Allele Frequency and Distribution of Single Nucleotide Polymorphisms in Promoter Region of Gene Encoding the Kidd Blood Group Antigens / 中国实验血液学杂志

OBJECTIVE@#To study the single nucleotide polymorphisms (SNPs) in promoter region of the Jk gene and its allele frequency as well as distribution characteristics in the Chinese Han nationality population.@*METHODS@#127 blood samples containing 8 Jk(a-b-) and 119 samples (as control) taken randomly from voluntary blood donors of Chinese Han nationality persons in Shenzhen Blood Center were collected. The Kidd phenotypes were identified by using the serologic test and urea hemolysis test; the Jk promoter, exon 1-11 region and respective flanking area were amplified and sequenced, then the sequence information was analyzed.@*RESULTS@#8 Jk(a-b-) samples all carried JkB/JkB allele which belongs to 2 kind of Jk genotypes commonly observed in Chinese Han nationality population. 6 IVS5-1g>a and 2 896G>A were found in 8 Jk(a-b-) samples. Besides, all Jk(a-b-) samples were homozygous for JkB/JkB allele. Three SNPs-110(rs900974), -160(rs1484877) and -258(rs1484878) in promoter region of the Jk gene were found and sequenceds calculation of allele and genotype frequencies showed that the result accorded with Hardy-Weinberg equilibrium, indicating that the population in this study possesses representative characteristics of the Chinese Han nationality population.@*CONCLUSION@#The polymorphism of the Jk gene occurs in promoter region. This study calculates the allele frequencies of three SNPs-110(rs900974), -160(rs1484877) and -258(rs1484878) in promoter region of the Jk gene, and shows their distribution characteristics in distinct Kidd phenotypes. These findings provide the basic foundation for further population genetics research.

Establishment and Application of a Method for Determination of Glycosyltransferase Activity / 中国实验血液学杂志

<p><b>OBJECTIVE</b>To establish a method for determination of glycosyltransferase and to explore the enzyme A, B glycosyltransferase activity in human serum so as to lay the foundation for the determination of enzyme level and enzyme activity.</p><p><b>METHODS</b>The glycosyltransferase activity kit was used to draw phosphate standard curves in our laboratory. The A and B glycosyltransferase activity were determined by the standard curves.</p><p><b>RESULTS</b>The standard curves (y=2671.3x-0.596 R=0.9998) for determing glycosyltransferase activity suitable for use in our laboratory were drawn. At the same time the method was set up for determination of A, B glycosyltransferase in human serum.</p><p><b>CONCLUSION</b>The establised method of the determination of glycosyltransferase is suitable for common type of enzyme activity and suitable for the A, B glycosyltransferase in human serum.</p>

Molecular polymorphism of gypa gene in association with MN human blood group in Chinese Han population / 中国实验血液学杂志

This study was purposed to investigate the molecular polymorphism of gypa gene in association with MN human blood group in Chinese Han population. The MN phenotypes of 202 random samples from unrelated Chinese Han volunteers were identified by serology techniques. The primer for gypa gene exon 2 were designed and synthesized according to reference sequences of NG-007470 gene from GenBank, the DNA of 202 samples was amplified by PCR, at the same time, the amplified products were analyzed by direct DNA sequencing. The results showed that all samples had 2 base substitutions at 1st and 56th nt of gypa exon 2, among them the MN phenotype heterozygote exited mainly in the form of 1A > C, 22T/C, 34A/G, 35T/G, 56T > C; the MM phenotype homozygote exited mainly in the form of 1A > C, 22C, 34G, 35T, 56T > C; the NN phenotype homozygote exited mainly in the form of 1A > C, 22T, 34A, 35G, 56T > C. It is concluded that the polymorphism of gypa gene in associated with MN blood group in Chinese Han population is decided by 5 nucleotide sites of 1, 22, 34, 35 and 56. The bases of 1 and 56 are non-functional gypa single nucleotide polymorphism.

