Prefused lysosomes cluster on autophagosomes regulated by VAMP8

Lysosome–autophagosome fusion is critical to autophagosome maturation. Although several proteins that regulate this fusion process have been identified, the prefusion architecture and its regulation remain unclear. Herein, we show that upon stimulation, multiple lysosomes form clusters around individual autophagosomes, setting the stage for membrane fusion. The soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) protein on lysosomes—vesicle-associated membrane protein 8 (VAMP8)—plays an important role in forming this prefusion state of lysosomal clusters. To study the potential role of phosphorylation on spontaneous fusion, we investigated the effect of phosphorylation of C-terminal residues of VAMP8. Using a phosphorylation mimic, we observed a decrease of fusion in an ensemble lipid mixing assay and an increase of unfused lysosomes associated with autophagosomes. These results suggest that phosphorylation not only reduces spontaneous fusion for minimizing autophagic flux under normal conditions, but also preassembles multiple lysosomes to increase the fusion probability for resuming autophagy upon stimulation. VAMP8 phosphorylation may thus play an important role in chemotherapy drug resistance by influencing autophagosome maturation.Subject terms: Cancer therapeutic resistance, Membrane fusion     

Autophagy is a therapeutic target in anticancer drug resistance

Autophagy is a type of cellular catabolic degradation response to nutrient starvation or metabolic stress. The main function of autophagy is to maintain intracellular metabolic homeostasis through degradation of unfolded or aggregated proteins and organelles. Although autophagic regulation is a complicated process, solid evidence demonstrates that the PI3K-Akt-mTOR, LKB1-AMPK-mTOR and p53 are the main upstream regulators of the autophagic pathway. Currently, there is a bulk of data indicating the important function of autophagy in cancer. It is noteworthy that autophagy facilitates the cancer cells' resistance to chemotherapy and radiation treatment. The abrogation of autophagy potentiates the re-sensitization of therapeutic resistant cancer cells to the anticancer treatment via autophagy inhibitors, such as 3-MA, CQ and BA, or knockdown of the autophagy related molecules. In this review, we summarize the accumulation of evidence for autophagy's involvement in mediating resistance of cancer cells to anticancer therapy and suggest that autophagy might be a potential therapeutic target in anticancer drug resistance in the future.     

Estrogen enhances human osteoblast survival and function via promotion of autophagy

Estrogen increases bone formation by promoting mineralization and prolonging the lifespan of osteoblasts. To understand the underlying molecular mechanism/s, we identified estrogen-regulated proteins at different stages of human osteoblast differentiation using differential proteomics approach. Among the identified proteins, we observed that estrogen upregulated RAB3GAP1 on day 1 and 5 of differentiation. RAB3GAP1 is critically involved in the process of autophagy, a eukaryotic degradative pathway essential for cell survival. We, therefore, investigated the effect of estrogen on autophagy in differentiating human osteoblasts and their precursors, the mesenchymal stem cells (MSCs). MSCs exhibited high autophagic flux which declined during osteoblast differentiation, resulting in high basal apoptosis in osteoblasts. Estrogen reduced apoptosis in differentiating osteoblasts by promoting autophagy, thus contributing towards their longer lifespan. Further, MSCs were resistant against starvation-induced apoptosis, whereas, differentiating osteoblasts showed significant susceptibility towards it. Estrogen, in addition to promoting mineralization, protected differentiating osteoblasts from starvation-induced apoptosis by increasing autophagic flux. Autophagic flux in RAB3GAP1 knockdown osteoblasts appeared diminished, and showed increased apoptosis even in nutrient-rich conditions, and exhibited significantly impaired mineralization. However, irrespective of the presence of estrogen, starvation further enhanced apoptosis in these cells. Furthermore, estrogen failed to promote mineralization in these osteoblasts. Our study illustrates that autophagy is essential for human osteoblast survival and mineralization, and osteoblasts are susceptible to apoptosis due to reduced autophagy during differentiation. Estrogen, via upregulation of RAB3GAP1, promotes autophagy in osteoblasts during differentiation thereby increasing their survival and mineralization capacity. Our study demonstrates the positive role of autophagy in bone homeostasis.     

