Molecular heterogeneity of the Jk(null) phenotype: expression analysis of the Jk(S291P) mutation found in Finns.

Polymerase chain reaction genotyping of 32 unrelated Jk(null) individuals originating predominantly from Polynesia and Finland indicated that all were homozygous for the JK*B polymorphism and that 17 of 32, including the 14 Polynesians, carried a 3'-acceptor splice site mutation of intron 5 that resulted in the skipping of exon 6 (called mutation Jk delta 6). The remaining 15 Jk(null) donors from Finland were homozygous for a new T871C transition resulting in a S291P amino acid substitution at a consensus N-glycosylation site of the Jk polypeptide. Transcription-translation assays revealed that the Jk(S291P) mutant was translated into a glycosylated component as efficiently as the wild-type Jk polypeptide (wt Jk)] in the presence of microsomes, thus indicating that the S291P mutation has no effect on the N-glycosylation pattern of the Jk protein. Expression studies in Xenopus oocytes revealed that the Jk(S291P) polypeptide functions as a urea transporter, but the transport activity and the membrane expression level of the mutant protein was reduced to a similar extent. A substantial fraction of the mutant protein was retained intracellularly suggesting that the transit to the plasma membrane was reduced, presumably because of the S-->P mutation. After transfection in erythroleukemia K562 cells the wild-type, but not the mutant, protein was efficiently expressed at the cell surface. Because the Jk(S291P) mutant polypeptide was not present in human red cells from Jk(null) individuals, expression data in the erythroid context clearly indicates that the S-->P mutation is the molecular basis of the Finnish Jk(null) phenotype. (Blood. 2000;96:1566-1573)

At physiological expression levels the Kidd blood group/urea transporter protein is not a water channel.

The Kidd (JK) blood group locus encodes a urea transporter that is expressed on human red cells and on endothelial cells of the vasa recta in the kidney. Here, we report the identification in human erythroblasts of a novel cDNA, designated HUT11A, which encodes a protein identical to the previously reported erythroid HUT11 urea transporter, except for a Lys(44) --> Glu substitution and a Val-Gly dipeptide deletion after proline 227, which leads to a polypeptide of 389 residues versus 391 in HUT11. Genomic typing by polymerase chain reaction and transcript analysis by ribonuclease protection assay demonstrated that HUT11A encodes the true Kidd blood group/urea transporter protein, which carries only 2 Val-Gly motifs. Upon expression at high levels in Xenopus oocytes, the physiological Kidd/urea transporter HUT11A conferred a rapid transfer of urea (which was insensitive to p-chloromercuribenzene sulfonate or phloretin), a high water permeability, and a selective uptake of small solutes including amides and diols, but not glycerol and meso-erythritol. However, at plasma membrane expression levels close to the level observed in the red cell membrane, HUT11A-mediated water transport and small solutes uptake were absent and the urea transport was poorly inhibited by p-chloromercuribenzene sulfonate, but strongly inhibited by phloretin. These findings show that, at physiological expression levels, the HUT11A transporter confers urea permeability but not water permeability, and that the observed water permeability is a feature of the red cell urea transporter when expressed at unphysiological high levels.