Characterization of a new human monoclonal antibody directed against the Vel antigen.

BACKGROUND AND OBJECTIVES: The Vel blood group antigen is a poorly characterized high-prevalence antigen. Until now, anti-Vel antibodies have been observed in only alloimmunized Vel-negative individuals. In this study, we aimed to establish a human hybridoma cell line secreting the first anti-Vel monoclonal antibody (mAb), clone SpG213Dc. MATERIALS AND METHODS: Peripheral blood lymphocytes from a French Vel-negative woman with anti-Vel in her plasma were transformed with Epstein-Barr virus and then hybridized with the myeloma cell line Sp2/O-Ag14 using the polyethylene glycol (PEG) method. A specific anti-Vel mAb was successfully produced and was extensively characterized by serological, flow cytometry and Western blot analyses. RESULTS: One human anti-Vel-secreting clone was produced and the secreted anti-Vel mAb (SpG213Dc) was examined. The specificity of the SpG213Dc mAb was assessed by its reactivity against a panel of nine genotyped RBCs including, respectively, three Vel-negative and six Vel-positive (three wild-type homozygous and three heterozygous) samples using flow cytometry method. Vel-positive RBCs were specifically stained and were subsequently used to perform Western blot and immunoprecipitation analysis of the Vel antigen. CONCLUSION: Serological characterization of the new monoclonal anti-Vel SpG213Dc showed a heterogeneous level of expression of the Vel antigen on the different RBCs. Our results suggest that the mAb SpG213Dc can be reliably used as a blood grouping reagent, thus allowing the mass-scale phenotyping of blood donors to strengthen rare blood banks with Vel-negative RBC units.

Gene conversion events between GYPB and GYPE abolish expression of the S and s blood group antigens.

BACKGROUND AND OBJECTIVE: The locus specifying the MNS blood group system is composed of three highly homologous genes, glycophorin A (GYPA), B (GYPB) and E (GYPE). While more than 20 hybrid genes between GYPA and GYPB have been identified, no hybrid genes between GYPB and GYPE have been reported so far. We serendipitously identified GYPB-E-B hybrid genes by studying three individuals whose rare S-s- blood phenotype failed to be predicted by our genotyping platform. MATERIALS AND METHODS: Long-range PCR amplification and extended Sanger sequencing were required to identify and characterize these GYPB-E-B hybrid genes. A PCR assay was developed to detect them in individual or pooled gDNA samples. RESULTS: The first S-s- proband appeared to have two silenced GYPB alleles, one harbouring the so-called P2 mutation and one harbouring GYPE Pseudoexon E4 in place of GYPB Exon B4 (GYPB-E-B hybrid). The two other S-s- probands were homozygous or hemizygous for other GYPB-E-B hybrid alleles, which also lack GYPB Exon B4 and thus do not carry the S/s polymorphism. CONCLUSION: The three GYPB-E-B hybrid genes reported here constitute the first evidence of recombination events between GYPB and GYPE. As these GYPB-E-B hybrid genes drive the S-s- blood phenotype, it is important to know they are a limitation for the current blood group genotyping methods, including those performed by commercial platforms.

The ABCB6 mutation p.Arg192Trp is a recessive mutation causing the Lan- blood type.

