Phosphorylation of Atg9 regulates movement to the phagophore assembly site and the rate of autophagosome formation

Macroautophagy is primarily a degradative process that cells use to break down their own components to recycle macromolecules and provide energy under stress conditions, and defects in macroautophagy lead to a wide range of diseases. Atg9, conserved from yeast to mammals, is the only identified transmembrane protein in the yeast core macroautophagy machinery required for formation of the sequestering compartment termed the autophagosome. This protein undergoes dynamic movement between the phagophore assembly site (PAS), where the autophagosome precursor is nucleated, and peripheral sites that may provide donor membrane for expansion of the phagophore. Atg9 is a phosphoprotein that is regulated by the Atg1 kinase. We used stable isotope labeling by amino acids in cell culture (SILAC) to identify phosphorylation sites on this protein and identified an Atg1-independent phosphorylation site at serine 122. A nonphosphorylatable Atg9 mutant showed decreased autophagy activity, whereas the phosphomimetic mutant enhanced activity. Electron microscopy analysis suggests that the different levels of autophagy activity reflect differences in autophagosome formation, correlating with the delivery of Atg9 to the PAS. Finally, this phosphorylation regulates Atg9 interaction with Atg23 and Atg27.     

Proteinase protection of prApe1 as a tool to monitor Cvt vesicle/autophagosome biogenesis

Due in part to the increasing number of links between autophagy malfunction and human diseases, this field has gained tremendous attention over the past decade. Our increased understanding of the molecular machinery involved in macroautophagy (hereafter autophagy) seems to indicate that the most complex step, or at least the stage of the process where the majority of the autophagy-related (Atg) proteins participate, is in the formation of the double-membrane sequestering vesicle. Thus, it is important to establish reliable approaches to monitor this specific process. One of the most commonly used methods is morphological analysis by electron microscopy of the cytosolic vesicles used in the cytoplasm-to-vacuole targeting (Cvt) pathway and autophagy, or the single-membrane intralumenal products, termed Cvt or autophagic bodies, that are formed after the fusion of these vesicles with the yeast vacuole. This method, however, can be costly and time consuming, and reliable analysis requires expert input. Furthermore, it is extremely difficult to detect an incomplete autophagosome by electron microscopy because of the difficulty of obtaining a section that randomly cuts through the open portion of the phagophore. The primary Cvt pathway cargo, precursor amminopeptidase I (prApe1), is enwrapped within either a Cvt vesicle or autophagosome depending on the nutritional conditions. The proteolytic sensitivity of the prApe1 propeptide can therefore serve as a useful tool to determine the completion status of double-membrane Cvt vesicles/autophagosomes in the presence of exogenously added proteinase. Here, we describe an assay that examines the proteinase protection of prApe1 for determining the completion of Cvt vesicles/autophagosomes.     

GFP-Atg8 protease protection as a tool to monitor autophagosome biogenesis

Perhaps the most complex step of macroautophagy is the formation of the double-membrane autophagosome. The majority of the autophagy-related (Atg) proteins are thought to participate in nucleation and expansion of the phagophore, and/or the completion of this compartment. Monitoring this part of the process is difficult, and typically involves electron microscopy analysis; however, unless three-dimensional tomography is performed, even this method cannot be used to easily determine if the phagophore is completely enclosed. Accordingly, a complementary approach is to examine the accessibility of sequestered cargo to exogenously added protease. This type of protease protection analysis has been used to monitor the formation of cytoplasm-to-vacuole targeting (Cvt) vesicles and autophagosomes by examining the protease sensitivity of precursor aminopeptidase I (prApe1). For determining the status of autophagosomes formed during nonselective autophagy, however, prApe1 is not the best marker protein. Here, we describe an alternative method for examining autophagosome completion using GFP-Atg8 as a marker for protease protection.     

GFP-Atg8 protease protection as a tool to monitor autophagosome biogenesis

Perhaps the most complex step of macroautophagy is the formation of the double-membrane autophagosome. The majority of the autophagy-related (Atg) proteins are thought to participate in nucleation and expansion of the phagophore, and/or the completion of this compartment. Monitoring this part of the process is difficult, and typically involves electron microscopy analysis; however, unless three-dimensional tomography is performed, even this method cannot be used to easily determine if the phagophore is completely enclosed. Accordingly, a complementary approach is to examine the accessibility of sequestered cargo to exogenously added protease. This type of protease protection analysis has been used to monitor the formation of cytoplasm-to-vacuole targeting (Cvt) vesicles and autophagosomes by examining the protease sensitivity of precursor aminopeptidase I (prApe1). For determining the status of autophagosomes formed during nonselective autophagy, however, prApe1 is not the best marker protein. Here, we describe an alternative method for examining autophagosome completion using GFP-Atg8 as a marker for protease protection.     

