Yan Lx

[Analysis of allele frequencies of HLA-DRB1*12:01:01G and HLA-DRB1*14:01:01G groups].

OBJECTIVE To discriminate and analyze the relative frequencies of alleles in HLA-DRB1*12:01:01G(HLA-DRB1*12:01:01/12:06/12:10/12:17) and HLA-DRB1*14:01:01G (DRB1*14:01:01/14:54) groups and assess their associations with HLA-DRB3 and HLA-DQB1 loci. METHODS A total of 115 DNA samples previously typed as HLA-DRB1*12:01:01G and 108 samples from HLA-DRB1*14:01:01G were selected. DNA sequences for exons 1 to 3 of the HLA-DRB1 locus were analyzed for HLA-DRB1*12:01:01G, and exons 2 to 3 were analyzed for HLA-DRB1*14:01:01G by polymerase chain reaction sequence-based typing (PCR-SBT). Genotyping of HLA-DRB3 and HLA-DQB1 were achieved by PCR-SBT. RESULTS Among 115 samples previously typed as HLA-DRB1*12:01:01G, 101 (87.8%) were confirmed as HLA-DRB1*12:01:01 and 14 (12.2%) were HLA-DRB1*12:10, but HLA-DRB1*12:06 and HLA-DRB1*12:17 alleles were not identified. For 108 samples previously typed as HLA-DRB1*14:01:01G, all were typed as HLA-DRB1*14:54. HLA-DRB1*12:01:01 was linked with HLA-DRB3*01:01:02 and HLA-DQB1*03:01, while HLA-DRB1*12:10 was strongly linked with HLA-DRB3*02:02:01 and HLA-DQB1*03:01. HLA-DRB1*14:54 was strongly linked with HLA-DRB3*02:02:01 and two different HLA-DQB1*05:02, *05:03 alleles. CONCLUSION HLA-DRB1*12:01:01 was more prevalent than HLA-DRB1*12:10 in the HLA-DRB1*12:01:01G group, and HLA-DRB1*14:54 was the dominant allele for HLA-DRB1*14:01:01G.

Study on a novel mutation of B glycosyltransferase gene related with an ABx variant

OBJECTIVE To explore the molecular basis of an individual featuring an ABx variant of ABO blood group system. METHODS Serological assays were used to characterize the erythrocyte phenotypes and salivary ABH secretors. All of the seven exons and flanking introns of ABO glycosyltransferase gene were amplified with polymerase chain reaction (PCR). And the products were sequenced bidirectionally following enzyme digestion. Exons 6 and 7 were also subcloned and analyzed for haplotypes of the ABO gene. RESULTS Erythrocytes of the proband have expressed a strong A antigen and a weak B antigen, which was identified as a rare ABx variant in addition with other serological features. Nine heterozygous sites in exon 6 (297A/G) and exon 7 (467C/T, 526C/G, 657C/T, 703G/A, 796C/A, 803G/C, 808T/A, 930G/A) of the coding region of the ABO gene were identified. Based on haplotype analysis, one allele was determined as common A102, whilst another was consistent with B101 except for an 808T>A mutation which has resulted in replacement of phenylalanine with isoleucine at position 270 of glycosyltransferase B. CONCLUSION The 808T>A mutation of the glycosyltransferase B gene may decrease the enzymatic activity and result in the Bx variant.

[Recombination between human leukocyte antigen -A and -C loci within two Chinese Han families].

OBJECTIVE To investigate the recombination events between human leukocyte antigen (HLA) loci within two families. METHODS Identification of HLA-A, -C, -B, -DRB1 and -DQB1 loci was firstly carried out using polymerase chain reaction-sequence specific oligonucleotide. Then HLA high resolution typing was performed using polymerase chain reaction sequencing-based typing. The recombination between HLA loci was identified by family genetic analysis. The parentage possibility was analyzed by short tandom repeat technique. RESULTS Recombination between the HLA-A and C loci was identified within two families. One individual inherited a paternal haplotype that was the result of a recombination event between the fathers HLA-A and -C loci on his chromosomes. The other individual inherited a maternal haplotype that was the result of a recombination event between the mothers HLA-A and -C loci. The high parentage possibilities were obtained in the family members. CONCLUSION The recombination events of HLA-A and -C have been found in two Chinese families, which may help further study on the mechanism of HLA recombination.

