Plasmodium falciparum isolates follows a hierarchy and suggests a conserved switching program that is independent of genetic background.

Antigenic variation of Plasmodium falciparum is mediated by a mutually exclusive expression mechanism that limits expression to an individual member of the multicopy var gene family. This process determines the antigenic and adhesive phenotype of the infected red blood cell. Previously, we showed that var gene switching is influenced by chromosomal position. Here, we address whether var gene transcription follows a general conserved pattern in long-term laboratory parasites and in recently culture-adapted field parasites. Activation of the var gene family was monitored in biological replicates in each parasite isolate every 3-5 generations for up to 3 months. We used transgenic parasites carrying a drug-selectable marker at a defined var locus to characterize var gene activation after the exclusive expression of the transgene. Transgenic parasites exhibited a repeatable hierarchy of var gene activation and a fluctuating transcriptional activity of the transgenic var locus. Transcriptional profiling of wild-type laboratory and field parasites showed a universal bias toward transcription of UpsC var genes and a fluctuating transcriptional activity of the dominant var promoter. The data suggest the existence of an intrinsic var gene transcription program that is independent of genetic background.

Antigenic variation in Plasmodium falciparum: moving beyond the laboratory strains.

Antigenic variation in Plasmodium falciparum malaria is mediated by the multicopy var gene gene family. Each parasite carries approximately 60 different var genes. A system of mutually exclusive expression ensures that only one gene is expressed in each individual cell. This ensures that only 1 of the 60 variants is exposed to the immune system. Switches in var gene expression result in antigenic variation. During recent years there has been a remarkable progress in the understanding of the mechanisms that regulate var gene expression. Genetic elements such as the var gene intron, chromatin modifications and nuclear repositioning have all been implicated in the control of this large and diverse gene family. It has also been shown that var gene expression in clonal cultures is relatively stable over long periods of time, suggesting that an imprinted epigenetic program coordinates the expression of the gene family. Most of the recent advances in var gene biology have been generated through experiments with laboratory adapted parasite lines. This raises 2 central questions: 1. Does var gene expression in laboratory isolates resemble var gene expression in field isolates? 2. How does the immune system influence var gene expression in natural infections? To start to address these questions, we embarked on a series of experiments studying var gene expression in parasites recently obtained from asymptomatically infected adults from Lambaréné, Gabon.