Heterogeneous Nuclear Ribonucleoprotein K (hnRNP K) is a limiting factor for prion propagation. However, little is known about the function of hnRNP K except that it is essential to cell survival. Here, we performed a synthetic-viability CRISPR ablation screen to identify epistatic interactors of HNRNPK . We found that deletion of Transcription Factor AP-2γ ( TFAP2C ) suppressed the death of hnRNP K-depleted LN-229 and U-251 MG cells, whereas its overexpression hypersensitized cells to hnRNP K loss. HNRNPK ablation decreased cellular ATP, downregulated genes related to lipid and glucose metabolism, and enhanced autophagy. Co-occurrent deletion of TFAP2C reversed these effects, restoring transcriptional balance and alleviating energy deficiency. We linked HNRNPK and TFAP2C functional and genetic interaction to mTOR signaling, observing that hnRNP K depletion inhibited mTORC1 activity through downregulation of mTOR and Rptor, while TFAP2C overexpression enhanced mTORC1 downstream functions. In prion-infected cells, TFAP2C activation reduced prion levels and countered the increased prion propagation caused by HNRNPK suppression. Short-term inhibition of mTORC1 also elevated prion levels and partially mimicked the effects of HNRNPK silencing. Our study identifies TFAP2C as a genetic interactor of HNRNPK , implicates their roles in mTOR metabolic regulation, and establishes a causative link between these activities and prion propagation.
Sellitto et al. (Mon,) studied this question.