TMED9-SEC12,an important "contact" for autophagy

Autophagosome biogenesis occurs via a complex mechanism that involves membranes from different subcellular compart-ments.Here,we review an elegant study from Li...     

LC3 and GATE-16 N termini mediate membrane fusion processes required for autophagosome biogenesis

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.     

Transmembrane phospholipid translocation mediated by Atg9 is involved in autophagosome formation

The mechanism of isolation membrane formation in autophagy is receiving intensive study. We recently found that Atg9 translocates phospholipids across liposomal membranes and proposed that this functionality plays an essential role in the expansion of isolation membranes. The distribution of phosphatidylinositol 3-phosphate in both leaflets of yeast autophagosomal membranes supports this proposal, but if Atg9-mediated lipid transport is crucial, symmetrical distribution in autophagosomes should be found broadly for other phospholipids. To test this idea, we analyzed the distributions of phosphatidylcholine, phosphatidylserine, and phosphatidylinositol 4-phosphate by freeze-fracture electron microscopy. We found that all these phospholipids are distributed with comparable densities in the two leaflets of autophagosomes and autophagic bodies. Moreover, de novo–synthesized phosphatidylcholine is incorporated into autophagosomes preferentially and shows symmetrical distribution in autophagosomes within 30 min after synthesis, whereas this symmetrical distribution is compromised in yeast expressing an Atg9 mutant. These results indicate that transbilayer phospholipid movement that is mediated by Atg9 is involved in the biogenesis of autophagosomes.     

De novo phosphatidylcholine synthesis is required for autophagosome membrane formation and maintenance during autophagy

ABSTRACT

Macroautophagy/autophagy can enable cancer cells to withstand cellular stress and maintain bioenergetic homeostasis by sequestering cellular components into newly formed double-membrane vesicles destined for lysosomal degradation, potentially affecting the efficacy of anti-cancer treatments. Using ¹³C-labeled choline and ¹³C-magnetic resonance spectroscopy and western blotting, we show increased de novo choline phospholipid (ChoPL) production and activation of PCYT1A (phosphate cytidylyltransferase 1, choline, alpha), the rate-limiting enzyme of phosphatidylcholine (PtdCho) synthesis, during autophagy. We also discovered that the loss of PCYT1A activity results in compromised autophagosome formation and maintenance in autophagic cells. Direct tracing of ChoPLs with fluorescence and immunogold labeling imaging revealed the incorporation of newly synthesized ChoPLs into autophagosomal membranes, endoplasmic reticulum (ER) and mitochondria during anticancer drug-induced autophagy. Significant increase in the colocalization of fluorescence signals from the newly synthesized ChoPLs and mCherry-MAP1LC3/LC3 (microtubule-associated protein 1 light chain 3) was also found on autophagosomes accumulating in cells treated with autophagy-modulating compounds. Interestingly, cells undergoing active autophagy had an altered ChoPL profile, with longer and more unsaturated fatty acid/alcohol chains detected. Our data suggest that de novo synthesis may be required to increase autophagosomal ChoPL content and alter its composition, together with replacing phospholipids consumed from other organelles during autophagosome formation and turnover. This addiction to de novo ChoPL synthesis and the critical role of PCYT1A may lead to development of agents targeting autophagy-induced drug resistance. In addition, fluorescence imaging of choline phospholipids could provide a useful way to visualize autophagosomes in cells and tissues.     

Regulation of autophagosome biogenesis by OFD1‐mediated selective autophagy

Autophagy is a lysosome‐dependent degradation pathway essential to maintain cellular homeostasis. Therefore, either defective or excessive autophagy may be detrimental for cells and tissues. The past decade was characterized by significant advances in molecular dissection of stimulatory autophagy inputs; however, our understanding of the mechanisms that restrain autophagy is far from complete. Here, we describe a negative feedback mechanism that limits autophagosome biogenesis based on the selective autophagy‐mediated degradation of ATG13, a component of the ULK1 autophagy initiation complex. We demonstrate that the centrosomal protein OFD1 acts as bona fide autophagy receptor for ATG13 via direct interaction with the Atg8/LC3/GABARAP family of proteins. We also show that patients with Oral‐Facial‐Digital type I syndrome, caused by mutations in the OFD1 gene, display excessive autophagy and that genetic inhibition of autophagy in a mouse model of the disease, significantly ameliorates polycystic kidney, a clinical manifestation of the disorder. Collectively, our data report the discovery of an autophagy self‐regulated mechanism and implicate dysregulated autophagy in the pathogenesis of renal cystic disease in mammals.     

