Atg4 recycles inappropriately lipidated Atg8 to promote autophagosome biogenesis

Atg8 is a ubiquitin-like protein required for autophagy in the budding yeast Saccharomyces cerevisiae. A ubiquitin-like system mediates the conjugation of the C terminus of Atg8 to the lipid phosphatidylethanolamine (PE), and this conjugate (Atg8–PE) plays a crucial role in autophagosome formation at the phagophore assembly site/pre-autophagosomal structure (PAS). The cysteine protease Atg4 processes the C terminus of newly synthesized Atg8 and also delipidates Atg8 to release the protein from membranes. While the former is a prerequisite for lipidation of Atg8, the significance of the latter in autophagy has remained unclear. Here, we show that autophagosome formation is significantly retarded in cells deficient for Atg4-mediated delipidation of Atg8. We find that Atg8–PE accumulates on various organelle membranes including the vacuole, the endosome and the ER in these cells, which depletes unlipidated Atg8 and thereby attenuates its localization to the PAS. Our results suggest that the Atg8–PE that accumulates on organelle membranes is erroneously produced by lipidation system components independently of the normal autophagic process. It is also suggested that delipidation of Atg8 by Atg4 on different organelle membranes promotes autophagosome formation. Considered together with other results, we propose that Atg4 acts to compensate for the intrinsic defect in the lipidation system; it recycles Atg8–PE generated on inappropriate membranes to maintain a reservoir of unlipidated Atg8 that is required for autophagosome formation at the PAS.     

Atg4 recycles inappropriately lipidated Atg8 to promote autophagosome biogenesis

Atg8 is a ubiquitin-like protein required for autophagy in the budding yeast Saccharomyces cerevisiae. A ubiquitin-like system mediates the conjugation of the C terminus of Atg8 to the lipid phosphatidylethanolamine (PE), and this conjugate (Atg8-PE) plays a crucial role in autophagosome formation at the phagophore assembly site/pre-autophagosomal structure (PAS). The cysteine protease Atg4 processes the C terminus of newly synthesized Atg8 and also delipidates Atg8 to release the protein from membranes. While the former is a prerequisite for lipidation of Atg8, the significance of the latter in autophagy has remained unclear. Here, we show that autophagosome formation is significantly retarded in cells deficient for Atg4-mediated delipidation of Atg8. We find that Atg8-PE accumulates on various organelle membranes including the vacuole, the endosome and the ER in these cells, which depletes unlipidated Atg8 and thereby attenuates its localization to the PAS. Our results suggest that the Atg8-PE that accumulates on organelle membranes is erroneously produced by lipidation system components independently of the normal autophagic process. It is also suggested that delipidation of Atg8 by Atg4 on different organelle membranes promotes autophagosome formation. Considered together with other results, we propose that Atg4 acts to compensate for the intrinsic defect in the lipidation system; it recycles Atg8-PE generated on inappropriate membranes to maintain a reservoir of unlipidated Atg8 that is required for autophagosome formation at the PAS.     

Fission yeast tropomyosin specifies directed transport of myosin-V along actin cables

A hallmark of class-V myosins is their processivity—the ability to take multiple steps along actin filaments without dissociating. Our previous work suggested, however, that the fission yeast myosin-V (Myo52p) is a nonprocessive motor whose activity is enhanced by tropomyosin (Cdc8p). Here we investigate the molecular mechanism and physiological relevance of tropomyosin-mediated regulation of Myo52p transport, using a combination of in vitro and in vivo approaches. Single molecules of Myo52p, visualized by total internal reflection fluorescence microscopy, moved processively only when Cdc8p was present on actin filaments. Small ensembles of Myo52p bound to a quantum dot, mimicking the number of motors bound to physiological cargo, also required Cdc8p for continuous motion. Although a truncated form of Myo52p that lacked a cargo-binding domain failed to support function in vivo, it still underwent actin-dependent movement to polarized growth sites. This result suggests that truncated Myo52p lacking cargo, or single molecules of wild-type Myo52p with small cargoes, can undergo processive movement along actin-Cdc8p cables in vivo. Our findings outline a mechanism by which tropomyosin facilitates sorting of transport to specific actin tracks within the cell by switching on myosin processivity.     