BACKGROUND AND OBJECTIVE: The membrane transporter ABCB6 has recently been shown to carry the high-frequency red-blood-cell (RBC) antigen Lan. All the Lan- individuals genotyped so far have inherited two recessive null mutations in ABCB6. The finding of a family with the Lan- blood type occurring in two successive generations prompted this study. METHODS: Mutations in ABCB6 were searched by Sanger sequencing of exons and flanking intronic regions. Expression analysis of the Lan antigen was carried out by serology and flow cytometry. PCR-RFLP genotyping and Western blot analysis were also applied. RESULTS: All the Lan- members of this family were homozygous for c.574C>T, p.Arg192Trp in ABCB6 while the Lan+ members were heterozygous for this missense mutation encoded by the SNP rs149202834. Homozygosity for p.Arg192Trp was associated not only with absence of the Lan antigen, but also of the ABCB6 transporter in RBC membrane. The complete absence of Lan expression resulting from p.Arg192Trp homozygosity was confirmed by the subsequent identification of five unrelated Lan- individuals who were homozygous for this mutation and who developed an anti-Lan. We also provide evidence that three other single amino acid mutations in ABCB6 (c.826C >T, p.Arg276Trp; c.85_87delTTC, p.Phe29del; c.1762G >A, p.Gly588Ser) may also define ABCB6 null alleles. CONCLUSION: p.Arg192Trp is the first ABCB6 missense mutation causing the Lan- blood type and appears to be a relatively frequent cause of this rare blood type. Like the previously reported frameshift, nonsense and essential splice-site mutations in ABCB6, this missense mutation is recessive and defines an ABCB6 null allele. Other single amino acid mutations in ABCB6 may also cause the Lan- blood type.

A new AQP1 null allele identified in a Gypsy woman who developed an anti-CO3 during her first pregnancy.

BACKGROUND AND OBJECTIVES: The Colton blood group antigens are carried by the AQP1 water channel. AQP1(-/-) individuals, also known as Colton-null since they express no Colton antigens, do not suffer any apparent clinical consequence but may develop a clinically significant alloantibody (anti-CO3) induced by transfusion or pregnancy. Identification and transfusion support of Colton-null patients are highly challenging, not only due to the extreme rarity of this phenotype, the lack of appropriate reagents in most laboratories, as well as the possibility of confusing it with the recently described CO:-1,-2,3,-4 phenotype where AQP1 is present. This study investigated a new Colton-null case and evaluated three commercially available anti-AQP1s to identify Colton-null red blood cell samples. METHODS: The Colton-null phenotype was investigated by standard serological techniques, AQP1 sequencing, immunoblot and flow cytometry analyses. RESULTS: We identified and characterized the Colton-null phenotype in a Gypsy woman who developed an anti-CO3 during her first pregnancy. After developing a simple and robust method to sequence AQP1, we showed that she was apparently homozygous for a new AQP1 null allele, AQP1 601delG, whose product is not expressed in her red blood cells. We also established the Colton specificity of three commercially available anti-AQP1s in immunoblot and/or flow cytometry analyses. CONCLUSION: This Gypsy woman represents the sixth Colton-null case characterized at the serological, genetic and biochemical levels. The validation here of new reagents and methods should facilitate the identification of Colton-null individuals.

Transfusion of rare cryopreserved red blood cell units stored at -80 degrees C: the French experience.

The technology allowing freezing of RBC units has been available for many decades. The high-glycerol method for RBC storage at -8 degrees C is predominantly used. Several studies have shown satisfactory results regarding the in vitro viability and function of cryopreserved RBCs. RBC freezing is nowadays mostly encountered in rare blood programs and military deployments. Preservation time of frozen RBCs appears to be virtually indefinite, but most countries apply a 10-year outdate. There is no mandatory time restriction in France. The National Rare Blood Bank currently includes 962 (17.5%) RBC units aged to years or more and 153 (2.8%) aged 20 years or more. Since 1994, 1957 RBC units have been thawed and transfused, among which 118 were aged 10 years or more and 8 were aged 20 years or more. Discarding RBC units older than to years may be highly sensitive for very rare blood groups, e.g., U-, of which approximately 30 percent of the cryopreserved units are aged to years or more. However, the lack of nucleic acid testing for HIV and HCV may be problematic for old RBC units drawn from donors who were not subsequently tested for these markers, which is now mandatory in most countries. Regarding the 118 transfused RBC units older than 10 years, no evidence of hemolysis of thawed RBCs and no transfusion reaction, clinical or biologic hemolysis, or transfusion ineffectiveness was reported, either by any of the parties involved in the transfusion supply of rare RBC units or through the French hemovigilance program, which requires a mandatory report of any transfusion reaction. It has recently been suggested to extend the 10-year restriction in some countries. Considering our experience and observational data, we may consider it safe and efficient to transfuse rare frozen RBC units older than 10 years. An international consensus for RBC cryopreservation time should ideally be established.