Study on polymorphism of membrane glycoprotein genes related to human platelet alloantigens

OBJECTIVE To investigate the polymorphisms of platelet membrane glycoprotein genes related to human platelet alloantigen (HPA)-1 to 17w. METHODS The DNA segments of platelet membrane glycoprotein genes related to HPA-1 to 17w were amplified using authors designed primers. The amplification products were purified and directly sequenced to identify the HPA genotype and glycoprotein gene polymorphisms. RESULTS Thirteen new single nucleotide polymorphisms (SNPs) and a micro-satellite sequence were found in the glycoprotein genes from the 112 random samples, in which two SNPs (1333G/A and 1960G/A) in ITGB3 gene result in two amino acid change (V419M and E628K) on glycoprotein GPIIIa. CONCLUSION New variants in platelet membrane glycoprotein genes were identified, which may lead to structure change of platelet membrane glycoprotein and affect the accuracy of partial HPA genotyping method.

[Study on the expression stability of mutant alpha-1,2 fucosyltransferase gene 293C to T and 658C to T in eukaryotic cells].

OBJECTIVE To establish the eukaryotic cell expression system for the alpha-1,2 fucosyltransferase gene FUT1 293C to T and 658C to T mutations and explore the mechanism of FUT1 mutations resulting in the reduced expression of H antigen. METHODS Genomic DNAs were extracted from individuals with para-Bombay phenotype and full coding region of FUT1 was amplified. The amplification fragments were ligated with pcDNA3.1 plasmid to construct the recombinant expression vectors. The recombinant plasmids were transfected into the COS-7 cells using lipofectamine transfection reagent and stable expression screening was performed. FUT1 mRNA expression was determined by real-time quantitative PCR. The activity of enzyme was measured by high performance liquid chromatography. Expressed protein was identified by SDS-PAGE and Western blotting. RESULTS pcDNA3.1-FUT1 wildtype, pcDNA3.1-FUT1 293C to T and pcDNA3.1-FUT1 658C to T recombinant vectors were constructed, respectively. COS-7 cells with stable expression of FUT1 were obtained through recombinant plasmid transfection and screening with G418. The FUT1 mRNA level of transfected cells with 293C to T and 658C to T recombinant vectors reached 97.10% and 104.74% of the wildtype FUT1 transfected cell. A specific protein band with about 46 000 was confirmed in the transfected cell lysates by SDS-PAGE electrophoresis and Western blotting with 6×His Tag antibody. The wildtype FUT1 transfected cell lysates can catalyze the enzymatic reaction, while the enzyme activity of cell lysates from 293C to T and 658C to T were abolished. CONCLUSION The results suggested that the 293C to T and 658C to T mutations of FUT1 gene did not affect the RNA and protein expression levels, but the enzyme activity of cells with FUT1 mutations was significantly decreased which resulted in the reduced expressin of H antigen.

[Identification of a novel allele HLA-B*15:129 by polymerase chain reaction with allele group-specific primers].

OBJECTIVE To analyze the sequence of the exons 2-4 of human leukocyte antigen (HLA) novel allele HLA-B*15:129. METHODS DNA of the proband was extracted from whole blood by commercial DNA extraction kit. The amplification for HLA-B exons 2-4 was performed separately by polymerase chain reaction (PCR) with allele group specific primers. The PCR products were digested with enzymes and then directly sequenced for exons 2-4 of HLA-B locus in both directions. RESULTS Sequencing results showed the HLA-B alleles of the proband included B*07:02 and a novel allele. The sequence of the novel allele has been submitted to GenBank (accession no. EF473219) and the allele has been officially named B*15:129 by the WHO Nomenclature Committee. Comparing with the HLA-B*15:01:01:01, the sequence of exons 2-4 of HLA-B*15:129 showed three nucleotide difference in exon 3 at positions 362 and 363 from GG to AT and positions 369 from C to T, which resulted in an amino acid change from Arg to Asn at codon 97. CONCLUSION A novel HLA-B allele was identified and has been officially named B15:129 by the WHO Nomenclature Committee.

Identification of an ABx09 phenotype of ABO subtype

OBJECTIVE To analyze the molecular basis for an individual with ABx09 phenotype of ABO subtype. METHODS The ABO group antigens on red blood cells of the proband were identified by monoclonal antibodies, and the ABO antibody in serum was detected by standard A, B, O cells. The exons 1 to 7 of ABO gene were amplified by polymerase chain reaction (PCR) respectively and the PCR products were sequenced directly. The amplified products for exons 5 to 7 were also cloned by TOPO TA cloning sequencing kit to split the two alleles apart, selected colonies were sequenced bidirectionally for exons 5 to 7 of the ABO gene. The samples of the probands parents were collected, then serological test of the blood group and sequence analysis for exons 6 and 7 of ABO gene were preformed. RESULTS Both A and B antigens were detected on red blood cells of the proband and there was anti-B antibody in the serum. There was no G deletion at position 261, while 297AG in exon 6, 467CT, 526CG, 657CT, 703GA, 796CA, 803GC, 889GA and 930GA heterozygote in exon 7 were detected by direct DNA sequencing, which can be assigned for A102Bx09 genotype. After cloning and sequencing, two alleles A102 and Bx09 were obtained. The sequence of Bx09 had one nucleotide changes (G to A) at position 889 compared with that of B101, which resulted in an amino acid change of Glu to Lys at 297 position. The Bx09 in the proband was inherited from her mother by family investigation. CONCLUSION G to A at nt889 of alpha-1,3 galactosyltransferasegene can result in Bx09 phenotype, with the presence of anti-B antibody in serum.

