Autophagy, a critical process for bulk degradation of proteins and organelles, requires conjugation of Atg8 proteins to phosphatidylethanolamine on the autophagic membrane. At least eight different Atg8 orthologs belonging to two subfamilies (LC3 and GATE-16/GABARAP) occur in mammalian cells, but their individual roles and modes of action are largely unknown. In this study, we dissect the activity of each subfamily and show that both are indispensable for the autophagic process in mammalian cells. We further show that both subfamilies act differently at early stages of autophagosome biogenesis. Accordingly, our results indicate that LC3s are involved in elongation of the phagophore membrane whereas the GABARAP/GATE-16 subfamily is essential for a later stage in autophagosome maturation.
Autophagy is a unique membrane trafficking pathway describing the formation and targeting of double membrane autophagosomes to the vacuole/lysosome. The biogenesis of autophagosomes and their delivery to the vacuole/lysosome depend on multiple membrane fusion events. Using a cell-free system, we have investigated the ability of LC3 and GATE-16, two mammalian Atg8 orthologs, to mediate membrane fusion. We found that both proteins promote tethering and membrane fusion, mediated by the proteins' N-terminal α helices. We further show that short, 10 amino acid long synthetic peptides derived from the N terminus of LC3 or GATE-16 are sufficient to promote membrane fusion. Our data indicate that the fusion activity of LC3 is mediated by positively charged amino acids, whereas the activity of GATE-16 is mediated by hydrophobic interactions. Finally, we demonstrate that LC3 and GATE-16 N termini in general and specific residues needed for the fusion activity are essential for the proteins role in autophagosome biogenesis.
Autophagy, an evolutionarily conserved intracellular catabolic process, leads to the degradation of cytosolic proteins and organelles in the vacuole/lysosome. Different forms of selective autophagy have recently been described. Starvation-induced protein degradation, however, is considered to be nonselective. Here we describe a novel interaction between autophagy-related protein 8 (Atg8) and fatty acid synthase (FAS), a pivotal enzymatic complex responsible for the entire synthesis of C16-and C18-fatty acids in yeast. We show that although FAS possesses housekeeping functions, under starvation conditions it is delivered to the vacuole for degradation by autophagy in a Vac8-and Atg24-dependent manner. We also provide evidence that FAS degradation is essential for survival under nitrogen deprivation. Our results imply that during nitrogen starvation specific proteins are preferentially recruited into autophagosomesA utophagy is a major cellular catabolic pathway in eukaryotes, responsible for the degradation of organelles and large protein aggregates. This process is induced under various stress conditions, such as amino acid starvation, hypoxia, and oxidative stress (1, 2).In yeast (Saccharomyces cerevisiae), nitrogen starvation is known to induce macroautophagy (hereafter termed autophagy), which is essential mainly for supplementing amino acids needed for protein synthesis (3). Autophagy has long been considered to be a nonselective process except for the recruitment of ribosomes into autophagosomes, which was suggested to be selective under conditions of nitrogen starvation (4). Selective autophagy is thought to play a role mainly in cell homeostasis, and it uses the core autophagy genes and varying sets of proteins for different cargos (5). Autophagy-related protein 8 (Atg8), a key autophagic factor essential for autophagosome biogenesis, also plays a major role in selective autophagy by recruiting cargo proteins into the autophagosome (6).Fatty acid synthase (FAS) is a large (2.6 MDa), essential enzymatic complex responsible for the entire synthesis of C16-and C18-fatty acids (7). FAS is composed of two subunits, Fas1 (Fasβ) and Fas2 (Fasα), which are arranged in an α 6 β 6 macromolecular complex. Deletion of one of the FAS subunits has been shown to result in degradation of the other (8). Whereas the unassembled Fas2 subunit is short-lived and degrades in the proteasome, the unassembled Fas1, once induced, is degraded by autophagy. Moreover, the FAS complex is known to be delivered to the vacuole under potassium acetate starvation (8).Here we investigated the role of autophagy in the degradation of the FAS complex. We report a physical interaction between Atg8 and FAS, and show that autophagy preferentially degrades FAS and decreases its activity during nitrogen starvation. We suggest that the selective degradation of FAS under nitrogen starvation requires the participation of Atg24 and Vac8, two factors that each play a role in selective autophagy (9-12). Finally, we show that FAS degradation is important ...
Transport of proteins between intracellular membrane compartments is mediated by a protein machinery that regulates the budding and fusion processes of individual transport steps. Although the core proteins of both processes are defined at great detail, much less is known about the involvement of lipids. Here we report that changing the cellular balance of cholesterol resulted in changes of the morphology of the Golgi apparatus, accompanied by an inhibition of protein transport. By using a well characterized cell-free intra-Golgi transport assay, these observations were further investigated, and it was found that the transport reaction is sensitive to small changes in the cholesterol content of Golgi membranes. Addition as well as removal of cholesterol (10 ؎ 6%) to Golgi membranes by use of methyl--cyclodextrin specifically inhibited the intra-Golgi transport assay. Transport inhibition occurred at the fusion step. Modulation of the cholesterol content changed the lipid raft partitioning of phosphatidylcholine and heterotrimeric G proteins, but not of other (non) lipid raft proteins and lipids. We suggest that the cholesterol balance in Golgi membranes plays an essential role in intra-Golgi protein transport and needs to be carefully regulated to maintain the structural and functional organization of the Golgi apparatus.
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