Detection of Intragraft Anti-Blood Group A and B Antibodies Following Renal Transplantation.

BACKGROUND: Graft immunocomplex capture fluorescence analysis is an attractive method to detect intragraft donor-specific anti-HLA antibodies. In ABO-incompatible transplantation, anti-A and B antibodies are also considered to be important donor specific antibodies (ABO-DSA). Therefore, it is useful to monitor intragraft ABO-DSAs to assess antibody-mediated rejection. METHODS: To capture A and B antigens, anti-Band III, von Willebrand factor (VW), and plasmalemma vesicle-associated protein (PLVAP) beads were produced. The allograft specimen was homogenized in a lysis buffer. Subsequently, A and B antigens were captured by anti-Band III, VW, or PLVAP beads. The immune complexes were then detected by phycoerythrin-conjugated anti-human IgG antibodies and analyzed using a Luminex system. RESULTS: Although Band III and VW beads yielded false positives and false negatives, PLVAP beads captured A and B antigens with high sensitivity (91.7%) and specificity (100%) when an index > 1.5 was considered positive. The proximity in A and B antigens and PLVAP expression was confirmed using immunohistochemical evaluation. Furthermore, sodium dodecyl sulfate polyacrylamide gel electrophoresis supported that PLVAP is an A and B antigen carrier protein. CASE REPORT: Biopsies were conducted following an ABO-incompatible renal transplant (type A to O) and evaluated for ABO-DSA. Graft immunocomplex capture fluorescence analysis was demonstrated as follows: 3.19 (1 h, serum creatinine [s-Cr] 3.95 mg/dL, titer IgG 1:512, glomerulitis [g] 0, peritubular capillaritis [ptc] 0, complement 4d [C4d] 1); 1.8 (4 d, s-Cr 2.29 mg/dL, titer 1:256, g 0, ptc 0, C4d 3); 1.2 (22 d, s-Cr 1.58 mg/dL, titer 1:128, g 0, ptc 2, C4d 3). This result indicated that the remnant ABO-DSA were adsorbed and subsequently removed from the allograft successfully. CONCLUSIONS: This novel application could be used to detect intragraft ABO-DSAs, which could lead to a correct diagnosis and shed light on the ABO-DSA kinetics following ABO-incompatible transplantation.

Clearance of Intra-graft Donor Specific Anti-HLA Antibodies in the Early Stage of Antibody-Mediated Rejection Following Rituximab and Apheresis Therapy in Renal Transplantation.

BACKGROUND: The management of acute or, in particular, chronic antibody-mediated rejection (AMR) resulting from donor-specific HLA antibodies (DSA) is a critical barrier to obtaining better long-term graft survival. To ascertain the efficacy of anti-AMR therapies, the transition of intra-graft DSA (g-DSA) was assessed. METHODS: Allograft biopsy specimens were analyzed by graft immunocomplex capture fluorescence analysis, as previously described. One hundred recipients who underwent graft biopsies between April 2016 and December 2017 were enrolled for this study. Fifteen recipients diagnosed with g-DSA positive (+) received anti-humoral treatments and underwent follow-up biopsies. g-DSA levels were assessed again by a follow-up biopsy at 6-12 months following the treatments. RESULTS: With anti-humoral treatments, 9 out of 15 recipients comprised a g-DSA negative (-) (3.59 ± 2.82-.58 ± .25): g-DSA6-12- group, while the remaining 6 recipients comprised a g-DSA +(20.6 ± 17.0-14.9 ± 14.1): g-DSA6-12+ group. The initial g-DSA scores were significantly higher in the g-DSA6-12+ group (P = .01). All samples were diagnosed as chronic AMR in the g-DSA+ groups, whereas there were 3 chronic AMR, 4 acute AMR, and 2 incomplete AMR samples in the g-DSA- group. Interestingly, the frequency of responsible DSA belonging to class II tended to be higher in the g-DSA6-12+ group (4/6) compared to the g-DSA6-12- group (2/9) (P = .14). CONCLUSION: These results imply that chronic exposure to DSA causes significant and irreversible damage to the allograft. Timely and adequate anti-humoral intervention might reverse the early phase of AMR with complete clearance of g-DSA.

Graft Immunocomplex Capture Fluorescence Analysis to Detect Donor-Specific Antibodies and HLA Antigen Complexes in the Allograft.

BACKGROUND: Immunocomplex capture fluorescence analysis (ICFA) is an attractive method to detect donor-specific anti-HLA antibodies (DSA) and HLA antigen complexes. Currently, antibody-mediated rejection (AMR) due to DSA is usually diagnosed by C4d deposition and serological DSA detection. Conversely, there is a discrepancy between these findings frequently. Thereupon, our graft ICFA technique may contribute to establish the diagnosis of AMR. METHODS: Graft samples were obtained by a percutaneous needle biopsy. Then, the specimen was dissolved in PBS by the lysis buffer. Subsequently, HLA antigens were captured by anti-HLA beads. Then, DSA-HLA complexes were detected by PE-conjugated anti-human IgG antibodies, where DSA had already reacted with the allograft in vivo, analyzed by a Luminex system. RESULTS: A ratio (sample MFI/blank beads MFI) was calculated: ≥ 1.0 was determined as positive. We found that DSA-HLA complexes in the graft were successfully detected from only slight positive 1.03 to 79.27 in a chronic active AMR patient by graft ICFA. Next, positive graft ICFA had predicted the early phase of AMR (MFI ratio: 1.38) even in patients with no serum DSA. Finally, appropriate therapies for AMR deleted DSA deposition (MFI ratio from 0.3 to 0.7) from allografts. CONCLUSIONS: This novel application would detect early phase or incomplete pathological cases of AMR, which could lead to a correct diagnosis and initiation of appropriate therapies. Moreover, graft ICFA might address a variety of long-standing questions in terms of DSA. ABBREVIATIONS: AMR: Antibody-mediated rejection; DSA: Donor-specific antibodies; ICFA: Immunocomplex capture fluorescence analysis.