Loss of Dictyostelium ATG9 results in a pleiotropic phenotype affecting growth,development, phagocytosis and clearance and replication of Legionella pneumophila

Infection of Dictyostelium discoideum with Legionella pneumophila resulted in a large number of differentially regulated genes among them three core autophagy genes, ATG8, ATG9 and ATG16. Macroautophagy contributes to many physiological and pathological processes and might also constitute an important mechanism in cell‐autonomous immunity. For further studies we selected the highly conserved ATG9. In colocalization studies with GFP‐tagged ATG9 and different organelle marker proteins we neither observed colocalization with mitochondria, the ER nor lysosomes. However, there was partial colocalization with the Golgi apparatus and many ATG9‐GFP‐containing vesicles localized along microtubules and accumulated around the microtubule organizing centre. ATG9‐deficient cells had pleiotropic defects. In addition to growth defects they displayed severe developmental defects, consistent with the known role of autophagy in Dictyostelium development. Unexpectedly, the ATG9 mutant also had a strong phagocytosis defect that was particularly apparent when infecting the cells with L. pneumophila. However, those Legionellae that entered the host could multiply better in mutant than in wild‐type cells, because of a less efficient clearance in the early and a more efficient replication in the late phase of infection. We conclude that ATG9 and hence macroautophagy has a protective role during pathogen infection.     

Francisella tularensis Harvests Nutrients Derived via ATG5-Independent Autophagy to Support Intracellular Growth

Francisella tularensis is a highly virulent intracellular pathogen that invades and replicates within numerous host cell types including macrophages, hepatocytes and pneumocytes. By 24 hours post invasion, F. tularensis replicates up to 1000-fold in the cytoplasm of infected cells. To achieve such rapid intracellular proliferation, F. tularensis must scavenge large quantities of essential carbon and energy sources from the host cell while evading anti-microbial immune responses. We found that macroautophagy, a eukaryotic cell process that primarily degrades host cell proteins and organelles as well as intracellular pathogens, was induced in F. tularensis infected cells. F. tularensis not only survived macroautophagy, but optimal intracellular bacterial growth was found to require macroautophagy. Intracellular growth upon macroautophagy inhibition was rescued by supplying excess nonessential amino acids or pyruvate, demonstrating that autophagy derived nutrients provide carbon and energy sources that support F. tularensis proliferation. Furthermore, F. tularensis did not require canonical, ATG5-dependent autophagy pathway induction but instead induced an ATG5-independent autophagy pathway. ATG5-independent autophagy induction caused the degradation of cellular constituents resulting in the release of nutrients that the bacteria harvested to support bacterial replication. Canonical macroautophagy limits the growth of several different bacterial species. However, our data demonstrate that ATG5-independent macroautophagy may be beneficial to some cytoplasmic bacteria by supplying nutrients to support bacterial growth.     

Hypertonic stress promotes autophagy and microtubule-dependent autophagosomal clusters

Osmotic homeostasis is fundamental for most cells, which face recurrent alterations of environmental osmolality that challenge cell viability. Protein damage is a consequence of hypertonic stress, but whether autophagy contributes to the osmoprotective response is unknown. Here, we investigated the possible implications of autophagy and microtubule organization on the response to hypertonic stress. We show that hypertonicity rapidly induced long-lived protein degradation, LC3-II generation and Ptdlns3K-dependent formation of LC3- and ATG12-positive puncta. Lysosomotropic agents chloroquine and bafilomycin A₁, but not nutrient deprivation or rapamycin treatment, further increased LC3-II generation, as well as ATG12-positive puncta, indicating that hypertonic stress increases autophagic flux. Autophagy induction upon hypertonic stress enhanced cell survival since cell death was increased by ATG12 siRNA-mediated knockdown and reduced by rapamycin. We additionally showed that hypertonicity induces fast reorganization of microtubule networks, which is associated with strong reorganization of microtubules at centrosomes and fragmentation of Golgi ribbons. Microtubule remodeling was associated with pericentrosomal clustering of ATG12-positive autolysosomes that colocalized with SQSTM1/p62 and ubiquitin, indicating that autophagy induced by hypertonic stress is at least partly selective. Efficient autophagy by hypertonic stress required microtubule remodeling and was DYNC/dynein-dependent as autophagosome clustering was enhanced by paclitaxel-induced microtubule stabilization and was reduced by nocodazole-induced tubulin depolymerization as well as chemical (EHNA) or genetic [DCTN2/dynactin 2 (p50) overexpression] interference of DYNC activity. The data document a general and hitherto overlooked mechanism, where autophagy and microtubule remodeling play prominent roles in the osmoprotective response.     

