Genomic structure of the human plasma prekallikrein gene, identification of allelic variants, and analysis in end-stage renal disease.
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Yu H, Anderson PJ, Freedman BI, Rich SS, Bowden DW
Genomic structure of the human plasma prekallikrein gene, identification of allelic variants, and analysis in end-stage renal disease.
Genomics. 2000 Oct 15;69(2):225-34.
- PubMed ID
- 11031105 [ View in PubMed]
- Abstract
Kallikreins are serine proteases that catalyze the release of kinins and other vasoactive peptides. Previously, we have studied one tissue-specific (H. Yu et al., 1996, J. Am. Soc. Nephrol. 7: 2559-2564) and one plasma-specific (H. Yu et al., 1998, Hypertension 31: 906-911) human kallikrein gene in end-stage renal disease (ESRD). Short sequence repeat polymorphisms for the human plasma kallikrein gene (KLKB1; previously known as KLK3) on chromosome 4 were associated with ESRD in an African American study population. This study of KLKB1 in ESRD has been extended by determining the genomic structure of KLKB1 and searching for allelic variants that may be associated with ESRD. Exon-spanning PCR primer sets were identified by serial testing of primer pairs designed from KLKB1 cDNA sequence and DNA sequencing of PCR products. Like the rat plasma kallikrein gene and the closely related human factor XI gene, the human KLKB1 gene contains 15 exons and 14 introns. The longest intron, F, is almost 12 kb long. The total length of the gene is approximately 30 kb. Sequence of the 5'-proximal promoter region of KLKB1 was obtained by shotgun cloning of genomic fragments from a bacterial artificial clone containing the KLKB1 gene, followed by screening of the clones using exon 1-specific probes. Primers flanking the exons and 5'-proximal promoter region were used to screen for allelic variants in the genomic DNA from ESRD patients and controls using the single-strand conformation polymorphism technique. We identified 12 allelic variants in the 5'-proximal promoter and 7 exons. Of note were a common polymorphism (30% of the population) at position 521 of KLKB1 cDNA, which leads to the replacement of asparagine with a serine at position 124 in the heavy chain of the A2 domain of the protein. In addition, an A716C polymorphism in exon 7 resulting in the amino acid change H189P in the A3 domain of the heavy chain was observed in 5 patients belonging to 3 ESRD families. A third polymorphism in the coding sequence was a C699A shift that caused an amino acid change, H183Q. This allele was observed in 8 cases from 6 ESRD families but was not found in any control DNAs. Individually or combined, the allelic variants observed are not statistically associated with ESRD, though in several cases (e.g., H183Q) the small number of people in the population carrying these alleles limits our ability to statistically test for significant association with ESRD. Two new CA/GT repeat polymorphic markers, designated KLK3f and KLK3g, that have heterozygosities of 0.65 and 0.84, respectively, were identified within introns M and N. Analysis using the relative predispositional effect technique indicated that the frequencies of alleles 4 and 8 of KLK3f and allele 8 of KLK3g were significantly different between controls and ESRD cases. They accounted for 0.226, 0.096, and 0.313, respectively, in the probands of 166 ESRD families compared to 0.172, 0.066, and 0.244 in 139 healthy race-matched controls (allele P and total P < 0.05 for all three alleles). Therefore, although polymorphisms in the coding and 5'-proximal promoter of KLKB1 show no statistically significant association with ESRD in African Americans, there is still evidence for association of this part of chromosome 4 with ESRD. This observation suggests that other sequences within or near KLKB1, or another gene nearby, may contribute to ESRD susceptibility.