Monoclonal antibody-specific immobilisation of erythrocyte antigens (MAIEA). A new technique to selectively determine antigenic sites on red cell membranes.

A new assay, the monoclonal antibody-immobilization of erythrocyte antigens (MAIEA) is described for the assignment of red cell antigens recognised by human allo-antisera, to particular membrane components of the red cell membrane. This technique detects tri-molecular complexes formed by the reaction of a human antibody and a mouse antibody with a particular red cell protein. A positive reaction, in an ELISA-type detection procedure, occurs if the epitopes recognised by the human and mouse antibodies are present on the same membrane component but different regions. The MAIEA assay has been developed to investigate blood group antigens and in this report its application to the study of the Lutheran, Yt and Kell blood group systems is described. The technique has been used to show that the Lu(a) and Lu3 antigens are carried on the Lutheran glycoprotein, Yta and Ytb on the enzyme acetylcholinesterase and K, k, Kpa and Kpb on the Kell glycoprotein.

Investigation of the biochemical relationship between the blood group antigens Xga and CD99 (12E7 antigen) on red cells.

The biochemical relationship between the red cell antigens Xga and the MIC2 gene product, CD99--previously designated the 12E7 antigen--has been examined by immunoblotting and immunoprecipitation analyses of the protein molecules bearing these antigens. Immunoblotting of membrane components and Xga-immunoprecipitates with anti-Xga has shown that Xga antigen is carried on a broad band of apparent molecular weight (Mr)) 24,500-29,500, which consists of a dark stained component at M(r)24,500 and a more diffusely stained component at approximately M(r) 26,500-29,500. Immunoblotting of membrane components and 12E7-immunoprecipitates with 12E7, and RFB-1 and NaM123 which also recognise CD99, distinguished two bands of M(r) 30,000 and 32,000. A non-radioactive immunoprecipitation technique was employed, which uses chemiluminescence detection of biotin-labelled red cell proteins. The protein of M(r) 32,000, which carries CD99, was identified by this method and the red cell quantitative polymorphism of CD99 was demonstrated. When the Xga protein was precipitated from biotin-labelled red cells, a protein of M(r) 32,000 was coprecipitated. This suggests that the proteins carrying the Xga antigen and CD99 are associated in the membrane.

Release of Choline Metabolites from Human Platelets: Evidence for Activation of Phospholipase D and of Phosphatidylcholine-specific Phospholipase C.

In aspirin-treated platelets labelled by preincubation with [(3)H]-choline, enhanced release of both [(3)H]-choline and [(3)H]-choline phosphate resulted from stimulation by collagen or thrombin. No such release accompanied stimulation by ADP, platelet-activating factor or adrenaline. Release of [(3)H]-choline phosphate was entirely dependent on aggregate formation whereas release of [(3)H]-choline was reduced but not eliminated, if aggregation was prevented. The properties of [(3)H]-choline and [(3)H]-choline phosphate release indicated that both collagen and thrombin induced activation of phospholipase D in the absence of aggregate formation. Such activation was augmented if aggregate formation occurred. Aggregation induced by these two agonists also caused activation of phosphatidylcholine-specific phospholipase C. These effects were prevented in the presence of staurosporine and could also be induced by addition of a synthetic 1,2-diacylglycerol indicating a role for protein kinase C.

Factors affecting the observation of a synergistic response in platelet aggregation induced by pairs of excitatory agonists.

When aggregation is measured as the disappearance of single platelets synergistic interaction between excitatory agonist pairs can be observed using washed platelets in a modified Tyrode's medium or platelet-rich plasma anticoagulated with hirudin; but not using citrated platelet-rich plasma. For aggregation induced by the ADP/adrenaline agonist pair, both the observation of synergistic interaction and the sensitivity of the platelets to these agonists, is a function of extracellular [Ca(2+)]. Synergistic interaction and reduced sensitivity to the individual agonists, especially adrenaline, is observed when extracellular [Ca(2+)] > 100 µM. The data suggest that lower affinity binding of Ca(2+) to the glycoprotein IIb/IIIa complex may modulate platelet sensitivity to these excitatory agonists. The conditions used to resuspend the platelets also influences the nature of the response to the ADP/adrenaline agonist pair and the sensitivity of the platelets to these agonists. A synergistic response and/or reduced sensitivity to ADP is observed on resuspension in modified Tyrode's medium but does not occur on resuspension in citrated plasma or in plasma anticoagulated with hirudin. The factor responsible for enhancing sensitivity, and hence abolishing the synergistic response, is a species of low molecular weight (M(r) less than 25 KDa). It is neither citrate nor Ca(2+).

