A large deletion spanning XG and GYG2 constitutes a genetic basis of the Xgnull phenotype, underlying anti-Xga production.

BACKGROUND: The PBDX/XG gene encoding the Xga blood group antigen was described in 1994, but the genetic determinant of XG expression on RBCs was reported only in 2018. However, the frequencies of Xg(a-) individuals could not explain the rarity of anti-Xga makers. We therefore sought to elucidate the molecular basis of the Xg(a-) phenotype in people producing anti-Xga . STUDY DESIGN AND METHODS: Two genomic DNA (gDNA) and 13 plasma-derived cell-free DNA (cfDNA) samples from anti-Xga makers were investigated (14 males and one female). PBDX/XG exon sequencing was attempted on one gDNA sample. Polymerase chain reaction assays were developed and bioinformatics used to define a suspected deletion in all samples. RESULTS: Investigation of one gDNA sample revealed a 114-kb deletion (esv2662319) on the X chromosome that spans XG exons 4 through 10 and the downstream GYG2 gene. A 3555-bp fragment bridging this deletion was amplified to confirm its presence. Another deletion-specific polymerase chain reaction of 714 bp enabled identification of esv2662319 in both gDNA samples and eight cfDNA samples while ruling it out in one cfDNA. Males were hemizygous for esv2662319 and the female likely homozygous. Four cfDNA sample results were inconclusive, probably due to poor sample quality. Sanger sequencing recognized the recombination junctions as a heterogeneous LTR6B sequence. CONCLUSION: We identified a large deletion on the X chromosome, resulting in a true, tissue-wide Xgnull phenotype. This deletion was found in 10 of 11 anti-Xga makers from which DNA could be amplified. One sample remained unexplained, indicating further heterogeneity to be explored.

Dombrock genotyping in a native Congolese cohort reveals two novel alleles.

BACKGROUND: Since variant alleles in the Dombrock (DO) blood group system are common in Africans, DNA typing of DO alleles in an uninvestigated Congolese Teke ethnic group was performed. STUDY DESIGN AND METHODS: DO exons were polymerase chain reaction amplified, using genomic DNA extracted from blood samples, and sequenced. Membrane expression in K562 cells transduced with DO-cDNAs using lentiviral vectors was studied by flow cytometry. Amino acid changes were mapped on the protein structure, predicted by homology modeling. RESULTS: In 41 samples investigated, there were 56 DOB or DOB-WL (68%), 15 DOA (18%), 6 HY (7%), and 3 JO (4%) alleles. The remaining two alleles were novel, that is, DOB-SH-Gln149Lys carrying a 445C>A transversion and DOB-(WL)-Ile175Asn showing a 524T>A transversion on a DOB or DOB-WL background. Transduced K562 cells revealed that DOB-SHGln149Lys variant was expressed to the same extent as DOB-SH but to a lesser extent than the DOB control. The DOB-Ile175Asn variant shows equivalent expression to DOB but is not recognized by monoclonal antibodies MIMA-53. As deduced from the protein model, these missense changes would lead to structure similar to the wild-type one, with only modified surface features. CONCLUSION: Molecular screening of Teke individuals revealed a high frequency of HY and JO alleles and two novel alleles, one on the DOB (or DOB-WL) and one on the DOB-SH background. Expression studies highlighted the impact of changes on Do protein expression. These findings suggest that allelic diversity is greater than expected and that expression level of DO alleles should be taken into account in transfusion

Murine monoclonal anti-s and other anti-glycophorin B antibodies resulting from immunizations with a GPB.s peptide.