ER–plasma membrane contact sites contribute to autophagosome biogenesis by regulation of local PI3P synthesis

The double‐membrane‐bound autophagosome is formed by the closure of a structure called the phagophore, origin of which is still unclear. The endoplasmic reticulum (ER) is clearly implicated in autophagosome biogenesis due to the presence of the omegasome subdomain positive for DFCP1, a phosphatidyl‐inositol‐3‐phosphate (PI3P) binding protein. Contribution of other membrane sources, like the plasma membrane (PM), is still difficult to integrate in a global picture. Here we show that ER–plasma membrane contact sites are mobilized for autophagosome biogenesis, by direct implication of the tethering extended synaptotagmins (E‐Syts) proteins. Imaging data revealed that early autophagic markers are recruited to E‐Syt‐containing domains during autophagy and that inhibition of E‐Syts expression leads to a reduction in autophagosome biogenesis. Furthermore, we demonstrate that E‐Syts are essential for autophagy‐associated PI3P synthesis at the cortical ER membrane via the recruitment of VMP1, the stabilizing ER partner of the PI3KC3 complex. These results highlight the contribution of ER–plasma membrane tethers to autophagosome biogenesis regulation and support the importance of membrane contact sites in autophagy.     

Mitophagy is required for mitochondrial biogenesis and myogenic differentiation of C2C12 myoblasts

Myogenesis is a crucial process governing skeletal muscle development and homeostasis. Differentiation of primitive myoblasts into mature myotubes requires a metabolic switch to support the increased energetic demand of contractile muscle. Skeletal myoblasts specifically shift from a highly glycolytic state to relying predominantly on oxidative phosphorylation (OXPHOS) upon differentiation. We have found that this phenomenon requires dramatic remodeling of the mitochondrial network involving both mitochondrial clearance and biogenesis. During early myogenic differentiation, autophagy is robustly upregulated and this coincides with DNM1L/DRP1 (dynamin 1-like)-mediated fragmentation and subsequent removal of mitochondria via SQSTM1 (sequestosome 1)-mediated mitophagy. Mitochondria are then repopulated via PPARGC1A/PGC-1α (peroxisome proliferator-activated receptor gamma, coactivator 1 alpha)-mediated biogenesis. Mitochondrial fusion protein OPA1 (optic atrophy 1 [autosomal dominant]) is then briskly upregulated, resulting in the reformation of mitochondrial networks. The final product is a myotube replete with new mitochondria. Respirometry reveals that the constituents of these newly established mitochondrial networks are better primed for OXPHOS and are more tightly coupled than those in myoblasts. Additionally, we have found that suppressing autophagy with various inhibitors during differentiation interferes with myogenic differentiation. Together these data highlight the integral role of autophagy and mitophagy in myogenic differentiation.     

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 novel regulator of autophagosome biogenesis and lipid droplet dynamics

Autophagosome biogenesis is the key event associated with the stress‐responsive autophagic pathway, allowing the capture of specific cargoes and their delivery to the lysosomal degradative compartment. Although the endoplasmatic reticulum (ER) appears to be central for the assembly of autophagosomal membranes, it is also involved in several events regulating trafficking and local signaling, e.g., the establishment of contact sites with other organelles, the vesicular transport to the Golgi apparatus, and the biogenesis and turnover of lipid droplets. In this issue of EMBO reports, Moretti et al 1 identify the ER transmembrane protein TMEM41B as a novel regulator of autophagosome biogenesis and unravel its involvement in lipid droplet dynamics, also highlighting the role of ER components at the interface of lipid metabolism and regulation of autophagy.     

Remodeling of ER‐exit sites initiates a membrane supply pathway for autophagosome biogenesis

Autophagosomes are double‐membrane vesicles generated during autophagy. Biogenesis of the autophagosome requires membrane acquisition from intracellular compartments, the mechanisms of which are unclear. We previously found that a relocation of COPII machinery to the ER–Golgi intermediate compartment (ERGIC) generates ERGIC‐derived COPII vesicles which serve as a membrane precursor for the lipidation of LC3, a key membrane component of the autophagosome. Here we employed super‐resolution microscopy to show that starvation induces the enlargement of ER‐exit sites (ERES) positive for the COPII activator, SEC12, and the remodeled ERES patches along the ERGIC. A SEC12 binding protein, CTAGE5, is required for the enlargement of ERES, SEC12 relocation to the ERGIC, and modulates autophagosome biogenesis. Moreover, FIP200, a subunit of the ULK protein kinase complex, facilitates the starvation‐induced enlargement of ERES independent of the other subunits of this complex and associates via its C‐terminal domain with SEC12. Our data indicate a pathway wherein FIP200 and CTAGE5 facilitate starvation‐induced remodeling of the ERES, a prerequisite for the production of COPII vesicles budded from the ERGIC that contribute to autophagosome formation.     