Analysis on expression and molecular basis for ABO glycosyltransferase with dual specificity / 中国实验血液学杂志

In order to elucidate the expression and molecular genetic background of ABO gene seven samples with ABO discrepancy further identified as bi-specific ABO gene were studied. All these samples were subjected to phenotyping by monoclonal and polyclonal antisera and were then genotyped by direct DNA sequencing and haplotype-sequencing at the exon 6 and 7 of ABO gene. As a result, six ABO dual-specific alleles were identified in Chinese population. An antigen expressed by these B (A) or Cis-AB individuals varied from very low level to the normal level, compared with common A blood group samples. In conclusion, molecular genetic backgrounds of two pairs out of four samples in all samples were the same, however, the ABO expression showed diverse.

Polymorphism of LW blood group gene in Chinese population / 中国实验血液学杂志

In order to study the polymorphism of Landsteiner-Wiener (LW) blood group gene in Chinese population, peripheral blood samples anticoagulated with EDTA from 160 unrelated volunteer blood donors were randomly collected, and genomic DNA were extracted. 160 DNA samples were analyzed for exon 1 of LW gene by direct DNA sequencing, and detected for LWa/LWb allele by improved PCR-SSP genotyping. The results showed that all LW allele in 160 donors were LWa homozygous, and the LWa allele occurred commonly. In conclusion, LWa allele occurs with incidence of 100% of donors in this study, while LWb allele has not been found in Chinese population.

Molecular genetic analysis of FUT1 and FUT2 gene in para-Bombay Chinese: a novel FUT1 allele is identified / 中华医学遗传学杂志

<p><b>OBJECTIVE</b>Molecular genetic analysis of FUT1 and FUT2 gene was performed for seven Chinese Han individuals serologically typed as para-Bombay.</p><p><b>METHODS</b>Seven DNA samples were studied by polymerase chain reaction and then by direct sequencing. Molecular cloning sequencing was done for an individual with a novel FUT1 allele. Family segregation analysis of the novel FUT1 allele was done to explore whether the allele was responsible for the fucosyltransferase defects of H.</p><p><b>RESULTS</b>The FUT1 genotypes of seven para-Bombay individuals were h1h1 (four individuals), h2h2 (two individuals), h328hnew (one individual), alleles h1 lost one of the three AG repeats located at the nucleotides 547-552 of the FUT1 gene, h2 lost two of the three T repeats located at the nucleotides 880-882, h328 (nt328G>A) was a missense mutation, all of them were known mutations, while allele hnew deleted GGTATTCCGCATCACCCTGCCCGTGCTGGCCCC at nt360-400, total 33 bases, and the frame-shift mutation was not previously reported. The segregation of the hnew allele in his family showed that his father genotype was Hh328, and his mother was Hhnew, while two brother were h328hnew. The FUT2 genotypes of seven para-Bombay individuals were Se357 Se357 (three individuals), Se357 Se357,385 (three individuals), Se357,716Se357,716(one individual), the functional Se357(nt357C>T), Se716(nt716G>A) and the weakly functional Se385(nt385A>T) were known. The seven para-Bombay individuals carried at least one copy of a functional FUT2 allele was consistent with their secretor status.</p><p><b>CONCLUSION</b>A novel FUT1 allele was identified in a para-Bombay Chinese individual, which was responsible for the inactivation of the FUT1-encoded enzyme activity.</p>

Genetic status of a AB chimeric blood group family / 中国实验血液学杂志

In order to study the genetic status of a rare chimeric family, some samples of A(3)B(3) family were identified by sequencing of ABO gene; flow-rSSO and PCR-SSP were used to detect loci of HLA-A, B, DRB1 genes, and multiplex amplifying with fluorescence-dye were performed for 16 short tandem repeat (STR) loci. The results indicated that two individuals from A(3)B(3) family contained more than two alleles at ABO gene, HLA-B, DRB1 and some STR loci. In conclusion, analysis of chimeric blood group by using genotyping techniques clearly demonstrating genetic status of this rare chimeric blood group promotes further elucidation of the existing state of specific genetic status.

