Relevance of the HPA-15 (Gov) polymorphism on CD109 in alloimmune thrombocytopenic syndromes

BACKGROUND: Alloantibodies against the human platelet (PLT) alloantigen (HPA)-15 system residing on CD109 can cause fetal and neonatal alloimmune thrombocytopenia (FNAIT), posttransfusion purpura, and PLT transfusion refractoriness. The detection of antibodies against HPA-15, however, is hampered by the variable low expression and instability of the CD109 molecule during preparation and storage. STUDY DESIGN AND METHODS: This study analyzed the occurrence of HPA-15 alloantibodies in 1403 patients: 930 FNAIT and 473 polytransfused (PT) patients by modified monoclonal antibody specific immobilization of PLT antigens (MAIPA) assay with well-defined phenotyped PLTs. A DNA typing technique was developed to confirm the phenotypes of PLT donors. B-cell lines were established as sources of reference DNA. RESULTS: Genotyping of 407 unrelated blood donors revealed the gene frequencies 0.512 and 0.488 for HPA-15a and -15b, respectively. Based on the selection of PLTs expressing high amounts of CD109 on the surface (mean fluorescence intensity ratio 4-5 on expression peak on Days 2-4 after apheresis) antibody screening by the MAIPA assay was performed. In total, 16 (1.1%) HPA-15 alloantibodies were found comprising four anti-HPA-15a and 12 anti-HPA-15b. Anti-HPA-15b without other PLT-reactive antibodies were detectable in three serum samples of PT patients. The incidence of HPA-15 alloimmunization in PT patients was significantly higher than in mothers with FNAIT (3.0% vs. 0.22%). In relation to all detected HPA-specific antibodies, HPA-15 is responsible for 6.2 percent of alloimmunizations. CONCLUSION: These observations indicate that alloimmunization against HPA-15 should be considered as a cause for immune thrombocytopenia, particularly in patients receiving multiple PLT transfusions.     

Low-avidity anti-HPA-1a alloantibodies are capable of antigen-positive platelet destruction in the NOD/SCID mouse model of alloimmune thrombocytopenia

BACKGROUND: Neonatal alloimmune thrombocytopenia (NAIT) is mostly caused by maternal antibodies against human platelet antigen 1a (HPA‐1a) expressed on glycoprotein (GP) IIb/IIIa. Accumulated evidence indicated that anti‐HPA‐1a could be overlooked by standard methods due to low avidity. Low‐avidity HPA‐1a antibodies were shown to be detectable by surface plasmon resonance (SPR). We sought to investigate the frequency and in vivo relevance of low‐avidity anti‐HPA‐1a. STUDY DESIGN AND METHODS: A retrospective cohort consisting of 82 HPA‐1bb mothers of HPA‐1ab newborns with thrombocytopenia was analyzed using standard serologic methods. Maternal immunoglobulin (Ig)G fractions were investigated for low‐avidity antibodies in SPR using purified GPIIb/IIIa (HPA‐1a or ‐1b). The capability of HPA‐1a antibodies to clear platelets (PLTs) in vivo was analyzed using the NOD/SCID mouse model of alloimmune thrombocytopenia. RESULTS: HPA antibodies were detectable in sera from 68 of 82 (83%) mothers using standard serologic methods and undetectable in 14 of 82 sera. In SPR, IgG fractions of sera reacting positive in monoclonal antibody immobilization of PLT antigen (MAIPA) assay showed specific binding to an HPA‐1a flow cell (mean, 87 ± 21 resonance units [RU]). When MAIPA‐negative sera were tested in SPR, binding with low avidity was observed in 7 of 14 to HPA‐1a (mean, 31 ± 5 RU), but not to HPA‐1b flow cell (mean, 5 ± 2 RU). In vivo, low‐avidity antibodies were capable of clearing HPA‐1ab PLTs but not HPA‐1bb PLTs in a NOD/SCID mouse model. Elimination kinetics were slower than observed with MAIPA‐positive antibodies. CONCLUSIONS: Low‐avidity HPA‐1a antibodies are present in a significant number of NAIT cases and, although they can escape detection by standard serology, they harbor the capability of PLT destruction in vivo.     

