Abstract 525: Novel DARPin multi-specific T-cell engager with an improved therapeutic window to overcome dose limiting toxicities in AML therapies

Purpose: The medical need due to high mortality in acute myeloid leukemia (AML) remains high, and the treatment of relapsed or refractory AML continues to be therapeutically challenging. MYLOTARG, the only approved anti-CD33 antibody drug conjugate (ADC), has provided proof-of-concept for targeted immunotherapies in AML. Currently, a plethora of ADCs and T-cell engager (TCE) therapies have entered clinical development in AML, but those therapies are often accompanied by dose limiting toxicities, preventing dose escalation to desired anti-tumor efficacy. The biggest challenges seem to be limited target specificity and hyperstimulation of the immune system leading to e.g. myelotoxicities and cytokine release syndrome, respectively. Therefore, more selective therapies are needed to allow for robust anti-tumor activity with a more acceptable safety profile. Experimental design: To address the selectivity challenge, we have generated multi-specific T-cell engaging DARPin® molecules, targeting two different tumor associated antigens (TAAs) with optimized affinity for their targets. In order to find the right target combination, the optimal affinity to increase tumor specificity via avidity, as well as the best molecular architecture, we took advantage of our unique modular DARPin® platform and screened 1000s of combinations of multi-specific DARPin® molecules, binding simultaneously to multiple TAAs in conjunction with our CD3-binding DARPin® molecule. Results: We constructed multi-specific TCEs targeting two different AML antigens with optimized affinity leading to a substantial avidity gain when both targets are co-expressed on tumor cells. The avidity gain resulted in strongly enhanced in vitro potency as shown by activation of both CD8+ and CD4+ T cells and subsequent killing of AML tumor cells, with bioactivities in the range of established TCE benchmark formats (e.g. BiTE® and DART®). In contrast, in an ex vivo whole blood assay the multi-specific DARPin® constructs induced profoundly less cytokine release as compared to benchmark molecules indicating an improved therapeutic window. Finally, we also demonstrated tumor regression in PMBC humanized mouse models bearing MOLM-13 tumors, using both half-life extended (HLE) and non-HLE lead constructs. In conclusion, we have generated TCEs based on multi-specific DARPin® constructs with high potency, selectivity and ultimately with the potential for an improved therapeutic window for the treatment of AML. Citati