HDAC6 and microtubules are required for autophagic degradation of aggregated huntingtin

CNS neurons are endowed with the ability to recover from cytotoxic insults associated with the accumulation of proteinaceous polyglutamine aggregates via a process that appears to involve capture and degradation of aggregates by autophagy. The ubiquitin-proteasome system protects cells against proteotoxicity by degrading soluble monomeric misfolded aggregation-prone proteins but is ineffective against, and impaired by, non-native protein oligomers. Here we show that autophagy is induced in response to impaired ubiquitin proteasome system activity. We show that ATG proteins, molecular determinants of autophagic vacuole formation, and lysosomes are recruited to pericentriolar cytoplasmic inclusion bodies by a process requiring an intact microtubule cytoskeleton and the cytoplasmic deacetylase HDAC6. These data suggest that HDAC6-dependent retrograde transport on microtubules is used by cells to increase the efficiency and selectivity of autophagic degradation.     

Compensatory mechanisms and the type of injury determine the fate of cells with impaired macroautophagy

The relationship between the degradative process of autophagy and cellular death pathways remains unclear. Macroautophagy may potentially function to prevent or promote cell death, and both effects have been reported in studies of cells with a block in macroautophagy. To better delineate the function of macroautophagy in cell death, we contrasted the responses to death stimuli in wild-type and atg5^-/- murine embryonic fibroblasts. We have reported that a knockout of the critical macroautophagy gene ATG5 sensitizes cells to death receptor ligand-induced death from Fas and tumor necrosis factor-α. Death occurs by caspase-dependent apoptosis resulting from activation of the mitochondrial death pathway. In contrast, atg5^-/- cells are more resistant to death induced by oxidative stress from menadione or UV light. This resistance was associated with an up-regulation of chaperone-mediated autophagy. Inhibition of this form of autophagy sensitizes cells to death from menadione, suggesting that the compensatory up-regulation of chaperone-mediated autophagy, and not the loss of macroautophagy, prevents death from menadione. These findings demonstrate that the effects of a loss of macroautophagy on the cellular death response differ depending on the mechanism of cellular injury and the compensatory changes in other forms of autophagy.

Addendum to: Wang Y, Singh R, Massey AC, Kane SS, Kaushik S, Grant T, Xiang Y, Cuervo AM, Czaja MJ. Loss of macroautophagy promotes or prevents fibroblast apoptosis depending on the death stimulus. J Biol Chem 2008; 283:4766-77.     

Autophagy is required for gamete differentiation in the moss Physcomitrella patens

Autophagy, a major catabolic process in eukaryotes, was initially related to cell tolerance to nutrient depletion. In plants autophagy has also been widely related to tolerance to biotic and abiotic stresses (through the induction or repression of programmed cell death, PCD) as well as to promotion of developmentally regulated PCD, starch degradation or caloric restriction important for life span. Much less is known regarding its role in plant cell differentiation. Here we show that macroautophagy, the autophagy pathway driven by engulfment of cytoplasmic components by autophagosomes and its subsequent degradation in vacuoles, is highly active during germ cell differentiation in the early diverging land plant Physcomitrella patens. Our data provide evidence that suppression of ATG5-mediated autophagy results in reduced density of the egg cell-mediated mucilage that surrounds the mature egg, pointing toward a potential role of autophagy in extracellular mucilage formation. In addition, we found that ATG5- and ATG7-mediated autophagy is essential for the differentiation and cytoplasmic reduction of the flagellated motile sperm and hence for sperm fertility. The similarities between the need of macroautophagy for sperm differentiation in moss and mouse are striking, strongly pointing toward an ancestral function of autophagy not only as a protector against nutrient stress, but also in gamete differentiation.     

