A framework integrating multiscale in-silico modeling and experimental data predicts CD33CAR-NK cytotoxicity across target cell types Article Swipe

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Cytotoxicity In silico Biology Flow cytometry Cell Cell biology Computational biology Cancer research Immunology In vitro Genetics Gene

Saeed Ahmad , Kun Xing , Harshana Rajakaruna , William C. Stewart , Kyle A. Beckwith , Indrani Nayak , Meisam Naeimi Kararoudi , Dean A. Lee , Jayajit Das ·

YOU? · · 2025 · Open Access · · DOI: https://doi.org/10.1101/2024.12.31.630941 · OA: W4405987120

Uncovering mechanisms and predicting tumor cell responses to CAR-NK cytotoxicity is essential for improving therapeutic efficacy. Currently, the complexity of these effector-target interactions and the donor-to-donor variations in NK cell receptor (NKR) repertoire require functional assays to be performed experimentally for each manufactured CAR-NK cell product and target combination. Here, we developed a computational mechanistic multiscale model which considers heterogenous expression of CARs, NKRs, adhesion receptors and their cognate ligands, signal transduction, and NK cell-target cell population kinetics. The model trained with quantitative flow cytometry and in vitro cytotoxicity data accurately predicts the short- and long- term cytotoxicity of CD33CAR-NK cells against leukemia cell lines across multiple CAR designs. Furthermore, using Pareto optimization we explored the effect of CAR proportion and NK cell signaling on the differential cytotoxicity of CD33CAR-NK cells to cancer and healthy cells. This model can be extended to predict CAR-NK cytotoxicity across many antigens and tumor targets.