A reverse translational study on the effect of rituximab, rituximab plus belimumab, or bortezomib on the humoral autoimmune response in SLE

Objectives To investigate whether bortezomib, a proteasome inhibitor approved for treatment of multiple myeloma, induces clinically relevant plasma cell (PC) depletion in patients with active, refractory systemic lupus erythematosus (SLE). Methods Twelve patients received a median of two (range 1–4) 21-day cycles of intravenous bortezomib (1.3 mg/m2) with the coadministration of dexamethasone (20 mg) for active SLE. Disease activity was assessed using the SLEDAI-2K score. Serum concentrations of anti–double-stranded DNA (anti-dsDNA) and vaccine-induced protective antibodies were monitored. Flow cytometry was performed to analyse peripheral blood B-cells, PCs and Siglec-1 expression on monocytes as surrogate marker for type-I interferon (IFN) activity. Results Upon proteasome inhibition, disease activity significantly declined and remained stable for 6 months on maintenance therapies. Nineteen treatment-emergent adverse events occurred and, although mostly mild to moderate, resulted in treatment discontinuation in seven patients. Serum antibody levels significantly declined, with greater reductions in anti-dsDNA (∼60%) than vaccine-induced protective antibody titres (∼30%). Bortezomib significantly reduced the numbers of peripheral blood and bone marrow PCs (∼50%), but their numbers increased between cycles. Siglec-1 expression on monocytes significantly declined. Conclusions These findings identify proteasome inhibitors as a putative therapeutic option for patients with refractory SLE by targeting PCs and type-I IFN activity, but our results must be confirmed in controlled trials.

Recent research in systemic lupus erythematosus (SLE) yielded new antigens and antibodies in SLE patients. We describe the various autoantibodies that can be detected in patients with SLE. A literature review, using the terms “autoantibody” and “systemic lupus erythematosus”, was conducted to search for articles on autoantibodies in SLE, their target antigens, association with disease activity and other clinical manifestations. One hundred and eighty autoantibodies were so far described in SLE patients. These include autoantibodies that target nuclear antigens, cytoplasmic antigens, cell membrane antigens, phospholipid-associated antigens, blood cells, endothelial cells, and nervous system antigens, plasma proteins, matrix proteins, and miscellaneous antigens. The target of an autoantibody, the autoantigen properties, autoantibody frequencies in SLE, as well as clinical associations, and correlation with disease activity are described for all 180 autoantibodies. SLE is so far the autoimmune disease with the largest number of detectable autoantibodies. Their production could be antigen-driven, the result of a polyclonal B cell activation, impaired apoptotic pathways, or the outcome of an idiotypic network dysregulation.

Autoantibodies are secreted by plasma cells and have an essential role in driving the renal manifestations of autoimmune diseases such as systemic lupus erythematosus and antineutrophil cytoplasmic autoantibody-associated vasculitis. Effective depletion of autoreactive plasma cells might be the key to curative treatment of these diseases. Two major plasma-cell compartments exist: short-lived plasmablasts or plasma cells, which result from differentiation of activated B cells, and long-lived plasma cells, which result from secondary immune responses. Long-lived plasma cells reside in survival niches in bone marrow and inflamed tissue and provide the basis of humoral memory and refractory autoimmune disease activity. Unlike short-lived plasmablasts, long-lived plasma cells do not respond to conventional immunosuppression or to therapies that target B cells. Existing therapies that target long-lived plasma cells, such as proteasome inhibitors and antithymocyte globulin, as well as promising approaches that target survival factors, cell homing or surface molecules, deplete the whole memory plasma cell pool, including cells that secrete protective antibodies. By contrast, we have developed a novel strategy that uses an affinity matrix to deplete pathogenic long-lived plasma cells in an autoantigen-specific manner without removing protective plasma cells. Targeting B-cell precursors to prevent replenishment of autoreactive long-lived plasma cells should also be considered.