The CD177 c.1291A Allele Leads to a Loss of Membrane Expression and Mimics a CD177-Null Phenotype.

CD177 is a glycosyl phosphatidyl inositol (GPI)-linked, neutrophil-specific glycoprotein that in 3-5% of normal individuals is absent from all neutrophils. The molecular mechanism behind the absence of CD177 has not been unravelled completely. Here, we analyse the impact of the recently described CD177 c.1291G>A variant on CD177 expression. Recombinant CD177 c.1291G>A was expressed in HEK293F cells and its expression on the cell surface, inside the cell, and in the culture supernatant was investigated. The CD177 c.1291G>A protein was characterised serologically and its interaction with proteinase 3 (PR3) was demonstrated by confocal laser scanning microscopy. Our experiments show that CD177 c.1291G>A does not interfere with CD177 protein biosynthesis but affects the membrane expression of CD177, leading to very low copy numbers of the protein on the cellular surface. The mutation does not interfere with the ability of the protein to bind PR3 or human polyclonal antibodies against wild-type CD177. Carriers of the c.1291G>A allele are supposed to be phenotyped as CD177-negative, but the protein is present in soluble form. The presence of CD177 c.1291A leads to the production of an unstable CD177 protein and an apparent "CD177-null" phenotype.

Fetal and neonatal alloimmune thrombocytopenia: No evidence of systemic inflammation as a modulator of disease severity. Could placental inflammation be key?

In fetal/neonatal alloimmune thrombocytopenia (FNAIT), maternal alloantibodies against paternal human platelet antigens (HPA) cross the placenta and lead to platelet destruction. The extent of thrombocytopenia varies among neonates, and inflammation may constitute an important trigger. A set of stable inflammatory markers was measured in serum samples from neonates with low platelet counts, of which n = 50 were diagnosed with FNAIT due to anti-HPA-1a antibodies and n = 50 were thrombocytopenic without detectable maternal HPA antibodies. Concentrations of C-reactive protein, soluble CD14, procalcitonin, and sFlt-1 did not differ between the two cohorts. There was no correlation between C-reactive protein or soluble CD14 and the platelet count, but a negative correlation between procalcitonin concentrations and the neonatal platelet count in both cohorts. sFlt-1 concentration and the platelet count were correlated in FNAIT cases exclusively. None of the inflammatory markers was statistically different between cases with and without intracranial haemorrhage. We were unable to identify systemic inflammation as a relevant factor for thrombocytopenia in FNAIT. The antiangiogenic enzyme sFlt-1, released by the placenta, did correlate with the platelet count in FNAIT cases. Our findings may give rise to the hypothesis that placental inflammation rather than systemic inflammation modulates disease severity in FNAIT.

Naturally occurring point mutation Cys460Trp located in the I-EGF1 domain of integrin ß3 alters the binding of some anti-HPA-1a antibodies.

BACKGROUND: Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is caused by the destruction of platelets in the fetus or newborn by maternal platelet alloantibodies, mostly against human platelet antigen (HPA)-1a. Recent studies indicate that two anti-HPA subtypes exist: Type I reacts with epitopes residing on the plexin-semaphorin-integrin (PSI) and type II with plexin-semaphorin-integrin/integrin epidermal growth factor 1 (I-EGF1) domains of the ß3 integrin. Here, we evaluated whether a Cys460Trp mutation in the I-EGF1 domain found in a patient with Glanzmann thrombasthenia can alter the binding of anti-HPA-1a. METHODS: Stable HEK293 cell lines expressing wild-type and mutant αIIbß3 and αvß3 were generated to prove the reactivity of different antibodies against HPA-1a. RESULTS: Flow cytometry analysis of wild-type (Cys460) and mutant (Trp460) expressed on HEK293 cells showed equal surface expression of αIIbß3 and αvß3. When tested with mutant αIIbß3 cells, reduced binding was observed in Type II but not in Type I anti-HPA-1a. These results could be confirmed with platelets carrying Cys460Trp mutation. Interestingly, reduced binding of Type I antibodies was detected with mutant αvß3 cells. Both antibody types were found in maternal sera from FNAIT cases by an antigen-capture assay with use of HEK293 transfected cells. CONCLUSIONS: These observations confirm the existence of Type I and Type II anti-HPA-1a. Furthermore, this study underlines different immunogenicity of HPA-1a antigen(s) residing on either αIIbß3 or αvß3. Further analysis of FNAIT cases from mothers having a fetus with and without intracranial bleedings with use of such an approach may highlight the functional relevance of different anti-HPA-1a subtypes.

