A modular and controllable T cell therapy platform for acute myeloid leukemia

Targeted T cell therapy is highly effective in disease settings where tumor antigens are uniformly expressed on malignant cells and where off-tumor on-target-associated toxicity is manageable. Although acute myeloid leukemia (AML) has in principle been shown to be a T cell-sensitive disease by the graft-versus-leukemia activity of allogeneic stem cell transplantation, T cell therapy has so far failed in this setting. This is largely due to the lack of target structures both sufficiently selective and uniformly expressed on AML, causing unacceptable myeloid cell toxicity. To address this, we developed a modular and controllable MHC-unrestricted adoptive T cell therapy platform tailored to AML. This platform combines synthetic agonistic receptor (SAR) -transduced T cells with AML-targeting tandem single chain variable fragment (scFv) constructs. Construct exchange allows SAR T cells to be redirected toward alternative targets, a process enabled by the short half-life and controllability of these antibody fragments. Combining SAR-transduced T cells with the scFv constructs resulted in selective killing of CD33(+) and CD123(+) AML cell lines, as well as of patient-derived AML blasts. Durable responses and persistence of SAR-transduced T cells could also be demonstrated in AML xenograft models. Together these results warrant further translation of this novel platform for AML treatment. Keypoints Modular platform enabling controlled targeting of AML by SAR-transduced T cells in combination with tandem scFv constructs. Efficient lysis of primary AML blasts in vitro and strong antitumoral effects and T cell persistence in xenograft models.

Automated summary

A modular and controllable MHC-unrestricted adoptive T cell therapy platform tailored to AML has been developed, combining synthetic agonistic receptor (SAR) -transduced T cells with AML-targeting tandem single chain variable fragment (scFv) constructs. This platform shows selective killing of AML cells and persistent responses in xenograft models, indicating its potential for further translation in AML treatment.