Rapid detection of HPA-1 alloantibodies by platelet antigens immobilized onto microbeads

BACKGROUND: Neonatal alloimmune thrombocytopenia (NAIT) is one of the most common bleeding disorders in neonates. It occurs when alloantibodies from an immunized mother react with paternally inherited alloantigens, mostly human platelet antigen 1a (HPA-1a), on the fetal platelets (PLTs). Currently, monoclonal antibody-immobilized PLT antigen (MAIPA) assay represents the standard technique for the serologic diagnosis of NAIT. MAIPA is time-consuming, however, and limited by the availability of monoclonal antibodies (MoAbs). Here, a gel antigen-specific assay (GASA) was developed, which allows rapid detection of HPA-1 alloantibodies without the use of MoAbs. STUDY DESIGN AND METHODS: Glycoprotein (GP) IIb/IIIa was purified by affinity chromatography from outdated PLT concentrates derived from HPA-1aa or HPA-1bb donors. Purified GPs were biotinylated, immobilized onto streptavidin beads, and used for the analysis of HPA-1a alloantibodies by a microtyping system. HPA-1a serum samples derived from mothers with NAIT (n = 36) and from posttransfusion purpura patients (n = 2) as well as HPA-1b (n = 4), HPA-5b (n = 2), HPA-3a (n = 4), and HLA Class I (n = 2) alloantiserum samples from multitransfused patients were investigated in GASA and MAIPA assays. RESULTS: GASA was able to detect all HPA-1a and -1b alloantibodies recognized by MAIPA. Cross-reactivity with other PLT-reactive alloantibodies was not observed. Interestingly, 3 of 36 serum samples, which showed only moderate reactivity in MAIPA, reacted strongly in GASA. CONCLUSION: GASA has proved to be a rapid method for the detection of HPA-1a alloantibodies and maybe useful for PLT antibody screening, especially in initial assessment of suspected NAIT cases.     

Heterogeneity of HPA-3 alloantibodies: consequences for the diagnosis of alloimmune thrombocytopenic syndromes

BACKGROUND: Immunization against the human platelet alloantigen (HPA)-3a residing on alphaIIbbeta3 integrin accounts for approximately 2 percent of fetal and neonatal alloimmune thrombocytopenia (FNAIT). Anti-HPA-3a alloantibodies are sometimes difficult to detect and can be overlooked by standard antigen capture assays. STUDY DESIGN AND METHODS: The reactivity of 12 anti-HPA-3a and 2 anti-HPA-3b alloantibodies from patients with FNAIT and posttransfusion purpura was analyzed by serologic (monoclonal antibody-specific immobilization of platelet antigens [MAIPA] assay, flow cytometry) and immunochemical (immunoprecipitation, immunoblotting) techniques. The influence of platelet (PLT) age, storage conditions, recombinant antigens from Chinese hamster ovary (CHO) cells, and sialic acids (treatment with neuraminidase) were analyzed. RESULTS: The most sensitive anti-HPA-3 alloantibody detection in MAIPA assay could be achieved with fresh homozygous PLTs. During a PLT storage period of 14 days before use, three types of anti-HPA-3 alloantibodies were found: 1) complete loss of reactivity (n = 6), 2) considerably weakened reaction (> or =50% reduction; n = 3), and 3) minor reduction of reactivity (< or =40% decrease; n = 5). When cryopreserved PLTs were used, 10 of 12 anti-HPA-3a and all anti-HPA-3b alloantibodies reacted positive. Only 6 of 10 serum samples reacted with recombinant HPA-3a on CHO cells. Neuraminidase treatment of PLTs showed that some anti-HPA-3a alloantibodies require the presence of sialic acids. The storage lesion seems to be related to cleavage of sialic acids. Immunochemical analysis revealed evidence that most anti-HPA-3a alloantibodies require an intact three-dimensional alphaIIbbeta3 integrin structure. CONCLUSIONS: Anti-HPA-3 alloantibodies show considerable heterogeneity, which may hamper the serologic diagnosis of FNAIT. Preservation of the alphaIIbbeta3 integrin and protection from enzymatic degradation seem to be important during PLT storage.     

