Publications (5)14.03 Total impact
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Article: Specific amino acid substitutions cause distinct expression of JAL (RH48) and JAHK (RH53) antigens in RhCE and not in RhD.
Transfusion 01/2010; 50(1):267-9. · 3.22 Impact Factor -
Article: RhCE protein variants in Southwestern Germany detected by serologic routine testing.
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ABSTRACT: Variant RHCE alleles with diminished expression of C, c, E, and e antigens have been described and indicate the genetic diversity of this gene locus in several populations. In this study the molecular background of variant RhCE antigens identified by standard serologic routine testing in German blood donors and patients was determined. Samples from blood donors and patients were routinely analyzed for RhCE phenotype using the PK7200 analyzer with two sets of monoclonal anti-C, -c, -E, and -e reagents. Samples with confirmed variant RhCE antigens were analyzed by nucleotide sequencing of the 10 RHCE exons. A multiplex polymerase chain reaction with sequence-specific priming (PCR-SSP) method was established for rapid typing of the rare RHCE alleles. We identified 43 samples with serologic RhCE variants. Molecular analysis revealed variant RHCE alleles in 34 samples. Altogether 22 RHCE alleles were detected; 10 have not been published before. Twenty alleles harbored distinct single-nucleotide substitutions, 18 of which encoded amino acid changes and 2 of which occurred in noncoding regions. Two samples represented RHCE-D-CE hybrid alleles involving different segments of the RHCE Exon 5. A multiplex PCR-SSP screening for 17 RHCE alleles was negative in 1344 samples of the DNA bank GerBS. The cumulative phenotype frequency was estimated between 1 in 488 (0.20%) and 1 in 8449 (0.012%). Single-amino-acid substitutions were the molecular basis for variant RhCE antigen expression in most samples. Nucleotide substitutions in RHCE exons were excluded as possible mechanism of diminished RhCE antigen expression in one-fifth of the serologically identified samples.Transfusion 06/2009; 49(9):1793-802. · 3.22 Impact Factor -
Article: A novel KEL*1,3 allele with weak Kell antigen expression confirming the cis-modifier effect of KEL3.
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ABSTRACT: KEL1 (K) is the most immunogenic red blood cell antigen of the Kell blood group system. The frequently occurring anti-KEL1 alloantibodies may cause hemolytic transfusion reactions as well as severe hemolytic disease of the fetus and newborn. So far, reports on weak KEL phenotypes are scarce. Blood samples of two unrelated Central European propositi with faint reactions in routine KEL1 typing were analyzed by extended serologic phenotyping, flow cytometry, genotyping by polymerase chain reaction with sequence-specific priming, and genomic DNA sequencing of separated parental KEL alleles. Both propositi exhibited an unusual KEL:1,2,3,4 phenotype: markedly weakened and negative reactions were observed in serologic KEL1 typing in gel and tube technique, respectively. No KEL1 epitope loss was detected using five different monoclonal anti-KEL1 reagents. KEL genotyping confirmed KEL*1/2 and KEL*3/4 (Kpa/Kpb) heterozygosity of both individuals. Importantly, DNA sequencing of the two separated parental alleles of both propositi revealed a KEL*1-specific coding nucleotide T578 and a KEL*3-specific T841 on the same allele. This novel KEL*1,3 (KKpa)allele was associated with an approximately 80 percent reduction in KEL1 expression, compared to KEL:1,2,-3,4 controls. The low KEL1 density was attributed to acis-modifier effect of KEL3, so far only reported in association with weakened expression of KEL2 (k). This is the first description of the KEL*1,3 allele encoding KEL1 and KEL3 on the same molecule. In individuals with weakened KEL1 because of KEL3 in cis, very sensitive serologic or molecular genetic techniques may be required for reliable Kell typing.Transfusion 05/2009; 49(4):733-9. · 3.22 Impact Factor -
Article: A Novel Variant B Allele of the ABO Blood Group Gene Associated with Lack of B Antigen Expression.
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ABSTRACT: SUMMARY: BACKGROUND: The gene locus for the ABO blood group system encodes a glycosyltransferase. Alterations in the DNA sequence are associated with the blood groups and the expression levels of antigens on red blood cells. A number of ABO alleles have been described as the molecular basis of weak A or B antigens. PATIENTS AND METHODS: Here, we describe a novel variant B allele in a blood donor with discrepant results in routine forward (group A) and reverse (very weak anti-B isoagglutinins) ABO blood grouping. RESULTS: Determination of the ABO genotype using polymerase chain reaction-sequence-specific primers (PCR-SSP) indicated blood group A(2)B. Sequencing of the ABO gene exons 6 and 7 showed for 1 allele a G insertion into the GGGGGG sequence at position 811-816 of exon 7. The 816insG mutation (designated ABO*Bw20) led to a frame shift of the coding sequence and subsequent alteration of the protein sequence. The location of the mutation on a B allele was proven by PCR-SSP. Screening for the novel mutation in 211 blood donors with regular ABO phenotypes indicated that *Bw20 is a rare variant. CONCLUSIONS: The low levels of anti-B isoagglutinins associated with this novel variant indicate that residual undetectable amounts of B antigen may be present on red blood cells. The serological and molecular analysis of members of the blood donor's family further proved the phenotype-genotype correlation of the *Bw20 allele with antigen O and individually variable levels of anti-B isoagglutinins. The characterization of novel alleles associated with ABO subgroups may ensure the correct determination of blood groups in which serological methods are combined with molecular genetic approaches.Transfusion Medicine and Hemotherapy 01/2008; 35(4):319-323. · 1.16 Impact Factor -
Article: Molecular basis of the JAHK (RH53) antigen.
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ABSTRACT: The JAHK antigen was first described in 1995 as a low-frequency red blood cell antigen. Family studies confirmed the association of the antigen with the rare r(G) phenotype of the Rh blood group system, which is associated with weak expression of C and e, but normal G expression. JAHK was allocated the Rh number RH53. The serologic findings indicated the location of the antigen on the RhCE protein, although the molecular basis for JAHK has not been known. The RHCE gene of eight persons from three unrelated families was analyzed by exon amplification and direct sequencing. Four of the samples were JAHK+ the remaining four were JAHK-. In one JAHK+ sample, the entire RHCE gene was sequenced. The remaining samples were sequenced for exons 1 to 3. A polymerase chain reaction procedure with sequence specific primers was developed for the specific detection of the JAHK allele. Analysis of the entire RHCE gene of one JAHK+ sample showed the expected CcEe-specific nucleotide sequences and revealed an additional nucleotide change (365C>T) in exon 3. This change represented a missense mutation, which led to an amino acid substitution from serine to leucine at position 122 of the RhCE protein. Three JAHK+ samples from two other unrelated families showed the 365C>T mutation and confirmed the association of the Ser122Leu substitution with the JAHK+ phenotype. The molecular basis of the JAHK antigen (RH53) is defined by a 365C>T mutation in exon 3 of the RHCE gene leading to the amino acid substitution Ser122Leu. Because the position 122 is predicted to be located in the transmembrane region adjacent to the second loop, the substitution of the neutral serine by the hydrophobic leucine seems to be the cause of the JAHK antigen by a conformational change of the RhCE protein. This structural change may also cause the weakened expression of the C and e antigens observed in JAHK+ individuals. Based on our results it is concluded that the JAHK-specific mutation is associated with a dCe haplotype.Transfusion 09/2005; 45(8):1314-8. · 3.22 Impact Factor
