Anti-CD20 Ab therapy has proven successful for treating B cell malignancies and a number of autoimmune diseases. However, how anti-CD20 Abs operate in vivo to mediate B cell depletion is not fully understood. In particular, the anatomical location, the type of effector cells, and the mechanism underlying anti-CD20 therapy remain uncertain. Here, we found that the liver is a major site for B cell depletion and that recirculation accounts for the decrease in B cell numbers observed in secondary lymphoid organs. Using intravital imaging, we established that, upon anti-CD20 treatment, Kupffer cells (KCs) mediate the abrupt arrest and subsequent engulfment of B cells circulating in the liver sinusoids. KCs were also effective in depleting malignant B cells in a model of spontaneous lymphoma. Our results identify Ab-dependent cellular phagocytosis by KCs as a primary mechanism of anti-CD20 therapy and provide an experimental framework for optimizing the efficacy of therapeutic Abs.
IntroductionAnti-CD20 therapy mediates the depletion of B cells and represents a breakthrough in the treatment of B cell malignancies and autoimmune disorders (1-3). Multiple underlying mechanisms have been proposed, including complement-dependent cytotoxicity, Ab-dependent cell-mediated cytotoxicity, and Ab-dependent cellular phagocytosis. Preclinical studies have highlighted the importance of Fc receptor-dependent (FcR-dependent) processes for B cell depletion (4, 5), a finding consistent with the observed influence of FcR polymorphism on the efficiency of anti-CD20 therapy in humans (6). Many immune cells, including NK cells, macrophages, and monocytes, kill anti-CD20-coated B cells in vitro and/or are required for depletion in murine models (4,5,7). Paradoxically, despite more than 15 years of clinical experience, the anatomical location, the precise immune cell type, and the mechanism underlying anti-CD20 therapy remain incompletely understood (8). Addressing these questions remains critical to facilitate the design of improved therapeutic Abs. Here, we used a combination of surgical procedures, intravital 2-photon imaging, and a spontaneous tumor model to uncover the mechanism by which anti-CD20 injection results in the clearance of normal and malignant B cells.