BACKGROUND: The blood group antigens S and s are defined by amino acids Met or Thr at position 29, respectively, on glycophorin B (GPB). Commercial anti-s reagents are expensive to produce because of the scarcity of human anti-s serum. Our aim was to develop hybridoma cell lines that secrete reagent-grade anti-s monoclonal antibodies (MoAbs) to supplement the supply of human anti-s reagents. STUDY DESIGN AND METHODS: Mice were immunized with the GPB(s) peptide sequence TKSTISSQTNGETGQLVHRF. Hybridomas were produced by fusing mouse splenocytes with mouse myeloma cells (X63.Ag8.653). Screening for antibody production was done on microtiter plates by hemagglutination. Characterization of the MoAbs was done by hemagglutination, immunoblotting, and epitope mapping. RESULTS: Eight immunoglobulin G MoAbs were identified. Five antibodies are specific by hemagglutination for s and two MoAbs, when diluted, are anti-S-like, but additional analyses shows a broad range of reactivity for GPB. Typing red blood cells (RBCs) for s from 35 donors was concordant with molecular analyses as were tests on RBCs with a positive direct antiglobulin test (DAT) from 15 patients. The anti-s MoAbs are most reactive with peptides containing the (31)QLVHRF(36) motif, with (29)Thr. By Pepscan analyses, the anti-S-like MoAbs reacted within the same regions as did anti-s, but independently of (29)Met. One antibody was defined serologically as anti-U; however, its epitope was identified as (21)ISSQT(25), a sequence common for both GPA and GPB. CONCLUSION: In addition to their value as typing reagents, these MoAbs can be used to phenotype RBCs with a positive DAT without pre-test chemical modification.

Mouse models of IgG- and IgM-mediated hemolysis.

Well-characterized mouse models of allo-immune antibody-mediated hemolysis would provide a valuable approach for gaining greater insight into the pathophysiology of hemolytic transfusion reactions. To this end, mouse red blood cells (mRBCs) from human glycophorin A transgenic (hGPA-Tg) donor mice were transfused into non-Tg recipients that had been passively immunized with IgG or IgM hGPA-specific monoclonal antibodies (mAbs). In this novel murine "blood group system," mRBCs from hGPA-Tg mice are "antigen positive" and mRBCs from non-Tg mice are "antigen negative." Passive immunization of non-Tg mice with the IgG1 10F7 and IgG3 NaM10-2H12 anti-hGPA mAbs each induced rapid clearance of incompatible transfused hGPA-Tg-mRBCs in a dose-response manner. Using various knockout mice as transfusion recipients, both the complement system and activating Fcgamma receptors were found to be important in the clearance of incompatible mRBCs by each of these IgG mAbs. In addition, the IgM E4 anti-hGPA mAb induced complement-dependent intravascular hemolysis of transfused incompatible hGPA-Tg-mRBCs accompanied by gross hemoglobinuria. These initial studies validate the relevance of these new mouse models for addressing important questions in the field of transfusion medicine.

The production of red blood cell alloantibodies in mice transfused with blood from transgenic Fyb-expressing mice.

BACKGROUND: A murine model would be useful to identify which immune mechanisms could be manipulated to treat or prevent red blood cell (RBC) alloimmunization in patients who become sensitized to multiple or widely expressed antigens. STUDY DESIGN AND METHODS: Transgenic mice (B6CBAF1/J-Tg-Fy(b)) expressing the human Fy(b) antigen of the Duffy (Fy) blood group were donors. Recipient B6CBA-F1 mice received four weekly intravenous (IV) transfusions: either 0.3 mL of washed buffy coat-depleted RBCs or 0.3 mL of RBCs with spleen cells. Titers of immunoglobulin M (IgM) and immunoglobulin G (IgG) were measured in recipient serum samples by flow cytometry with RBCs from donor mice as target cells. Recipient serum samples were also tested against human RBCs of various Fy phenotypes. Additionally, RBC survival studies were performed in alloimmunized mice utilizing biotin-labeled Fy(b) transgenic mouse RBCs. RESULTS: B6CBA-F1 mice receiving washed buffy coat-depleted RBCs first made IgM, followed by IgG alloantibodies to transgenic mouse Fy(b)-positive RBCs. Recipients of Fy(b)-positive RBCs mixed with spleen cells also produced IgM and IgG alloantibodies, but at a slower rate than recipients of washed buffy coat-depleted RBCs. Serum samples showed specificity for Fy3, Fy(b), and Fy6. Decreased survival of transfused RBCs was evident at 24 hours after transfusion. CONCLUSIONS: It is possible to elicit the formation of anti-Fy alloantibodies by IV transfusion in mice that lack Fy antigens. The transfusion of RBCs alone was adequate to stimulate alloantibody production in B6CBA-F1 recipient mice. The survival of transfused Fy(b)-positive RBCs is diminished in sensitized mice. This model will be useful in further studies of RBC alloimmunization.

