Abstract
Effective cancer therapeutics often kill a large fraction of tumor cells, while sparing a small surviving population, which can resurface as future tumor recurrence. Mechanisms of resistance in these residual tumors may involve rare preexisting clones with mutations, as well as de novo development of resistance through various genetic and/or non-genetic processes. In the context of acute stress resulting from cancer therapeutics, the initial adaptation is essential for tumor cell survival and allows for subsequent development of resistance through additional genetic and non-genetic mechanisms. As an integrator of environmental signals and cellular response, the mTOR pathway is a critical driver of cellular adaptation to environmental changes. In particular, mTOR regulates embryonic diapause, a reversible dormancy state in mammalian development in response to unfavorable environments. Analogous to its role in regulating embryonic diapause, mTOR inhibition may induce a diapause-like state in cancer cells, leading to drug tolerance and persistence of residual tumors following therapy. In line with this notion, recent studies have reported markedly reduced mTOR activity in residual tumors. However, the causal relationship between mTOR inhibition and chemosensitivity has not been investigated. Through a genome-wide CRISPR knockout library screen in pancreatic cancer cells treated with chemotherapeutic agents, we have identified the mTOR pathway as a prominent determinant of chemosensitivity. Pharmacological suppression of mTOR activity in cancer cells from diverse tissue origins leads to the persistence of a reversibly resistant population, which is otherwise eliminated by chemotherapeutic agents. Conversely, activation of the mTOR pathway increases chemosensitivity and predicts better survival among various human cancers. Survival of the persisters is dependent on the regulation of autophagy, G2/M checkpoint, and cell death pathways, as revealed by a small-molecule chemical library screen. Thus, mTOR plays a causal yet paradoxical role in regulating chemotherapeutic response; inhibition of the mTOR pathway, while suppressing tumor expansion, facilitates the development of a reversible drug-tolerant persister state.
Citation Format: Yuanhui Liu, Nancy Azizian, Delaney Sullivan, Yulin Li. mTOR inhibition attenuates chemosensitivity through induction of a persister state [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1692.