[The red blood cell antigen terminologies]. / Les nomenclatures de groupes sanguins érythrocytaires.

Since the discovery of blood groups in humans, several hundred new red blood cell antigens have been identified. Multiple terminology modes have been used to denote each new antigen identified, but without any consistent rules, nor international consensus. This was largely due to the many discoverers of these antigens, using either letters of the alphabet, numbers, part of the patient or donor's name, place of discovery or animal names. Besides, alternative terminologies for the Rh system were implemented in the middle of the twentieth century (Rosenfield, Fisher-Race, Wiener). The International Society of Blood Transfusion described for the first time in 1980 the advantages of an alphanumeric and homogeneous nomenclature, keeping with the genetic bases of blood groups, as well as a classification of all RBC antigens within several families. A variant of this new terminology, exclusively numerical, was simultaneously established, mainly designed for computer data exchange. Nearly 30 years later, 308 red blood cell antigens are described within 30 systems, 12 collections, one 700 series and one 901 series of blood groups. Any person involved in the field of immuno-haematology must master both the usual and international nomenclatures. The Wiener nomenclature used for Rh haplotypes, still largely used today, is also important to be known. The systematic use of the international nomenclature should be strongly encouraged, either in the labelling of blood products, clinical laboratory reports or blood type cards.

[Genotyping of blood group systems at the CNRGS. I: FY, JK, MNS systems]. / Génotypage des systèmes de groupe sanguin d'intérêt transfusionnel au CNRGS. I: les systèmes FY, JK, MNS.

AIM OF THE STUDY: Determination of blood group antigens from data obtained by using molecular methods (genotyping) has become an indispensable tool in the specialized immunohematology laboratories. The French National Reference Centre for Blood group typing (CNRGS) routinely performs genotyping of the FY, JK and MNS system (common genotyping), providing a phenotype deduced from genotyping data for FY1, FY2, JK1, JK2, MNS3 and MNS4 antigens. PATIENTS AND METHODS: We performed a study to evaluate the common genotyping prescriptions referred to the CNRGS over the last three years. RESULTS: Between February 2006 and February 2009, the CNRGS performed 2392 genotyping, including 981 common genotyping. Analysis of 172 common genotyping performed in 2008 showed that 63.8% of the prescriptions expressed a genotyping demand. Of the latter, 42.7% were genotyping prescriptions only, whereas 57.2% were prescriptions of genotyping associated with alloantibody identification. All prescriptions refer to blood group genotyping indications issued from guidelines, with no incorrect prescription, that are patients transfused within four months before blood sampling in 63.6% of cases or a positive direct antiglobulin test in 24.5% of cases. Lastly, 36% of the blood samples referred to the CNRGS had no genotyping prescription. Yet, common genotyping was performed by the CNRGS to get complete immunohematology data for antibody identification. CONCLUSION: Usefulness of blood group genotyping in specialized immunohematology laboratories is obvious. However, the strategy for implementation of molecular methods remains to be defined. Use of high-throughput DNA analysis should change our way of working.

Management of the blood supply for a Jk(a-b-) patient with an anti-Jk3 in preparation for an urgent heart transplant: An illustrative example of a successful international cooperation.

The Kidd blood group system currently comprises two polymorphic and antithetical antigens, Jka and Jkb, and one high-prevalence antigen, Jk3. Jknull individuals do not express any of the Kidd antigens, and are at risk of developing an anti-Jk3 which is known to be dangerous and responsible for acute or delayed hemolytic transfusion reaction. We report a case of an immunized Jknull patient, who was scheduled to undergo a heart transplant. In order to organize his blood provision management, two conference calls were held between the clinical team and the different staff involved in this challenging blood supply. In light of the blood needs, the available resources, and the constraints, a mix of fresh and frozen units were used. As the supply from France was not sufficient, Finland and New Zealand provided the majority of the fresh units. We report here how this international supply chain was organized, including the difficulties that we encountered. Anticipation, communication and flexibility were essential in making this heart transplant possible without needing to transfuse incompatible units.