Autophagy Contributes to Leaf Starch Degradation

Transitory starch, a major photosynthetic product in the leaves of land plants, accumulates in chloroplasts during the day and is hydrolyzed to maltose and Glc at night to support respiration and metabolism. Previous studies in Arabidopsis thaliana indicated that the degradation of transitory starch only occurs in the chloroplasts. Here, we report that autophagy, a nonplastidial process, participates in leaf starch degradation. Excessive starch accumulation was observed in Nicotiana benthamiana seedlings treated with an autophagy inhibitor and in autophagy-related (ATG) gene-silenced N. benthamiana and in Arabidopsis atg mutants. Autophagic activity in the leaves responded to the dynamic starch contents during the night. Microscopy showed that a type of small starch granule-like structure (SSGL) was localized outside the chloroplast and was sequestered by autophagic bodies. Moreover, an increased number of SSGLs was observed during starch depletion, and disruption of autophagy reduced the number of vacuole-localized SSGLs. These data suggest that autophagy contributes to transitory starch degradation by sequestering SSGLs to the vacuole for their subsequent breakdown.     

Dicot-specific ATG8-interacting ATI3 proteins interact with conserved UBAC2 proteins and play critical roles in plant stress responses

Selective macroautophagy/autophagy targets specific cargo by autophagy receptors through interaction with ATG8 (autophagy-related protein 8)/MAP1LC3 (microtubule associated protein 1 light chain 3) for degradation in the vacuole. Here, we report the identification and characterization of 3 related ATG8-interacting proteins (AT1G17780/ATI3A, AT2G16575/ATI3B and AT1G73130/ATI3C) from Arabidopsis. ATI3 proteins contain a WxxL LC3-interacting region (LIR) motif at the C terminus required for interaction with ATG8. ATI3 homologs are found only in dicots but not in other organisms including monocots. Disruption of ATI3A does not alter plant growth or development but compromises both plant heat tolerance and resistance to the necrotrophic fungal pathogen Botrytis cinerea. The critical role of ATI3A in plant stress tolerance and disease resistance is dependent on its interaction with ATG8. Disruption of ATI3B and ATI3C also significantly compromises plant heat tolerance. ATI3A interacts with AT3G56740/UBAC2A and AT2G41160/UBAC2B (Ubiquitin-associated [UBA] protein 2a/b), 2 conserved proteins implicated in endoplasmic reticulum (ER)-associated degradation. Disruption of UBAC2A and UBAC2B also compromised heat tolerance and resistance to B. cinerea. Overexpression of UBAC2 induces formation of ATG8- and ATI3-labeled punctate structures under normal conditions, likely reflecting increased formation of phagophores or autophagosomes. The ati3 and ubac2 mutants are significantly compromised in sensitivity to tunicamycin, an ER stress-inducing agent, but are fully competent in autophagy-dependent ER degradation under conditions of ER stress when using an ER lumenal marker for detection. We propose that ATI3 and UBAC2 play an important role in plant stress responses by mediating selective autophagy of specific unknown ER components.     

Mitophagy is primarily due to alternative autophagy and requires the MAPK1 and MAPK14 signaling pathways

In cultured cells, not many mitochondria are degraded by mitophagy induced by physiological cellular stress. We observed mitophagy in HeLa cells using a method that relies on the pH-sensitive fluorescent protein Keima. With this approach, we found that mitophagy was barely induced by carbonyl cyanide m-chlorophenyl hydrazone treatment, which is widely used as an inducer of PARK2/Parkin-related mitophagy, whereas a small but modest amount of mitochondria were degraded by mitophagy under conditions of starvation or hypoxia. Mitophagy induced by starvation or hypoxia was marginally suppressed by knockdown of ATG7 and ATG12, or MAP1LC3B, which are essential for conventional macroautophagy. In addition, mitophagy was efficiently induced in Atg5 knockout mouse embryonic fibroblasts. However, knockdown of RAB9A and RAB9B, which are essential for alternative autophagy, but not conventional macroautophagy, severely suppressed mitophagy. Finally, we found that the MAPKs MAPK1/ERK2 and MAPK14/p38 were required for mitophagy. Based on these findings, we conclude that mitophagy in mammalian cells predominantly occurs through an alternative autophagy pathway, requiring the MAPK1 and MAPK14 signaling pathways.     

