Lack of Association of CD55 Receptor Genetic Variants and Severe Malaria in Ghanaian Children.

In a recent report, the cellular receptor CD55 was identified as a molecule essential for the invasion of human erythrocytes by Plasmodium falciparum, the causal agent of the most severe form of malaria. As this invasion process represents a critical step during infection with the parasite, it was hypothesized that genetic variants in the gene could affect severe malaria (SM) susceptibility. We performed high-resolution variant discovery of rare and common genetic variants in the human CD55 gene. Association testing of these variants in over 1700 SM cases and unaffected control individuals from the malaria-endemic Ashanti Region in Ghana, West Africa, were performed on the basis of single variants, combined rare variant analyses, and reconstructed haplotypes. A total of 26 genetic variants were detected in coding and regulatory regions of CD55 Five variants were previously unknown. None of the single variants, rare variants, or haplotypes showed evidence for association with SM or P. falciparum density. Here, we present the first comprehensive analysis of variation in the CD55 gene in the context of SM and show that genetic variants present in a Ghanaian study group appear not to influence susceptibility to the disease.

Endothelial protein C receptor gene variants not associated with severe malaria in ghanaian children.

BACKGROUND: Two recent reports have identified the Endothelial Protein C Receptor (EPCR) as a key molecule implicated in severe malaria pathology. First, it was shown that EPCR in the human microvasculature mediates sequestration of Plasmodium falciparum-infected erythrocytes. Second, microvascular thrombosis, one of the major processes causing cerebral malaria, was linked to a reduction in EPCR expression in cerebral endothelial layers. It was speculated that genetic variation affecting EPCR functionality could influence susceptibility to severe malaria phenotypes, rendering PROCR, the gene encoding EPCR, a promising candidate for an association study. METHODS: Here, we performed an association study including high-resolution variant discovery of rare and frequent genetic variants in the PROCR gene. The study group, which previously has proven to be a valuable tool for studying the genetics of malaria, comprised 1,905 severe malaria cases aged 1-156 months and 1,866 apparently healthy children aged 2-161 months from the Ashanti Region in Ghana, West Africa, where malaria is highly endemic. Association of genetic variation with severe malaria phenotypes was examined on the basis of single variants, reconstructed haplotypes, and rare variant analyses. RESULTS: A total of 41 genetic variants were detected in regulatory and coding regions of PROCR, 17 of which were previously unknown genetic variants. In association tests, none of the single variants, haplotypes or rare variants showed evidence for an association with severe malaria, cerebral malaria, or severe malaria anemia. CONCLUSION: Here we present the first analysis of genetic variation in the PROCR gene in the context of severe malaria in African subjects and show that genetic variation in the PROCR gene in our study population does not influence susceptibility to major severe malaria phenotypes.

Familial Mediterranean fever with amyloidosis associated with novel exon 2 mutation (S1791) of the MEFV gene.

Familial Mediterranean fever (FMF) is an autosomal recessive disorder characterized by recurrent attacks of fever, serositis, and a risk for AA amyloidosis. FMF is caused by mutations in the Mediterranean fever gene (MEFV), which is expressed in blood cells of the myelomonocytic differentiation pathway. We identified a novel mutation S1791 in exon 2 of MEFV in two members of a family of Turkish origin. In both cases, S1791 was in compound heterozygosity with MEFV mutation M694V, and the characteristic clinical syndrome of FMF including amyloidosis was found. The location of S1791 in exon 2 is of interest because (1) amyloidosis in FMF has previously been found to be strongly associated with compound exon 10 mutations and (2) it supports the notion that the mechanism causing FMF is connected to the cytoplasmic rather than nuclear function of the molecule.