Platelet-specific alloantigens and antibodies in Tunisian women after three or more pregnancies

Pregnancy may allow alloimmunization against human platelet antigens (HPA), which can lead to neonatal alloimmune thrombocytopenia (NAIT). The specificities of alloantibodies are closely related to the distribution of the HPA systems. A total of 281 Tunisian multiparous women (mean number of pregnancies: 4.5) were phenotyped for the HPA-1, -3 and -5 systems, by monoclonal antibody immobilization of platelet antigens (MAIPA). We searched for antibodies against HPA-1a, HPA-3a, HPA-5b and HPA-5a in HPA-1b1b, HPA-3b3b, HPA-5a5a and HPA-5b5b individuals, respectively. The gene frequencies were: 0·83 for HPA-1a, 0·17 for HPA-1b, 0·78 for HPA-3a, 0·22 for HPA-3b, 0·82 for HPA-5a and 0·18 for HPA-5b. Anti-HPA-5b antibodies were present in eight sera and anti-HPA-3a antibodies were present in one serum. The anti-HPA-5b system is the most frequently involved in platelet alloimmunization in Tunisian multiparous women. However, prospective trials are required to confirm this result and to determine the exact frequencies and clinical relevance of platelet alloantibodies in pregnant Tunisian women.     

Frequency and specificity of platelet-specific alloantibodies in HLA-immunized haematologic–oncologic patients

The frequency and specificity of platelet-alloantibodies to human platelet antigens (HPA) -1, -3 and -5 was investigated in 59 multitransfused, HLA-immunized patients. Using the MAIPA test (monoclonal antibody specific immobilization of platelet antigens) platelet alloantibodies could be demonstrated in 10 (17%) patients.   In one patient the antibody was present prior to any transfusions and probably induced by multiple previous pregnancies. This antibody was directed to HPA-5b. The remaining nine antibodies were found in patients ( n  = 36) with HLA-antibodies reacting with over 95% of unselected lymphocytes. In these patients the target antigens were HPA-1b in six, HPA-3a in one and both antigens in two patients.   Our findings demonstrate platelet alloimmunization induced by transfusions to be restricted to patients with high HLA-immunization. 25% of these patients (9/36) show platelet-specific antibodies, primarily HPA-1b.     

Alloantibodies against low-frequency human platelet antigens do not account for a significant proportion of cases of fetomaternal alloimmune thrombocytopenia: evidence from 1054 cases

BACKGROUND: Maternal alloantibodies against the five common human platelet antigen (HPA) systems (HPA-1 to -3, -5, and -15) are found in only 20% of cases referred for fetal and neonatal thrombocytopenia (FMAIT) investigations. The question asked was whether mismatches for the remaining 11 low-frequency HPAs (HPA-4 and -6bw to -17bw) might in part explain the remaining 80% of cases.
STUDY DESIGN AND METHODS: A total of 1054 paternal DNA samples from referred FMAIT cases (among which 223 cases where antibodies against a common HPA were found) were genotyped for 11 low-frequency HPAs as well as a recently discovered polymorphism ( ITGA2B -C2320T). The initial genotyping was carried out by TaqMan and potential heterozygotes were confirmed by DNA sequencing. Clinical and serologic data were collected for each case with a heterozygote father.
RESULTS: In total, eight heterozygous fathers were identified: four for HPA-6w, one each for HPA-10w and -11w, and two for HPA-12w. Maternal antibodies against the corresponding antigen were identified in four of the eight cases. In two of these cases, antibodies against HPA-1a and HPA-1b were also found.
CONCLUSION: It was concluded that the minor alleles of HPA-4 and -6bw to -17bw are exceptionally rare in the Caucasian population and therefore do not explain the large number of FMAIT referrals which test negative for the common HPA antibodies.     

