Selective Depletion of ABO-Responsive B Cells by T-Cell-Engaging Bispecific Antibody Conjugates for ABOi Transplantation Available to Purchase

• A bispecific antibody-ligand conjugate (BiALC) was developed to selectively eliminates A antigen-responsive B cells by recruiting T cells.

• A-antigen-conjugated BiALC depletes target B cells in human PBMCs with efficacy comparable to rituximab, while sparing bystander B cells.

Organ transplantation is a pivotal treatment for patients with organ failure. ABO-incompatible (ABOi) transplantation, developed to expand the donor pool, presents significant clinical challenges due to pre-existing antibodies targeting ABO antigens on donor organs. Current therapies employing broad B-cell depletion, such as rituximab, effectively reduce antibody-mediated rejection but increase infection risks. Therefore, there is a critical need of targeted methods to specifically eliminate ABO-responsive B cells. Here, we developed a novel bispecific antibody-ligand conjugate (BiALC) platform designed to selectively target ABO-responsive B cells. Utilizing synthetic trisaccharide A antigens conjugated to T-cell-recruiting Fab fragments, our optimized hexameric construct, (A3-peg)2-αCD3, demonstrated enhanced affinity and potent cytotoxicity specifically against type A antigen-responsive B cells. Notably, BiALC maintained robust efficacy even in the presence of circulating anti-A antibodies. In murine models, (A3-peg)2-αCD3 selectively depleted A-responsive B cells without broadly affecting total IgM+ and IgG+ B cell populations, preserving overall immune competence. Similarly, the human-compatible BiALC, (A3-peg)2-αhCD3, effectively and selectively depleted type A-responsive B cells from human PBMCs, with potency comparable to rituximab, while sparing total antibody-secreting cells. Overall, the BiALC strategy offers a promising antigen-specific approach to reduce rejection risks in ABOi transplantation without inducing broad immunosuppression through nonspecific pan-B cell depletion, supporting its potential for clinical translation.