Abstract
iCasp9 suicide gene has been widely used as a promising killing strategy in various cell therapies. However, different cells show significant heterogeneity in response to apoptosis inducer, posing challenges in clinical applications of killing strategy. The cause of the heterogeneity remains elusive so far. Here, by simultaneously monitoring the dynamics of iCasp9 dimerization, Caspase3 activation, and cell fate in single cells, we found that the heterogeneity was mainly due to cell-to-cell variability in initial iCasp9 expression and XIAP/Caspase3 ratio. Moreover, multiple-round drugging cannot increase the killing efficiency. Instead, it will place selective pressure on protein levels, especially on the level of initial iCasp9, leading to drug resistance. We further show this resistance can be largely eliminated by combinatorial drugging with XIAP inhibitor at the end, but not at the beginning, of the multiple-round treatments. Our results unveil the source of cell fate heterogeneity and drug resistance in iCasp9-mediated cell death, which may enlighten better therapeutic strategies for optimized killing.
Highlights
Inducible Caspase9 is a cellular suicide gene that allows conditional cell elimination [1]
We found that heterogeneous cell fates were originated from cell-to-cell variability in the initial Inducible Caspase9 (iCasp9) expression and the ratio between XIAP and Caspase3 expression levels (XIAP/C3 ratio)
The killing efficiency was increased with a knockdown on XIAP, while a knockdown on Caspase3 led to a decrease in the death percentage
Summary
Inducible Caspase (iCasp9) is a cellular suicide gene that allows conditional cell elimination [1]. It comprises a human Caspase fused with an inducer-binding domain which could be dimerized by the Chemical Inducer of Dimerization (CID), AP20187, or AP1903 [2, 3]. Due to the efficient induction of cell death, iCasp has been used as one of the most promising killing strategies in cancer therapies [5,6,7] and adoptive cell therapies [8,9,10,11,12,13,14]. The incomplete killing of cells leads to drug resistance and hampers the further use of the iCasp suicide gene [15, 16]. An understanding of the source of heterogeneous cell responses to the drug and how such heterogeneity contributes to resistance could lead to more effective treatment strategies
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