The monoclonal antibody-specific immobilization of erythrocyte antigens assay (MAIEA) in the investigation of human red-cell antigens and their associated membrane proteins.

The monoclonal antibody-specific immobilization of erythrocyte antigens (MAIEA) technique is an immunoassay devised primarily for locating blood group antigens on specific red-cell membrane proteins. The assay involves the incubation of intact red cells with two antibodies, one human alloantibody, the other a nonhuman antibody, usually a rodent monoclonal antibody, but polyclonal antibodies of rabbit origin have been utilized. For a positive result, both antibodies must bind to the same membrane protein. The red cells are lysed, the membrane solubilized and the trimolecular complex of two antibodies and membrane protein is captured in a well coated with goat antirodent (or rabbit) immunoglobulin. The immobilized complex is then detected by the use of peroxidase-conjugated goat antihuman (or rodent) immunoglobulin. Negative results, due to mutual blocking between the human and animal antibodies when their epitopes are close together on the same molecule, have permitted a degree of localization of epitopes on some proteins. This has been most effective in the mapping of Cromer blood group system antigens on the complement control protein domains of decay-accelerating factor (DAF, CD55), but has also proved informative in the clustering of antigens on the Lutheran and Kell glycoproteins. MAIEA is an effective tool for the identification of antibodies to Knops-system antigens on complement receptor 1 (CR1, CD35) in immunohaematology reference laboratories. These antibodies are clinically unimportant, but must be identified before they can be ignored for transfusion purposes.

Application of the MAIEA assay to the Kell blood group system.

The monoclonal antibody-specific immobilisation of erythrocyte antigens (MAIEA) test has been employed to investigate the Kell system using five monoclonal antibodies which recognise high frequency epitopes on the 93,000-molecular weight Kell glycoprotein: BRIC 18, BRIC 68, BRIC 107, BRIC 203 and 6-22. BRIC 107, which has anti-k-like (KEL2) specificity, identifies a distinct epitope, whilst competitive binding assays suggested that BRIC 203 (anti-Kpbc), BRIC 18, BRIC 68 and 6-22 (anti K14) comprise an overlapping set of epitopes. The MAIEA assay has been very successful in confirming the assignment of most of the Kell and para-Kell antigens to the Kell protein. Due to the competitive nature of the assay and the fact that the monoclonal antibodies bind to different regions, the results also suggest the relative positions of some of the Kell antigens on the Kell protein; these appear to be located in at least five spatially distinct regions.

Toxicity of bone marrow in dentists exposed to nitrous oxide.

The morphology of the bone marrow of 21 dentists who habitually used nitrous oxide in their surgeries was investigated. Exposure to nitrous oxide was measured with an atmospheric sampling device, and each dentist was invited to fill in a questionnaire giving details of medical history, diet, and intake of alcohol. During the trial a full neurological and haematological investigation was carried out and a bone marrow aspirate was examined both morphologically and by the deoxyuridine suppression test. Mean exposures to nitrous oxide ranged from 159 to 4600 parts per million. In all subjects serum vitamin B12 and folate concentrations were within normal limits. Abnormal results of deoxyuridine suppression tests were obtained in three of the 20 dentists tested; two of these three had abnormal white cells in their peripheral blood films. This study provides direct evidence that occupational exposure to nitrous oxide may cause depression of vitamin B12 activity resulting in measurable changes in bone marrow secondary to impaired synthesis of deoxyribonucleic acid.

Analysis of Knops blood group antigens on CR1 (CD35) by the MAIEA test and by immunoblotting.