PI3P phosphatase activity is required for autophagosome maturation and autolysosome formation

Autophagosome formation is promoted by the PI3 kinase complex and negatively regulated by myotubularin phosphatases, indicating that regulation of local phosphatidylinositol 3‐phosphate (PtdIns3P) levels is important for this early phase of autophagy. Here, we show that the Caenorhabditis elegans myotubularin phosphatase MTM‐3 catalyzes PtdIns3P turnover late in autophagy. MTM‐3 acts downstream of the ATG‐2/EPG‐6 complex and upstream of EPG‐5 to promote autophagosome maturation into autolysosomes. MTM‐3 is recruited to autophagosomes by PtdIns3P, and loss of MTM‐3 causes increased autophagic association of ATG‐18 in a PtdIns3P‐dependent manner. Our data reveal critical roles of PtdIns3P turnover in autophagosome maturation and/or autolysosome formation.     

SEC11 is required for signal peptide processing and yeast cell growth

Among the collection of temperature-sensitive secretion mutants of Saccharomyces cerevisiae, sec11 mutant cells are uniquely defective in signal peptide processing of at least two different secretory proteins. At 37 degrees C, the restrictive growth temperature, sec11 cells accumulate core-glycosylated forms of invertase and acid phosphatase, each retaining an intact signal peptide. In contrast, other sec mutant strains in which transport of core-glycosylated molecules from the endoplasmic reticulum is blocked show no defect in signal peptide cleavage. A DNA fragment that complements the sec11-7 mutation has been cloned. Genetic analysis indicates that the complementing clone contains the authentic SEC11 gene, and that a null mutation at the SEC11 locus is lethal. The DNA sequence of SEC11 predicts a basic protein (estimated pI of 9.5) of 167 amino acids including an NH2-terminal hydrophobic region that may function as a signal and/or membrane anchor domain. One potential N-glycosylation site is found in the 18.8-kD (Sec 11p) predicted protein. The mass of the SEC11 protein is very close to that found for two of the subunits of the canine and hen oviduct signal peptidases. Furthermore, the chromatographic behavior of the hen oviduct enzyme indicates an overall basic charge comparable to the predicted pI of the Sec11p.     

Commentary: ATG16L1 meets ATG9 in recycling endosomes: Additional roles for the plasma membrane and endocytosis in autophagosome biogenesis

Autophagosomes are formed by double-membraned structures, which engulf portions of cytoplasm. Autophagosomes ultimately fuse with lysosomes, where their contents are degraded. The origin of the autophagosome membrane may involve different sources, such as mitochondria, Golgi, endoplasmic reticulum, plasma membrane, and recycling endosomes. We recently observed that ATG9 localizes on the plasma membrane in clathrin-coated structures and is internalized following a classical endocytic pathway through early and then recycling endosomes. By contrast, ATG16L1 is also internalized by clathrin-mediated endocytosis but via different clathrin-coated pits, and appears to follow a different route to the recycling endosomes. The R-SNARE VAMP3 mediates the coalescence of the 2 different pools of vesicles (containing ATG16L1 or ATG9) in recycling endosomes. The heterotypic fusion between ATG16L1- and ATG9-containing vesicles strongly correlates with subsequent autophagosome formation. Thus, ATG9 and ATG16L1 both traffic from the plasma membrane to autophagic precursor structures and provide 2 routes from the plasma membrane to autophagosomes.     

Recognition of the N-terminal lectin domain of FimH adhesin by the usher FimD is required for type 1 pilus biogenesis

In this work we discover that a specific recognition of the N-terminal lectin domain of FimH adhesin by the usher FimD is essential for the biogenesis of type 1 pili in Escherichia coli. These filamentous organelles are assembled by the chaperone-usher pathway, in which binary complexes between fimbrial subunits and the periplasmic chaperone FimC are recognized by the outer membrane protein FimD (the usher). FimH adhesin initiates fimbriae polymerization and is the first subunit incorporated in the filament. Accordingly, FimD shows higher affinity for the FimC/FimH complex although the structural basis of this specificity is unknown. We have analysed the assembly into fimbria, and the interaction with FimD in vivo, of FimH variants in which the N-terminal lectin domain of FimH was deleted or substituted by different immunoglobulin (Ig) domains, or in which these Ig domains were fused to the N-terminus of full-length FimH. From these data, along with the analysis of a FimH mutant with a single amino acid change (G16D) in the N-terminal lectin domain, we conclude that the lectin domain of FimH is recognized by FimD usher as an essential step for type 1 pilus biogenesis.     

