Abstract
In yeast, early adaptation to hyperosmotic stress involves organelle-based mechanisms, including synthesis of phosphatidylinositol 3,5-bisphosphate (PI(3,5)P(2)) at the vacuole. This low-level signaling lipid drives vacuolar fragmentation and activates the V-ATPase proton pump, which acidifies the vacuole and drives salt sequestration. The vacuole-resident V-ATPase subunit Vph1 interacts with PI(3,5)P(2) via its N-terminal domain (Vph1NT), directly linking lipid signaling to proton pump regulation. Under NaCl stress, PI(3,5)P(2) rapidly accumulates, triggering increased V-ATPase activity and vacuolar remodeling; these responses are impaired by deficient PI(3,5)P(2) synthesis. A Vph1NT-GFP fusion protein with no membrane domain is cytosolic without salt, but upon NaCl addition, rapidly relocalizes to a region adjacent to the vacuole in a PI(3,5)P(2)-dependent manner. The intensity and duration of this response depend on salt concentration. Vph1NT-GFP returns to the same location upon repeated salt challenge, suggesting that PI(3,5)P(2) synthesis occurs at a localized domain/contact site. Disrupting PI(3,5)P2 signaling, V-ATPase activity, or the high osmolarity glycerol pathway, which coordinates long-term transcriptional changes, compromises cellular adaptation to salt, underscoring the integration of lipid signaling and transcriptional regulation in hyperosmotic stress. These findings suggest activation of the V-ATPase, and possibly other targets, by PI(3,5)P(2) synthesis provides immediate protection that primes cells for longer-term survival strategies.