Blockade of maternal anti-HPA-1a–mediated platelet clearance by an HPA-1a epitope–specific F(ab')2 in an in vivo mouse model of alloimmune thrombocytopenia

BACKGROUND: Neonatal alloimmune thrombocytopenia (NAIT) is most commonly caused by transplacental passage of maternal human platelet-specific alloantigen (HPA)-1a antibodies that bind to fetal platelets (PLTs) and mediate their clearance. SZ21, a monoclonal antibody (MoAb) directed against PLT glycoprotein IIIa, competitively inhibits the binding of anti-HPA-1a alloantibodies to PLTs in vitro. The purpose of this investigation was to determine whether SZ21 F(ab')₂ fragments might be therapeutically effective in inhibiting or displacing maternal HPA-1a antibodies from the fetal PLT surface and preventing their clearance from circulation.
STUDY DESIGN AND METHODS: Resting human PLTs from HPA-1ab heterozygous donors were injected into nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice. Purified F(ab')₂ fragments of SZ21 or control immunoglobulin G (IgG) were injected intraperitoneally 30 minutes before introduction of HPA-1a antibodies. Blood samples were taken periodically and analyzed by flow cytometry to determine the percentage of circulating human PLTs.
RESULTS: Anti-HPA-1a IgG from NAIT cases were able to efficiently clear HPA-1a–positive PLTs from murine circulation. Administration of SZ21 F(ab')₂ fragments not only inhibited binding of HPA-1a antibodies to circulating human PLTs, preventing their clearance, but also displaced bound HPA-1a antibodies from the PLT surface.
CONCLUSION: F(ab')₂ fragments of HPA-1a–selective MoAb SZ21 effectively inhibit anti-HPA-1a–mediated clearance of human PLT circulating in an in vivo NOD/SCID mouse model. These results suggest that agents that inhibit binding of anti-HPA-1a to PLTs may have therapeutic potential in the treatment of NAIT.     

Fetal and Neonatal Alloimmune Thrombocytopenia—New Prospects for Fetal Risk Assessment of HPA-1a–Negative Pregnant Women

Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is a rare and potentially serious bleeding condition in the fetus/newborn. FNAIT is usually considered as the platelet counterpart of hemolytic disease of the fetus and newborn. In FNAIT, maternal alloantibodies against paternally inherited platelet antigens traverse the placenta and cause thrombocytopenia in the fetus/newborn. The most common and most serious cases of FNAIT among white people are caused by alloantibodies against the human platelet antigen 1a (HPA-1a), which is absent in 2.3% of women. Today, there is no screening for FNAIT, and for this reason, FNAIT is not suspected until an otherwise healthy child, born at term, presents with thrombocytopenia. Clinical management of subsequent pregnancies at risk of FNAIT is mostly based on the obstetric history. During the last 5 decades, hemolytic disease of the fetus and newborn caused by antibodies against RhD has successfully been prevented by administration of hyperimmune anti-D IgG drug products to RhD-negative women after delivery of an RhD-positive child. Similarly, a hyperimmune anti–HPA-1a IgG (NAITgam) is under development for the prevention of HPA-1a immunization and FNAIT. If NAITgam becomes licensed for FNAIT prophylaxis and national health authorities decide to include FNAIT screening in their antenatal health care programs, it will be necessary to improve today's tools for assessing the risk of FNAIT. Although the primary risk factor for HPA-1a immunization is platelet type HPA-1bb, not all HPA-1a–negative women develop anti–HPA-1a. The women who are HLA-DRB3:01:01 negative (72%) only rarely develop anti–HPA-1a, and for those few who become HPA-1a immunized, it is quite rare to have a child with severe thrombocytopenia. Determination of fetal HPA-1 type is important because 15% of HPA-1a–negative women will carry an HPA-1a–negative fetus and therefore not be at risk of FNAIT. The severity of FNAIT seems to be associated with the level of anti–HPA-1a. Hence, in Norway, for example, an Ab threshold of 3 IU/mL is used to distinguish between low- and high-risk pregnancies. The current review will discuss to what extent these analyses, as well as determination of subtypes of anti–HPA-1a (anti-β3, anti-αIIbβ3, and anti-αvβ3) and Fc core fucosylation of anti–HPA-1a IgG, can be used as risk stratification tools.     

