Rejuvenation of RBCs: validation of a manufacturing method suitable for clinical use.

BACKGROUND: Rejuvenation of stored red blood cells (RBCs) increases levels of adenosine 5'-triphosphate (ATP) and 2,3-diphosphoglycerate (2,3-DPG) to those of fresh cells. This study aimed to optimize and validate the US-approved process to a UK setting for manufacture and issue of rejuvenated RBCs for a multicenter randomized controlled clinical trial in cardiac surgery. STUDY DESIGN AND METHODS: Rejuvenation of leukoreduced RBC units involved adding a solution containing pyruvate, inosine, phosphate, and adenine (Rejuvesol, Zimmer Biomet), warming at 37°C for 60 minutes, then "manual" washing with saline adenine glucose mannitol solution. A laboratory study was conducted on six pools of ABO/D-matched units made the day after donation. On Days 7, 21, and 28 of 4 ± 2°C storage, one unit per pool was rejuvenated and measured over 96 hours for volume, hematocrit, hemolysis, ATP, 2,3-DPG, supernatant potassium, lactate, and purines added (inosine) or produced (hypoxanthine) by rejuvenation. Subsequently, an operational validation (two phases of 32 units each) was undertaken, with results from the first informing a trial component specification applied to the second. Rejuvenation effects were also tested on crossmatch reactivity and RBC antigen profiles. RESULTS: Rejuvenation raised 2,3-DPG to, and ATP above, levels of fresh cells. The final component had potassium and hemolysis values below those of standard storage Days 7 and 21, respectively, containing 1.2% exogenous inosine and 500 to 1900 µmoles/unit of hypoxanthine. The second operational validation met compliance to the trial component specification. Rejuvenation did not adversely affect crossmatch reactivity or RBC antigen profiles. CONCLUSION: The validated rejuvenation process operates within defined quality limits, preserving RBC immunophenotypes, enabling manufacture for clinical trials.

Neonatal alloimmune thrombocytopenia due to a new alloantigen Bl(a) defined by an Asp458Gly substitution in GPIIIa.

BACKGROUND: Neonatal alloimmune thrombocytopenia (NAIT) commonly arises due to antibodies against a small number of well-defined human platelet antigens (HPAs). A minority of NAIT cases occur due to maternal immunization against low-frequency polymorphisms in platelet glycoprotein that result in new immunogenic epitopes. Antibodies to these novel epitopes can be detected by the incubation of maternal serum with paternal platelets and is usually performed after initial investigation using HPA-typed panel platelets has failed to provide evidence of NAIT. STUDY DESIGN AND METHODS: The propositus and the parents from a case of suspected neonatal alloimmune thrombocytopenia (NAIT) were investigated using serologic and molecular techniques to detect and identify relevant platelet-specific antibodies and for HPA typing. Calculations of molecular dynamics were undertaken to explore potential variations in the molecular structure. RESULTS: Maternal antibodies were detected that were reactive only in crossmatch with paternal platelets using the platelet immunofluorescence test (PIFT) and a GPIIb/IIIa monoclonal antibody immobilization of platelet antigen (MAIPA) assay. In the propositus and father, a novel mutation c.1373 A > G was found in exon 10 of ITGB3 resulting in the substitution of an aspartic acid for a glycine (p.Asp458Gly). Recombinant GPIIIa glycoprotein mutated to contain the novel mutation and expressed in HEK293 cells with GPIIb was also specifically recognized by maternal antibodies. Calculations of molecular dynamics identified that the mutation was in a structurally constrained site. CONCLUSION: This case describes a low-frequency platelet antigen (Asp458Gly) that defines a further alloantigenic target in NAIT. The case emphasizes the role of the platelet crossmatch as the single most useful tool to establish evidence of immunization of low-frequency platelet glycoprotein polymorphisms. A crossmatch should always be performed where there is strong clinical evidence of NAIT but initial laboratory investigations are not confirmatory.

A V740L mutation in glycoprotein IIb defines a novel epitope (War) associated with fetomaternal alloimmune thrombocytopenia.

