Atg9 Trafficking in Autophagy-Related Pathways

The origin of the autophagosomal membrane and the lipid delivery mechanism during autophagy remain unsolved mysteries. Some important hints to these questions come from Atg9, which is the only integral membrane protein required for autophagosome formation and considered a membrane carrier in autophagy-related pathways. In S. cerevisiae, Atg9 cycles between peripheral sites and the preautophagosomal structure/phagophore assembly site (PAS), the nucleating site for formation of the sequestering vesicle. We recently identified a peripheral membrane protein, Atg11, as a binding partner of Atg9, in a yeast two-hybrid screen. Based on our analysis we propose a model for Atg9 cycling. Our model suggests that a pool of Atg11 mediates the anterograde transport of Atg9 to the PAS along the actin cytoskeleton, and that this delivery process may serve as a membrane shuttle for vesicle assembly during yeast selective autophagy. Here, we discuss the implications of the model and present additional evidence that extends it with regard to membrane trafficking modes during pexophagy.

Addendum to:

Recruitment of Atg9 to the Preautophagosomal Structure by Atg11 is Essential for Selective Autophagy in Budding Yeast

C. He, H. Song, T. Yorimitsu, I. Monastyrska, W.-L. Yen, J.E. Legakis and D.J. Klionsky

J Cell Biol 2006; 175:925-35     

Atg9 Trafficking in Yeast Saccharomyces cerevisiae

Autophagy can be divided into selective and non-selective modes. This process is considered selective when a precise cargo is specifically and exclusively incorporated into autophagosomes, the double-membrane vesicles that are the hallmark of autophagy. In contrast, during nonselective, bulk autophagy, cytoplasmic components are randomly enwrapped into autophagosomes. To date, approximately 30 autophagy-related genes called ATG have been identified. Sixteen of them compose the general basic machinery catalyzing the formation of double-membrane vesicles in all eukaryotic cells. The rest of them are often not conserved between species and cooperate with the basic Atg proteins during either selective or nonselective autophagy. Atg9 is the only integral membrane component of the conserved Atg machinery and appears to be a crucial organizational element.5 Recent studies in the S. cerevisiae have shown that Atg9 transport is differentially regulated depending on the autophagy mode. In this addendum, we will review and discuss what has recently been unveiled about yeast S. cerevisiae Atg9 trafficking, its modulators and its potential role in double-membrane vesicle biogenesis.

Addendum to:

Atg9 Sorting from Mitochondria is Impaired in Early Secretion and VFT Complex Mutants in Saccharomyces cerevisiae

F. Reggiori and D.J. Klionsky

J Cell Sci 2006: 119:2903-11     

Atg9 trafficking in Mammalian cells

The molecular mechanisms of autophagy have been best characterized in the yeast Saccharomyces cerevisiae, where a number of proteins have been identified to be essential for this degradative pathway. ATG (autophagy-related) proteins(1) localize to a unique compartment, the pre-autophagosomal structure (PAS). Isolation membranes are suggested to originate from the PAS, enwrapping cytoplasmic components to form a double membrane autophagosome, which then fuses with the vacuole. Although many Atg proteins have been identified, the source of the PAS membrane in yeast is unknown. Identification of the source of the PAS in yeast has been hindered due to the transient association of Atg proteins with forming autophagosomes.(2) Likewise, in mammalian cells, it is not known if a PAS equivalent exists or if the formation of autophagosomes occurs from numerous membrane sources. The identification of stably associated markers would allow us to address this question further. Thus, characterization of the only transmembrane autophagy protein so far identified, Atg9, may aid in the search for the source of the PAS. Recent data from our lab suggests that mammalian Atg9 (mAtg9) traffics between the Golgi and endosomes, and suggests an involvement of the Golgi complex in the autophagic pathway.(3) Here we address the implications of our model with regard to membrane trafficking events in mammalian cells after starvation.     

siRNA抑制哺乳动物细胞内Rab9 GTPase表达的研究

构建Rab9 GTPase siRNA表达载体,观察siRNA对哺乳动物细胞内Rab9 GTPase表达的抑制作用,为应用Rab9 GTPase siRNA表达载体进行抗麻疹病毒感染研究奠定基础。根据Rab9 GTPase基因的mRNA序列设计合成2对靶向Rab9 GTPase基因的寡核苷酸,克隆到表达载体pSUPER.neo EGFP,通过双酶切和序列分析对重组表达载体进行鉴定。将鉴定为阳性的重组表达载体转染B95a细胞株,通过逆转录聚合酶链反应(RT-PCR)和免疫印迹技术(Western-blot)检测B95a细胞内Rab9 GTPase mRNA和蛋白的表达水平。双酶切和序列分析表明成功构建了Rab9 GTPase siRNA表达载体,RT-PCR和Western-blot技术实验表明重组表达载体可显著抑制B95a细胞内Rab9 GTPase mRNA和蛋白的表达(最高抑制率分别为89.4%±0.5%和87.6%±0.7%),而对照组则没有变化。结果表明,成功构建了Rab9 GTPase siRNA表达载体,该表达载体可有效地抑制Rab9 GTPase在哺乳动物细胞内的表达。     