The first case of alloantibody against human platelet antigen‐15b in Japan: possible alloimmunization by a hydatidiform mole

BACKGROUND: The involvement of the human platelet antigen (HPA)‐15 system in neonatal alloimmune thrombocytopenia (NAIT) has been reported in various populations, but not in the Japanese population. In Japan, the mixed passive hemagglutination assay (MPHA) is used for detection of HPA alloantibodies. However, most of the reported cases of HPA‐15 incompatibility are based on the monoclonal antibody immobilization of platelet antigen (MAIPA) assay or immunoprecipitation; thus there is a possibility that HPA‐15 alloantibodies are not efficiently detected by the MPHA, and currently, the causative antibody is not detectable in approximately half of the suspected NAIT cases in Japan. STUDY DESIGN AND METHODS: We examined the sera of mothers from NAIT cases, previously with undetected HPA antibodies by MPHA, using the MAIPA technique. Sera from 90 mothers of suspected NAIT were tested by MAIPA for the presence of anti‐HPA‐15 alloantibodies. RESULTS: Anti‐HPA‐15b was detected in one case. This case was a mother in the first pregnancy diagnosed as hydatid mole–coexisting fetus, and the baby was born with suspected NAIT. The familial analysis revealed compatibility of HPA‐15 genotype between the mother and the baby (both HPA‐15a/a), but incompatibility with the paternal one (HPA‐15a/b). The hydatid mole's tissue was genotyped as HPA‐15b positive. Besides anti‐HPA‐15b, maternal sera contain strong HLA Class I antibody CONCLUSIONS: Here we reported the first case of anti‐HPA‐15 in Japan. Alloimmunization against the hydatid mole seems to be responsible for the production of HPA‐15b alloantibody. This antibody, however, did not apparently involve in the development of NAIT of the newborn, the coexisting anti‐HLA Class I being the possible cause.     

A simple and practical assay for the antigen-specific detection of platelet antibodies

BACKGROUND: The antigen-specific assays currently used for characterization of platelet (PLT)-reactive auto- and alloantibodies are too technically complex and impracticable for most routine laboratories. Here, a novel antigen-specific particle assay (ASPA) for PLTs similar to that of red blood cells is described. STUDY DESIGN AND METHODS: PLTs were solubilized and then incubated with red-dyed polystyrene particles coated with monoclonal antibodies (MoAbs) to various PLT glycoprotein complexes. These particles were directly tested for coating with autoantibodies (n = 8) or indirectly tested for serum autoantibodies (n = 33) or alloantibodies against HPA-1a (n = 4) or HPA-5b (n = 5). Serum samples from healthy blood donors (n = 100) served as negative controls. RESULTS: Negative reactions were clearly distinguishable from positive reactions, and the results of the particle assay were in concordance with those obtained by the standard MoAb-specific immobilization of PLT antigen assay (MAIPA) in all cases with alloanti-bodies. In three patients, only the ASPA was able to detect autoantibodies that were completely undetectable by the MAIPA. In contrast, in only one patient, the MAIPA detected autoantibodies that the ASPA failed to detect. CONCLUSION: In our opinion, the new ASPA is reliable, yet less complex and time-consuming than the currently available assays, and it can be implemented in any routine laboratory.     

Epidemiology and management of fetal and neonatal alloimmune thrombocytopenia

Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is a disease in pregnancy characterized by maternal alloantibodies directed against the human platelet antigen (HPA). These antibodies can cause intracranial hemorrhage (ICH) or other major bleeding resulting in lifelong handicaps or death. Optimal fetal care can be provided by timely identification of pregnancies at risk. However, this can only be done by routinely antenatal screening. Whether nationwide screening is cost-effective is still being debated. HPA-1a alloantibodies are estimated to be found in 1 in 400 pregnancies resulting in severe burden and fetal ICH in 1 in 10.000 pregnancies. Antenatal treatment is focused on the prevention of fetal ICH and consists of weekly maternal IVIg administration. In high-risk FNAIT treatment should be initiated at 12–18 weeks gestational age using high dosage and in standard-risk FNAIT at 20–28 weeks gestational age using a lower dosage. Postnatal prophylactic platelet transfusions are often given in case of severe thrombocytopenia to prevent bleedings. The optimal threshold and product for postnatal transfusion is not known and international consensus is lacking. In this review practical guidelines for antenatal and postnatal management are offered to clinicians that face the challenge of reducing the risk of bleeding in fetuses and infants affected by FNAIT.     