Emerging nexus between RAB GTPases,autophagy and neurodegeneration

The RAB class of small GTPases includes the major regulators of intracellular communication, which are involved in vesicle generation through fusion and fission, and vesicular trafficking. RAB proteins also play an imperative role in neuronal maintenance and survival. Recent studies in the field of neurodegeneration have also highlighted the process of autophagy as being essential for neuronal maintenance. Here we review the emerging roles of RAB proteins in regulating macroautophagy and its impact in the context of neurodegenerative diseases.     

Phagophores evolve from recycling endosomes

The membrane origins of autophagosomes have been a key unresolved question in the field. The earliest morphologically recognizable structure in the macroautophagy/autophagy itinerary is the double-membraned cup-shaped phagophore. Newly formed phosphatidylinositol 3-phosphate (PtdIns3P) on the membranes destined to become phagophores recruits WIPI2, which, in turn, binds ATG16L1 to define the sites of autophagosome formation. Here we review our recent study showing that membrane recruitment of WIPI2 requires coincident detection of PtdIns3P and RAB11A, a protein that marks recycling endosomes. We found that multiple core autophagy proteins are more tightly associated with the recycling endosome compartment than with endoplasmic reticulum (ER)-mitochondrial contact sites. Furthermore, biochemical isolation of the recycling endosomes confirmed that they recruit autophagy proteins. Finally, fixed and live-cell imaging data revealed that recycling endosomes engulf autophagic substrates. Indeed, the sequestration of mitochondria after mitophagy stimulation depends on early autophagy regulators. These data suggest that autophagosomes evolve from the RAB11A compartment.     

Central role of mitofusin 2 in autophagosome-lysosome fusion in cardiomyocytes

In the heart, autophagy has been implicated in cardioprotection and ischemia-reperfusion tolerance, and the dysregulation of autophagy is associated with the development of heart failure. Mitochondrial dynamic proteins are profoundly involved in autophagic processes, especially the initiation and formation of autophagosomes, but it is not clear whether they play any role in cardiac autophagy. We previously reported that mitofusin 2 (MFN2), a mitochondrial outer membrane protein, serves as a major determinant of cardiomyocyte apoptosis mediated by oxidative stress. Here, we reveal a novel and essential role of MFN2 in mediating cardiac autophagy. We found that specific deletion of MFN2 in cardiomyocytes caused extensive accumulation of autophagosomes. In particular, the fusion of autophagosomes with lysosomes, a critical step in autophagic degradation, was markedly retarded without altering the formation of autophagosomes and lysosomes in response to ischemia-reperfusion stress. Importantly, MFN2 co-immunoprecipitated with RAB7 in the heart, and starvation further increased it. Knockdown of MFN2 by shRNA prevented, whereas re-expression of MFN2 restored, the autophagosome-lysosome fusion in neonatal cardiomyocytes. Hearts from cardiac-specific MFN2 knock-out mice had abnormal mitochondrial and cellular metabolism and were vulnerable to ischemia-reperfusion challenge. Our study defined a novel and essential role of MFN2 in the cardiac autophagic process by mediating the maturation of autophagy at the phase of autophagosome-lysosome fusion; deficiency of MFN2 caused multiple molecular and functional defects that undermined cardiac reserve and gradually led to cardiac vulnerability and dysfunction.     

Alterations of autophagy in the peripheral neuropathy Charcot-Marie-Tooth type 2B

Charcot-Marie-Tooth type 2B (CMT2B) disease is a dominant axonal peripheral neuropathy caused by 5 mutations in the RAB7A gene, a ubiquitously expressed GTPase controlling late endocytic trafficking. In neurons, RAB7A also controls neuronal-specific processes such as NTF (neurotrophin) trafficking and signaling, neurite outgrowth and neuronal migration. Given the involvement of macroautophagy/autophagy in several neurodegenerative diseases and considering that RAB7A is fundamental for autophagosome maturation, we investigated whether CMT2B-causing mutants affect the ability of this gene to regulate autophagy. In HeLa cells, we observed a reduced localization of all CMT2B-causing RAB7A mutants on autophagic compartments. Furthermore, compared to expression of RAB7A^WT, expression of these mutants caused a reduced autophagic flux, similar to what happens in cells expressing the dominant negative RAB7A^T22N mutant. Consistently, both basal and starvation-induced autophagy were strongly inhibited in skin fibroblasts from a CMT2B patient carrying the RAB7A^V162M mutation, suggesting that alteration of the autophagic flux could be responsible for neurodegeneration.     

