Physicochemical properties of the vacuolar membrane and cellular factors determine formation of vacuolar invaginations

Abstract

AbstractVacuoles change their morphology in response to stress. In yeast exposed to chronically high temperatures, vacuolar membranes get deformed and invaginations are formed. We show that phase-separation of vacuolar membrane occurred after heat stress leading to the formation of the invagination. In addition, Hfl1, a vacuolar membrane-localized Atg8-binding protein, was found to suppress the excess vacuolar invaginations after heat stress. At that time, Hfl1 formed foci at the neck of the invaginations in wild-type cells, whereas it was efficiently degraded in the vacuole in theatg8Δ mutant. Genetic analysis showed that the endosomal sorting complex required for transport (ESCRT) machinery was necessary to form the invaginations irrespective of Atg8 or Hfl1. In contrast, a combined mutation with the vacuole BAR domain protein Ivy1 led to vacuoles inhfl1Δivy1Δ andatg8Δivy1Δ mutants having constitutively invaginated structures; moreover, these mutants showed stress-sensitive phenotypes. Our findings suggest that vacuolar invaginations result from the combination of changes in the physiochemical properties of the vacuolar membrane and other cellular factors.Summary statementVacuolar invaginations occur through a combination of the changes of physiochemical properties of the vacuolar membrane and other cellular factors in yeast. Particularly, Hfl1 suppresses the excess invaginations.