Hemolysis and Free Heme Impact Therapeutic Activity of Anti-CD20 Antibody

Hemolysis is a process of destruction of erythrocytes that can occur in different hereditary or acquired pathologies. It is accompanied by release of hemoglobin and heme, which both manifest potent pro-oxidative and pro-inflammatory activities. If released in large quantities hemoglobin and heme can directly contribute to systemic inflammation and tissue injury in hemolytic diseases. Moreover, it was demonstrated that heme binds to a significant fraction (ca. 10 %) of human antibodies (Abs) and this binding can result in considerable functional changes. Thus, heme-bound human IgG acquire reactivity towards a large set of unrelated proteins, including autoantigens. In a previous study we observed that 14 % of a repertoire of 117 clinical-stage therapeutic mAbs are able to bind heme and as a result they acquired autoreactivity and polyreactivity. Among these Abs some are specific for CD20 and used in lymphoma therapy (e.g. Rituximab). Importantly, therapeutic mAbs can be administered in patients with ongoing hemolysis. Thus, it is of critical importance to decipher molecular mechanism and functional consequences of interaction of heme with therapeutic mAbs and understand how the therapy of lymphoma can be affected by underling hemolysis and heme release.

The present study has the following objective: to elucidate the effect of heme on the therapeutic activity of anti-CD20 therapy in in vitro and in vivo models of B cell lymphoma. Effect of heme on anti-CD20 therapeutic Abs was assessed by i) binding assays - ELISA, western blot; protein microarrays; absorbance spectroscopy; surface plasmon resonance, and ii) molecular modeling. The impact of heme on functional and therapeutic activity of Rituximab was analyzed by i) site-directed mutagenesis; ii) flow cytometry; iv) in vitro and in vivo models of human B cell lymphoma.

Our data reveled molecular and functional details about the interaction of heme with Rituximab and other anti-CD20 Abs. Thus, we characterized the interaction of Abs with heme, and identified in case of Rituximab the putative binding site for heme that overlapped with antigen binding site. By using a protein array with >9800 human proteins, we identified the target proteins of heme-bound Rituximab. A mouse model of human B cell lymphoma revealed that the therapeutic activity of Rituximab was compromised following exposure to cell free heme under condition of acute intravascular hemolysis. Our study delineates that a fraction of currently used therapeutic mAbs show high sensitivity to heme and their therapeutic activity can be compromised under hemolytic conditions. This finding suggests that therapeutic interventions that reduce free heme and /or intravascular hemolysis should precede therapy with these Abs. Moreover, we identified sequence features of Abs that determine the sensitivity to heme. This finding can help to reduce sensitivity of heme of therapeutic Abs by protein engineering.