Atg9 trafficking in autophagy-related pathways

The origin of the autophagosomal membrane and the lipid delivery mechanism during autophagy remain unsolved mysteries. Some important hints to these questions come from Atg9, which is the only integral membrane protein required for autophagosome formation and considered a membrane carrier in autophagy-related pathways. In S. cerevisiae, Atg9 cycles between peripheral sites and the pre-autophagosomal structure/phagophore assembly site (PAS), the nucleating site for formation of the sequestering vesicle. We recently identified a peripheral membrane protein, Atg11, as a binding partner of Atg9, in a yeast two-hybrid screen. Based on our analysis we propose a model for Atg9 cycling. Our model suggests that a pool of Atg11 mediates the anterograde transport of Atg9 to the PAS along the actin cytoskeleton, and that this delivery process may serve as a membrane shuttle for vesicle assembly during yeast selective autophagy. Here, we discuss the implications of the model and present additional evidence that extends it with regard to membrane trafficking modes during pexophagy.     

Atg27 is required for autophagy-dependent cycling of Atg9

Autophagy is a catabolic pathway for the degradation of cytosolic proteins or organelles and is conserved among all eukaryotic cells. The hallmark of autophagy is the formation of double-membrane cytosolic vesicles, termed autophagosomes, which sequester cytoplasm; however, the mechanism of vesicle formation and the membrane source remain unclear. In the yeast Saccharomyces cerevisiae, selective autophagy mediates the delivery of specific cargos to the vacuole, the analog of the mammalian lysosome. The transmembrane protein Atg9 cycles between the mitochondria and the pre-autophagosomal structure, which is the site of autophagosome biogenesis. Atg9 is thought to mediate the delivery of membrane to the forming autophagosome. Here, we characterize a second transmembrane protein Atg27 that is required for specific autophagy in yeast. Atg27 is required for Atg9 cycling and shuttles between the pre-autophagosomal structure, mitochondria, and the Golgi complex. These data support a hypothesis that multiple membrane sources supply the lipids needed for autophagosome formation.     

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.     

Mammalian Atg8s: One is simply not enough

Yeast Atg8, a key factor in the autophagic process, is a ubiquitin-like protein that undergoes a unique conjugation to phosphatidylethanolamine (PE). Atg8 plays a dual role in early stages of autophagosome formation: It was implicated in recruitment of cargo proteins such as Atg19 and Atg32 for Cvt and mitophagy, respectively, and in autophagosome biogenesis, serving as an elongation factor by mediating membrane hemi-fusion. Similarly, the mammalian Atg8 proteins, LC3s and GABARAPs, recruit cargo into autophagosomes by binding to adaptor proteins such as p62, NBR1 and Nix. These functions, however, are not essential for bulk autophagic flux. Other studies in which the activity of the mammalian Atg8s was blocked either by knockout of the E2-like enzyme Atg3 or by using a dominant negative mutant of the promiscuous protease Atg4B revealed, in agreement with the yeast Atg8 data, that the mammalian factors are crucial for the formation of normal and mature autophagosomes. While it seems that the single yeast Atg8 and the mammalian Atg8s share similar roles, it is still unclear why the mammalian system employs several homologs. Recent publications demonstrated that the mammalian Atg8s differ in their cargo specificity, as Nix, for example, binds exclusively to GABARAP-L1. This may suggest that these proteins exhibit distinct activity also in autophagosome biogenesis. In our study we divided the mammalian Atg8s into two subfamilies of homologs based on amino acid similarity, the LC3 and GABARAP/GATE-16 subfamilies, and tested their essentiality and role in autophagy. In agreement with previous studies we found that the mammalian Atg8s are essential for autophagy but, more importantly, that each of these subfamilies has a distinct role in the process of autophagosome biogenesis.     

Autophagy regulation through Atg9 traffic

Rapid membrane expansion is the key to autophagosome formation during nutrient starvation. In this issue, Yamamoto et al. (2012. J. Cell Biol. http://dx.doi.org/10.1083/jcb.201202061) now provide a mechanism for vesicle-mediated initiation of autophagosome biogenesis. They show that Atg9 vesicles, produced de novo during starvation, are ～30-60 nm in size and contain ～30 molecules of Atg9. These vesicles assemble to form an autophagosome, and subsequently, the Atg9 embedded in the outer membrane is recycled to avoid degradation.     