[Analysis of alpha-1,2-fucosyltransferase gene mutations in a Chinese family with para-Bombay phenotype].

OBJECTIVE To investigate the molecular genetic basis of para-Bombay phenotype in a Chinese family. METHODS ABO and H phenotypes of the proband and his pedigree were characterized by serological techniques. The exons 6 and 7 of the ABO gene and full coding region of alpha-1,2-fucosyltransferase (FUT1) gene of the pedigree were analyzed by polymerase chain reaction and direct sequencing of the amplified fragments. The haplotypes of compound heterozygote of the FUT1 gene were also analyzed by cloning sequencing. RESULTS Three para-Bombay phenotypes were identified in nine family members by serological technology. Three heterozygous variants (35C/T, 235G/C and 682A/G) were found in FUT1 gene of the proband, and the hapotype of FUT1 gene was h(235C)/h(35T+628G)according to the cloning sequencing. The alleles h(235C)and h(35T+628G) caused G79R, A12V and M228V amino acid substitutions in alpha-1,2-fucosyltransferase, respectively. CONCLUSION A novel 235G>C mutation of FUT1 gene which was associated with para-Bombay phenotype was found in the Chinese pedigree.

[Establishment of allele specific primer polymerase chain reaction sequence-based typing and investigation of the polymorphism in exon 3 of HLA-DRB1].

OBJECTIVE To establish the allele specific primer polymerase chain reaction sequence-based typing (PCR-SBT) and investigate the polymorphism of exon 3 of human leukocyte antigen( HLA)-DRB1. METHODS The fragment containing exons 2 and 3 of HLA-DRB1 gene was amplified by group specific primers. The amplified products were digested by restriction enzymes and directly sequenced in both directions. The genotype was assigned by using Assign 3.5 SBT software. RESULTS The exon 3 sequences of HLA-DRB1*08:09 and HLA-DRB1*12:02:01 were identified for the first time. There were 27 polymorphic sites in exon 3 among the twenty-five HLA-DRB1 alleles, which was 9.56% of all nucleotides of exon 3. The method could discriminate the HLA-DRB1*14:01:01/14:54 ambiguous samples, and the HLA-DRB1*14:01:01 was identified in the Chinese population. CONCLUSION The PCR-SBT method for exon 3 of HLA-DRB1 from the present study was reliable and there were polymorphisms in exon 3 of HLA-DRB1.

Molecular genetic analysis of a new B112 allele of ABO blood group

OBJECTIVE To analyze the molecular genetic basis for a new B112 allele of ABO blood group and the pedigree of the proband. METHODS The ABO group antigens on red cells of the proband were identified by monoclonal antibodies. The ABO antibody in serum was detected by using standard A, B and O cells. The exons 5-7 of ABO gene for the proband was amplified by polymerase chain reaction and the amplified products were digested with double enzymes and sequenced for exons 6 and 7. A magnetic bead-based, haplotype specific extraction was used to separate the diploid sample of the proband into its haploid components. The exons 6 and 7 of the two single ABO haplotypes were then amplified and sequenced separately. The samples of the parents of the proband were collected, and the blood group serological test and sequence analysis for exons 6 and 7 of ABO gene were performed. RESULTS The serum characteristic of the proband was consisted with the normal B phenotype. The DNA sequencing of exons 6 and 7 showed 261G/del, 297A/G, 526C/G, 559C/T, 657C/T, 703G/A, 796C/A, 803G/C and 930G/A heterozygotes and was assigned for B/O genotype. After separation of the two single strands of the proband with haplotype specific extraction, a B112 and an O01 allele were identified after sequencing. The B112 allele had one nucleotide change (C to T) at position 559 compared with B101, which resulted in an amino acid change at position 187 (Arg to Cys). The B112 in the proband was identified to inherit from his mother after pedigree analysis, the ABO blood group serological characteristics and sequences of exons 6 and 7 of the mother were identical to that of the proband. CONCLUSION A novel B112 allele of ABO group system with 559C>T was identified. It had normal B antigen expression, suggesting that Arg118Cys of alpha-1, 3 galactosyltransferase did not affect its enzyme activity.