The computer crossmatch: a safe alternative to the serological crossmatch.

The crossmatch has evolved from including a wide range of techniques through a test purely to eliminate ABO incompatibility (immediate spin) to computer crossmatching in which no serological testing is carried out and validation ensures the correct ABO/RhD type blood is issued. The crossmatch was always considered to be the most important feature of the compatibility test and in particular the antiglobulin phase; however, there are potential risks associated with serological and computer crossmatching including technical and procedural errors. The use of immediate spin and computer crossmatch change the emphasis for safety of the compatibility test from the crossmatch to the antibody screen. UK guidelines have now been published describing the features necessary for the introduction of computer crossmatching. Computer crossmatching is used by many institutions in various countries. It is considered safe practice and brings benefits to the laboratory and the patient. Compatibility testing is only one element of the blood transfusion procedure; the others are equally as important and include correct patient identification at the time of collection of the blood sample and at the administration of the blood transfusion.

Monoclonal antibodies to Rh D--development and uses.

Monoclonal anti-D has proved impossible to make in rodent systems. Human monoclonal anti-D has been produced using EBV transformed peripheral B cells, coupled with fusions to myeloma cell lines. More recently molecular biology techniques have been used to produce monoclonal anti-D. The range of monoclonal anti-D produced is considered. The selection of monoclonal anti-D for use as blood grouping reagents for typing donors and recipients is reviewed--all types of D positive should be typed as positive when donors are considered. However, DVI patients should be typed as D negative. Considerations for the development of monoclonal anti-D for prophylactic use are reviewed.

Site directed mutagenesis of the human Rh D antigen: molecular basis of D epitopes.

Previous attempts to define the molecular configuration of D epitopes has been confined to the analysis of the serological profile and Rh D molecular structure of partial D phenotypes. There are numerous drawbacks in this approach, most fundamental of which is that with the exception of RoHar, partial D phenotypes are defined by the loss of D epitope expression, and is thus difficult to directly correlate a specific amino acid to a particular D epitope. Furthermore, most partial D phenotypes are associated with multiple amino acid changes in the mutant Rh protein species associated with partial D expression. In our study we have applied site directed mutagenesis to introduce RhD amino acids in a stepwise manner to a Rh cE cDNA. This cDNA was introduced into K562 cells using retroviral mediated gene delivery, and D epitope expression analysed by flow cytometry. Our study provides evidence for at least six different epitope clusters on the external face of the Rh D protein. The relative predicted positions of these epitope clusters has resulted in us presenting a model for the hypothetical arrangement of external Rh D protein loops.

Epitopes on Rh proteins.

Analyses of the reactions of monoclonal anti-D with Rh D variant red cells have shown that there are at least 24 different epitopes of the Rh D antigen. Similar studies Of Rh E variant red cells with monoclonal anti-E indicate that there are at least 4 epitopes of the Rh E antigen. The relation of these serologically defined epitopes to the structure of the Rh proteins is reviewed. Most epitopes are discontinuous, with critical residues present in different loops of the proteins.

Molecular configuration of Rh D epitopes as defined by site-directed mutagenesis and expression of mutant Rh constructs in K562 erythroleukemia cells.

The Rh D antigen is the most clinically important protein blood group antigen of the erythrocyte. It is expressed as a collection of at least 37 different epitopes. The external domains of the Rh D protein involved in epitope presentation have been predicted based on the analysis of variant Rh D protein structures inferred from their cDNA sequences and their D epitope expression. This analysis can never be absolute because (1) most partial D phenotypes involve multiple amino acid changes in the Rh D protein and (2) deficiency for 1 or more epitopes may be due to gross structural alteration in the variant Rh D protein structure. We report here the amino acid requirements for the majority of D epitopes. They have been defined by generating a series of novel Rh mutant constructs by mutagenesis using an Rh cE cDNA as template and mutagenic oligonucleotide primers. When transfected into K562 cells, the D epitope expression of the derived mutant clones was then assessed by flow cytometry. The introduction of 9 externally predicted Rh D-specific amino acids on the Rh cE protein was sufficient to express 80% of all tested D epitopes, whereas other clones expressed none. We concluded from our data that the D epitope expression is consistent with at least 6 different epitope clusters localized on external regions of the Rh D protein, most involving overlapping regions within external loops 3, 4, and 6.

International reference reagents: antihuman globulin. An ISBT/ICSH joint working party report. International Society of Blood Transfusion. International Committee for Standardization in Haematology.

An international working party has conducted a study designed to select a suitable reference reagent for antihuman globulin, to replace those first made available in 1987. The chosen preparation contains levels of anti-IgG and anti-C3 (anti-C3c and anti-C3d) potency that are considered suitable to serve for reference when evaluating either polyspecific antihuman globulin reagents or those containing their separate monospecific components. The reference material is available in 2-ml freeze-dried aliquots from seven assigned distribution centres.

Detection of weak D and D(VI) red cells in D-negative mixtures by flow cytometry: implications for feto-maternal haemorrhage quantification and D typing policies for newborns.