The Atg1-Atg13 complex regulates Atg9 and Atg23 retrieval transport from the pre-autophagosomal structure

To survive extreme environmental conditions, and in response to certain developmental and pathological situations, eukaryotic organisms employ the catabolic process of autophagy. Structures targeted for destruction are enwrapped by double-membrane vesicles, then delivered into the interior of the lysosome/vacuole. Despite the identification of many specific components, the molecular mechanism that directs formation of the sequestering vesicles remains largely unknown. We analyzed the trafficking of Atg23 and the integral membrane protein Atg9 in the yeast Saccharomyces cerevisiae. These components localize both to the pre-autophagosomal structure (PAS) and other cytosolic punctate compartments. We show that Atg9 and Atg23 cycle through the PAS in a process governed by the Atg1-Atg13 signaling complex. Atg1 kinase activity is essential only for retrograde transport of Atg23, while recycling of Atg9 requires additional factors including Atg18 and Atg2. We postulate that Atg9 employs a recycling system mechanistically similar to that used at yeast early and late endosomes.     

Unconventional Trafficking of Mammalian Phospholipase D3 to Lysosomes

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Mammalian Atg18 (WIPI2) localizes to omegasome-anchored phagophores and positively regulates LC3 lipidation

Autophagosome formation is a complex process that begins with the nucleation of a pre-autophagosomal structure (PAS) that expands into a phagophore or isolation membrane, the precursor of the autophagosome. A key event in the formation of the phagophore is the production of PtdIns3P by the phosphatidylinsitol kinase Vps34. In yeast the two closely related proteins, Atg18 and Atg21, are the only known effectors of PtdIns3P that act in the autophagy pathway. The recruitment of Atg18 or Atg21 to the PAS is an essential step in the formation of the phagophore. Our bioinformatic analysis of the Atg18 and Atg21 orthologues in all eukaryotes shows that WIPI1 and WIPI2 are both mammalian orthologues of Atg18. We show that WIPI2 is a mammalian effector of PtdIns3P and is ubiquitously expressed in a variety of cell lines. WIPI2 is recruited to early autophagosomal structures along with Atg16L and ULK1 and is required for the formation of LC3-positive autophagosomes. Furthermore, when WIPI2 is depleted, we observe a remarkable accumulation of omegasomes, ER-localized PtdIns3P-containing structures labeled by DFCP1 (double FYVE domain-containing protein 1), which are thought to act as platforms for autophagosome formation. In view of our data we propose a role for WIPI2 in the progression of omegasomes into autophagosomes.     

Early Steps in Autophagy Depend on Direct Phosphorylation of Atg9 by the Atg1 Kinase

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Double duty of Atg9 self-association in autophagosome biogenesis

The understanding of the membrane flow process during autophagosome formation is essential to illuminate the role of autophagy under various disease-causing conditions. Atg9 is the only identified integral membrane protein required for autophagosome formation, and it is thought to cycle between the membrane sources and the phagophore assembly site (PAS). Thus, Atg9 may play an important role as a membrane carrier. We report the self-interaction of Atg9 and generate an Atg9 mutant that is defective in this interaction. This mutation results in abnormal autophagy, due to altered phagophore formation as well as inefficient membrane delivery to the PAS. Based on our analyses, we discuss a model suggesting dual functions for the Atg9 complex: by reversibly binding to another Atg9 molecule, Atg9 can both promote lipid transport from the membrane origins to the PAS, and also help assemble an intact phagophore membrane.     

Modes of Growth in Mammalian Cells

The increase of cell volume as a function of time was studied throughout the generation cycle in synchronous cultures of Chinese hamster cells using a Coulter aperture and a multichannel analyzer calibrated against known cell volumes. The experimental results were compared to a mathematical model of cell volume increase which considered the effect of the distribution of individual cell generation times on the progress of the population. Several modes of volume increase, including linear and exponential, were considered. The mean volume vs. time curve was rounded at the ends of the cycle even when linear growth was assumed. The experimental results show that cell volume increased in a smooth fashion as a function of time, with no discontinuities in rate detectable at periods when cells may have been undergoing metabolic shifts as, for example, through the phases associated with DNA synthesis, G₁, S, G₂. A statistical test on the comparison of the modal cell volume vs. time data to the predictions of linear and exponential growth models accepted both hypotheses within the resolution of these experiments. However, exponential growth was favored over linear growth in one cell line. Volume dispersion was almost constant with time in both sublines which is also consistent with exponential growth. Limitations of the electronic technique of volume measurement and indications for future experiments are discussed.     

Baculoviruses as Vectors in Mammalian Cells

The Baculoviridae are a large family of enveloped DNA viruses exclusively pathogenic to arthropods. Baculoviruses have been extensively used in insect cell-based recombinant protein expression system and as biological pesticides. They have been deomostrated to be safe to mammals, birds and fish. Recently, baculoviruses has been shown to transduce different mammalian cells in spite of the fact that they cannot replicate in mammalian cells (11, 73, 76). This has resulted in the development of baculoviruses as mammalian expression systems and even as vestors for gene therapy.