BACKGROUND: Most recently described human platelet antigens (HPAs) have been detected in cases of fetomaternal alloimmune thrombocytopenia (FMAIT) where the mother has been immunized against a low-frequency antigen that the fetus has inherited from the father. Low-frequency antigens are not represented in normal panel platelets (PLTs) and antibody detection and identification in such cases requires incubation of maternal serum with paternal PLTs and definition of the causative mutation. STUDY DESIGN AND METHODS: A suspected case of FMAIT was investigated for PLT-specific antibodies using a panel of both HPA-typed and paternal PLTs. HPA typing was performed by polymerase chain reaction with sequence-specific primers and further DNA analysis was performed using direct sequencing of the coding regions of the ITGA2B and ITGB3 genes. RESULTS: Maternal antibodies reactive only with paternal PLTs were localized to glycoprotein (GP)IIb/IIIa using the monoclonal antibody immobilization of PLT antibody assay. A single-nucleotide polymorphism was detected in Exon 23 of ITGA2B in the father and affected child, which predicted a V740L substitution in the mature protein. Recombinant V740L mutated GPIIb expressed in HEK293 cells was specifically recognized by maternal antibodies. The polymorphism was not detected either in the mother or in a cohort of 100 donors. CONCLUSION: The V740L polymorphism defines a new low-frequency antigen implicated in two cases of FMAIT in a single family. Low-frequency HPAs are clinically important and their elucidation requires both crossmatch studies and gene sequencing in cases where there is strong clinical evidence of FMAIT but initial laboratory investigations do not support the diagnosis.

Detection of HNA-3a and -3b antibodies using transfected cell lines and recombinant proteins.

BACKGROUND: HNA-3 is a diallellic system located on choline transporter-like protein 2 (CTL2), defined by a polymorphism at Amino Acid 154. HNA-3a antibodies are of clinical importance in transfusion-related acute lung injury but antibody detection requires labor-intensive granulocyte isolation from HNA-typed donors and the use of techniques such as the granulocyte agglutination test or granulocyte immunofluorescence test. Also, there is no commercial test for detection of HNA-3 antibodies. STUDY DESIGN AND METHODS: HEK293 cells were transfected to generate stable cell lines expressing CTL2 fragments (Amino Acids 55-230) and full-length membrane bound CTL2 with HNA-3a and -3b epitopes. Soluble fragments were used in enzyme-linked immunosorbent assays to detect HNA-3 antibodies. The cell lines expressing full-length proteins were trypsin treated to remove HLA antigens and frozen at -80°C. Thawed cells were then used to detect HNA-3 antibodies by flow cytometry. RESULTS: Glycosylated and soluble CTL2 fragments were correctly recognized by 15 of 31 anti-HNA-3a sera and by both available anti-HNA-3b sera. Twenty-one anti-HLA sera reacted variably with untreated cell lines expressing full-length CTL2. After trypsin treatment of the cell lines, reactivity with HLA antisera was abrogated and all 31 anti-HNA-3a and two anti-HNA-3b sera bound to the corresponding cell line. CONCLUSION: Whereas soluble, glycosylated CTL2 fragments cannot be used for the detection of HNA-3 antibodies, the HEK293 cells expressing full-length CTL2 proteins were useful in the detection of HNA-3 antibodies even in the presence of HLA antibodies. Moreover, the cell lines can be stored for at least 6 months before use.

Critical band 3 multiprotein complex interactions establish early during human erythropoiesis.

Band 3, the major anion transport protein of human erythrocytes, forms the core of a multiprotein complex in the erythrocyte membrane. Here we studied the spatiotemporal mechanisms of band 3 multiprotein complex assembly during erythropoiesis. Significant pools of intracellular band 3 and Rh-associated glycoprotein (RhAG) were found in the basophilic erythroblast. These intracellular pools decreased in the polychromatic erythroblast, whereas surface expression increased and were lowest in the orthochromatic erythroblast and reticulocytes. Protease treatment of intact cells to remove extracellular epitopes recognized by antibodies to band 3 and RhAG was used to study surface delivery kinetics and intracellular complex composition from the proerythroblast stage to the enucleated reticulocyte. Newly synthesized band 3 and protein 4.2 interact initially in the early stages of the secretory pathway and are found associated at the plasma membrane from the basophilic stage of erythropoiesis. Although we could successfully coimmunoprecipitate Rh with RhAG from plasma membrane pools at a similar stage, no intracellular interaction between these proteins was detectable. Knockdown of RhAG during early erythropoiesis was accompanied by a concomitant drop in membrane expression of Rh polypeptides. These data are consistent with assembly of major components of the band 3 macrocomplex at an early stage during erythropoiesis.