Autophagy Is Involved in the Reduction of Myelinating Schwann Cell Cytoplasm during Myelin Maturation of the Peripheral Nerve

Peripheral nerve myelination involves dynamic changes in Schwann cell morphology and membrane structure. Recent studies have demonstrated that autophagy regulates organelle biogenesis and plasma membrane dynamics. In the present study, we investigated the role of autophagy in the development and differentiation of myelinating Schwann cells during sciatic nerve myelination. Electron microscopy and biochemical assays have shown that Schwann cells remove excess cytoplasmic organelles during myelination through macroautophagy. Inhibition of autophagy via Schwann cell-specific removal of ATG7, an essential molecule for macroautophagy, using a conditional knockout strategy, resulted in abnormally enlarged abaxonal cytoplasm in myelinating Schwann cells that contained a large number of ribosomes and an atypically expanded endoplasmic reticulum. Small fiber hypermyelination and minor anomalous peripheral nerve functions are observed in this mutant. Rapamycin-induced suppression of mTOR activity during the early postnatal period enhanced not only autophagy but also developmental reduction of myelinating Schwann cells cytoplasm in vivo. Together, our findings suggest that autophagy is a regulatory mechanism of Schwann cells structural plasticity during myelination.     

One step closer to understanding mammalian macroautophagy initiation: Interplay of 2 HORMA architectures in the ULK1 complex

ULK1 and ATG13 assemble with RB1CC1/FIP200 and ATG101 to form a macroautophagy (hereafter autophagy) induction (ULK1) complex in higher eukaryotes. The yeast counterpart, the Atg1 complex, is comprised of Atg1 and Atg13 (ULK1 and ATG13 homologs), Atg17 (a proposed functional homolog of RB1CC1), and either the Atg101 subunit (in Schizosaccharomyces pombe) or the Atg29-Atg31 heterodimer (in Saccharomyces cerevisiae). With mutual exclusivity of, and no detectable homology between, the Atg29-Atg31 dimer and Atg101, knowledge about the roles of these proteins in autophagy induction is an important piece in the puzzle of understanding the molecular mechanism of autophagy initiation. A recent study reporting the structure of the S. pombe homolog Atg101 bound to the Atg13^HORMA domain is a notable contribution to this knowledge (see the punctum in this issue of the journal).     

eIF4A,a target of siRNA derived from rice stripe virus,negatively regulates antiviral autophagy by interacting with ATG5 in Nicotiana benthamiana

Autophagy is induced by viral infection and has antiviral functions in plants, but the underlying mechanism is poorly understood. We previously identified a viral small interfering RNA (vsiRNA) derived from rice stripe virus (RSV) RNA4 that contributes to the leaf-twisting and stunting symptoms caused by this virus by targeting the host eukaryotic translation initiation factor 4A (eIF4A) mRNA for silencing. In addition, autophagy plays antiviral roles by degrading RSV p3 protein, a suppressor of RNA silencing. Here, we demonstrate that eIF4A acts as a negative regulator of autophagy in Nicotiana benthamiana. Silencing of NbeIF4A activated autophagy and inhibited RSV infection by facilitating autophagic degradation of p3. Further analysis showed that NbeIF4A interacts with NbATG5 and interferes with its interaction with ATG12. Overexpression of NbeIF4A suppressed NbATG5-activated autophagy. Moreover, expression of vsiRNA-4A, which targets NbeIF4A mRNA for cleavage, induced autophagy by silencing NbeIF4A. Finally, we demonstrate that eIF4A from rice, the natural host of RSV, also interacts with OsATG5 and suppresses OsATG5-activated autophagy, pointing to the conserved function of eIF4A as a negative regulator of antiviral autophagy. Taken together, these results reveal that eIF4A negatively regulates antiviral autophagy by interacting with ATG5 and that its mRNA is recognized by a virus-derived siRNA, resulting in its silencing, which induces autophagy against viral infection.     