Evaluation of an enzyme-linked immunosorbent assay kit (GTI PakPlus) for the detection of antibodies against human platelet antigens

Twenty-six serum samples from 24 patients were investigated for the presence of platelet-specific antibodies in a partly retrospective (n = 15) and partly prospective (n = 9) study. The sera contained either alloantibodies to human platelet antigens (HPA) (n = 23) or were from clinically suspected cases of fetomaternal alloimmune thrombocytopenia (FMAITP) in which platelet-specific antibodies had not been detected (n = 3). Three techniques were used to detect platelet antibodies: the platelet immunofluorescence test, the monoclonal antibody immobilization of platelet antigens (MAIPA) assay and a commercially available enzyme-linked immunosorbent assay--GTI PakPlus (GTI kit). Two alkaline phosphatase-conjugated antiglobulin reagents provided by the manufacturer were used in the GTI kit: an antihuman IgG/IgA/IgM (IgGAM) conjugate and an antihuman IgG conjugate. The GTI kit with the anti-IgGAM conjugate failed to detect eight antibody specificities in seven sera (anti-HPA-1a [n = 3], anti-HPA-3a [n = 1], anti-HPA-3b [n = 1] and anti-HPA-5b [n = 3]). Greater signal-to-background ratios were achieved in the GTI kit with the anti-IgG conjugate but five antibody specificities (anti-HPA-1a [n = 1], anti-HPA-3a [n = 1], anti-HPA-3b [n = 1], anti-HPA-5b [n = 2]) remained undetectable. All the sera were detected by MAIPA assay and, furthermore, the MAIPA assay achieved the greatest signal-to-background ratio in the majority of sera tested. These findings re-emphasize the value of the MAIPA assay in reference laboratories and illustrate that the GTI kit may either fail to detect or incorrectly identify clinically significant HPA antibodies.     

The detection of platelet antibodies by simultaneous analysis of specific platelet antibodies and the monoclonal antibody–specific immobilization of platelet antigens: an interlaboratory comparison

BACKGROUND: Glycoprotein (GP)‐specific platelet (PLT) antibodies can cause allo‐ or autoimmune thrombocytopenia. Their detection is of high diagnostic value. The simultaneous analysis of specific PLT antibodies (SASPA) assay is based on simultaneous detection of various PLT‐specific antibodies by flow cytometry and has entered routine use in our Mannheim institution. In this study, we performed an interlaboratory comparison investigation of PLT‐specific antibodies using SASPA versus the “gold standard,” the monoclonal antibody–specific immobilization of PLT antigen (MAIPA) assay. STUDY DESIGN AND METHODS: Sera from 194 patients with suspected PLT allo‐ or autoantibodies were tested against GPIIb/IIIa, IX, Ia/IIa, IV, and HLA Class I by SASPA (in Mannheim) and MAIPA (in Vienna). All data were reported blinded to those from the respective other method. Sensitivity studies included dilution studies with known antibodies against HPA‐1a, ‐1b, ‐3b, ‐5b, and ‐15b and HLA Class I. RESULTS: Overall, results were concordant in 78.9%. The specificity and sensitivity of SASPA, based on the MAIPA results, were 97.3 and 86.3%, respectively, for the detection of alloantibodies. The respective results for the detection of autoantibodies were 95.3 and 44.9%. Serial dilution experiments with sera containing anti‐HPA1a, ‐1b, ‐3b, ‐5b, and ‐15b and anti‐HLA Class I revealed a higher sensitivity of the SASPA assay with all alloantibodies. CONCLUSION: In this first blind interlaboratory comparison, SASPA yielded similar results to those of MAIPA. The SASPA assay may be superior to the MAIPA assay for the detection of weak alloantibodies while simultaneous detection of a variety of antibody specificities or immunoglobulin classes and the need of fewer PLTs are obvious advantages.     

