Topology and Function of the S. cerevisiae Autophagy Protein Atg15.

The putative phospholipase Atg15 is required for the intravacuolar lysis of autophagic bodies and MVB vesicles. Intracellular membrane lysis is a highly sophisticated mechanism that is not fully understood. The amino-terminal transmembrane domain of Atg15 contains the sorting signal for entry into the MVB pathway. By replacing this domain, we generated chimeras located in the cytosol, the vacuole membrane, and the lumen. The variants at the vacuole membrane and in the lumen were highly active. Together with the absence of Atg15 from the phagophore and autophagic bodies, this suggests that, within the vacuole, Atg15 can lyse vesicles where it is not embedded. In-depth topological analyses showed that Atg15 is a single membrane-spanning protein with the amino-terminus in the cytosol and the rest, including the active site motif, in the ER lumen. Remarkably, only membrane-embedded Atg15 variants affected growth when overexpressed. The growth defects depended on its active site serine 332, showing that it was linked to the enzymatic activity of Atg15. Interestingly, the growth defects were independent of vacuolar proteinase A and vacuolar acidification.

Piecemeal microautophagy of the nucleus: genetic and morphological traits.

Nucleus-vacuole (NV) junctions are formed in Saccharomyces cerevisiae through interactions between Vac8 in the vacuole membrane and Nvj1 in the perinuclear ER. Upon starvation, vesicles containing part of the nucleus emanate from these contact sites and finally pinch off into invaginations of the vacuole. Due to its morphological similarity to microautophagy this process had been termed "piecemeal microautophagy of the nucleus" (PMN). We recently discovered that a number of ATG genes required for macroautophagy and micropexophagy are also required for PMN and accordingly named it micronucleophagy. Therefore, PMN represents a novel model system to investigate the functions of the highly conserved but poorly understood core autophagic apparatus. We here extend the morphological analysis of PMN using immunogold and freeze fracture electron microscopy.