The Atg17-Atg31-Atg29 complex and Atg11 regulate autophagosome-vacuole fusion

The macroautophagy (hereafter autophagy) process involves de novo formation of double-membrane autophagosomes; after sequestering cytoplasm these transient organelles fuse with the vacuole/lysosome. Genetic studies in yeasts have characterized more than 40 autophagy-related (Atg) proteins required for autophagy, and the majority of these proteins play roles in autophagosome formation. The fusion of autophagosomes with the vacuole is mediated by the Rab GTPase Ypt7, its guanine nucleotide exchange factor Mon1-Ccz1, and soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins. However, these factors are not autophagosome-vacuole fusion specific. We recently showed that 2 autophagy scaffold proteins, the Atg17-Atg31-Atg29 complex and Atg11, regulate autophagosome-vacuole fusion by recruiting the vacuolar SNARE Vam7 to the phagophore assembly site (PAS), where an autophagosome forms in yeast.     

Physiological functions of Atg6/Beclin 1： a unique autophagy-related protein

The most striking morphological feature of eukaryotic cells is the presence of various membrane-enclosed compartments. These compartments, including organelles and transient transport intermediates, are not static. Rather, dynamic exchange of proteins and membrane is needed to maintain cellular homeostasis. One of the most dramatic examples of membrane mobilization is seen during the process ofmacroautophagy. Macroautophagy is the primary cellular pathway for degradation of long-lived proteins and organelles. In response to environmental cues, such as starvation or other types of stress, the cell produces a unique membrane structure, the phagophore. The phagophore sequesters cytoplasm as it forms a double-membrane cytosolic vesicle, an autophagosome. Upon completion, the autophagosome fuses with a lysosome or a vacuole in yeast, which delivers hydrolases that break down the inner autophagosome membrane along with its cargo, and the resulting macromolecules are released back into the cytosol for reuse. Autophagy is therefore a recycling process, allowing cells to survive periods of nutrient limitation; however, it has a wider physiological role, participating in development and aging, and also in protection against pathogen invasion, cancer and certain neurodegenerative diseases. In many cases, the role ofautophagy is identified through studies of an autophagy-related protein, Atg6/Beclin 1. This protein is part of a lipid kinase complex, and recent studies suggest that it plays a central role in coordinating the cytoprotective function ofautophagy and in opposing the cellular death process of apoptosis. Here, we summarize our current knowledge ofAtg6/Beclin 1 in different model organisms and its unique function in the cell.     

Blame it on Southern,but it's a western blot

Edwin M. Southern is a professor emeritus at the University of Oxford. He is perhaps best known for development of the “Southern blot” (Dr. Southern was at the University of Edinburgh when he wrote his landmark paper). The Southern blot provided a scientific breakthrough by allowing scientists to detect a particular DNA sequence without first purifying it from the rest of the genome; the basic method involves the transfer of the DNA to a membrane, followed by detection with a specific probe. Although few people perform Southern blots as originally carried out by Southern, due in part to the more recent technique of the polymerase chain reaction, the basic concept continues to play an important role in molecular biology.     

Atg1-mediated myosin II activation regulates autophagosome formation during starvation-induced autophagy

Autophagy is a membrane-mediated degradation process of macromolecule recycling. Although the formation of double-membrane degradation vesicles (autophagosomes) is known to have a central role in autophagy, the mechanism underlying this process remains elusive. The serine/threonine kinase Atg1 has a key role in the induction of autophagy. In this study, we show that overexpression of Drosophila Atg1 promotes the phosphorylation-dependent activation of the actin-associated motor protein myosin II. A novel myosin light chain kinase (MLCK)-like protein, Spaghetti-squash activator (Sqa), was identified as a link between Atg1 and actomyosin activation. Sqa interacts with Atg1 through its kinase domain and is a substrate of Atg1. Significantly, myosin II inhibition or depletion of Sqa compromised the formation of autophagosomes under starvation conditions. In mammalian cells, we found that the Sqa mammalian homologue zipper-interacting protein kinase (ZIPK) and myosin II had a critical role in the regulation of starvation-induced autophagy and mammalian Atg9 (mAtg9) trafficking when cells were deprived of nutrients. Our findings provide evidence of a link between Atg1 and the control of Atg9-mediated autophagosome formation through the myosin II motor protein.     

