Project description:Current CAR-T cell therapy's clinical potential is hampered by its autologous nature that poses significant challenges in manufacturing, costs, and patient selection. This spurs demand for off-the-shelf therapies. Here we introduce an ex vivo feeder-free culture to differentiate gene-engineered HSCs into allogeneic NKT cells and their CAR-armed derivatives (AlloCAR-NKT cells). The AlloCAR-NKT cells are generated at high yield, purity, and robustness. These cells exhibit potent antitumor efficacy, showing effective tumor homing, clonal expansion, and persistence In vivo. Impressively, AlloCAR-NKT cells can alter the tumor microenvironment by selectively depleting immunosuppressive TAMs and MDSCs, and can antagonize tumor immune evasion by deploying CAR/TCR/NKR triple-targeting mechanisms. AlloCAR-NKT cells also demonstrate an appealing safety profile with low GvHD and CRS risks, and exhibit a stable “hypoimmunogenic” phenotype attributed to epigenetic and signaling regulations. The reported technology presents a scalable strategy for diverse allogeneic CAR-NKT cell products, with potential for clinical translation and commercialization against various cancers.

Project description:Epigenetic Editing Balances TCR Suppression and Persistence in CAR T cells

Project description:While T cell-based immunotherapies have shown promising clinical responses, current cancer treatments are restricted to autologous cellular products due to the risk of graft-versus-host disease (GvHD) by allogeneic cell transfer. Invariant natural killer T (iNKT) cells are ideal cell carriers for developing off-the-shelf allogeneic cellular therapy because they are powerful immune cells targeting a broad range of cancers without causing GvHD. However, current immunotherapies using iNKT cells are impeded by their extremely low number in cancer patients. In this study, we aimed to overcome this limitation by generating a large number of iNKT cells through TCR engineering of human hematopoietic stem cells (HSCs) and differentiation of HSCs to iNKT cells in an in vitro cultured system. Additionally, Chimeric antigen receptor (CAR) engineering and the CRISPR-Cas9 gene editing tool were utilized to enhance the tumor killing efficacy of iNKT cells and eliminate HLA molecules on their surface, making the cellular product suitable for cancer therapy and allogeneic adoptive transfer. Our results demonstrated successful generation of the promising off-the-shelf B cell maturation antigen (BCMA)-CAR engineered iNKT cells for treating multiple myeloma, and the same strategy will be applied to multiple cellular products for treating other cancers.

Project description:While T cell-based immunotherapies have shown promising clinical responses, current cancer treatments are restricted to autologous cellular products due to the risk of graft-versus-host disease (GvHD) by allogeneic cell transfer. Invariant natural killer T (iNKT) cells are ideal cell carriers for developing off-the-shelf allogeneic cellular therapy because they are powerful immune cells targeting a broad range of cancers without causing GvHD. However, current immunotherapies using iNKT cells are impeded by their extremely low number in cancer patients. In this study, we aimed to overcome this limitation by generating a large number of iNKT cells through TCR engineering of human hematopoietic stem cells (HSCs) and differentiation of HSCs to iNKT cells in an in vitro cultured system. Additionally, Chimeric antigen receptor (CAR) engineering and the CRISPR-Cas9 gene editing tool were utilized to enhance the tumor killing efficacy of iNKT cells and eliminate HLA molecules on their surface, making the cellular product suitable for cancer therapy and allogeneic adoptive transfer. Our results demonstrated successful generation of the promising off-the-shelf B cell maturation antigen (BCMA)-CAR engineered iNKT cells for treating multiple myeloma, and the same strategy will be applied to multiple cellular products for treating other cancers.

Project description:The direct integration of chimeric-antigen-receptor (CAR) T cell with allogeneic hematopoietic cell transplantation (allo-HCT) carries the risk of graft-versus-host disease (GVHD) induction by allogeneic CAR-T cells. Based on our past experiments, it has been shown that post-transplantation cyclophosphamide (PTCy) prevents GVHD induction by other cell infusions after T-cell-replete MHC-haploidentical murine allo-HCT models. In this study, we investigated whether CAR-T cells, given in a similar manner in the same MHC-haploidentical murine allo-HCT model, could safely exert anti-tumor effects. We showed that anti-CD19 CAR-T cells administered early after (day +5 of transplant) or prior to (day 0 of transplant) PTCy for allo-HCT cleared leukemia without toxicity or GVHD exacerbation. Using next generation single-cell RNA sequencing approaches, we demonstrated that in comparison to CAR-T cells infused early after PTCy (day +5), CAR-T cells infused prior to PTCy (day 0) exhibited transcriptional changes consistent with increased CD4+ T-cell activation and CD8+ T-cell cytotoxicity.

Project description:The excessive cytokine release and limited persistence represent major obstacles to successful chimeric antigen receptor T (CAR-T) cell therapy in solid tumors. Conventional CARs employ an intracellular domain (ICD) from the ζ chain of CD3 as a signaling module, and it is largely unknown how alternative CD3 chains potentially contribute to CAR design. Here, we obtained a series of CAR-T cells against HER2 and mesothelin using a domain containing one immunoreceptor tyrosine-based activation motif from different CD3 subunits as the ICD of CARs. While these reconstituted CARs conferred sufficient antigen-specific cytolytic activity on equipped T cells, they elicited low tonic signal, ameliorated CAR-T cell exhaustion and facilitated memory differentiation. Intriguingly, the CD3ε-derived ICD outperformed others in generation of CAR-T cells that produced minimized cytokines. Mechanistically, CD3ε-based CARs displayed a restrained cytomembrane expression on engineered T cells, which was ascribed to endoplasmic reticulum retention mediated by the carboxyl terminal basic residues. The present study demonstrated the applicability of CAR reconstitution using signaling modules from different CD3 subunits, and depicted a novel pattern of CAR expression that reduces cytokine release, thus paving a way for generation of CAR-T cells with improved safety and persistence against diverse tumor antigens.

