Validation and cross-reactivity pattern assessment of monoclonal antibodies used for the screening of donor-specific IgG antibody subclasses in transplant recipients.

The screening for IgG subclass donor-specific antibodies (DSAs) in allograft recipients uses IgG1-4 subclass-specific monoclonal antibodies (mAbs) that should be mono-specific. The cross-reactivity discrepancies reported for IgG subclass-specific mAbs warranted a critical cross-reactivity pattern analysis of the IgG subclass-specific mAbs most commonly used to detect DSAs. We tested the reactivity of 2 anti-IgG1-, 3 anti-IgG2-, 1 anti-IgG3-, and 2 anti-IgG4-specific PE-conjugated mAbs against microbeads coated with IgG1-4 proteins separately. Each IgG subclass protein was coated at three densities on the beads (0.5, 1, and 2 µg of protein per 106 beads), and the PE-conjugated mAbs were titrated from 0.04 µg/mL to 5 µg/mL. The IgG subclass reactivity of the sample was acquired on the Luminex multiplex platform. Among the IgG subclass-specific mAbs, only the anti-IgG3 (clone: HP6050) mAb was mono-specific. All other mAbs tested were binding to IgG subclass proteins other than their respective immunogen, thereby being cross-reactive. IgG subclass cross-reactivity patterns were dependent on the concentration of both IgG subclass-specific mAbs and IgG1-4 protein targets coated onto the beads. With the current IgG subclass mAbs available, 3 of the 15 possible combinations of IgG1-4 subclass protein could be identified. While the remaining 12 unique combinations cannot be distinguished clearly, 6 groups that corresponded to two different unique combinations of IgG1-4 subclass protein could be identified. The dilution of serum samples and IgG subclass-specific mAbs, other than the anti-IgG3 (clone: HP6050), must be further optimized before their implementation in IgG subclass DSA screening in allograft recipients.

Distribution of de novo Donor-Specific Antibody Subclasses Quantified by Mass Spectrometry: High IgG3 Proportion Is Associated With Antibody-Mediated Rejection Occurrence and Severity.

Donor-specific antibodies (DSAs) are the main risk factor for antibody-mediated rejection (ABMR) and graft loss but could have variable pathogenicity according to their IgG subclass composition. Luminex-based test might lack sensitivity for the detection of IgG subclasses and this test does not allow quantifying the relative abundance of each IgG subclass. We investigated the precise repartition of each DSA subclass and their role in ABMR occurrence and severity, using an innovative mass spectrometry-based method. Between 2014 and 2018, we enrolled 69 patients who developed de novo DSA (n = 29 without ABMR, and n = 40 with ABMR) in two transplant centers. All IgG subclasses were detected in every samples tested: 62.7% were IgG1, 26.6% were IgG2, 6.6% were IgG3, and 4.2% were IgG4. The IgG3 proportion was significantly higher in the ABMR+ compared to the ABMR- group (8.4% vs. 5.6%, p = 0.003). The proportion of IgG1, IgG2, and IgG4 of DSA was similar between the two groups. Higher IgG3 level was associated with higher C4d deposition, higher microvascular inflammation scores, and glomerular filtration rate decline >25%. IgG3 proportion was not correlated with DSA MFI. Multivariate analysis showed that proteinuria and high level of IgG3 DSA were the only two factors independently associated with ABMR. In conclusion, de novo DSA are always composed of the four IgG subclasses, but in different proportions. High IgG3 proportion is associated with ABMR occurrence and severity and with poorer outcome, independently of DSA MFI.

HLA Class II Antibodies at the Time of Kidney Transplantation and Cardiovascular Outcome: A Retrospective Cohort Study.