Current Anti-HPA-1a Standard Antibodies React with the ß3 Integrin Subunit but not with αIIbß3 and αvß3 Complexes.

BACKGROUND: Fetal/neonatal alloimmune thrombocytopenia (FNAIT) results from maternal alloantibodies (abs) reacting with fetal platelets expressing paternal human platelet antigens (HPAs), mostly HPA-1a. Anti-HPA-1a abs, are the most frequent cause of severe thrombocytopenia and intracranial hemorrhage (ICH). OBJECTIVES: Titration of anti-HPA-1a in maternal serum using standard National Institute for Biological Standards and Control (NIBSC) 03/152 is one diagnostic approach to predict the severity of FNAIT. Recently, we found three anti-HPA-1a subtypes reacting with the ß3 subunit independently or dependently from complexes with αIIb and αv. Endothelial cell-reactive anti-αvß3 abs were found predominantly in cases with ICH. Our aim was to assess whether available standard material represents all anti-HPA-1a subtypes. MATERIALS AND METHODS: In this study, anti-HPA-1a sera (NIBSC 03/152) and human monoclonal antibodies (moabs) against HPA-1a (moabs 26.4 and 813) were evaluated using transfected cell lines expressing αIIbß3, αvß3 or monomeric cß3. RESULTS: Flow cytometry analyses with well-characterized murine moabs recognizing αIIbß3, αvß3, or ß3 alone demonstrated that AP3 reacts compound-independently, whereas compound-dependent moabs Gi5 and 23C6 reacted only with complexes. NIBSC 03/152, moabs 26.4, and 813 against HPA-1a reacted like AP3, same results were obtained with monomeric cß3 in immunoblotting. Antigen capture assay targeting endothelial cells showed anti-HPA-1a reactivity disappearance after cß3 beads adsorption. Furthermore, in contrast to anti-HPA-1a abs from ICH cases, none of NIBSC 03/152, 26.4, and 813 inhibited tube formation. CONCLUSION: These results suggest that current anti-HPA-1a standard material contains only the anti-ß3 subtype. The absence of anti-αvß3 makes NIBSC 03/152 less suitable as standard to predict the severity of FNAIT.

Immunisation against αIIbß3 and αvß3 in a type 1 variant of Glanzmann's thrombasthenia caused by a missense mutation Gly540Asp on ß3.

Treatment of bleeding in patients with Glanzmann's thrombasthenia (GT) can be hampered by iso-antibodies against the αIIbß3 integrin, which cause rapid clearance of transfused donor platelets. Type 1 GT patients with a total absence of αIIbß3 from the platelet surface are known to be susceptible to form such isoantibodies. In this study, we describe a type 1 GT patient with a missense mutation (Gly540Asn) located in the EGF3 domain of the ß3 integrin subunit. Cotransfection analysis in CHO cells demonstrates total absence of αIIbß3 from the surface, based on inappropriate αIIb maturation. The patient's serum was reactive with αIIbß3 and αvß3 integrins in a capture assay, when platelets and endothelial cells were used. Two specificities could be isolated from the patient's serum, anti-αIIbß3 and anti-αvß3 isoantibodies. Both specificities did not interfere with platelet aggregation. In contrast, isoantibodies against αvß3, but not against αIIbß3, were able to disturb endothelial cell adhesion onto vitronectin, triggered endothelial cell apoptosis and interfered with endothelial tube formation. This intriguing finding may explain more recently observed features of fetal/neonatal iso-immune thrombocytopenia in children from type 1 GT mothers with intracranial haemorrhage, which could be related to anti-endothelial activity of the maternal antibodies. In conclusion, we give evidence that two isoantibody entities exist in type 1 GT patients, which are unequivocally different, both in an immunological and functional sense. Further research on the clinical consequences of immunisation against αvß3 is required, predominantly in GT patients of childbearing age.