Quantitation of feto-maternal haemorrhage (FMH) by flow cytometry (FC) has been shown to be more accurate than the Kleihauer-Bekte test. Fetal cells will be predominately of R1r or R2r phenotype, with antigen site numbers per cell (SPC) of between 9900 and 16000. If the fetus is of weak D or partial D(VI) phenotype, fewer SPC will be present. Red cells from 20 adult weak D samples were mixed with rr red cells to give 1% mixes. Mixtures were stained and analysed by FC, using two different monoclonal reagents. The SPC of each sample was measured using SOL-ELSA with Scatchard plot analysis. 18 samples could not be distinguished and had <1000 SPC. Two samples that could be distinguished had 1350 and 3000 SPC. Red cells from seven samples of D(VI) were also analysed. None of these samples could be distinguished: SPC were all <1000. Although one of the reagents used reacts with D(VI) cells, quantitation of a D(VI) FMH would not be possible due to low SPC. The ability of fetal red cells with low Rh D SPC to cause immunization is questionable; failure to measure FMH in these cases is unlikely to cause clinical problems, as long as suitably sensitive serological reagents and techniques are used to type all weak D and D variant babies as Rh D positive, and thus ensure that the mother is given the appropriate dose of anti-D.

Site-directed mutagenesis of the human D antigen: definition of D epitopes on the sixth external domain of the D protein expressed on K562 cells.

BACKGROUND: The antigens of the human Rh system are of great clinical significance in transfusion medicine and pregnancy. Of the Rh system antigens, D is clinically the most important, being one of the most immunogenic structures arising from human cells. The human D antigen represents a collection of epitopes expressed on a red cell membrane protein that is predicted to have 12 membrane-spanning segments giving rise to six exofacial domains. STUDY DESIGN AND METHODS: By site-directed mutagenesis using the method of inverse polymerase chain reaction, cE and D cDNA mutant constructs were generated with changes to the RHD-specific residues 350, 353, and 354 in the predicted sixth exofacial loop. Each mutant cDNA was subcloned into the pBabe puromycin retroviral vector, and supernatants were used to transduce K562 cells. Puromycin-resistant K562 clones were screened by flow cytometric analysis using a panel of monoclonal antibodies with specificities to ep (epitope) D1 through epD9. RESULTS: De novo expression of epD3 and epD9 was generated in the K562 cell lines expressing the mutated cE polypeptide (cE-Asp350His, Gly353Trp, Ala354Asn). Expression of c and E was unaffected. Conversely, the cells expressing the mutated D polypeptide demonstrated loss of expression of epD1, epD2, epD3, epD4, and epD9. CONCLUSION: The data provide strong evidence for the critical involvement of three amino acids, Asp350, Gly353, and Ala354, in the expression of epD3 and epD9 on the predicted sixth external domain of the D protein. This domain also appears to be essential for the expression of epD1, epD2, and epD4, as a loss of expression of these epitopes was observed in K562 cells transduced with the Dmut construct (encoding His350, Trp353, and Asn354). The K562/Dmut cell line has an identical molecular and serologic profile as the red cell D(IVb) phenotype, which confirms that retroviral gene transfer of Rh cDNA into K562 cells provides us with a powerful means by which to further map epitopes of D.

New reference reagent for the quality assurance of anti-D antibody detection.

A UK BTS-NIBSC freeze-dried anti-D preparation has been prepared and used to monitor the performance of routine antibody detection tests and of the test operators. With the day-to-day use of this preparation, adverse changes in test performance and in test operator may be detected and appropriate action taken before the effect becomes significant. Two dilutions of this preparation have been defined, one which should be detected unequivocally in every test; the other, more dilute, may not be detected in every test but is used to monitor changes in performance. Experience with the use of this preparation is reported from three test centres undertaking routine antibody detection tests. By monitoring results over a series of working days, significant differences were noted in operator performance within one test centre, as was a reduced sensitivity of a given test system within one test centre compared with the same system in the other test centres. These differences were detected only by monitoring the results obtained with this preparation.

IgG anti-Jka/Jkb antibodies are unlikely to fix complement.

Antibodies in the Kidd blood group system show a great deal of serological variability, are notoriously elusive and hence evoke difficulties in detection. However, they have been regularly reported as causing severe immediate or delayed haemolytic transfusion reactions and this clinical potential has been largely attributed to their complement binding ability. In initial investigations on 43 anti-Jka/Jkb sera with a range of titres of IgG antibody only a few seemed to fix complement, though following repeated tests on 20 of these sera a further five were shown to bind complement, making a total of 12 (27.9%) showing evidence of complement binding. Twenty-three sera were unavailable for re-testing. Subsequent tests revealed that only those sera which showed direct agglutination or were positive with an anti-IgM reagent in an indirect antiglobulin test (IAT) fixed complement. Evaluations on the IgG fractions of six selected potent anti-Jka sera failed to reveal any complement-fixing ability although all the original sera bound complement avidly and contained variable amounts of IgM antibody, some at very low subagglutinating levels. These findings challenge past perceptions and give cause for reflection on the changing methodologies and strategies which could unduly compromise the detection of these potentially clinically damaging antibodies.