BACKGROUND: The negative role of HLA class II donor-specific antibody on graft outcome is well recognized. However, the potentially negative cardiovascular effects of preformed HLA class II antibodies and donor HLA in kidney transplant recipients (KTRs) remain unestablished. METHODS: We conducted a single-center, retrospective cohort study including 1115 KTRs (2003-2016) with up to 4449 person-years of follow-up after transplantation and a median follow-up time of 5.1 years (interquartile range, 2.7-7.6). We evaluated the unadjusted and multivariable-adjusted association between pretransplant HLA class I and II antibodies, as well as HLA-DR1 donor/recipient genotype and the primary (major adverse cardiac and cerebrovascular event [MACCE] or all-cause mortality) and secondary (MACCE or cardiovascular mortality) outcome. RESULTS: In a multivariate Cox proportional hazard model, HLA class II antibodies before transplantation were associated with increased adjusted hazard ratio (aHR) for MACCE or all-cause mortality (aHR, 1.71 [1.13-2.60]; P = 0.012) even after adjustment for time-varying covariate graft loss (aHR, 1.68 [1.08-2.62]; P = 0.022) and biopsy-proven acute rejection (aHR, 1.71 [1.13-2.60]; P = 0.012). HLA class II antibodies were also associated with increased aHR for the secondary outcome, MACCE, or cardiovascular mortality (aHR, 1.92 [1.12-3.30]; P = 0.018). We investigated the effect of donor and recipient HLA-DR1 on these outcome parameters and demonstrated that KTRs with HLA-DR1 positive donors had an increased aHR for MACCE with all-cause (aHR, 1.45 [1.09-1.94]; P = 0.012) and cardiovascular mortality (aHR, 1.49 [1.00-2.22]; P = 0.05). CONCLUSIONS: Prior sensitization against HLA class II antigens is associated with unfavorable long-term cardiovascular outcome in KTRs independent of graft loss or rejection. Recipients of an HLA-DR1 donor also have an impaired cardiovascular outcome.

The Biology of IgG Subclasses and Their Clinical Relevance to Transplantation.

Immunoglobulin G (IgG) is the dominant immunoglobulin and can be divided into 4 distinct subclasses. The evolution of IgG subclass switches is regulated by interaction with T cells and follows a 1-way direction (IgG3 → IgG1 → IgG2 → IgG4). Based on their structure, the 4 IgG subclasses can initiate different effector function such as complement activation, recruitment of various cells by Fc receptors, and agonistic signaling. Using current assays for HLA antibody detection as a template and replacing the generic reporter antibody with IgG subclass-specific reporter antibodies, it is possible to investigate the IgG subclasses of HLA antibodies. There are 15 different IgG subclass compositions possible. Based on the capability to activate the complement system and the class switch direction, 3 arbitrary patterns can be defined (ie, only complement-binding subclasses [IgG3 and/or IgG1], expansion to noncomplement-binding subclasses [IgG3 and/or IgG1 plus IgG2 and/or IgG4], and switch to noncomplement-binding subclasses [IgG2 and/or IgG4]). The latter group accounts for less than 5%, whereas the former 2 groups have a similar prevalence close to 50%. In the past 5 years, several studies correlated the IgG subclass pattern with occurrence of antibody-mediated rejection and allograft outcomes. Because of differences of the used IgG subclass assay, the time point of analyses, and the definition of outcomes, a clear picture has not emerged yet. Future needs are standardization of the assay, a more detailed knowledge of the initiated effector functions, and more well-designed clinical studies also looking at changes of the IgG subclass pattern over time.

Successful transfusion of antigen positive blood to alloimmunised patients using a monocyte monolayer assay.

