Unexpected antibody against the high-prevalence P antigen before cardiac surgery.

P is a high-prevalence antigen present in 99.9 percent of the population and is fully developed at birth. P- individuals form naturally occurring antibodies against P, which are often of immunoglobulin (Ig)M and/or IgG type, very potent in complement activation, and able to cause serious intravascular hemolytic transfusion reactions. Some people with anti-P have the rare P1 k phenotype, which lacks P in the presence of P1 and Pk. Blood transfusion in patients with anti-P is challenging, as is described here. A male patient without a history of blood transfusion was admitted for a planned cardiac surgery. The preoperative ABO blood group could not be determined because of unexpected reactions in the reverse grouping, and all red blood cells (RBCs) in the antibody detection test were positive, except for the autocontrol. Further analysis of the patient's sample confirmed the presence of the P1 k phenotype, and anti-P was identified. If transfusion was needed, P- blood would be required, and the only P- RBCs available were at the national Sanquin Bank of Frozen Blood. These units are limited, expensive, and only available for 48 hours after thawing. In the case of massive blood loss, first ABO and Rh-compatible units should be transfused, followed by P- units after the bleeding stops. In our case, the surgery was conducted without transfusion. This case illustrates the importance of preoperative ABO blood group testing and antibody screening in cases where blood loss can be expected. In recent years, more focus has been put on patient blood management. A good collaboration between the local laboratory, surgery department, and dedicated blood transfusion laboratory is critical to prevent unnecessary incompatible blood transfusions with potentially serious outcomes.

Differential interaction between DARC and SDF-1 on erythrocytes and their precursors.

The Duffy Antigen Receptor for Chemokines (DARC) is expressed on erythrocytes and on endothelium of postcapillary venules and splenic sinusoids. Absence of DARC on erythrocytes, but not on endothelium, is referred to as the Duffy negative phenotype and is associated with neutropenia. Here we provide evidence that stromal cell-derived factor 1 (SDF-1), the chemokine that restricts neutrophil precursors to the bone marrow, binds to erythrocyte progenitors in a DARC-dependent manner. Furthermore, we show that SDF-1 binding to DARC is dependent on the conformation of DARC, which gradually changes during erythroid development, resulting in the absence of SDF-1 binding to mature erythrocytes. However, SDF-1 binding to erythrocytes was found to be inducible by pre-treating erythrocytes with IL-8 or with antibodies recognizing specific epitopes on DARC. Taken together, these novel findings identify DARC on erythrocyte precursors as a receptor for SDF-1, which may be of interest in beginning to understand the development of neutropenia in situations where DARC expression is limited.

Glycophorin-C sialylation regulates Lu/BCAM adhesive capacity during erythrocyte aging.

Lutheran/basal cell adhesion molecule (Lu/BCAM) is a transmembrane adhesion molecule expressed by erythrocytes and endothelial cells that can interact with the extracellular matrix protein laminin-α5. In sickle cell disease, Lu/BCAM is thought to contribute to adhesion of sickle erythrocytes to the vascular wall, especially during vaso-occlusive crises. On healthy erythrocytes however, its function is unclear. Here we report that Lu/BCAM is activated during erythrocyte aging. We show that Lu/BCAM-mediated binding to laminin-α5 is restricted by interacting, in cis, with glycophorin-C-derived sialic acid residues. Following loss of sialic acid during erythrocyte aging, Lu/BCAM is released from glycophorin-C and allowed to interact with sialic acid residues on laminin-α5. Decreased glycophorin-C sialylation, as observed in individuals lacking exon 3 of glycophorin-C, the so-called Gerbich phenotype, was found to correlate with increased Lu/BCAM-dependent binding to laminin-α5. In addition, we identified the sialic acid-binding site within the third immunoglobulin-like domain within Lu/BCAM that accounts for the interaction with glycophorin-C and laminin-α5. Last, we present evidence that neuraminidase-expressing pathogens, such as Streptococcus pneumoniae, can similarly induce Lu/BCAM-mediated binding to laminin-α5, by cleaving terminal sialic acid residues from the erythrocyte membrane. These results shed new light on the mechanisms contributing to increased adhesiveness of erythrocytes at the end of their lifespan, possibly facilitating their clearance. Furthermore, this work may contribute to understanding the pathology induced by neuraminidase-positive bacteria, because they are especially harmful to patients suffering from sickle cell disease and are associated with the occurrence of vaso-occlusive crises.

KEL*02 alleles with alterations in and around exon 8 in individuals with apparent KEL:1,-2 phenotypes.