A panel of monoclonal antibodies recognizing GPI-anchored ADP-ribosyltransferase ART4, the carrier of the Dombrock blood group antigens.

ART4 (CD297) is a member of the family of toxin-related ADP-ribosyltransferases (ARTs) and is the carrier of the Dombrock blood group alloantigens (Do). Two mouse monoclonal antibodies (MIMA-52 and MIMA-53), and two rat monoclonal antibodies (N0NI-B4 and NONI-B63) were obtained following immunization of mice with human Do/ART4-transfected cells and of rats with human Do/ART4 cDNA, respectively. All four mAbs recognize Do/ART4-transfected Jurkat cells but not untransfected cells by FACS analysis. Staining of Do/ART4-transfected cells by these mAbs was reduced following treatment of cells with PI-PLC, confirming that Do/ART4 is anchored in the cell membrane by linkage to glycosylphosphatidylinositol as predicted from its amino acid sequence. The four mAbs did not react with Gy(a-) (Dombrock null) erythrocytes but agglutinated other red blood cells. By flow cytometric analysis, all mAbs reacted prominently with erythrocytes, and weakly with peripheral blood monocytes and splenic macrophages, but not with B-lymphocytes or T-lymphocytes. The mAbs reacted weakly also with human umbilical vein endothelial cells and the basophilic leukemia KU-812. Immunohistology revealed staining of epithelia and endothelia on sections of tonsils. In FACS analyses NONI-B4 competed with MIMA-52 for binding to Do/ART4-transfected cells and erythrocytes, whereas NONI-B63 competed with MIMA-53. Neither of the mAbs reacted with mouse ART4-transfected cells, but NONI-B63 and MIMA-53 did react with a mouse/human ART4 chimera, indicating that the epitope recognized by these mAbs lies in the C-terminal half of the protein.

The Fya, Fy6 and Fy3 epitopes of the Duffy blood group system recognized by new monoclonal antibodies: identification of a linear Fy3 epitope.

Four new anti-Duffy murine monoclonal antibodies (MAbs): two anti-Fy6 (MIMA-107 and MIMA-108), one anti-Fya (MIMA-19) and one anti-Fy3 (MIMA-29) were characterized. Identification of epitopes by means of synthetic peptides (Pepscan) showed that the anti-Fy6 reacted most strongly with peptides containing the sequence 19QLDFEDV25 of the Duffy glycoprotein, and less strongly with peptides containing LDFEDV (MIMA-107) or LDF only (MIMA-108). The anti-Fya recognized epitope 38DGDYGA43 containing the Gly42 residue, which defines the Fya blood group antigen. MIMA-29 is the first anti-Fy3 reactive with a linear epitope 281ALDLL285 located in the fourth extracellular domain (ECD4, loop 3) of the Duffy glycoprotein. The four new antibodies extend the list of six anti-Fy MAbs formerly characterized by Pepscan analysis that allow some general conclusions. Fine specificities of various anti-Fya, or anti-Fy6 are not identical, but all of them recognize linear epitopes located around, respectively, Gly42 or between two potential N-glycosylation sites at Asn16 and Asn27. Anti-Fy3 recognize either a linear epitope located in ECD4, or a conformational epitope that includes amino acid residues of ECD4 and of other ECDs.