Choline Transporter-Like Protein-2: New von Willebrand Factor-Binding Partner Involved in Antibody-Mediated Neutrophil Activation and Transfusion-Related Acute Lung Injury.

OBJECTIVE: In contrast to other antibodies involved in transfusion-related acute lung injury, anti-HNA-3a antibodies are incapable of inducing direct neutrophil activation and seem to interact with endothelial cells (ECs) primarily. In animal studies, anti-HNA-3a-mediated transfusion-related acute lung injury could be precipitated in the absence of neutrophils, but was stronger when neutrophils were present. In a different context the target protein of these antibodies, choline transporter-like protein-2 (CTL-2), was reported to interact with a protein of the inner ear carrying 2 von Willebrand factor (VWF) A-domains. These observations prompted us to investigate whether VWF might be involved in anti-HNA-3a-mediated neutrophil activation, and whether signaling via CD11b/CD18 is involved, as in various other experimental settings. APPROACH AND RESULTS: Cell adhesion demonstrated specific binding of CTL-2 to VWF. Immunoprecipitation analysis of CTL-2/CD11b/CD18 coexpressing cells indicated that anti-HNA-3a colocalizes CTL-2 and CD11b/CD18 when VWF is present. Functional studies revealed that anti-HNA-3a-mediated neutrophil agglutination is an active, protein kinase C-dependent and partially Fc-dependent process. Agglutination and the production of reactive oxygen species seem to require the formation of a trimolecular complex between the target antigen (CTL-2), CD11b/CD18 and VWF. In line with these observations, anti-HNA-3a induced less severe transfusion-related acute lung injury and less neutrophil recruitment to the alveolar space in VWF knockout mice. CONCLUSIONS: We introduce CTL-2 as a new binding partner for VWF. Interaction of neutrophils with VWF via CTL-2 allows anti-HNA-3a to induce signal transduction via CD11b/CD18, which leads to neutrophil activation and agglutination. In transfusion-related acute lung injury, this mechanism may further aggravate endothelial leakage.

Rapid enzyme-linked immunosorbent assay for the detection of antibodies against human neutrophil antigens -1a, -1b, and -1c.

BACKGROUND: Several methods exist for the detection of neutrophil antibodies; most of them, however, require fresh neutrophils. In this study, an enzyme-linked immunosorbent assay (ELISA) using recombinant HNA-1 antigens (rHNAs) was developed to detect HNA-1a, -1b, and -1c alloantibodies in serum samples. STUDY DESIGN AND METHODS: Soluble rHNA-1a, -1b, and -1c were isolated from culture supernatant of transfected insect cells. Purified rHNA antigens were immobilized on microtiter wells using antibody against V5-Tag protein. Sera were added, and bound antibodies were detected by enzyme-labeled secondary antibodies. In parallel, monoclonal antibody-immobilized granulocyte antigen (MAIGA) was performed with two different monoclonal antibodies (MoAbs) against FcγRIIIb (3G8 and BW209). RESULTS: Fifteen MAIGA-positive sera containing HNA-1a alloantibodies were tested in ELISA. Thirteen of 15 (86.7%) MAIGA-positive sera captured by MoAbs 3G8 and/or BW209 reacted specifically with rHNA-1a. Four (26.7%) HNA-1a sera showed additional reaction with rHNA-1c. When anti-HNA-1b alloantibodies were analyzed in ELISA, 13 of 15 (86.7%) showed specific positive reaction with rHNA-1b, and 12 of 15 (80.0%) cross-reacted with rHNA-1c. Two HNA-1c sera reacted specifically with rHNA-1c. Immunoprecipitation analysis of all ELISA-negative HNA-1a and -1b sera did not show any specific band indicating false-positive reaction of these sera in MAIGA assay. CONCLUSIONS: These results suggested that rapid ELISA using recombinant neutrophil antigens may provide a valuable method for rapid screening of human alloantibodies against HNA-1a, -1b, and -1c in patients with neutropenia and in blood donors.

Implication of transfected cell lines for the detection of alloantibodies against human neutrophil antigen-3.