Atg14L recruits PtdIns 3-kinase to the ER for autophagosome formation

Divergent phosphoinositides are generated to characterize specific organelles and recruit specific effector proteins to these sites. For example, phosphatidylinositol-3-phosphate (PtdIns(3)P) is a typical endosome marker and recruits many types of PtdIns(3)P binding proteins such as EEA1, Hrs, and sorting nexins, which are critical in endosomal functions. Likewise, the plasma membrane contains PtdIns(4,5)P?, whereas the Golgi complex has PtdIns(4)P. In this sense, the endoplasmic reticulum is known to be essentially free of phosphoinositide. In other words, this situation provides the ER with the opportunity to recruit whatever proteins are in demand. Recently, we have uncovered how PtdIns(3)P is generated on the ER for the autophagic process.     

Live cell imaging of mitochondrial movement along actin cables in budding yeast

BACKGROUND: Mitochondrial inheritance is essential for cell division. In budding yeast, mitochondrial movement from mother to daughter requires (1) actin cables, F-actin bundles that undergo retrograde movement during elongation from buds into mother cells; (2) the mitochore, a mitochondrial protein complex implicated in linking mitochondria to actin cables; and (3) Arp2/3 complex-mediated force generation on mitochondria. RESULTS: We observed three new classes of mitochondrial motility: anterograde movement at velocities of 0.2-0.33 microm/s, retrograde movement at velocities of 0.26-0.51 microm/s, and no net anterograde or retrograde movement. In all cases, motile mitochondria were associated with actin cables undergoing retrograde flow at velocities of 0.18-0.62 microm/s. Destabilization of actin cables or mutations of the mitochore blocked all mitochondrial movements. In contrast, mutations in the Arp2/3 complex affected anterograde but not retrograde mitochondrial movements. CONCLUSIONS: Actin cables are required for movement of mitochondria, secretory vesicles, mRNA, and spindle alignment elements in yeast. We provide the first direct evidence that one of the proposed cargos use actin cables as tracks. In the case of mitochondrial inheritance, anterograde movement drives transfer of the organelle from mothers to buds, while retrograde movement contributes to retention of the organelle in mother cells. Interaction of mitochondria with actin cables is required for anterograde and retrograde movement. In contrast, force generation on mitochondria is required only for anterograde movement. Finally, we propose a novel mechanism in which actin cables serve as "conveyor belts" that drive retrograde organelle movement.     

Spindle orientation in Saccharomyces cerevisiae depends on the transport of microtubule ends along polarized actin cables

Microtubules and actin filaments interact and cooperate in many processes in eukaryotic cells, but the functional implications of such interactions are not well understood. In the yeast Saccharomyces cerevisiae, both cytoplasmic microtubules and actin filaments are needed for spindle orientation. In addition, this process requires the type V myosin protein Myo2, the microtubule end-binding protein Bim1, and Kar9. Here, we show that fusing Bim1 to the tail of the Myo2 is sufficient to orient spindles in the absence of Kar9, suggesting that the role of Kar9 is to link Myo2 to Bim1. In addition, we show that Myo2 localizes to the plus ends of cytoplasmic microtubules, and that the rate of movement of these cytoplasmic microtubules to the bud neck depends on the intrinsic velocity of Myo2 along actin filaments. These results support a model for spindle orientation in which a Myo2-Kar9-Bim1 complex transports microtubule ends along polarized actin cables. We also present data suggesting that a similar process plays a role in orienting cytoplasmic microtubules in mating yeast cells.     

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.     

An Atg9-containing compartment that functions in the early steps of autophagosome biogenesis

Eukaryotes use the process of autophagy, in which structures targeted for lysosomal/vacuolar degradation are sequestered into double-membrane autophagosomes, in numerous physiological and pathological situations. The key questions in the field relate to the origin of the membranes as well as the precise nature of the rearrangements that lead to the formation of autophagosomes. We found that yeast Atg9 concentrates in a novel compartment comprising clusters of vesicles and tubules, which are derived from the secretory pathway and are often adjacent to mitochondria. We show that these clusters translocate en bloc next to the vacuole to form the phagophore assembly site (PAS), where they become the autophagosome precursor, the phagophore. In addition, genetic analyses indicate that Atg1, Atg13, and phosphatidylinositol-3-phosphate are involved in the further rearrangement of these initial membranes. Thus, our data reveal that the Atg9-positive compartments are important for the de novo formation of the PAS and the sequestering vesicle that are the hallmarks of autophagy.     