Neonatal alloimmune thrombocytopenia due to anti-HPA 5a in a HPA-5a homozygous neonate

The most frequently involved antigen in severe fetal and neonatal alloimmune thrombocytopenia (FNAIT) is the human platelet antigen 1a. Cases of FNAIT caused by HPA-5a antigen are extremely rare, and usually not severe. We report a case of FNAIT caused by anti-HPA antibodies directed to the HPA-5a antigen. The thrombocytopenia was moderate with a minimal platelet count of 36 × 10⁹/L by day 3, and spontaneously resolved by day 10.The pregnancy had been obtained by in vitro fertilization using embryo donation, creating a complete genetic disparity between the HPA 5b5b mother and the HPA 5a5a homozygous neonate.The use of ART with gamete donation can increase the risk and the severity of alloimmune thrombocytopenia and must be considered in new and subsequent pregnancies.     

Foetal and neonatal alloimmune thrombocytopenia – The role of the HLA-DRB3*01:01 allele for HPA-1a-immunisation and foetal/neonatal outcome

Foetal and neonatal alloimmune thrombocytopenia (FNAIT) is the platelet counterpart of haemolytic disease of the foetus and newborn. Among Caucasians, around 80 % of FNAIT cases and some of the most severe cases, are caused by alloantibodies against the human platelet antigen 1a (HPA-1a). For around 3 decades it has been known that almost all HPA-1a-immunised women are HLA-DRB3*01:01 positive. The HLA molecule encoded by the HLA-DRA/DRB3*01:01 genes seems to be of crucial importance for initiating the immune response against HPA-1a. The HLA-DRB3*01:01 carrier status is not only important as a risk factor for immunisation, but does also have a significant impact on foetal/neonatal outcome. The possible role of HLA-DRB3*01:01 typing as tool for risk stratification is discussed.     

Immunization against a low-frequency human platelet alloantigen in fetal alloimmune thrombocytopenia is not a single event: characterization by the combined use of reference DNA and novel allele-specific cell lines expressing recombinant antigens

BACKGROUND: Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is caused by maternal immunization against a fetal platelet (PLT) alloantigen. In cases of FNAIT attributed to low-frequency PLT alloantigens, the laboratory diagnosis is often hampered by the lack of adequate PLTs. STUDY DESIGN AND METHODS: Three families with maternal immunization against fetal PLT antigens were analyzed. In Family 1, previous immunization of another female or woman has been observed. In Families 2 and 3, newborns presented with the typical clinical picture of FNAIT. Genotyping was performed by polymerase chain reaction-restriction fragment length polymorphism and direct sequencing with reference to DNA from Epstein-Barr virus-transformed B-lymphoblastoid cell lines. Antibodies were characterized by glycoprotein (GP)-specific immunoassay with a panel of stable Chinese hamster ovary cell lines expressing low-frequency alloantigens. RESULTS: In three families, maternal immunization associated with the low-frequency alloantigens human PLT antigen (HPA)-8bw (Sra), HPA-11bw (Groa), and HPA-13bw (Sita) was identified. Maternal serum samples showed positive reactions in an antigen capture assay with cell lines carrying recombinant GP IIb/IIIa (HPA-8bw and -11bw) or GPIa/IIa (HPA-13bw), respectively. These results could be confirmed by genotyping analysis of fathers and newborns. CONCLUSION: This study demonstrates that cases of FNAIT attributed to low-frequency PLT alloantigens cannot be regarded as single events. The availability of reference DNA and cell lines expressing recombinant PLT alloantigens can facilitate their identification.     