BACKGROUND: Providing adequate transfusion support for alloimmunised patients for whom antigen negative blood is not readily available is hampered by the risk of a haemolytic reaction. The monocyte monolayer assay (MMA) has shown good correlation between the antibody clinical significance and the fate of antigen positive blood. MATERIALS AND METHODS: From 2006 to 2013, the clinical significance of red cell alloantibodies produced by 61 patients was evaluated using a MMA; and antigen positive blood offering the best survival advantage was selected for transfusion following a secondary MMA crossmatch. Post-transfusion, patients were evaluated for clinical signs of haemolysis. RESULTS: Overall, 19 of 61 (31·1%) of our antibodies were potentially clinically significant, with a monocyte index (MI) > 5%. There was no correlation between the clinical significance as showed by the MMA, and the specificity of the antibody or the strength of reactivity at antihuman globulin (AHG) phase. Using the MMA as a secondary crossmatch method, 31 alloimmunised patients (including: eight anti-hr(B), four anti-Yt(a), one each anti-Rg1, -Co(a), Er(a), Le(b), -LW, -Sl1) received 103 antigen positive blood units with no clinical sign of a post-transfusion reaction. For three patients (one each anti-Jo(a), -AnWj, unidentified 'HTLA'), initial MMA was performed as part of an investigation of a suspected haemolytic reaction. In each case, the MMA accurately identified the unit responsible for the reaction. CONCLUSION: Used as a crossmatch surrogate, the MMA provided valuable information in the decision of transfusing antigen positive blood to alloimmunised patients, avoiding delay because of the search of rare antigen negative units.

Donor-specific HLA antibodies: evaluating the risk for graft loss in renal transplant recipients with isotype switch from complement fixing IgG1/IgG3 to noncomplement fixing IgG2/IgG4 anti-HLA alloantibodies.

Human leukocyte antigen alloantibodies have a multitude of damaging effects on the allograft, both complement (C') activation and Fc-independent ones. To date, the clinical significance of non-C' fixing (NCF) HLA donor-specific antibodies (DSA) is still unclear. In this study, we investigated whether renal transplant recipients with NCF-DSA subclasses (IgG2/IgG4, IgA1/IgA2) are at higher risk of graft loss compared to patients with exclusively C' fixing (IgG1/IgG3). Blood samples from 274 patients were analyzed for HLA IgG and IgA subclasses using a modified single-antigen bead assay. We identified 50 (18.2%) patients with circulating NCF antibodies either DSA (n=17) or against third-party HLA (n=33). NCF-DSAs were preferentially of IgG2/IgG4 isotype (11/17) and were mainly directed against HLA class II (13/17). NCF DSA were present as a mixture with strong C' fixing IgG1/IgG3. Graft survival was similar between patients with exclusively C' fixing antibodies and those with a mixture panel (log rang test P=0.162), and also among patients with different immunoglobulin isotype and subclasses (long-rank test, P=0.732). We conclude that expansion of DSA to NCF subclasses postrenal transplantation does not seem to be associated with worse graft survival as compared to the presence of exclusive C' fixing subclasses.

Class II alloantibody and mortality in simultaneous liver-kidney transplantation.

Hyperacute kidney rejection is unusual in crossmatch positive recipients of simultaneous liver-kidney transplants (SLKT). However, recent data suggest that these patients remain at risk for antibody-mediated kidney rejection. To further investigate the risk associated with donor-specific alloantibodies (DSA) in SLKT, we studied 86 consecutive SLKT patients with an available pre-SLKT serum sample. Serum samples were analyzed in a blinded fashion for HLA DSA using single antigen beads (median florescence intensity≥2,000=positive). Post-SLKT samples were analyzed when available (76%). Thirty patients had preformed DSA, and nine developed de novo DSA. Preformed class I DSA did not change the risk of rejection, patient or allograft survival. In contrast, preformed class II DSA was associated with a markedly increased risk of renal antibody mediated rejection (AMR) (p=0.006), liver allograft rejection (p=0.002), patient death (p=0.02), liver allograft loss (p=0.02) and renal allograft loss (p=0.045). Multivariable modeling showed class II DSA (preformed or de novo) to be an independent predictor of patient death (HR=2.2; p=0.043) and liver allograft loss (HR=2.2; p=0.044). These data warrant reconsideration of the approach to DSA in SLKT.

Pretransplant IgG subclasses of donor-specific human leukocyte antigen antibodies and development of antibody-mediated rejection.