BACKGROUND: Alloantibodies against human neutrophil antigen-3 (HNA-3) are responsible for the fatalities reported in transfusion-related acute lung injury. Consequently, reliable detection of these alloantibodies is mandatory to improve blood transfusion safety. In this study, we developed stable cell lines for the detection of HNA-3 antibodies. STUDY DESIGN AND METHODS: HEK293T were transfected with HNA-3a or HNA-3b constructs and sorted by flow cytometry according to high surface expression. Transfected cells were tested with sera containing HNA-3 antibodies in flow cytometry and antibody capture assay (ACA). The results were compared with granulocyte agglutination test and granulocyte immunofluorescence test. RESULTS: In flow cytometry, 12 of 14 HNA-3a sera reacted specifically with HNA-3aa cells. One serum sample showed positive reaction with HNA-3bb cells. All HNA-3b sera recognized HNA-3bb cells. No reaction was observed with broad reactive antibodies against HLA Class I. In ACA, all HNA-3a sera (12/12) showed positive reactivity with HNA-3aa cells with no cross-reactivity with HNA-3bb cells. Again, all HNA-3b sera reacted with HNA-3bb cells only. Furthermore, genotyping of 249 individuals detected a new HNA-3 allele caused by a nucleotide substitution C>T at Position 457 leading to L(153)F mutation in choline transporter-like protein-2. This mutation impairs polymerase chain reaction with sequence-specific primers based HNA-3a typing. However, analysis with cells expressing F(153) isoform showed that this mutation did not alter the binding of HNA-3 antibodies. CONCLUSIONS: This study demonstrated that HEK293T cells expressing stable recombinant HNA-3 are suitable for the detection of HNA-3 alloantibodies allowing reliable screening of blood products.

Mechanism of transfusion-related acute lung injury induced by HLA class II antibodies.

Transfusion-related acute lung injury (TRALI) is the leading cause of transfusion-associated mortality in the United States and other countries. In most TRALI cases, human leukocyte antigen (HLA) class II antibodies are detected in implicated donors. However, the corresponding antigens are not present on the cellular key players in TRALI: neutrophils and endothelium. In this study, we identify monocytes as a primary target in HLA class II-induced TRALI. Monocytes become activated when incubated with matched HLA class II antibodies and are capable of activating neutrophils, which, in turn, can induce disturbance of an endothelial barrier. In an ex vivo rodent model, HLA class II antibody-dependent monocyte activation leads to severe pulmonary edema in a relevant period of time, whenever neutrophils are present and the endothelium is preactivated. Our data suggest that in most TRALI cases, monocytes are cellular key players, because HLA class II antibodies induce TRALI by a reaction cascade initiated by monocyte activation. Furthermore, our data support the previous assumption that TRALI pathogenesis follows a threshold model. Having identified the biologic mechanism of HLA class II antibody-induced TRALI, strategies to avoid plasma from immunized donors, such as women with a history of pregnancy, appear to be justified preventive measures.

Bernard-Soulier syndrome due to the homozygous Asn-45Ser mutation in GPIX: an unexpected, frequent finding in Germany.

Bernard-Soulier syndrome (BSS) is a rare inherited disorder with giant platelets, thrombocytopenia and a prolonged bleeding time. These abnormalities are caused by genetic defects of the glycoprotein (GP) Ib-IX complex that constitutes the von Willebrand factor receptor on the platelet surface. Here, we describe four unrelated German patients with low platelet counts and mild bleeding tendency. Three patients had been diagnosed with immune thrombocytopenia (ITP) and were treated with steroids without response. Another patient presented with easy bruising. Peripheral blood smears showed giant platelets. Ristocetin-induced platelet aggregation was almost absent, and quantitative flow cytometry and Western blotting disclosed a greatly reduced surface expression of GPIb-IX. Unexpectedly, sequencing the entire coding regions of GPIbalpha, GPIbbeta and GPIX revealed that all four unrelated patients were homozygous for an A to G mutation in position 1826 of the GPIX gene, constituting a Asn-45Ser change. This mutation has been described before and now represents by far the most often identified molecular defect causing BSS in Caucasians. Because BSS patients are likely to be misdiagnosed with ITP, treatment-resistant ITP patients should be re-evaluated thoroughly. Asn-45Ser genotyping may be a helpful tool for differential diagnosis.