DBT: a partial D phenotype associated with the low-incidence antigen Rh32.

Eight probands are described with a D phenotype in which a partial D antigen is associated with Rh32 antigen; three of these probands were investigated because of the anti-D in their serum. The partial D lacks epD1-epD5 and epD9 and some epD6/7 and only expresses epD8 and other parts of epD6/7. The strength of the partial D antigen varies between unrelated DBT individuals. The Rh32 antigen of the DBT cells is weaker than that of D(C)(e) cells. Tests on DBT, DFR and R0Har cells with anti-epD6/7 split these monoclonal anti-D into eight patterns of reaction. A new pattern of reactions was observed, presaging a new epitope, but this was not numbered.

Molecular basis of the D variant phenotypes DNU and DII allows localization of critical amino acids required for expression of Rh D epitopes epD3, 4 and 9 to the sixth external domain of the Rh D protein.

The discovery of Rh partial D variant red cells by discrepant reactions with different monoclonal anti-D has demonstrated the range of Rh D epitopes that have arisen due to alterations in Rh D protein structure. There are two current classification systems, one which uses a nine epitope model (epD1-epD9) whereas a more recent model proposes 30 different epitopes. We describe here the molecular basis of two D variants which lack epD4 and epD9 namely the DNU and D(II) phenotypes. These would have both been originally classified as D(II) phenotype individuals, but we have revealed subtle differences in the serological profile of these erythrocytes. Such a differential reactivity and determination of the molecular bases of these phenotypes allows us to predict critical amino acids for epD3, epD4 and epD9 expression. The DNU phenotype arises from a single point mutation in the RHD gene resulting in a single amino acid change (Gly353Arg). Sequence analysis of exon 7 of the RHD gene derived from the D(II) propositus indicates that there is a single point mutation in this exon resulting in a single amino acid change (Ala354Asp). It is likely that this point mutation gives rise to the D(II) phenotype. Both mutations result in the change to Rh D-specific residues. Our results indicate that the following amino acids are crucial for epD3a (Asp350), epD3b (Asp350 + Gly353), epD4a (Gly353 + Ala354), epD4b (Ala354), epD9a (Asp350 + Gly353 + Ala354) and epD9b (Asp350 + Ala354) expression. All of these amino acids reside on the predicted sixth external domain of the Rh D protein, so it is possible that epD3, 4 and 9 are continuous epitopes.

Molecular analysis of Rh transcripts and polypeptides from individuals expressing the DVI variant phenotype: an RHD gene deletion event does not generate All DVIccEe phenotypes.

The D antigen is a mosaic comprising at least 30 epitopes. Partial Rh D phenotypes occur when there is absence of one or more of these epitopes, with the remainder expressed. The DVI phenotype is the most common of the partial D phenotypes, lacking most D antigen epitopes (ep D) (epD1, 2, 5-8 using the 9-epitope model or epD 1-4, 7-22, 26-29 using the 30-epitope model). DVI mothers may become immunized by transfusion with D-positive blood (if typed as D-positive using polyclonal typing reagents) or by fetuses which have all of the D antigen. This situation can give rise to severe hemolytic disease of the newborn (HDN). The molecular basis of the DVI phenotype has previously been proposed to occur by two different genetic mechanisms, one (in individuals of DVICcee phenotype) where a gene conversion event generates a hybrid RHD-RHCE-RHD gene; the second (in individuals of DVIccEe phenotype) was proposed to be caused by a partial RHD gene deletion. We present evidence that in four DVICcee phenotypes studied, this phenotype is not generated by a partial RHD gene deletion, but occurs by a similar mechanism to the DVICcee phenotypes. In two individuals we have found hybrid RHD-RHCE-RHD transcripts in both DVICe and DVIcE haplotypes. These differ in that the DVICe transcripts are derived from an RHD gene where exons 4-6 have been replaced with RHCE equivalents (encoding Ala226); the DVIcE transcripts are derived from an RHD gene where exons 4 and 5 are replaced by RHCE equivalents (encoding Pro226). We provide direct evidence that Rh DVI polypeptides are expressed at the erythrocyte surface as full-length polypeptide products. We have used immunoprecipitation experiments using anti-D reactive with DVI erythrocytes followed by immunoblotting the immune complexes with rabbit sera immunoreactive to the fourth external and C-terminal domains of all Rh polypeptides. Our results illustrate that these domains are present on all Rh DVI proteins studied, and suggest that Rh DVI polypeptide species studied here exist as full-length Rh proteins.

An explanation and the clinical significance of the failure of microcolumn tests to detect weak ABO and other antibodies.

Shear forces are proposed to explain the failure of antiglobulin and 'neutral' (no antiglobulin) microcolumn tests at 37 degrees C to detect weak ABO incompatibilities and other weak antibodies, clearly detectable by spin-tube methods. These shear forces can be minimized in a microcolumn test using a biphasic centrifugation phase. Although this biphasic test is not suitable for routine use, it may be of use as an investigational method for reference laboratories. This failure of microcolumn test to detect weak ABO incompatibilities is of little clinical significance as the antibodies are dubiously active at 37 degrees C.