BACKGROUND AND OBJECTIVES: Antibodies to antigens in the Kell blood group system, especially anti-KEL1, are involved in both haemolytic disease of the newborn and foetus and haemolytic transfusion reactions. Correct typing results are important and discrepancies between serologic and genetic typing must be resolved. Here, we describe the investigation of three healthy individuals who were initially phenotyped as KEL:1,-2. MATERIALS AND METHODS: Antigen typing was performed by standard serological techniques and by flow cytometric analysis. The KEL*01/02 polymorphism was tested by an allele-discrimination TaqMan assay as well as by PCR with allele-specific primers and PCR-RFLP. DNA sequencing of the KEL coding region was also performed. RESULTS: Two KEL*02N alleles with mutated splice sites around exon 8 were identified: intron 7 -1g>c (novel) and intron 8 +1g>t (previously reported in one case of K(0)). In the third sample, a missense mutation in exon 8, 787G>A (novel) predicting Gly263Arg, was detected on a KEL*02 allele and associated with dramatically weakened KEL2 antigen expression. CONCLUSION: Resolution of discrepant phenotype/genotype results identified silencing mutations in or around exon 8. A combination of molecular and serologic methods has the potential to improve the quality of test results and was required to ensure both the accurate KEL2 antigen status and KEL*01 zygosity of these individuals.

Section 1C: Assessment of the functional activity and IgG Fc receptor utilisation of 64 IgG Rh monoclonal antibodies. Coordinator's report.

Sixty-four IgG Rh monoclonal antibodies (Mabs) submitted to the Fourth International Workshop on Monoclonal Antibodies Against Human Red Blood Cells and Related Antigens were characterised and tested in quantitative functional assays at five laboratories. The biological assays measured the ability of anti-D to mediate phagocytosis or extracellular lysis of RBC by IgG Fc receptor (Fc gamma R)-bearing effector cells. Interactions of RBC pre-sensitised with anti-D (EA-IgG) with monocytes in chemiluminescence (CL) assays were found proportional to the amount of IgG anti-D on the RBC. Using antibodies to inhibit Fc gamma RI, Fc gamma RII or Fc gamma RIII, the only receptor utilised in the monocyte CL and ADCC assays for interactions with EA-IgG1 was found to be Fc gamma RI. In these assays, enhanced interactions were promoted by EA-IgG3 and additional Fc gamma receptors may have contributed. IgG2 anti-D was not reactive in these assays and EA-IgG4 promoted weak reactions through Fc gamma RI. A macrophage ADCC assay showed that haemolysis of EA-IgG3 was greater than that of EA-IgG1, mediated mainly through Fc gamma RIII. In ADCC assays using lymphocytes (NK cells) as effector cells and papainised RBC target cells, only a minority of IgG1 anti-D Mabs were shown to be able to mediate haemolysis in the presence of monomeric IgG (AB serum or IVIg). These interactions were mediated solely through Fc gamma RIII. Haemolysis via Fc gamma RIII may depend on the presence of certain sugars on the oligosaccharide moiety of IgG. Most Mabs (IgG1, IgG2, IgG3 and IgG4) elicited intermediate, low or no haemolysis in these assays. Blocking studies indicated that low activity IgG1 and IgG4 anti-D utilised only Fc gamma RI. Other IgG1 and IgG3 Mabs appeared to promote haemolysis through Fc gamma RI and Fc gamma RIII while IgG2 was inhibited by Mabs to both Fc gamma RII and Fc gamma RIII, suggesting a variety of Fc gamma R are utilised for anti-D of low haemolytic activity. Excellent agreement between the results of the lymphocyte ADCC assays and antibody quantitation was observed between the participating laboratories.

Partial expression of RHc on the RHD polypeptide.

BACKGROUND: In the human Rh blood group system, c is, after D, the most immunogenic antigen. STUDY DESIGN AND METHODS: The background of a new partial c phenotype (D(c)), identified on the RBCs of two unrelated white persons, was studied. This was done by analyzing the reactivity of the RBCs from the donors with anti-c reagents, by performing sequence analysis, and by carrying out transduction studies. RESULTS: Serologic results suggested the existence of a new partial c phenotype. Genomic DNA and cDNA analysis revealed a normal RHCe allele, a normal RHD allele, and an RHD allele that carried two point mutations: 307T>C and 329T>C (the latter known to be associated with the DVII, Tar-positive phenotype). No normal RHc allele was found. Thus, it was most likely that c is encoded by the mutated RHD allele (phenotype DD(c)CCee). Indeed, subsequent transduction of K562 erythroleukemic cells with an RHD cDNA carrying the 307T>C point mutation (leading to S103P) resulted in the expression of c. CONCLUSION: In the human Rh system, P103 is involved in the expression of c. Moreover, c can be expressed in vivo on the D polypeptide.

DAR, a new RhD variant involving exons 4, 5, and 7, often in linkage with ceAR, a new Rhce variant frequently found in African blacks.

