Comparative evaluation of antitumor effects of TNF superfamily costimulatory ligands delivered by mesenchymal stem cells.

Stimulation of costimulatory receptors serves as an alternative immunotherapeutic strategy other than checkpoint inhibition. However, systemic administration of the agonistic antibodies is associated with severe toxicities, which is one of the major obstacles for their clinical application. This study aimed to develop a mesenchymal stem cell (MSC)-based system for tumor-targeted delivery of TNF superfamily ligands and assess their potential in enhancing antitumor immunity. Here we established an MSC-based system for tumor-targeted delivery of TNF superfamily ligands, including TNFSF4, 9 and 18. The TNFSF receptors (TNFRSFs) were evaluated in mouse models and patient samples for lung and colorectal cancers. TNFRSFs were all expressed at various levels on tumor-infiltrated lymphocytes, with TNFRSF18 being the most prevalent receptor. Human umbilical cord-derived MSCs expressing these costimulatory ligands (MSC-TNFSFs) effectively activated lymphocytes in vitro and elicited antitumor immunity in mice. TNFSF4 showed the least antitumor efficacy in both LLC1 and CT26 tumor models. MSC-TNFSF9 showed the most potent tumor-inhibiting effect in the LLC1 tumor model, while MSCs expressing TNFSF18 in combination with CXCL9 most significantly repressed CT26 tumor growth. Overall, TNFSF9 and TNFSF18 exhibited stronger lymphocyte-stimulating and antitumor activities than TNFSF4. Our study provides evidence that antitumor effects of agonism of different costimulatory receptors may vary in different tumor types and presents a promising approach for targeted delivery of TNF superfamily costimulatory ligands to avoid the systemic toxicities and side effects associated with immune agonist antibodies.

Strategies for modifying the chimeric antigen receptor (CAR) to improve safety and reduce toxicity in CAR T cell therapy for cancer.

Immune cell therapy with chimeric antigen receptor (CAR) T cells, which has shown promising efficacy in patients with some hematologic malignancies, has introduced several successfully approved CAR T cell therapy products. Nevertheless, despite significant advances, treatment with these products has major challenges regarding potential toxicity and sometimes fatal adverse effects for patients. These toxicities can result from cytokine release or on-target off-tumor toxicity that targets healthy host tissue following CAR T cell therapy. The present study focuses on the unexpected side effects of targeting normal host tissues with off-target toxicity. Also, recent safety strategies such as replacing or adding different components to CARs and redesigning CAR structures to eliminate the toxic impact of CAR T cells, including T cell antigen coupler (TAC), switch molecules, suicide genes, and humanized monoclonal antibodies in the design of CARs, are discussed in this review.

Generation and Functional Characterization of PLAP CAR-T Cells against Cervical Cancer Cells.

Chimeric antigen receptor (CAR) T-cell therapy is one of the cancer treatment modalities that has recently shown promising results in treating hematopoietic malignancies. However, one of the obstacles that need to be addressed in solid tumors is the on-target and off-tumor cytotoxicity due to the lack of specific tumor antigens with low expression in healthy cells. Placental alkaline phosphatase (PLAP) is a shared placenta- and tumor-associated antigen (TAA) that is expressed in ovarian, cervical, colorectal, and prostate cancers and is negligible in normal cells. In this study, we constructed second-generation CAR T cells with a fully human scFv against PLAP antigen andthen evaluated the characteristics of PLAP CAR T cells in terms of tonic signaling and differentiation in comparison with ΔPLAP CAR T cells and CD19 CAR T cells. In addition, by co-culturing PLAP CAR T cells with HeLa and CaSki cells, we analyzed the tumor-killing functions and the secretion of anti-tumor molecules. Results showed that PLAP CAR T cells not only proliferated during co-culture with cancer cells but also eliminated them in vitro. We also observed increased secretion of IL-2, granzyme A, and IFN-γ by PLAP CAR T cells upon exposure to the target cells. In conclusion, PLAP CAR T cells are potential candidates for further investigation in cervical cancer and, potentially, other solid tumors.