Recruitment of Atg9 to the preautophagosomal structure by Atg11 is essential for selective autophagy in budding yeast

Autophagy is a conserved degradative pathway that is induced in response to various stress and developmental conditions in eukaryotic cells. It allows the elimination of cytosolic proteins and organelles in the lysosome/vacuole. In the yeast Saccharomyces cerevisiae, the integral membrane protein Atg9 (autophagy-related protein 9) cycles between mitochondria and the preautophagosomal structure (PAS), the nucleating site for formation of the sequestering vesicle, suggesting a role in supplying membrane for vesicle formation and/or expansion during autophagy. To better understand the mechanisms involved in Atg9 cycling, we performed a yeast two-hybrid-based screen and identified a peripheral membrane protein, Atg11, that interacts with Atg9. We show that Atg11 governs Atg9 cycling through the PAS during specific autophagy. We also demonstrate that the integrity of the actin cytoskeleton is essential for correct targeting of Atg11 to the PAS. We propose that a pool of Atg11 mediates the anterograde transport of Atg9 to the PAS that is dependent on the actin cytoskeleton during yeast vegetative growth.     

A mammalian autophagosome maturation mechanism mediated by TECPR1 and the Atg12-Atg5 conjugate

Autophagy is a major catabolic pathway in eukaryotes associated with a broad spectrum of human diseases. In autophagy, autophagosomes carrying cellular cargoes fuse with lysosomes for degradation. However, the molecular mechanism underlying autophagosome maturation is largely unknown. Here we report that TECPR1 binds to the Atg12-Atg5 conjugate and phosphatidylinositol 3-phosphate (PtdIns[3]P) to promote autophagosome-lysosome fusion. TECPR1 and Atg16 form mutually exclusive complexes with the Atg12-Atg5 conjugate, and TECPR1 binds PtdIns(3)P upon association with the Atg12-Atg5 conjugate. Strikingly, TECPR1 localizes to and recruits Atg5 to autolysosome membrane. Consequently, elimination of TECPR1 leads to accumulation of autophagosomes and blocks autophagic degradation of LC3-II and p62. Finally, autophagosome maturation marked by GFP-mRFP-LC3 is defective in TECPR1-deficient cells. Thus, we propose that the concerted interactions among TECPR1, Atg12-Atg5, and PtdIns(3)P provide the fusion specificity between autophagosomes and lysosomes and that the assembly of this complex initiates the autophagosome maturation process.     

A missing piece of the puzzle: Atg11 functions as a scaffold to activate Atg1 for selective autophagy

The mechanism regulating Atg1 kinase activity for the initiation of selective macroautophagy (hereafter autophagy) under nutrient-rich conditions has been a long-standing question. Canonically in yeast, nutrient starvation or rapamycin treatment repress TOR complex 1 and stimulate the Atg1 complex (including at least Atg1, Atg13, Atg17, Atg29 and Atg31), which allows the recruitment of downstream autophagy-related (Atg) components to the phagophore assembly site (PAS), culminating in phagophore formation, and, subsequently, autophagosome biogenesis. Atg1 also functions under conditions promoting selective autophagy that do not necessarily require nutrient deprivation for induction. However, there has been some debate as to whether Atg1 catalytic activity plays a more important role under conditions of nutrient starvation-induced autophagy (i.e., bulk autophagy) vs. selective autophagy (e.g., the cytoplasm-to-vacuole targeting [Cvt] pathway). A recent paper by Kamber and colleagues investigates the mechanism regulating Atg1 activity during selective autophagy.     

Atg11 links cargo to the vesicle-forming machinery in the cytoplasm to vacuole targeting pathway

Proteins are selectively packaged into vesicles at specific sites and then delivered correctly to the various organelles where they function, which is critical to the proper physiology of each organelle. The precursor form of the vacuolar hydrolase aminopeptidase I is a selective cargo molecule of the cytoplasm to vacuole targeting (Cvt) pathway and autophagy. Precursor Ape1 along with its receptor Atg19 forms the Cvt complex, which is transported to the pre-autophagosomal structure (PAS), the putative site of Cvt vesicle formation, in a process dependent on Atg11. Here, we show that this interaction occurs through the Atg11 C terminus; subsequent recruitment of the Cvt complex to the PAS depends on central regions within Atg11. Atg11 was shown to physically link several proteins, although the timing of these interactions and their importance are unknown. Our mapping shows that the Atg11 coiled-coil domains are involved in self-assembly and the interaction with other proteins, including two previously unidentified partners, Atg17 and Atg20. Atg11 mutants defective in the transport of the Cvt complex to the PAS affect the localization of other Atg components, supporting the idea that the cargo facilitates the organization of the PAS in selective autophagy. These findings suggest that Atg11 plays an integral role in connecting cargo molecules with components of the vesicle-forming machinery.     

