Small-scale hypoxic cultures for monitoring the spatial reorganization of glycolytic enzymes in Saccharomyces cerevisiae.

At normal oxygen concentration, glycolytic enzymes are scattered in the cytoplasm of Saccharomyces cerevisiae. Under hypoxia, however, most of these enzymes, including enolase, pyruvate kinase, and phosphoglycerate mutase, spatially reorganize to form cytoplasmic foci. We tested various small-scale hypoxic culture systems and showed that enolase foci formation occurs in all the systems tested, including in liquid and on solid media. Notably, a small-scale hypoxic culture in a bench-top multi-gas incubator enabled the regulation of oxygen concentration in the media and faster foci formation. Here, we demonstrate that the foci formation of enolase starts within few hours after changing the oxygen concentration to 1% in a small-scale cultivation system. The order of foci formation by each enzyme is tightly regulated, and of the three enzymes, enolase was the fastest to respond to hypoxia. We further tested the use of the small-scale cultivation method to screen reagents that can control the spatial reorganization of enzymes under hypoxia. An AMPK inhibitor, dorsomorphin, was found to delay formation of the foci in all three glycolytic enzymes tested. These methods and results provide efficient ways to investigate the spatial reorganization of proteins under hypoxia to form a multienzyme assembly, the META body, thereby contributing to understanding and utilizing natural systems to control cellular metabolism via the spatial reorganization of enzymes.

Foci-forming regions of pyruvate kinase and enolase at the molecular surface incorporate proteins into yeast cytoplasmic metabolic enzymes transiently assembling (META) bodies.

Spatial reorganization of metabolic enzymes to form the "metabolic enzymes transiently assembling (META) body" is increasingly recognized as a mechanism contributing to regulation of cellular metabolism in response to environmental changes. A number of META body-forming enzymes, including enolase (Eno2p) and phosphofructokinase, have been shown to contain condensate-forming regions. However, whether all META body-forming enzymes have condensate-forming regions or whether enzymes have multiple condensate-forming regions remains unknown. The condensate-forming regions of META body-forming enzymes have potential utility in the creation of artificial intracellular enzyme assemblies. In the present study, the whole sequence of yeast pyruvate kinase (Cdc19p) was searched for condensate-forming regions. Four peptide fragments comprising 27-42 amino acids were found to form condensates. Together with the fragment previously identified from Eno2p, these peptide regions were collectively termed "META body-forming sequences (METAfos)." METAfos-tagged yeast alcohol dehydrogenase (Adh1p) was found to co-localize with META bodies formed by endogenous Cdc19p under hypoxic conditions. The effect of Adh1p co-localization with META bodies on cell metabolism was further evaluated. Expression of Adh1p fused with a METAfos-tag increased production of ethanol compared to acetic acid, indicating that spatial reorganization of metabolic enzymes affects cell metabolism. These results contribute to understanding of the mechanisms and biological roles of META body formation.