Compensatory mechanisms and the type of injury determine the fate of cells with impaired macroautophagy

The relationship between the degradative process of autophagy and cellular death pathways remains unclear. Macroautophagy may potentially function to prevent or promote cell death, and both effects have been reported in studies of cells with a block in macroautophagy. To better delineate the function of macroautophagy in cell death, we contrasted the responses to death stimuli in wild-type and atg5(-/-) murine embryonic fibroblasts. We have reported that a knockout of the critical macroautophagy gene ATG5 sensitizes cells to death receptor ligand-induced death from Fas and tumor necrosis factor-alpha. Death occurs by caspase-dependent apoptosis resulting from activation of the mitochondrial death pathway. In contrast, atg5(-/-) cells are more resistant to death induced by oxidative stress from menadione or UV light. This resistance was associated with an upregulation of chaperone-mediated autophagy. Inhibition of this form of autophagy sensitizes cells to death from menadione, suggesting that the compensatory upregulation of chaperone-mediated autophagy, and not the loss of macroautophagy, prevents death from menadione. These findings demonstrate that the effects of a loss of macroautophagy on the cellular death response differ depending on the mechanism of cellular injury and the compensatory changes in other forms of autophagy.     

Monitoring autophagy in wheat living cells by visualization of fluorescence protein-tagged ATG8

Autophagy is a highly conserved eukaryotic degradation process during which bulk cytoplasmic materials are transported by double-membrane autophagosomes into the vacuole for degradation. Methods of monitoring autophagy are indispensable in studying the mechanism and functions of autophagy. AuTophaGy-related protein 8 (ATG8) functions in autophagosome assembly by decorating on autophagic membranes, and the inner membrane-bound ATG8 proteins enter the vacuole via active autophagy flux. Fluorescence protein (FP)-tagged forms of ATG8 have been explored as visual markers to monitor autophagy in animals and several plant species. Here, we evaluated and modified this FP-ATG8-based autophagy monitoring method in wheat (Triticum aestivum L.) by fluorescence observation of green fluorescence protein (GFP)-tagged and Discosoma red fluorescent protein (DsRED)-tagged forms of one wheat ATG8, TaATG8h, in wheat mesophyll protoplasts. Under a nutrient-starvation condition, punctate GFP/DsRED- TaATG8h fluorescence representing autophagosomes was clearly observed in the cytoplasm. The accumulation of GFP-TaATG8h-labeled autophagosomes was impaired by the autophagosome biogenesis inhibitor 3-methyladenine but enhanced by the vacuolar degradation inhibitor concanamycin A. In addition, accumulated spreading fluorescence was observed in the vacuole, indicating active autophagy fluxes which led to continuous degradation of GFP/DsRED-TaATG8h fusions and release of protease-tolerant free GFP/DsRED proteins in the vacuole. To observe FP-tagged TaATG8h in other types of wheat cell, we also expressed GFP-TaATG8h in leaf epidermal cells. Consistent with its performance in protoplasts, GFP-TaATG8h showed punctate fluorescence representing autophagosomes in leaf epidermal cells. Taken together, our results proved the feasibility of using FP-tagged ATG8 to monitor both autophagosome accumulation and autophagy flux in living wheat cells.     

Arabidopsis AUGMIN Subunit8 Is a Microtubule Plus-End Binding Protein That Promotes Microtubule Reorientation in Hypocotyls

In plant cells, cortical microtubules provide tracks for cellulose-synthesizing enzymes and regulate cell division, growth, and morphogenesis. The role of microtubules in these essential cellular processes depends on the spatial arrangement of the microtubules. Cortical microtubules are reoriented in response to changes in cell growth status and cell shape. Therefore, an understanding of the mechanism that underlies the change in microtubule orientation will provide insight into plant cell growth and morphogenesis. This study demonstrated that AUGMIN subunit8 (AUG8) in Arabidopsis thaliana is a novel microtubule plus-end binding protein that participates in the reorientation of microtubules in hypocotyls when cell elongation slows down. AUG8 bound to the plus ends of microtubules and promoted tubulin polymerization in vitro. In vivo, AUG8 was recruited to the microtubule branch site immediately before nascent microtubules branched out. It specifically associated with the plus ends of growing cortical microtubules and regulated microtubule dynamics, which facilitated microtubule reorientation when microtubules changed their growth trajectory or encountered obstacle microtubules during microtubule reorientation. This study thus reveals a novel mechanism underlying microtubule reorientation that is critical for modulating cell elongation in Arabidopsis.