Detection of human platelet antigen-1a alloantibodies in cases of fetomaternal alloimmune thrombocytopenia using recombinant β3 integrin fragments coupled to fluorescently labeled beads

BACKGROUND: Testing for alloantibodies against human platelet antigens (HPAs) is essential for the clinical diagnosis of fetomaternal alloimmune thrombocytopenia (FMAIT), posttransfusion purpura, and platelet (PLT) refractoriness. Most of the methods currently used for HPA alloantibody detection rely on the availability of panels of HPA‐typed PLTs and some rely on validated monoclonal antibodies (MoAbs) against the PLT glycoproteins. Recombinant β3 integrins displaying the HPA‐1a (rHPA‐1a) or HPA‐1b (rHPA‐1b) epitopes have been produced as an alternative source of antigen. The suitability of these integrin fragments was evaluated for the development of an HPA‐1a alloantibody screening assay, using Luminex xMAP technology. STUDY DESIGN AND METHODS: A 3‐plex bead assay was developed by coupling biotinylated rHPA‐1a, rHPA‐1b, and recombinant glycoprotein VI to LumAvidin microspheres. Forty patient samples referred for FMAIT diagnostic testing, which were previously screened by the MoAb‐specific immobilization of PLT antigens (MAIPA) assay, were used to assess the assay. RESULTS: The rHPA‐1a‐ and rHPA‐1b‐coupled beads were able to detect HPA‐1a and HPA‐1b alloantibodies in all patient samples tested that were previously confirmed to contain HPA‐1‐specific antibodies. Furthermore, HLA Class I antibodies did not cross‐react with the coupled beads. CONCLUSION: The 3‐plex bead assay can be used to detect HPA‐1a antibodies with sufficient specificity and sensitivity for use in the clinical setting of FMAIT. The development of other recombinant integrin fragments with the use of Luminex xMAP technology may assist in providing more rapid HPA antibody detection, enabling prompt diagnosis of alloimmune PLT disorders.     

External quality assessment of platelet serology and human platelet antigen genotyping: a 10-year review

BACKGROUND: In this review, the results of an external quality assessment (EQA) over 10 years of platelet (PLT) serology and of human platelet antigen (HPA) polymorphisms genotyping are shown. The detection and identification of PLT antibodies and the distinction between PLT-specific antibodies and HLA Class I antibodies are evaluated. STUDY DESIGN AND METHODS: Each year, serum samples from five patients and four donor blood samples for DNA typing were distributed. Laboratories could participate as a screening laboratory (SL; n = 7) or as an identification laboratory (IL; n = 8). RESULTS: SLs scored 57 to 100 percent correct positive and 91 to 100 percent correct negative results in the detection of PLT-specific antibodies. SLs only using a PLT immunofluorescence test (PIFT) scored less well than those using a PLT glycoprotein-based antibody detection method. ILs scored 70 to 100 percent correct positive and 87 to 100 percent correct negative results for, respectively, the detection and identification of PLT-specific antibodies. Both the specificity and the sensitivity for the detection and identification of PLT-specific antibodies were not as good in ILs using solid-phase enzyme-linked immunosorbent assay methods as in those using the monoclonal antibody immobilization of PLT antigens (MAIPA) assay. For HPA-1, -2, -3, and -5 genotyping, incorrect results were observed only twice in 280 genotyping assays. CONCLUSION: The data underscore the necessity of using the most accurate methods with a high level of knowledge, experience, and technical training. For screening purposes, it is not sufficient to use only the PIFT, whereas for identification of PLT-specific antibodies, the MAIPA assay is the superior assay.     

Febrile nonhaemolytic transfusion reaction caused by antibodies against human platelet antigen 5a

Anti-human platelet antigens (HPA) alloantibodies are seldom involved in febrile nonhaemolytic reactions (FNHTRs). We describe a case in which anti-HPA-5a alloantibodies are related to an FNHTR. We studied the specificity of the alloantibodies by flow cytometry, ELISA and MACE. Typing of donors and the patient was performed by sequence-specific polymerase chain reaction. The alloantibodies were found reactive with HPA-5a antigens. The patient was HPA-5b/b, whereas the donor of the platelet apheresis involved in the FNHTR was HPA-5a/a. Despite the low frequency of anti-HPA-5a antibodies, they might be responsible for FNHTR.