[The rare blood groups: a public health challenge]. / Les phénotypes érythrocytaires rares: un enjeu de santé publique.

A rare blood group is usually defined as the absence of a high prevalence antigen or the absence of several antigens within a single blood group system, if its prevalence in France is 4/1000 or less in the general population. An individual with a rare blood phenotype can develop a naturally-occurring or immune antibody corresponding to his rare specificity. In case an extremely low stock of compatible blood is available at the national level, a so-called "transfusion deadlock" is described. Most of the individuals with a rare blood group are coincidently identified when a routine pretransfusion testing or pregnancy follow-up is performed, if the antibody(ies) corresponding to the rare specificity is(are) present. Other individuals are discovered following a systematic red cell typing, or family investigations in siblings. One hundred and twenty-one rare blood specificities and 42 rare blood genotypes are currently defined at the French National Reference Laboratory for Blood Groups (CNRGS-Paris). The French national registry of individuals with a rare blood phenotype/genotype includes about 9600 people, who are urged to regularly donate blood for the National Rare Blood Bank. This bank, based on a homologous blood transfusion program, is in charge of the long-term storage of rare frozen blood units, that can only be delivered after receiving authorization from the CNRGS. The global and individual care management of the individuals with a rare blood group, concerning potentially several hundred thousand people in France, requires a close cooperation between all the protagonists within the transfusion chain.

How to mitigate the risk of inducing transfusion-associated adverse reactions.

Transfusion has become extremely safe but can still be associated with adverse reactions. Some adverse reactions can be mitigated by applying measures to donor selection, the process of separating blood components as well as hospital-based procedures consisting in matching the donor and the recipient; special attention is given to optimizing the best fit between the component and the beneficiary, which is not only an immuno-hematological challenge (fresh versus old blood, testing for certain viruses such as CMV, parvovirus B19, etc.). Considerable progress has also been achieved to strengthen the overall quality and safety of the whole transfusion chain. Guidelines and recommendations have resulted in substantial progress, and the recent revisiting of patients as part of a more holistic approach has enabled blood management programs to be created. Such programs, when wisely applied in a context of optimal blood use, reinforce patient safety; they enhance hospital recognition of transfusion and hemovigilance specialists as useful players acting in the interests of patients in full compliance with hospital budgets. This review considers the step-by-step processes that reinforce transfusion safety and identifies hurdles that cannot yet be properly addressed; it proposes steps for further progress, in light of personalized medicine.

Transfusion-associated hazards: A revisit of their presentation.

As a therapy or a support to other therapies, despite being largely beneficial to patients in general, transfusion it is not devoid of some risks. In a moderate number of cases, patients may manifest adverse reactions, otherwise referred to as transfusion-associated hazards (TAHs). The latest French 2016 haemovigilance report indicates that 93% of TAHs are minor (grade 1), 5.5% are moderate (grade 2) and 1.6% are severe (grade 3), with only five deaths (grade 4) being attributed to transfusion with relative certainty (imputability of level [or grade] 1 to 3). Health-care providers need to be well aware of the benefits and potential risks (to best evaluate and discuss the benefit-risk ratio), how to prevent TAHs, the overall costs and the availability of alternative therapeutic options. In high-income countries, most blood establishments (BEs) and hospital blood banks (HBBs) have developed tools for reporting and analysing at least severe transfusion reactions. With nearly two decades of haemovigilance, transfusion reaction databases should be quite informative, though there are four main caveats that prevent it from being fully efficient: (ai) reporting is mainly declarative and is thus barely exhaustive even in countries where it is mandatory by law; (aii) it is often difficult to differentiate between the different complications related to transfusion, diseases, comorbidities and other types of therapies in patients suffering from debilitating conditions; (aiii) there is a lack of consistency in the definitions used to describe and report some transfusion reactions, their severity and their likelihood of being related to transfusion; and (aiv) it is difficult to assess the imputability of a particular BC given to a patient who has previously received many BCs over a relatively short period of time. When compiling all available information published so far, it appears that TAHs can be analysed using different approaches: (bi) their pathophysiological nature; (bii) their severity; (biii) the onset scheme; (biv) a quality assessment (preventable or non-preventable); (bv) their impact on ongoing therapy. Moreover, TAHs can be reported either in a non-integrative or in an integrative way; in the latter case, presentation may also differ when issued by a blood establishment or a treating ward. At some point, a recapitulative document would be useful to gain a better understanding of TAHs in order to decrease their occurrence and severity and allow decision makers to determine action plans: this is what this review attempts to make. This review attempts to merge the different aspects, with a focus on the hospital side, i.e., how the most frequent TAHs can be avoided or mitigated.

