AMPK alters proteasome phosphorylation status and prevents persistent proteasome condensates

Proteasomes are large multiprotein complexes required for selective intracellular protein degradation, regulating numerous cellular processes and maintaining protein homeostasis and organismal health. In the budding yeast Saccharomyces cerevisiae grown under different glucose conditions, proteasomes undergo dynamic phase transitions between free and condensate states concomitant with nucleocytoplasmic translocation. Low glucose-induced cytoplasmic proteasome condensates are usually reversible but become persistent in the absence of AMP-activated protein kinase (AMPK). AMPK is important for proteasome condensate dissolution and proteasome nuclear reimport upon glucose refeeding of quiescent cells. Here we found that AMPK activities and the AMPK signaling pathway affect proteasome subunit phosphorylation, which correlates with the solubility and reversibility of proteasome condensates. Nuclear and cytoplasmic AMPK isoforms function redundantly in proteasome condensate dissolution. AMPK interacts with the proteasome regulatory particle in an AMPK activity-independent manner. At least 50 kinases and phosphatases have been found to associate with the AMPK complex. Therefore, the prevention of persistent proteasome condensate formation by AMPK likely results from regulating the antagonistic effects of downstream kinases and phosphatases on proteasome phosphorylation. A mechanistic understanding of the downstream effector proteins of AMPK that directly regulate proteasome subunit phosphorylation will provide insights into how proteasome phosphorylation is linked to proteasome condensate regulation.