BACKGROUND: The subclass of IgG antibodies contributes to their capability to activate complement. It is currently unknown whether the pretransplant IgG subclass composition allows distinguishing harmful from presumably irrelevant donor-specific human leukocyte antigen (HLA) antibodies (HLA-DSA) detected by single-antigen flow beads (SAFB). METHODS: Seventy-four patients transplanted in the presence of HLA-DSA were investigated. HLA-DSA characteristics were not different between patients experiencing antibody-mediated rejection (AMR) (n=40) and patients who did not (n=34) experience AMR. Sera were reanalyzed using SAFB with IgG subclass-specific reporter antibodies. RESULTS: The 74 patients had in total 141 HLA-DSA. IgG1 was the predominant subclass (78%), followed by IgG2 (49%), IgG3 (36%), and IgG4 (20%). When grouped according to the complement-activating capability, only 4 of 74 patients (5%) had exclusively weak/no complement-activating HLA-DSA (i.e., IgG2 and IgG4), 21 of 74 patients (28%) had isolated strong complement-activating HLA-DSA (i.e., IgG1 and IgG3), and 46 of 74 patients (62%) had a mixture of both. There was no difference between the strong complement-activating and the mixture group regarding incidence of AMR (57% vs. 54%; P=0.81), phenotypes of AMR (P=0.70), and death-censored allograft survival at 5 years (78% vs. 78%; P=0.74). Interestingly, patients with exclusively weak/no complement-activating HLA-DSA (n=4) had a numerically lower incidence of AMR (25%) and no allograft loss has occurred yet. CONCLUSION: In 90% of patients, pretransplant HLA-DSA are composed of isolated strong or a mixture of strong and weak/no complement-activating IgG subclasses. Because outcomes in these two groups were similar, pretransplant IgG subclass analysis is likely not providing substantial value beyond the standard IgG SAFB assay for pretransplant risk stratification.

Clinical relevance and IgG subclass determination of non-HLA antibodies identified using endothelial cell precursors isolated from donor blood.

BACKGROUND: ABO and human leukocyte antigen (HLA) alloantibodies provide major immunologic barriers to successful transplantation; however, there is increasing recognition for the role of anti-endothelial cell antibodies (AECAs) in allograft rejection. We investigated the relationship between AECAs identified using donor-derived endothelial cell precursors (ECPs) and kidney allograft rejection and function. METHODS: Sixty live donor kidney recipients were tested pretransplant for AECAs and HLA-antibodies using flow cytometric crossmatch tests and solid-phase bead immunoassays. Renal allograft function was assessed by serum creatinine (SCr) values collected at early (mean, 50 days) and late (mean, 815 days) time points posttransplant and by incidence and type of rejection. Immunoglobulin G (IgG) subtype determination of both AECAs and HLA antibodies bound to ECPs was performed using flow cytometry. RESULTS: Fourteen patients (23%) tested positive for donor-reactive IgG AECAs and had statistically higher SCr values and incidences of cellular rejection early posttransplant compared with 46 patients who tested negative (P=0.014 and P<0.05). SCr values were not statistically different late posttransplant. IgG subclass determination showed AECAs to be enriched for IgG2 and IgG4, subclasses that do not activate complement effectively. Detection of donor-reactive immunoglobulin M (IgM) AECAs did not correlate with increased SCr or incidence of rejection. CONCLUSION: Crossmatch tests performed using donor-derived ECPs allow for the identification of alloantibodies that are associated with cellular rejection and are distinct from alloantibodies detected using lymphocytes.

The characterization and classification of concurrent blood group antibodies.