[Difficulties of the care of public antigen alloimmunization]. / Difficultés de la prise en charge de l'allo-immunisation anti-public.

Alloimmunization against high-frequency erythrocyte antigens is a problematic situation in terms of laboratory diagnosis, transfusion and obstetrical management. We report the case of a pregnant woman alloimmunized against public Ag. We detail the difficulties of alloantibody (Ab) identification and transfusion management of the deliveries. A 29-year-old pregnant woman was hospitalized in gynecology and obstetrics departments at 36 weeks of gestation for assessment of hydrops fetalis. Antibody identification test revealed the presence of a pan-reactive antibody. Investigations realized in CNRGS (Paris) concluded in anti-GE2+anti-RH3+autoantibody. The red cell phenotype was GE: -2,3. A therapeutic interruption of the pregnancy was indicated. A program of autologous transfusion was organized with withdrawal of 2 units of blood. The 2nd pregnancy took place normally. Before delivery, an autologous blood reserve consisting of 2 red cell packs and 2 fresh frozen plasma was withdrawn and transfused after delivery. The management of anti-public alloimmunization poses several problems. The first one is of diagnostic nature with, on the one hand, the difficulty of Ab identification by the available red cell panels and, on the other hand, the possible presence of alloantibodies of transfusional or obstetric interest masked by anti-public Ab. The second is represented by transfusional care of these patients. In the absence of a national reserve of frozen rare blood, the autologous transfusion remains the only alternative. However, it can answer only a limited number of indications and only in case of moderate blood loss.

International society of blood transfusion working party on red cell immunogenetics and terminology: report of the Seoul and London meetings.

The Working Party has met twice since the last report: in Seoul, South Korea 2014, and in London, UK 2015, both in association with the International Society of Blood Transfusion (ISBT) Congress. As in previous meetings, matters pertaining to blood group antigen nomenclature were discussed. Eleven new blood group antigens were added to seven blood group systems. This brings the current total of blood group antigens recognized by the ISBT to 346, of which 308 are clustered within 36 blood groups systems. The remaining 38 antigens are currently unassigned to a known blood group system.

[Quality control of labile blood products. Why and howto properly take a specimen? Labile Blood Products Group of the French Blood Transfusion Society]. / Le contrôle de qualité des produits sanguins labiles. Pourquoi et comment bien prélever un échantillon? Groupe de produits sanguins labiles de la Société française de transfusion sanguine.

This article reviews the various techniques of sampling used for the quality control of blood cell products. The importance of this stage for the validity of quality control results is emphasized. Three sampling methods, i.e., stripping, the sterile connection of sampling bag and the destructive method, are described in the form of operating modes and analyzed according to their advantages and drawbacks. The results of a comparative study carried out by the working group 'Blood Cell Products' of the French Society of Blood Transfusion are presented, showing that each method is valid and permits one to obtain a representative sample of the product to be controlled. Thus the diversity of the sampling methods allows us to select the one most adapted to the product to be controlled and to the analyses to be carried out afterward.

