Kim Hue‐Roye scite author profile

The results provide an explanation for the variation in typing results in antibody producers. The ablation of Jo(a) in the Hy- phenotype and the weakening of Hy in the Jo(a-) phenotype may be due to the close proximity of these antigens. The 898 C>G mutation, within the sequence motif for glycosylphosphatidylinositol linkage, may cause reduced efficiency of anchoring the protein to the RBC membrane, thereby weakening the expression of Gy(a) and Do(b).

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DIIIa and DIII Type 5 are encoded by the same allele and are associated with altered RHCE*ce alleles: clinical implications

Westhoff

Vege

Halter-Hipsky

et al. 2010

Transfusion

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BACKGROUND-The partial D phenotype DIIIa was originally reported to be associated with 455A>C in Exon 3, 602C>G in Exon 4, and 667T>G in Exon 5. Other alleles with these changes were subsequently identified and designated DIII Types 5, 6, and 7, as they had additional alterations. The observation that DNA samples associated with the DIIIa phenotype had more changes than those originally reported motivated us to reanalyze the DIIIa probands (BP and DJ) from the original study. We also studied additional DIIIa samples to clarify the RHD background and establish the associated RHCE.

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DNA analysis for the Dombrock polymorphism

et al. 2001

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Genomic analyses of RH alleles to improve transfusion therapy in patients with sickle cell disease

Reid

Hipsky

Hue‐Roye

et al. 2014

Blood Cells, Molecules, and Diseases

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Background: Red cell (RBC) blood group alloimmunization remains a major problem in transfusion medicine. Patients with sickle cell disease (SCD) are at particularly high risk for developing alloantibodies to RBC antigens compared to other multiply transfused patient populations. Hemagglutination is the classical method used to test for blood group antigens, but depending on the typing methods and reagents used may result in discrepancies that preclude interpretation based on serologic reactivity alone. Molecular methods, including customized DNA microarrays, are increasingly used to complement serologic methods in predicting blood type. The purpose of this study was to determine the diversity and frequency of RH alleles in African Americans and to assess the performance of a DNA microarray for RH allele determination. Material and methods: Two sets of samples were tested: (i) individuals with known variant Rh types and (ii) randomly selected African American donors and patients with SCD. Standard hemagglutination tests were used to establish the Rh phenotype, and cDNA- and gDNA-based analyses (sequencing, PCR-RFLP, and customized RHD and RHCE microarrays were used to predict the genotype. Results: In a total of 829 samples (1,658 alleles), 72 different alleles (40 RHD and 32 RHCE) were identified, 22 of which are novel. DNA microarrays detected all nucleotides probed, allowing for characterization of over 900 alleles. Conclusions: High-throughput DNA testing platforms provide a means to test a relatively large number of donors and potentially prevent immunization by changing the way antigen-negative blood is provided to patients. Because of the high RH allelic diversity found in the African American population, determination of an accurate Rh phenotype often requires DNA testing, in conjunction with serologic testing. Allele-specific microarrays offer a means to perform high-throughput donor Rh typing and serve as a valuable adjunct to serologic methods to predict Rh type. Because DNA microarrays test for only a fixed panel of allelic polymorphisms and cannot determine haplotype phase, alternative methods such as Next Generation Sequencing hold the greatest potential to accurately characterize blood group phenotypes and ameliorate the clinical course of multiply-transfused patients with sickle cell disease.

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The JAL antigen (RH48) is the result of a change in RHCE that encodes Arg114Trp

et al. 2009

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BACKGROUND-The JAL antigen (Rh48) was discovered more than 30 years ago when it caused hemolytic disease of the fetus and newborn in an African American family. A decade later it was found to cause hemolytic disease of the fetus and newborn in a Caucasian family. The presence of the same low-prevalence antigen in two different ethnic groups is rare, but additional JAL+ in both groups was subsequently identified. This study was undertaken to investigate the RH gene(s) responsible for expression of JAL and to determine the structural relationship between JAL and other Rh antigens.

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Molecular basis of the Dombrock null phenotype

et al. 2001

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Kim Hue‐Roye

Determination of 24 minor red blood cell antigens for more than 2000 blood donors by high‐throughput DNA analysis

A flexible array format for large‐scale, rapid blood group DNA typing

Insights into the Holley– and Joseph– phenotypes

DIIIa and DIII Type 5 are encoded by the same allele and are associated with altered RHCE*ce alleles: clinical implications

DNA analysis for the Dombrock polymorphism

Genomic analyses of RH alleles to improve transfusion therapy in patients with sickle cell disease

The JAL antigen (RH48) is the result of a change in RHCE that encodes Arg114Trp

Molecular basis of the Dombrock null phenotype

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