BACKGROUND: Concurrent alloantibodies are defined as two or more blood group (BG) antibodies coexisting in a given patient. These antibodies are significant because they can present major problems in compatibility testing. The goals of this study were to determine the properties of concurrent BG antibodies. STUDY DESIGN AND METHODS: The transfusion records of 18,750 patients at a Veterans Affairs medical center were reviewed to identify alloimmunized individuals. The following data were collected on patients making concurrent antibodies: antibody specificities, time of first detection, whether the antibodies disappeared over time, and, if so, their time of disappearance. RESULTS: Multiple alloimmunization occurred in 21.7% (96/443) of alloimmunized patients, constituting 39.9% (230/577) of all antibodies. The rate at which an antibody was concurrent with another antibody varied by antigenic specificity (p < 0.05). Anti-C (21/28; 71.4%) and anti-c (19/27; 70.4%) were most likely to coexist with another antibody, while anti-P(1) (3/22; 13.6%) and anti-M (3/18; 16.7%) were least likely. The most common alloantibody pairs were anti-K/-E, anti-D/-C, and anti-E/-c. Paired antibodies were initially detected in the same antibody screen in most cases. The majority of antibody pairs were either both persistent or both evanescent. When they were evanescent, both antibodies usually became undetectable at the same time. The persistence over time of concurrent alloantibodies (70.4%) was not higher than that of antibodies occurring singly (67.5%; p = 0.63). CONCLUSIONS: Antibody concurrence varied by BG antigenic specificity. Paired BG antibodies tended to appear and disappear in a coordinated fashion. Concurrent alloimmunization had no effect on antibody persistence.

Characterization of anti-D monoclonal antibody reagents based on their reactivity with the weak D phenotype.

BACKGROUND: Anti-D monoclonal antibody (MoAb) reagents have improved D typing in routine tests. However, they exhibit a wide range of reactivity with the weak D phenotype depending on the characteristics of the different MoAbs used. We analyzed the reactivity of immunoglobulin (IgM) anti-D by cluster analysis to characterize MoAb that have similar reactivities with the weak D phenotype. STUDY DESIGN AND METHODS: We used 36 consecutive samples with weak D phenotype in routine testing and determined their reactivity with different IgM and IgG anti-D MoAbs. The samples were characterized as belonging to a weak D type or category using commercial molecular biology kits. RESULTS: The various anti-D MoAbs showed a wide grade of reactivity with the weak D samples. Similarities and dissimilarities in the behavior of the anti-D MoAbs with the weak D phenotype samples were detected with cluster analysis and the multidimensional scaling analysis. These analyses indicated different families of MoAbs characterized as having a high degree of homogeneity in their reactivity with the weak D phenotype. Between these MoAb families, the most effective at reacting with the weak D phenotype were RUM-1 and 175-2. CONCLUSIONS: The results show that it is possible to classify the anti-D MoAbs on the basis of their reactivity with the weak D phenotype. This provides information about different MoAbs' properties on the basis of their belonging to a given of anti-D family.

Impact of HLA-C and Bw epitopes disparity on liver transplantation outcome.

The occurrence of graft rejection episodes after orthotopic liver transplantation (OLT) despite the use of immunosuppressive drugs designed to suppress T lymphocyte functions, indicates the involvement of other types of cells in this process. The activity of natural killer cells and their killer immunoglobulin-like receptors (KIR) is regulated by human leukocyte antigen (HLA) class I determinants; C and Bw epitopes. Because recipient/donor pairs are usually HLA mismatched, recipient natural killer alloreactivity may be the mediating factor in rejection. In this retrospective study, we have analyzed rejection occurrence and outcome in 66 OLT recipients, 42 with and 24 without C or Bw epitope disparity in the rejection direction. Recipients transplanted from donors with no C epitope disparity had significantly fewer rejection episodes in the first year after transplantation compared with recipients transplanted across C epitope disparity (p = 0.0002). Moreover, this effect was more pronounced when the outcome was analyzed in OLT recipients across negative crossmatching for the anti-HLA class I and II antibodies. In contrast, Bw epitope disparity did not affect the outcome. In conclusion, C epitopes disparity between recipients and donors in the rejection direction appears to influence posttransplant liver outcome. This finding may be helpful in the choice of appropriate liver donor and planning immune suppression.

Section 1A: Rh serology. Coordinator's report.

