Introduction: Kidd blood group system is distributed differently within populations. In Malaysia, the prevalence of Kidd phenotypes have been reported but not in Hospital Umum Sarawak (HUS).We characterised Kidd phenotypes among regular blood donors in HUS. Methods: A cross-sectional study was done from 1st September 2015 to 10th September 2015. Blood samples were collected from 250 regular blood donors of different ethnicities in HUS. Samples were then investigated for Kidd blood group phenotypes by utilising Seraclon anti-Jka and anti-Jkb reagents employing the Diamed-ID gel card system. Results: Phenotype Jk(a+b+) was found in 110 out of 250 (44.0%) and phenotype Jk (a-b-) phenotype in seven out of 250 (2.8%) blood donors. Jk(a+b-) was detected in 60 out of 250 (24.0%) and Jk(a-b+) in 73 out of 250 (29.2%) donors. Kidd phenotype was detected in four ethnics; Chinese 50.8%, Malays 38.4%, Bidayuh 10.0% and Iban 0.8%. Jk(a-b-) phenotype was present only in the Malays; seven out of 250 (2.8%) but not found in other ethnicities. Conclusion: Jk(a+b+) is the most common Kidd phenotype found in regular blood donors in HUS in the four ethnicities studied. Only Malays exhibit the Jk(a-b-) phenotype which is a rare phenotype. The results of this study may serve as a preliminary database for Kidd blood group profile of regular blood donors in HUS.
; Kidd phenotype

The purpose of this study was to find the rare individual JK(a-b-) phenotype of proband family and explore its molecular mechanism and the genetic background, in order to provide base for searching compatible donor to blood transfusion of the individuals with rare JK(a-b-) phenotype. Urea lysis test was used to screen the JK(a-b-) phenotype and results were confirmed with serological method. The genotypes were detected with PCR-SSP. The 4-11 exons and their flanking intron regions of JK gene were amplified and sequenced. The results showed that her elder brother has a same phenotype JK(a-b-) and genotypes JK(a)/JK(b) with proband. The phenotype and genotypes of their parent is JK (a+b-) and JK(a)/JK(b), respectively; and the younger sister's is JK (a+b-) and JK(a)/JK(a). Acceptor site of intron 5 3' g > a mutation was detected in proband and her elder brother, which may cause the JK(a-b-) phenotype of proband and her elder brother. There is g/a and a at this site in their parent and younger sister, respectively. Additionally, the SNP (ncbi:rs8090908) a > g at nt-99 in intron 3 was found in proband and her elder brother, it needs to be explored whether the SNP is related to JK(a-b-) phenotype. This SNP was not found in their parent and younger sister. This JK(a-b-) phenotype abides by the rule of dominant inheritance in the family, suggesting that there is higher probability to find homology phenotype and genotype by investigating in their family, especially in their siblings.
Adult ; Alleles ; Exons ; Female ; Genotype ; Humans ; Introns ; Kidd Blood-Group System ; genetics ; Male ; Pedigree ; Phenotype

OBJECTIVE: To screen for Jk(a-b-) phenotype among blood donors from Jining area and explore its molecular basis to enrich the rare blood group bank for the region. METHODS: The population who donated blood gratuitously at Jining Blood Center from July 2019 to January 2021 were selected as the study subjects. The Jk(a-b-) phenotype was screened with the 2 mol/L urea lysis method, and the result was confirmed by using classical serological methods. Exons 3 to 10 of the SLC14A1 gene and its flanking regions were subjected to Sanger sequencing. RESULTS: Among 95 500 donors, urea hemolysis test has identified three without hemolysis, which was verified by serological method as the Jk(a-b-) phenotype and demonstrated no anti-Jk3 antibody. The frequency of the Jk(a-b-) phenotype in Jining area is therefore 0.0031%. Gene sequencing and haplotype analysis showed that the genotypes of the three samples were JK*02N.01/JK*02N.01, JK*02N.01/JK-02-230A and JK*02N.20/JK-02-230A, respectively. CONCLUSION The splicing variant of c.342-1G>A in intron 4, missense variants of c.230G>A in exon 4, and c.647_ 648delAC in exon 6 probably underlay the Jk(a-b-) phenotype in the local population, which is different from other regions in China. The c.230G>A variant was unreported previously.
Humans ; Phenotype ; Blood Donors ; Hemolysis ; Kidd Blood-Group System/genetics* ; Urea ; Molecular Biology

OBJECTIVETo study the molecular genetics characteristics of Jk(a-b-) phenotype of blood donors from Chengdu.

METHODSExons 4-11 of the JK genes and their flanking intronic regions for 8 Jk(a-b-) samples were analyzed with PCR-sequence specific primers (PCR-SSP) and DNA sequencing.

RESULTSAll samples had AA genotype at position 838 of exon 9 predicting a null Jk(b)-like alleles. Sequence analysis has revealed 4 mutant alleles, which included: (1) IVS5-1G>A, A to G at position 588 (Pro196Pro) of exon 7; (2) G to A at position 896 (Gly299Glu) of exon 9, A to G at position 588 (Pro196Pro) of exon 7; (3) IVS5-1G>A, C>A at position 222 (Asn74Lys) of exon 5, A to G at position 499 (Met167Val) of exon 7, A to G at position 588 (Pro196Pro) of exon 7; and (4) IVS5-1G>A, G to A at position 896 (Gly299Glu) of exon 9, A to G at position 588 (Pro196Pro) of exon 7.

CONCLUSIONIVS5-1G>A, C to A at position 222 (Asn74Lys) of exon 5 and G to A at position 896 (Gly299Glu) of exon 9 might have been the molecular genetic mechanisms underlying Jk(a-b-) phenotype of the selected blood donors.

Alleles ; Base Sequence ; Blood Donors ; China ; Exons ; Genotype ; Humans ; Introns ; Kidd Blood-Group System ; genetics ; Mutation ; Phenotype