Project description:Ovarian cancer (OC) poses a significant challenge due to frequent recurrence linked to tumor heterogeneity and an immunosuppressive tumor microenvironment (TME). Targeting both OC cells and TME simultaneously holds promise for effective treatment. This study comprehensively analyzed 17 chemonaive and 18 refractory/recurrent OC samples, identifying mesothelin (MSLN) and natural killer receptor (NKR) ligands as tumor targets and CD1d as an OC TME target. Leveraging hematopoietic stem cell (HSC) gene engineering and feeder-free differentiation culture, we generated allogeneic MSLN-targeting CAR (MCAR)-engineered invariant natural killer T (MCAR-NKT) cells, demonstrating high-yield and high-purity production, potent antitumor efficacy, multiple tumor targeting mechanism, and significant in vivo expansion and persistence. Notably, these cells selectively deplete immunosuppressive TAMs and MDSCs, counteract tumor immune evasion, display a favorable safety profile with low risks of GvHD and CRS, and exhibit a stable “hypoimmunogenic” phenotype attributed to epigenetic and signaling regulations. These findings underscore the feasibility and therapeutic potential of allogeneic MCAR-NKT cell products for OC, laying a foundation for further translation and clinical development.

Project description:Ovarian cancer (OC) poses a significant challenge due to frequent recurrence linked to tumor heterogeneity and an immunosuppressive tumor microenvironment (TME). Targeting both OC cells and TME simultaneously holds promise for effective treatment. This study comprehensively analyzed 17 chemonaive and 18 refractory/recurrent OC samples, identifying mesothelin (MSLN) and natural killer receptor (NKR) ligands as tumor targets and CD1d as an OC TME target. Leveraging hematopoietic stem cell (HSC) gene engineering and feeder-free differentiation culture, we generated allogeneic MSLN-targeting CAR (MCAR)-engineered invariant natural killer T (MCAR-NKT) cells, demonstrating high-yield and high-purity production,potentantitumor efficacy, multiple tumor targeting mechanism, and significant in vivo expansion and persistence. Notably, these cells selectively deplete immunosuppressive TAMs and MDSCs, counteract tumor immune evasion, display a favorable safety profile with low risks of GvHD and CRS, and exhibit a stable “hypoimmunogenic” phenotype attributed to epigenetic and signaling regulations. These findings underscore the preclinical feasibility and therapeutic potential of allogeneic MCAR-NKT cell products for OC, laying a foundation for translational and clinical development.

Project description:Ovarian cancer (OC) poses a significant challenge due to frequent recurrence linked to tumor heterogeneity and an immunosuppressive tumor microenvironment (TME). Targeting both OC cells and TME simultaneously holds promise for effective treatment. This study comprehensively analyzed 17 chemonaive and 18 refractory/recurrent OC samples, identifying mesothelin (MSLN) and natural killer receptor (NKR) ligands as tumor targets and CD1d as an OC TME target. Leveraging hematopoietic stem cell (HSC) gene engineering and feeder-free differentiation culture, we generated allogeneic MSLN-targeting CAR (MCAR)-engineered invariant natural killer T (MCAR-NKT) cells, demonstrating high-yield and high-purity production, potent antitumor efficacy, multiple tumor targeting mechanism, and significant in vivo expansion and persistence. Notably, these cells selectively deplete immunosuppressive TAMs and MDSCs, counteract tumor immune evasion, display a favorable safety profile with low risks of GvHD and CRS, and exhibit a stable “hypoimmunogenic” phenotype attributed to epigenetic and signaling regulations. These findings underscore the feasibility and therapeutic potential of allogeneic MCAR-NKT cell products for OC, laying a foundation for further translation and clinical development.

Project description:Ovarian cancer (OC) poses a significant challenge due to frequent recurrence linked to tumor heterogeneity and an immunosuppressive tumor microenvironment (TME). Targeting both OC cells and TME simultaneously holds promise for effective treatment. This study comprehensively analyzed 17 chemonaive and 18 refractory/recurrent OC samples, identifying mesothelin (MSLN) and natural killer receptor (NKR) ligands as tumor targets and CD1d as an OC TME target. Leveraging hematopoietic stem cell (HSC) gene engineering and feeder-free differentiation culture, we generated allogeneic MSLN-targeting CAR (MCAR)-engineered invariant natural killer T (MCAR-NKT) cells, demonstrating high-yield and high-purity production, potent antitumor efficacy, multiple tumor targeting mechanism, and significant in vivo expansion and persistence. Notably, these cells selectively deplete immunosuppressive TAMs and MDSCs, counteract tumor immune evasion, display a favorable safety profile with low risks of GvHD and CRS, and exhibit a stable “hypoimmunogenic” phenotype attributed to epigenetic and signaling regulations. These findings underscore the feasibility and therapeutic potential of allogeneic MCAR-NKT cell products for OC, laying a foundation for further translation and clinical development.