AbstractPhosphoinositide lipids provide spatial landmarks during polarized secretion. Here, we elucidate a role for phosphatidylinositol 4-phosphate (PI4P) metabolism in the control of cell polarity. In budding yeast, PI4P is enriched at the plasma membrane of growing daughter cells. Upon heat shock however, PI4P rapidly increases at the plasma membrane in mother cells resulting in a more uniform PI4P distribution. Rather than phosphoinositide kinase activation, PI4P hydrolysis is impaired to generate the heat-induced PI4P signal in mother cells. This fine tune control of PI4P metabolism is mediated through attenuation of the Osh3 protein that binds and presents PI4P to a phosphoinositide phosphatase. Importantly, Osh3 undergoes phase transitions upon environmental stress conditions, resulting in intracellular aggregates and reduced cortical localization. The chaperone Hsp104 co-assembles with intracellular Osh3 granules, but is not required for their formation. Interestingly, the Osh3 GOLD domain, also present in the ER-localized p24 cargo adaptor family, is sufficient to form stress granules. Accordingly, GOLD-mediated phase transitions may provide a general mechanism to modulate secretion and growth upon transient changes in physiological and environmental conditions.
Lamellar-to-hexagonalII phase transitions in the plasma membrane of isolated protoplasts after freeze-induced dehydration.