Study on ABO gene polymorphism in Uighur nationality in Xinjiang of China / 中华医学遗传学杂志

<p><b>OBJECTIVE</b>To study the distribution of ABO gene polymorphism in Uighur population in Xinjiang area of China.</p><p><b>METHODS</b>DNA was extracted from 160 Uygur unrelated donorso blood and PCR-sequence specific primer analysis was performed. Some difficult samples were further directly sequenced.</p><p><b>RESULTS</b>Six alleles were detected in a population of 160 Uighur individuals, the gene frequencies of which were 0.2062(A101), 0.0563(A102), 0.0156(A201), 0.0031(A205),0.1875(B01),0.5312(O01), respectively.</p><p><b>CONCLUSION</b>The characteristics for AB gene structure of Xinjiang Uighur suggests that genetic polymorphism is distinguished between Xinjiang Uighur nationality and Chinese Han nationality, and both of them have discrepancy and confluent characters.</p>

Molecular genetic analysis of Diego blood group Dia and Dib in Chinese Han population / 法医学杂志

OBJECTIVE@#To study the molecular genetic background of Diego blood group in Chinese Han population.@*METHODS@#A total of 2990 blood samples from unrelated blood donors were phenotyped for Dia and Dib by serological method. Twenty randomly selected samples of Di(a-b+) type and all of the samples of rare Di(a+b-) phenotype by screening were genotyped by PCR-SSP and direct DNA Sequencing.@*RESULTS@#Of the 2990 samples identified by serological method, 2821 were Di(a-b+), 167 were Di(a+b+) and 2 were Di(a+b-). All of the 20 randomly-selected samples with Di(a-b+) phenotype were DI2DI2 homozygote by PCR-SSP genotyping, with nucleotide C at nt position 2561 in exon 19 by direct sequencing of the DI gene. The 2 samples of rare Di (a+b-) phenotype were both the DI1DI1 homozygote, with nucleotide T at nt position 2561 in exon 19.@*CONCLUSION@#Our results indicate that the expression of Dia and Dib antigens in Chinese Han population most likely result from a single nucleotide T to C substitution at nucleotide position 2561 in exon 19 of the DI gene, which subsequently leads to an amino acid 854 change from Pro to Leu.

Study on molecular genetic structure of Ael blood subgroup / 中华医学遗传学杂志

<p><b>OBJECTIVE</b>To study the ABO allele molecular characteristics of Ael blood subgroup.</p><p><b>METHODS</b>Five individuals of diagnosed as Ael blood subgroup were subjected to PCR amplify ABO alleles using four pairs of sequence-specific primers. Exon 6 and exon 7 at ABO locus of all samples were sequenced. An individual with AelB phenotype was chosen for further analysis of transcript structure of ABO gene.</p><p><b>RESULTS</b>Sequence analysis indicated one Ael phenotype sample with reported Ael01 allele, one Ael phenotype sample with an Ael05 allele, and two AelB and one Ael individuals did not contain referred A allele, but contain O01 or O02 allele with 261G deletion.</p><p><b>CONCLUSION</b>Molecular bases for the Ael have highly polymorphism. The mechanism responsible for the express weak A antigen of O allele with 261G deletion awaits to be elucidated.</p>

Molecular genetic analysis for the A3 alleles / 中国实验血液学杂志

To study four A(3) subgroup samples identified by serologic tests, among which two belong to a family, three were A(3) subgroup, one was A(3)B subgroup. All four samples were genotyped by PCR-SSP method, and the nucleotide sequences of Exon 6, Exon 7 and part introns at the ABO locus for these samples were detected by ABI Prism 3100 DNA sequencer. Comparison with the consensus of A101 was performed. The results showed that haplotypes of two A(3) subgroups were common A102 allele and O1-2 allele, and haplotypes of one A(3) subgroup were common A102 allele and rare O(1v)-4 allele. Unexpectedly, a synonymous substitution 838C-->T had been found in A allele of the A(3)B subgroup sample, which predict a Leu280Phe alteration. The results suggested that molecular genetic background of the A(3) phenotypes is polymorphic. Possibly, the missense mutation 838C-->T is the molecular genetic basis of A(3)B subgroup that lead to low activity of the glycosyltransferases.