Components of SurA required for outer membrane biogenesis in uropathogenic Escherichia coli

Background

SurA is a periplasmic peptidyl-prolyl isomerase (PPIase) and chaperone of Escherichia coli and other Gram-negative bacteria. In contrast to other PPIases, SurA appears to have a distinct role in chaperoning newly synthesized porins destined for insertion into the outer membrane. Previous studies have indicated that the chaperone activity of SurA rests in its “core module” (the N- plus C-terminal domains), based on in vivo envelope phenotypes and in vitro binding and protection of non-native substrates.

Methodology/Principal Findings

In this study, we determined the components of SurA required for chaperone activity using in vivo phenotypes relevant to disease causation by uropathogenic E. coli (UPEC), namely membrane resistance to permeation by antimicrobials and maturation of the type 1 pilus usher FimD. FimD is a SurA-dependent, integral outer membrane protein through which heteropolymeric type 1 pili, which confer bladder epithelial binding and invasion capacity upon uropathogenic E. coli, are assembled and extruded. Consistent with prior results, the in vivo chaperone activity of SurA in UPEC rested primarily in the core module. However, the PPIase domains I and II were not expendable for wild-type resistance to novobiocin in broth culture. Steady-state levels of FimD were substantially restored in the UPEC surA mutant complemented with the SurA N- plus C-terminal domains. The addition of PPIase domain I augmented FimD maturation into the outer membrane, consistent with a model in which domain I enhances stability of and/or substrate binding by the core module.

Conclusions/Significance

Our results confirm the core module of E. coli SurA as a potential target for novel anti-infective development.     

Vaccinia virus A11 is required for membrane rupture and viral membrane assembly

Although most enveloped viruses acquire their membrane from the host by budding or by a wrapping process, collective data argue that nucleocytoplasmic large DNA viruses (NCLDVs) may be an exception. The prototype member of NCLDVs, vaccinia virus (VACV) may induce rupture of endoplasmic‐reticulum‐derived membranes to build an open‐membrane sphere that closes after DNA uptake. This unconventional membrane assembly pathway is also used by at least 3 other members of the NCLDVs. In this study, we identify the VACV gene product of A11, as required for membrane rupture, hence for VACV membrane assembly and virion formation. By electron tomography, in the absence of A11, the site of assembly formed by the viral scaffold protein D13 is surrounded by endoplasmic reticulum cisternae that are closed. We use scanning transmission electron microscopy–electron tomography to analyse large volumes of cells and demonstrate that in the absence of A11, no open membranes are detected. Given the pivotal role of D13 in initiating VACV membrane assembly, we also analyse viral membranes in the absence of D13 synthesis and show that this protein is not required for rupture. Finally, consistent with a role in rupture, we show that during wild‐type infection, A11 localises predominantly to the small ruptured membranes, the precursors of VACV membrane assembly. These data provide strong evidence in favour of the unusual membrane biogenesis of VACV and are an important step towards understanding its molecular mechanism.     

BCCIP is required for nucleolar recruitment of eIF6 and 12S pre-rRNA production during 60S ribosome biogenesis

Ribosome biogenesis is a fundamental process required for cell proliferation. Although evolutionally conserved, the mammalian ribosome assembly system is more complex than in yeasts. BCCIP was originally identified as a BRCA2 and p21 interacting protein. A partial loss of BCCIP function was sufficient to trigger genomic instability and tumorigenesis. However, a complete deletion of BCCIP arrested cell growth and was lethal in mice. Here, we report that a fraction of mammalian BCCIP localizes in the nucleolus and regulates 60S ribosome biogenesis. Both abrogation of BCCIP nucleolar localization and impaired BCCIP–eIF6 interaction can compromise eIF6 recruitment to the nucleolus and 60S ribosome biogenesis. BCCIP is vital for a pre-rRNA processing step that produces 12S pre-rRNA, a precursor to the 5.8S rRNA. However, a heterozygous Bccip loss was insufficient to impair 60S biogenesis in mouse embryo fibroblasts, but a profound reduction of BCCIP was required to abrogate its function in 60S biogenesis. These results suggest that BCCIP is a critical factor for mammalian pre-rRNA processing and 60S generation and offer an explanation as to why a subtle dysfunction of BCCIP can be tumorigenic but a complete depletion of BCCIP is lethal.