[A KEL*02mod allele responsible for an apparent maternity exclusion]. / Un allèle KEL*02mod responsable d'une exclusion apparente de maternité

The patient's rare KEL:1,-2 phenotype was highlighted in course of a routine preoperative erythrocyte typing. Unexpectedly, her two daughters presented a KEL:-1,2 phenotype what appeared first as an apparent maternity exclusion. Flow cytometry, genotyping and adsorption-elution analyses were then performed for those three patients. KEL genotyping showed that the patient's genotype was KEL*01/KEL*02 whereas that of her daughters was KEL*02/KEL*02. By using polyclonal anti-KEL2 reagent, weak amount of KEL2 was identified on the patient's erythrocytes, a result which was confirmed by both flow cytometry and adsorption-elution assays, suggesting that patient's phenotype was in fact KEL:1,2w. These results are in favour of a weak expressed KEL*02 allele (KEL*2mod) transmission coding for a KEL2 antigen detected in some technical conditions only. Those results allowed to explain the apparent maternity exclusion based on initial KEL phenotype. This study also seems to confirm the presence of a compensatory mechanism of the KELmod allele deficient expression in heterozygote patients. A KEL phenotype retrospective study of 80,000 subjects showed a local KEL:1,-2 frequency four times lower than that described in literature. Moreover, a significant number of those individuals would in reality be KEL:1,2w, what still would decrease the real frequency of the KEL:1,2 subjects.

[Guidelines for blood transfusion teaching to medical laboratory technology students]. / Référentiel d'enseignement de la transfusion sanguine aux étudiants techniciens de laboratoire de biologie médicale.

PURPOSE OF THE STUDY: The new French law about clinical laboratory medicine, the requirements of the ISO/CEI 15189 standard, the numerous abilities expected from the medical laboratory technologists and their involvement in blood bank management has led the working group "Recherche et démarche qualité" of the French Society of Blood Transfusion to initiate an inventory of blood transfusion teaching syllabus for medical laboratory technology students and to propose transfusion medicine teaching guidelines. MATERIAL AND METHODS: Seven worksheets have been established for that purpose including red blood cell antigen typing and antibody screening, blood sampling in immunohaematology, automation, clinical practices, blood products, blood delivery and haemovigilance. RESULTS: These guidelines aim at contributing to the harmonization of transfusion medicine teaching and at providing objective elements to the medical laboratory managers regarding the practical and theoretical skills of theirs collaborators.

Blood group genotyping by high-throughput DNA analysis: application to the French panel of RBC reagents.

BACKGROUND: The use of blood group genotyping for the prediction of antigen expression has been discussed in clinical transfusion settings, but much less for reagent red blood cells selection. In France, the Centre National de Référence pour les Groupes Sanguins (CNRGS) produces a reference panel of reagent red blood cells, mainly used for red cell antibody identification. The use of high-throughput DNA analysis has never been applied to blood donors whose red blood cells are used as reagents. The aim of this study was to compare the serological phenotype and that predicted from DNA analysis in such donors, and to determine the benefit of DNA analysis in reagent red blood cells selection strategy. STUDY DESIGN AND METHOD: Red blood cells of 346 blood donors were typed with two different reagents for each antigen. The genotyping was performed by using HEA v1.2 BeadChips, BioArray Solutions, Immucor. The comparison between the serologically determined phenotype and that predicted from DNA analysis held on 8876 paired results obtained from 10 blood group systems and 25 antigens. RESULTS: A 99.95% concordance was observed. Four cases of discrepancy for RH, KEL, LU and DO blood group systems were analyzed. Genotyping precisions were of special interest for the Duffy blood group system. CONCLUSION: Systematic DNA analysis brings important information on reagent red blood cells selection. It can be used at a routine level. Especially, the notion of "antigen of double dose" which is specified in several countries by government bodies should evolve regarding data obtained from DNA analysis. This should improve the quality of reagent red blood cells as first step for antibody identification.