One hundred forty-two Rh-specific monoclonal antibodies (Mabs) were evaluated by serology in 27 laboratories. Evaluators were asked to test each Mab at three dilutions in specified serological techniques against normal positive and normal negative phenotype cells, and any Rh variant cells that they had available. Raw data was submitted to the coordinator for overall analysis. Results were analysed by expressing the sum of reaction grades for each Mab with each variant cell as a percentage of the sum of reaction grades of that Mab with normal phenotype cells. Anti-D Mabs were sorted into 23 groups which had the same pattern of reactions with different partial D phenotype cells. Eighteen of these corresponded to previously defined patterns; five were new patterns. Combined with data from the previous workshop, this means that 30 different reaction patterns have been defined. A new nomenclature is introduced for numbering the epitopes. Reactions with new variants DNB, DNU and DAR indicated some further subsplits of these patterns. Reactions with Category Va cells indicated that there were five different types of Va cells that could be distinguished serologically with monoclonal antibodies. No patterns of reactivity corresponding to the epitope groups could be observed with the different types of weak D tested. Anti-E Mabs were sorted into 14 groups, and the E variant cells into seven groups.

Classification of the kinetics of factor VIII inhibitors in haemophilia A: plasma dilution studies are more discriminatory than time-course studies.

Factor VIII inhibitors have previously been classified as type I or type II using complex experiments that study the time course of inactivation of factor VIII and the effect of varying the antibody concentration. Classification may be important to better understand inhibitor behaviour in vivo. To determine the most reliable method of classifying the kinetics of factor VIII inactivation, we studied 11 patients with haemophilia A, comprising five severe, three mild and three acquired cases, and compared the classification obtained from plasma dilution studies and time-course studies. The plasma dilution studies showed two distinctly different patterns: a steep slope with complete FVIII:C inactivation at high antibody concentrations for type I inhibitors and a FVIII:C plateau with incomplete inactivation for type II inhibitors. Six type I (four severe, one mild and one acquired) and two type II (one mild and one acquired) inhibitors were classified using either plasma samples or purified and concentrated IgG, while the remaining were undetermined owing to insufficient available plasma. In contrast, the time-course studies could not discriminate between these groups. We recommend that plasma dilution studies be used for the classification of in vitro kinetics of factor VIII inhibitors.

Ceftizoxime-induced hemolysis secondary to combined drug adsorption and immune-complex mechanisms.

BACKGROUND: Immune hemolytic anemia has been associated with the administration of various antibiotics, including cephalosporins. Presented here is a patient who developed severe acute hemolysis while receiving ceftizoxime (Ceftizox, Fujisawa USA), a third-generation cephalosporin. This is the fourth reported case of hemolysis in association with ceftizoxime. In the previous cases, ceftizoxime was shown to induce hemolysis by the immune-complex mechanism. However, in one of those reports, the concentration of drug used to treat the target RBCs in vitro may not have been optimal. CASE REPORT: The patient's antemortem blood samples were analyzed retrospectively for drug-dependent antibodies by the drug-adsorption and immune-complex methods. Antibody class and titer were evaluated. RESULTS: The patient's sample agglutinated RBCs coated with ceftizoxime as well as uncoated RBCs in the presence of ceftizoxime. The antibodies to ceftizoxime were IgM and IgG. CONCLUSION: This is the first report on both the immune-complex and drug-adsorption mechanisms of ceftizoxime-induced hemolysis. The differential diagnosis of a falling Hct in a patient receiving antibiotics should include drug-related hemolysis; once this diagnosis is considered, management includes the appropriate serologic workup, immediate cessation of the implicated drugs, and possible transfusion support.

Decision aides in immunohematology: detection of anti-erythrocyte antibodies. / Aide à la décision en immunohématologie: recherche des anticorps anti-érythrocytaires (RAI).

Detection and identification of irregular red-cell antibody in the serum or plasma of a patient is of prime importance for the prevention of hemolytic transfusion reactions and the biological supervision of the hemolytic disease of the foetus or the newborn. Practice in these tests is replete with complex biological problems. Using problem solving strategies, we discuss the recognition and resolution of the most frequent difficulties encountered in red cell antibody identification.