Gene conversion events between GYPB and GYPE abolish expression of the S and s blood group antigens.

BACKGROUND AND OBJECTIVE: The locus specifying the MNS blood group system is composed of three highly homologous genes, glycophorin A (GYPA), B (GYPB) and E (GYPE). While more than 20 hybrid genes between GYPA and GYPB have been identified, no hybrid genes between GYPB and GYPE have been reported so far. We serendipitously identified GYPB-E-B hybrid genes by studying three individuals whose rare S-s- blood phenotype failed to be predicted by our genotyping platform. MATERIALS AND METHODS: Long-range PCR amplification and extended Sanger sequencing were required to identify and characterize these GYPB-E-B hybrid genes. A PCR assay was developed to detect them in individual or pooled gDNA samples. RESULTS: The first S-s- proband appeared to have two silenced GYPB alleles, one harbouring the so-called P2 mutation and one harbouring GYPE Pseudoexon E4 in place of GYPB Exon B4 (GYPB-E-B hybrid). The two other S-s- probands were homozygous or hemizygous for other GYPB-E-B hybrid alleles, which also lack GYPB Exon B4 and thus do not carry the S/s polymorphism. CONCLUSION: The three GYPB-E-B hybrid genes reported here constitute the first evidence of recombination events between GYPB and GYPE. As these GYPB-E-B hybrid genes drive the S-s- blood phenotype, it is important to know they are a limitation for the current blood group genotyping methods, including those performed by commercial platforms.

Mapping of Char10, a novel malaria susceptibility locus on mouse chromosome 9.

Resistance to blood-stage malaria in AcB55 and AcB61 is caused by a loss of function mutation in pyruvate kinase (Pklr(I90N)). Likewise, pyruvate kinase (PK) deficiency in humans is protective against Plasmodium replication in vitro. We identified a third AcB strain, AcB62 that also carries the Pklr(I90N) mutation. However, AcB62 mice were susceptible to P.chabaudi infection and showed high levels of parasite replication (54-62% peak parasitemia). AcB62 mice showed the hallmarks of PK deficiency-associated anemia similar to AcB55/61 with reticulocytosis, splenic red pulp expansion, tissue iron overload, and increased expression of iron metabolism proteins. This suggests that malaria susceptibility in AcB62 is not because of absence of PK deficiency-associated pathophysiology. To map novel genetic factors affecting malaria susceptibility in AcB62, we generated an informative F2 population using AcB62 (Pklr(I90N)) and CBA-Pk(slc) (Pklr(G338D)) as progenitors and identified a novel locus on chromosome 9 (Char10; LOD=7.24) that controls peak parasitemia. A weaker linkage to the Pklr region of chromosome 3 (LOD=3.7) was also detected, a finding that may reflect the segregation of the two defective Pklr alleles. AcB62 alleles at both loci are associated with higher peak parasitemia. These results identify Char10 as a novel locus modulating severity of malaria in the context of PK deficiency.