The highly polymorphic Rh system is encoded by 2 homologous genes RHD and RHCE. Gene rearrangements, deletions, or point mutations may cause partial D and CE antigens. In this study, a new RHD variant, DAR, and a new RHCE variant, ceAR, are described in 4 Dutch African Blacks. Serologically, DAR showed weaker reactions with a monoclonal antibody and polyclonal antiserum against D. The DAR phenotype was characterized by complete loss of at least 9 of 37 Rh D epitopes. Erythrocytes expressing ceAR were all typed as VS(-), V(+). DNA analysis showed a partial D allele with only 3 mutations: C602G (exon 4), T667G (exon 5), and T1025C (exon 7). The ceAR allele carried G48C (exon 1), a hybrid exon 5 (A712G, C733G, A787G, and T800A), and A916G (exon 6). To study the frequency of these variants, 326 South-African Blacks was screened genomically. Of the 326 donors, 16 (4.9%) carried the DAR allele, 20 (6.1%) the ceAR allele, and 14 (4.3%) both mutated alleles. Five of these donors (1.5%) had the DAR phenotype, indicating that they carried the DAR allele homozygously or next to a D-negative allele. Immunogenicity of the D antigen for individuals with the DAR phenotype was proven, because 1 of the 4 Dutch individuals produced allo-antibodies against D after multiple transfusions with D-positive blood. In a multiethnic society, the prevalence of this D phenotype will increase and is therefore relevant in transfusion practice and in prevention of hemolytic disease of the newborn.

Molecular background of VS and weak C expression in blacks.

BACKGROUND: The Rh system is complex and consists of as many as 45 different antigens. Red cells of about 25 percent of the black population carry VS an Rh-system antigen (Rh20), but this antigen is very rare in whites. VS positivity is always associated with a weak expression of e, and usually also of C. STUDY DESIGN AND METHODS: The RH genes of 11 black VS-positive donors were studied. Transcripts were sequenced for four VS-positive donors, three of whom had red cells with a weak expression of C. In the other donors, only analysis of genomic DNA was carried out. RESULTS: The occurrence of VS was shown to be related to a single-point mutation in exon 5 of the RHCE gene (cytosine 733 guanine, leading to the Leu245Val substitution). The presence of this polymorphism in exon 5 may explain the simultaneously occurring weak e, because the E/e polymorphism is located in the same exon. Study of VS-positive donors with different Rh phenotypes showed that the polymorphism can occur in different alleles of the RHCE gene. In all three donors whose red cells showed a weak expression of C, a hybrid D-CE-D transcript was found, containing exon 4, 5, 6, 7, and (probably) 8 from the RHCE gene. No transcripts were encountered carrying DNA markers normally associated with C expression. CONCLUSION: It is therefore postulated that the hybrid gene is responsible for the weak expression of C in these individuals. The hybrid gene carried a Leu62Phe substitution, as well as the Leu245Val substitution responsible for VS. The gene most probably cosegregates with a C allele encoding Cys 16 (normally encoded only by the C allele) and Val245 (responsible for VS antigenicity when encoded by the RHCE gene). This explains the combination of weak expression of C and VS positivity that is frequently found in blacks.

Involvement of Gly96 in the formation of the Rh26 epitope.

BACKGROUND: The Rh system, a complex blood group system, comprises at least 45 antigens. Red cells expressing c usually express Rh26. Rare cells that are c+ Rh:-26 give variable reactions with anti-c and may have weak expression of f (ce). STUDY DESIGN AND METHODS: Serologic and molecular studies were performed with red cells from persons with the c+ Rh:-26 phenotype occurring in two unrelated Dutch families. Red cells of 11 members of these two families were typed for Rh26, for c (with monoclonal and polyclonal reagents), and for f (ce). The cDNA of three donors was sequenced, while restricted DNA analysis was carried out on material from available members of the two families. RESULTS: Serologic tests showed that the rare c+ Rh:-26 phenotype was associated with a weak expression of c and a normal expression of f. The cDNA analysis of three members of one family revealed a single-point mutation (G286A) in exon 2 of the ce allele. Allele-specific primer amplification, polymerase chain reaction followed by allele-specific restriction analysis, and single-strand conformation polymorphism showed the same polymorphism in all other members of both families, whereas it was absent in 80 control donors. CONCLUSION: The c+ Rh:-26 phenotype, identified in two families, is associated with a single-point mutation at nucleotide 286 (G286A) in the ce allele, which predicts a Gly96Ser amino acid substitution. This substitution also affects c, because all anti-c reagents reacted more weakly. Other polymorphic sites apparently are involved in the formation of the Rh26 epitope as well, because Rh26 is expressed only on the c polypeptide, whereas Gly96 is expressed on all polypeptides.