Atg5 regulates late endosome and lysosome biogenesis

Autophagy is an evolutionarily conserved lysosome-based degradation process.Atg5 plays a very important role in autophagosome formation.Here we show that Atg5 is required for biogenesis of late endosomes and lysosomes in an autophagy-independent manner.In Atg5 cells,but not in other essential autophagy genes defecting cells,recycling and retrieval of late endosomal components from hybrid organelles are impaired,causing persistent hybrid organelles and defective formation of late endosomes and lysosomes.Defective retrieval of late endosomal components from hybrid organelles resulting from impaired recruitment of a component of V1-ATPase to acidic organelles blocks the pH-dependent retrieval of late endosomal components from hybrid organelles.Lowering the intracellular pH restores late endosome/lysosome biogenesis in Atg5 cells.Our data demonstrate an unexpected role of Atg5 and shed new light on late endosome and lysosome biogenesis.     

The role of Atg29 phosphorylation in PAS assembly

Macroautophagy (hereafter autophagy) initiates at the phagophore assembly site (PAS), where most of the AuTophaGy-related (Atg) proteins are at least transiently localized. As the first protein complex targeted to the PAS, the Atg17-Atg31-Atg29 complex serves as the scaffold for other Atg proteins and plays a critical role for the organization of the PAS, and in autophagy initiation. We recently showed that this complex is constitutively formed and activated by the phosphorylation of Atg29 when autophagy is induced. Phosphorylation of Atg29 is required for its interaction with Atg11, another scaffold protein, and its function for promoting the proper assembly of the PAS. Single-particle electron microscopy analysis of the Atg17-Atg31-Atg29 complex reveals an elongated structure with Atg29 located at the opposing ends. This structural arrangement allows Atg29 to interact with Atg11, and is critical in the organization of the intact Atg1 complex.     

Atg1 kinase organizes autophagosome formation by phosphorylating Atg9

The conserved Ser/Thr kinase Atg1/ULK1 plays a crucial role in the regulation of autophagy. However, only very few Atg1 targets have been identified, impeding elucidation of the mechanisms by which Atg1 regulates autophagy. In our study, we determined the Saccharomyces cerevisiae Atg1 consensus phosphorylation sequence using a peptide array-based approach. Among proteins containing this sequence we identified Atg9, another essential component of the autophagic machinery. We showed that phosphorylation of Atg9 by Atg1 is required for phagophore elongation, shedding light on the mechanism by which Atg1 regulates early steps of autophagy.     

Detection of Saccharomyces cerevisiae Atg13 by western blot

The proteins that comprise the Atg1 kinase complex constitute a key set of components that participate in macroautophagy (hereafter autophagy). Among these proteins, Atg13 plays a particularly important, although as yet undefined role, in that it is critical for the proper localization of Atg1 to the phagophore assembly site (PAS) and its efficient kinase activity. Atg13 is hyperphosphorylated in vegetative conditions when autophagy occurs at a basal level, and is largely dephosphorylated upon the induction of autophagy. Inhibitory phosphorylation of Atg13 reflects the activity of TOR complex 1 (TORC1) and protein kinase A. Accordingly, monitoring the phosphorylation state of Atg13 provides a convenient way to follow early steps of autophagy induction as well as the activity of some of the upstream nutrient-sensing kinases. However, the detection of Atg13 by western blot can be problematic. Here, we present a detailed protocol for sample preparation and detection of the Atg13 protein from yeast.     

Detection of Saccharomyces cerevisiae Atg13 by western blot

The proteins that comprise the Atg1 kinase complex constitute a key set of components that participate in macroautophagy (hereafter autophagy). Among these proteins, Atg13 plays a particularly important, although as yet undefined role, in that it is critical for the proper localization of Atg1 to the phagophore assembly site (PAS) and its efficient kinase activity. Atg13 is hyperphosphorylated in vegetative conditions when autophagy occurs at a basal level, and is largely dephosphorylated upon the induction of autophagy. Inhibitory phosphorylation of Atg13 reflects the activity of TOR complex 1 (TORC1) and protein kinase A. Accordingly, monitoring the phosphorylation state of Atg13 provides a convenient way to follow early steps of autophagy induction as well as the activity of some of the upstream nutrient-sensing kinases. However, the detection of Atg13 by western blot can be problematic. Here, we present a detailed protocol for sample preparation and detection of the Atg13 protein from yeast.