Molecular Defects Underlying the Kell Null Phenotype

Soohee Lee,David C.W Russo,Alexander P Reiner,Jeffrey H Lee,Michael Y Sy,Marilyn J Telen,W John Judd,Philippe Simon,Maria J Rodrigues,Teresa Chabert,Joyce Poole,Snezana Jovanovic-Srzentic,Cyril Levene,Vered Yahalom,Colvin M Redman

doi:10.1074/jbc.m103433200

Abstract

Expression of the Kell blood group system is dependent on two proteins, Kell and XK, that are linked by a single disulfide bond. Kell, a type II membrane glycoprotein, is a zinc endopeptidase, while XK, which has 10 transmembrane domains, is a putative membrane transporter. A rare phenotype termed Kell null (Ko) is characterized by the absence of Kell protein and Kell antigens from the red cell membrane and diminished amounts of XK protein. We determined the molecular basis of eight unrelated persons with Ko phenotypes by sequencing the coding and the intron-exon splice regions of KEL and, in some cases, analysis of mRNA transcripts and expression of mutants on the cell surface of transfected cells. Six subjects were homozygous: four with premature stop codons, one with a 5' splice site mutation, G to A, in intron 3, and one with an amino acid substitution (S676N) in exon 18. Two Ko persons with premature stop codons had identical mutations in exon 4 (R128Stop), another had a different mutation in exon 4 (C83Stop), and the fourth had a stop codon in exon 9 (Q348Stop). Two Ko persons were heterozygous for two mutations. One had a 5' splice site mutation (G to A) in intron 3 of one allele that caused aberrant splicing and exon skipping, and the other allele had an amino acid substitution in exon 10 (S363N). The other heterozygote had the same amino acid substitution in exon 10 (S363N) in one allele and a premature stop codon in exon 6 (R192Stop) in the other allele. The S363N and S676N mutants, expressed in 293T cells, were retained in a pre-Golgi compartment and were not transported to the cell surface, indicating that these mutations inhibit trafficking. We conclude that several different molecular defects cause the Kell null phenotype.

Highlights

Two distinct proteins, Kell and XK, linked by a single disulfide bond, are responsible for expressing the Kell blood group antigens
We have identified three different types of point mutations in eight unrelated persons with the Ko phenotype
The most common mutation, causing the Ko phenotype, introduced premature stop codons that are located in exons 4, 6, and 9, downstream from exon 3, which encodes the single transmembrane domain present in Kell, a type II membrane glycoprotein [41, 42]

Summary

The abbreviations used are

Kell null; ECE, endothelin-converting enzyme; PCR, polymerase chain reaction; PAGE, polyacrylamide gel electrophoresis; PBS, phosphate-buffered saline; RFLP, restriction fragment length polymorphism; ER, endoplasmic reticulum; bp, base pair(s); CMV, cytomegalovirus; nt, nucleotide. The endothelins play many different physiological roles. They function in the regulation of blood pressure by affecting contraction and proliferation of vascular smooth muscle, and they have vasodilator effects via endothelin-mediated release of nitric oxide. We report on eight unrelated Ko persons among whom we have identified several different molecular defects within the gene encoding Kell protein (KEL). These newly identified KEL mutations lead to alternative RNA splicing, premature stop codons, or amino acid substitutions that affect protein trafficking, all of which can cause the Ko phenotype. 5Ј-AGATAAAGGGGGAGGAGAAGCCTG-3Ј 5Ј-CTTACATTCCCTCCCCTCCAGTGG-3Ј 5Ј-CCCAGTCCTCCGAATCAGCTCCTA-3Ј 5Ј-GGGAGGAACCAAGAGGTGAAAGAT-3Ј 5Ј-CACTGATGTTGTCACTCTCGGCTC-3Ј 5Ј-GATGCAGGGAGGAAGAAGAACCATG-3Ј 5Ј-CATGGTTCTTCTTCCTCCCTGCATC-3Ј 5Ј-ACAGGGTTTGGAGCAGTCATGGTC-3 5Ј-CTTATGATATAGGGCATGACTCCCCA-3Ј 5Ј-TATCACACAGGTGTCCTCTCTTCC-3Ј 5Ј-ATATTCCCCACCTCCCCACACCTG-3Ј 5Ј-CTAGGAGGAAGAAGGAAAGGAGGTAA-3Ј 5Ј-CCCCAGTTAGCCTGTTCTCTTCTT-3Ј 5Ј-ATCTACGGTGCTCAGGCTCTCCTC-3Ј 5Ј-AAGGAGCTAGATCCCACCCCAACC-3Ј 5Ј-TGCCGACATTTACCCCTCAAAAGAG-3Ј 5Ј-TCCCAGGAGGCTTTTGAAACCCCA-3Ј 5Ј-ATAGAAGAGGGAAGGCTGCTTTGG-3Ј 5Ј-CCCTTTTCCAAGGGTCAGAAGCTG-3Ј 5Ј-TCCCCATCTCGCTTGTTCCAATAC-3Ј 5Ј-ACTCACACTGGCAACAATGTGAGAGG-3Ј 5Ј-TCTGTTCTTCTGCCAGCAAGACGT-3Ј 5Ј-CCTAATCCCTGGATGCCTGCCTGT-3Ј 5Ј-GGGCTTATTTGACCCCCAGAATCT-3Ј 5Ј-GTAGTCTTTCCAGCTGGACTCCTC-3Ј 5Ј-CCTCAAACCCTCAAATAACCTCCCT-3Ј 5Ј-CTCACCTAGGCAGCACCAACCCTA-3Ј 5Ј-CAGTGAGGACATCTGCAGAAGAGG-3Ј 5Ј-CAAATGCTCCATGTGGCCCTTGGG-3Ј 5Ј-ACTGGGTGGCCTTCAAACCCACCA-3Ј

EXPERIMENTAL PROCEDURES

RESULTS

DISCUSSION