Arabidopsis VILLIN1 generates actin filament cables that are resistant to depolymerization

Dynamic cytoplasmic streaming, organelle positioning, and nuclear migration use molecular tracks generated from actin filaments arrayed into higher-order structures like actin cables and bundles. How these arrays are formed and stabilized against cellular depolymerizing forces remains an open question. Villin and fimbrin are the best characterized actin-filament bundling or cross-linking proteins in plants and each is encoded by a multigene family of five members in Arabidopsis thaliana. The related villins and gelsolins are conserved proteins that are constructed from a core of six homologous gelsolin domains. Gelsolin is a calcium-regulated actin filament severing, nucleating and barbed end capping factor. Villin has a seventh domain at its C terminus, the villin headpiece, which can bind to an actin filament, conferring the ability to crosslink or bundle actin filaments. Many, but not all, villins retain the ability to sever, nucleate, and cap filaments. Here we have identified a putative calcium-insensitive villin isoform through comparison of sequence alignments between human gelsolin and plant villins with x-ray crystallography data for vertebrate gelsolin. VILLIN1 (VLN1) has the least well-conserved type 1 and type 2 calcium binding sites among the Arabidopsis VILLIN isoforms. Recombinant VLN1 binds to actin filaments with high affinity (K(d) approximately 1 microM) and generates bundled filament networks; both properties are independent of the free Ca(2+) concentration. Unlike human plasma gelsolin, VLN1 does not nucleate the assembly of filaments from monomer, does not block the polymerization of profilin-actin onto barbed ends, and does not stimulate depolymerization or sever preexisting filaments. In kinetic assays with ADF/cofilin, villin appears to bind first to growing filaments and protects filaments against ADF-mediated depolymerization. We propose that VLN1 is a major regulator of the formation and stability of actin filament bundles in plant cells and that it functions to maintain the cable network even in the presence of stimuli that result in depolymerization of other actin arrays.     

Immobilization of endoplasm flowing contiguous to the actin cables upon electrical stimulus inNitella internodes

Summary Using a stroboscopic centrifuge microscope, we demonstrated that, when actin cables (=bundles of F-actin) had been previously removed locally from the cell cortex ofNitella internodes, the passively flowing endoplasm found there under centrifugal force did not stop at all upon electrical stimulus, while the actively flowing endoplasm contiguous to the actin cables at the normal cell cortex promptly stopped following the stimulus and was immobilized for several seconds. The results present evidence that, upon electrical stimulus, the presence of actin cables is required to immobilize the endoplasm flowing contiguous to the actin cables in a state that resists displacement by centrifugal force.Abbreviations APW artificial pond water - CMS centrifuge microscope     

CASP4/caspase-11 promotes autophagosome formation in response to bacterial infection

CASP4/caspase-11-dependent inflammasome activation is important for the clearance of various Gram-negative bacteria entering the host cytosol. Additionally, CASP4 modulates the actin cytoskeleton to promote the maturation of phagosomes harboring intracellular pathogens such as Legionella pneumophila but not those enclosing nonpathogenic bacteria. Nevertheless, this non-inflammatory role of CASP4 regarding the trafficking of vacuolar bacteria remains poorly understood. Macroautophagy/autophagy, a catabolic process within eukaryotic cells, is also implicated in the elimination of intracellular pathogens such as Burkholderia cenocepacia. Here we show that CASP4-deficient macrophages exhibit a defect in autophagosome formation in response to B. cenocepacia infection. The absence of CASP4 causes an accumulation of the small GTPase RAB7, reduced colocalization of B. cenocepacia with LC3 and acidic compartments accompanied by increased bacterial replication in vitro and in vivo. Together, our data reveal a novel role of CASP4 in regulating autophagy in response to B. cenocepacia infection.     

