Description

Autoimmune disease refers to the disease in which the immune system reacts to the host's own body and causes damage to tissues and organs. At present, the pathogenesis of various autoimmune diseases is still not well understood, but an imbalanced immune tolerance plays a key role in this process.

An ideal therapy to autoimmune disease should eradicate pathogenic autoimmune cells but retain the protective immunity. The chimeric antigen receptor-modified T (CAR-T) cell technology has proven to be highly effective in targeting B cell malignancies, and the treatment-induced B cell and antibody deficiencies have implications for treating autoantibody-related autoimmune diseases. Studies have shown that CAR-T cells targeting B cell surface molecules can kill autoreactive B lymphocytes in pemphigus vulgaris (PV) and systemic lupus erythematosus (SLE) patients. Thus, CAR-T targeting antibody-producing cells has potential in treating autoimmune diseases including PV, SLE, autoimmune hemolytic anemia, Sjogren's syndrome etc..

MSCs have immune modulatory and immunosuppressive effects. MSCs have been extensively studied and clinically evaluated for the treatment of autoimmune diseases and graft versus host disease (GVHD) caused by hematopoietic stem cell transplantation (HSCT). In many studies, MSCs have demonstrated promising beneficial effects that can reduce severe autoimmune reactions. In recent years, MSCs have been used in synergy with CAR-T cells to address the shortcomings of CAR-T cells. Fetal tissue-derived clonal MSCs (fMSCs) have extended expansion potential and express rich levels of various growth factors. The fMSCs also resove a main limitation in MSC quality and reliability issues related to product consistency of MSCs. As such, innovative strategies to maximise the synergistic effects of CAR-Ts and MSCs have been proposed by either using MSCs as a supplementary intervention to assist in CAR-T based immunotherapies or as part of a sequential therapy regimen.

CD19- and BCMA-specific CAR is based on activation of intracellular signalijng domains of T cells by the extracellular single chain variable fragment (scFv) antibodies against CD19 and BCMA. The activated CAR-T cells can target and kill B cells. The investigation plans to use genetically modified T cells to express 4th generation lentiviral CARs with an inducible caspase 9 self-withdrawal gene (4SCAR) to increase the safety of this specific approach. Besides targeting CD19 and BCMA, other B cell and plasma cell surface molecules will also be targeted and included in the treatment design. Based on accumulated experiences, the 4SCAR T cells have shown high safety profile without serious cytokine release syndrome (CRS) or neural toxicities in patients. Through this trial, the safety and long-term efficacy of synergistic B-cell- and plasma-cell-specific 4SCAR T-cell therapy with MSCs will be evaluated, providing clinical evidence to support the use of 4SCAR-T cells and MSCs in the treatment of autoimmune diseases.