Decreased tRNA abundance contributes to decreased translation elongation rate in a prolonged mitosis

Cells undergo dramatic structural rearrangements upon entering Mitosis. In addition, the biochemistry of mitotic cells is dramatically altered, including a significant decrease in protein synthesis. The majority of studies of mitotic translation have used cells synchronized by cell cycle altering drugs in transformed cells and much less is known about mitotic translation in primary cells under native conditions. Previous work has found that Mitosis activates the integrated stress response (ISR) to trigger eIF2α phosphorylation, but little is known about the input for this response. In this study, we focus on mitotic translational regulation in an immortalized, non-transformed cell line. We confirm decreased mitotic protein synthesis in primary cells and under native conditions. Additionally, we confirm activation of the ISR by phosphorylation of eIF2α during both normal and prolonged Mitosis. Interestingly, we also find that decreased translational elongation during Mitosis, as evidenced by increased eEF2 phosphorylation and a slower elongation rate. Analysis of mitotic ribosome profiling data revealed an increase in pausing at Alanine-GCG codons during Mitosis and a decreased abundance of its cognate tRNA-Ala^CGC by northern blotting. Decreased tRNA-Ala^CGC is likely sustained by the inability to synthesize additional tRNA due to RNAPol III inhibition in Mitosis, yielding an stronger effect with an increased time in Mitosis. These results suggest that decreased translation elongation in Mitosis triggers inhibition of initiation to decrease global protein synthesis.