Kna, McCa, Sla and Yka are red cell antigens of relatively high frequency, located on complement receptor 1 (CR1, CD35). Antibodies to these Knops system antigens are not uncommon. They are not haemolytic and do not reduce the survival of transfused incompatible red cells, but they are a nuisance in transfusion laboratories as they can cause an incompatible crossmatch and must be identified before they can be dismissed as clinically insignificant. Human red cell alloantibodies can be shown to be Knops system antibodies by the monoclonal-antibody-specific immobilization of erythrocyte antigens (MAIEA) test, using murine monoclonal anti-CR1. In addition to confirming that Kna, McCa, Sla and Yka are located on CR1, the MAIEA test was used to confirm that Csa is not on CR1. Red cells of the Helgeson phenotype, the null phenotype of the Knops system by conventional serological methods, have levels of Kna, McCa, Sla and Yka intermediate between those of alpha-chymotrypsin-treated cells (which lack Knops system antigens) and those of positive control cells. Level of expression of Knops system antigens is very variable and intensity of staining of immunoblots probed with monoclonal anti-CR1 correlated with strength of Knops system antigens, as determined by the MAIEA test. In individuals heterozygous for alleles producing different allotypes, separate bands representing each allotype on an immunoblot showed identical intensity of staining, suggesting that the quantity of CR1 on red cells is controlled, at least in part, by a locus independent of CR1. An analysis of CR1 on red cells of individuals who have made Knops system antibodies suggested that the Knops system antigens and the antibodies that detect them are complex and heterogeneous.

Demonstration by the monoclonal antibody-specific immobilization of erythrocyte antigens assay that a new red cell antigen belongs to the Kell blood group system.

BACKGROUND: The Kell blood group system comprises 21 antigens residing on a red cell membrane glycoprotein of apparent M(r) 93,000. STUDY DESIGN AND METHODS: Serologic techniques were used to identify a new red cell antigen. The monoclonal antibody-specific immobilization of erythrocyte antigens (MAIEA) assay was used to identify the red cell membrane component carrying that antigen. RESULTS: A new high-frequency red cell antigen was identified and provisionally named RAZ. RAZ is absent from K.o red cells and from red cells treated with 2-amino-ethylisothiouronium bromide and is expressed weakly on McLeod phenotype cells. It differs from all other Kell system antigens, and no depression of other Kell system antigens on RAZ+ red cells was noticed. The RAZ antigen was shown by the MAIEA assay to be located on the Kell glycoprotein. CONCLUSION: RAZ is a new high-frequency antigen located on the Kell glycoprotein. The MAIEA assay is a very effective method of demonstrating the membrane structure carrying a red cell antigen.

Use of the MAIEA technique to confirm the relationship between the Cromer antigens and decay-accelerating factor and to assign provisionally antigens to the short-consensus repeats.

The MAIEA (monoclonal-antibody-specific immobilisation of erythrocyte antigens) assay has recently been developed for the assignment of red cell antigens, recognised by human alloantisera, to particular membrane components of the red cell membrane. This technique detects trimolecular complexes formed by the reaction of a human antibody and a mouse antibody with a particular red cell protein. A positive reaction, in an ELISA-type detection procedure, occurs if the epitopes to the human and mouse antibodies are present on the same membrane component but at different regions. In this report, we show how the MAIEA assay can be used to confirm the relationship between Cromer system antigens and the complement-regulatory protein, decay-accelerating factor (DAF, CD 55). In addition, the location of the antigens along the protein is postulated by using three anti-DAF monoclonal antibodies with specificities to different regions of DAF. Tca and Esa are assigned provisionally to the first short-consensus repeat (SCR), UMC to the second SCR, Dra to the third SCR and Cra, WESa and WESb to the fourth SCR or to the serine/threonine rich region of the DAF protein.

A new low-incidence antigen in the Kell blood group system: VLAN (KEL25).

A multilaboratory investigation has identified a new low-incidence antigen "VLAN' on the red cells of a blood donor. The VLAN antigen is destroyed by 2-aminoethylisothiouronium bromide treatment of the donor's red cells suggesting an association with the Kell system. Monoclonal antibody-specific immobilization of erythrocyte antigen analysis with anti-VLAN and with several mouse monoclonal antibodies directed at epitopes on the Kell glycoprotein gave positive results, indicating that the VLAN antigen is located on the Kell glycoprotein. The VLAN red blood cells have the common Kell phenotype: KEL:-1,2,-3,4,5,-6,7,-10,11,12,13,14,-17,18,19,-21,22,-23,-24. Additional serologic data indicate that the VLAN antigen is not part of any other ISBT blood group system, collection or series. A family study showed that the VLAN antigen is inherited since the red cells of two sisters and one niece of the propositus are also VLAN+. The ISBT Working Party on Terminology for Red Cell Surface Antigens has assigned VLAN to the Kell blood group system as KEL25 (number for computer listings 006025).