The actin cytoskeleton participates in the early events of autophagosome formation upon starvation induced autophagy

Autophagy is a process by which cytoplasmic material is sequestered in a double-membrane vesicle destined for degradation. Nutrient deprivation stimulates the pathway and the number of autophagosomes in the cell increases in response to such stimulus. In the current report we have demonstrated that actin is necessary for starvation-mediated autophagy. When the actin cytoskeleton is depolymerized, the increase in autophagic vacuoles in response to the starvation stimulus was abolished without affecting maturation of remaining autophagosomes. In addition, actin filaments colocalized with ATG14, BECN1/Beclin1 and PtdIns3P-rich structures, and some of them have a typical omegasome shape stained with the double FYVE domain or ZFYVE1/DFCP1. In contrast, no major colocalization between actin and ULK1, ULK2, ATG5 or MAP1LC3/LC3 was observed. Taken together, our data indicate that actin has a role at very early stages of autophagosome formation linked to the PtdIns3P generation step. In addition, we have found that two members of the Rho family of proteins, RHOA and RAC1 have a regulatory function on starvation-mediated autophagy, but with opposite roles. Indeed, RHOA has an activatory role whereas Rac has an inhibitory one. We have also found that inhibition of the RHOA effector ROCK impaired the starvation-mediated autophagic response. We propose that actin participates in the initial membrane remodeling stage when cells require an enhanced rate of autophagosome formation, and this actin function would be tightly regulated by different members of the Rho family.     

The role of actin cables in directing the morphogenesis of the pharyngeal pouches

The pharyngeal arches are separated by endodermal outpocketings, the pharyngeal pouches. These are structures of considerable importance; they are required to segregate the mesenchymal populations of each arch and to induce the formation of arch components, and they generate specific derivatives, including the parathyroid and the thymus. The pharyngeal pouches are first evident as localised sites at which the endoderm contacts the ectoderm, and they then expand along the proximodistal axis to generate the narrow, tight morphology of the mature pouch. We currently have no knowledge of the morphogenetic mechanisms that direct formation of the pharyngeal pouches. Here, in chick, we show that cells within the pharyngeal pouch endoderm have an abundance of apically located actin fibres that are networked within the endodermal sheet, via their insertion into N-cadherin adherens junctions, to form a web of supra-cellular actin cables. Cytochalasin D disruption of these actin structures results in the formation of aberrant pouches that fail to generate their normal slit-like morphology. This suggests that the process of pharyngeal pouch morphogenesis involves the constraining influence of these actin cables that direct expansion, within the pouch, along the proximodistal axis. These results, importantly, provide us with vital insights into how the pharyngeal pouches form their normal morphology. They also give evidence, for the first time, of actin cables functioning as constraints during complex vertebrate morphogenetic episodes.     

The actin cytoskeleton participates in the early events of autophagosome formation upon starvation induced autophagy

Autophagy is a process by which cytoplasmic material is sequestered in a double-membrane vesicle destined for degradation. Nutrient deprivation stimulates the pathway and the number of autophagosomes in the cell increases in response to such stimulus. In the current report we have demonstrated that actin is necessary for starvation-mediated autophagy. When the actin cytoskeleton is depolymerized, the increase in autophagic vacuoles in response to the starvation stimulus was abolished without affecting maturation of remaining autophagosomes. In addition, actin filaments colocalized with ATG14, BECN1/Beclin1 and PtdIns3P-rich structures, and some of them have a typical omegasome shape stained with the double FYVE domain or ZFYVE1/DFCP1. In contrast, no major colocalization between actin and ULK1, ULK2, ATG5 or MAP1LC3/LC3 was observed. Taken together, our data indicate that actin has a role at very early stages of autophagosome formation linked to the PtdIns3P generation step. In addition, we have found that two members of the Rho family of proteins, RHOA and RAC1 have a regulatory function on starvation-mediated autophagy, but with opposite roles. Indeed, RHOA has an activatory role whereas Rac has an inhibitory one. We have also found that inhibition of the RHOA effector ROCK impaired the starvation-mediated autophagic response. We propose that actin participates in the initial membrane remodeling stage when cells require an enhanced rate of autophagosome formation, and this actin function would be tightly regulated by different members of the Rho family.     

Chemokine signaling directs trunk lymphatic network formation along the preexisting blood vasculature

The lymphatic system is crucial for fluid homeostasis, immune responses, and numerous pathological processes. However, the molecular mechanisms responsible for establishing the anatomical form of the lymphatic vascular network remain largely unknown. Here, we show that chemokine signaling provides critical guidance cues directing early trunk lymphatic network assembly and patterning. The chemokine receptors Cxcr4a and Cxcr4b are expressed in lymphatic endothelium, whereas chemokine ligands Cxcl12a and Cxcl12b are expressed in adjacent tissues along which the developing lymphatics align. Loss- and gain-of-function studies in zebrafish demonstrate that chemokine signaling orchestrates the stepwise assembly of the trunk lymphatic network. In addition to providing evidence for a lymphatic vascular guidance mechanism, these results also suggest a molecular basis for the anatomical coalignment of lymphatic and blood vessels.