TRIM-mediated precision autophagy targets cytoplasmic regulators of innate immunity

The present paradigms of selective autophagy in mammalian cells cannot fully explain the specificity and selectivity of autophagic degradation. In this paper, we report that a subset of tripartite motif (TRIM) proteins act as specialized receptors for highly specific autophagy (precision autophagy) of key components of the inflammasome and type I interferon response systems. TRIM20 targets the inflammasome components, including NLRP3, NLRP1, and pro–caspase 1, for autophagic degradation, whereas TRIM21 targets IRF3. TRIM20 and TRIM21 directly bind their respective cargo and recruit autophagic machinery to execute degradation. The autophagic function of TRIM20 is affected by mutations associated with familial Mediterranean fever. These findings broaden the concept of TRIMs acting as autophagic receptor regulators executing precision autophagy of specific cytoplasmic targets. In the case of TRIM20 and TRIM21, precision autophagy controls the hub signaling machineries and key factors, inflammasome and type I interferon, directing cardinal innate immunity response systems in humans.     

The integration of autophagy and cellular trafficking pathways via RAB GAPs

Macroautophagy is a conserved degradative pathway in which a double-membrane compartment sequesters cytoplasmic cargo and delivers the contents to lysosomes for degradation. Efficient formation and maturation of autophagic vesicles, so-called phagophores that are precursors to autophagosomes, and their subsequent trafficking to lysosomes relies on the activity of small RAB GTPases, which are essential factors of cellular vesicle transport systems. The activity of RAB GTPases is coordinated by upstream factors, which include guanine nucleotide exchange factors (RAB GEFs) and RAB GTPase activating proteins (RAB GAPs). A role in macroautophagy regulation for different TRE2-BUB2-CDC16 (TBC) domain-containing RAB GAPs has been established. Recently, however, a positive modulation of macroautophagy has also been demonstrated for the TBC domain-free RAB3GAP1/2, adding to the family of RAB GAPs that coordinate macroautophagy and additional cellular trafficking pathways.     

Live-cell imaging of Aspergillus nidulans autophagy

We exploited the amenability of the fungus Aspergillus nidulans to genetics and live-cell microscopy to investigate autophagy. Upon nitrogen starvation, GFP-Atg8-containing pre-autophagosomal puncta give rise to cup-shaped phagophores and circular (0.9-μm diameter) autophagosomes that disappear in the vicinity of the vacuoles after their shape becomes irregular and their GFP-Atg8 fluorescence decays. This ‘autophagosome cycle’ gives rise to characteristic cone-shaped traces in kymographs. Autophagy does not require endosome maturation or ESCRTs, as autophagosomes fuse with vacuoles directly in a RabS (homolog of Saccharomyces cerevisiae Ypt7 and mammalian RAB7; written hereafter as RabS^RAB7)-HOPS-(homotypic fusion and vacuole protein sorting complex)-dependent manner. However, by removing RabS^RAB7 or Vps41 (a component of the HOPS complex), we show that autophagosomes may still fuse, albeit inefficiently, with the endovacuolar system in a process almost certainly mediated by RabA^RAB5/RabB^RAB5 (yeast Vps21 homologs)-CORVET (class C core vacuole/endosome tethering complex), because acute inactivation of HbrA/Vps33, a key component of HOPS and CORVET, completely precludes access of GFP-Atg8 to vacuoles without affecting autophagosome biogenesis. Using a FYVE₂-GFP probe and endosomal PtdIns3P-depleted cells, we imaged PtdIns3P on autophagic membranes. PtdIns3P present on autophagosomes decays at late stages of the cycle, preceding fusion with the vacuole. Autophagy does not require Golgi traffic, but it is crucially dependent on RabO^RAB1. TRAPPIII-specific factor AN7311 (yeast Trs85) localizes to the phagophore assembly site (PAS) and RabO^RAB1 localizes to phagophores and autophagosomes. The Golgi and autophagy roles of RabO^RAB1 are dissociable by mutation: rabO^A136D hyphae show relatively normal secretion at 28°C but are completely blocked in autophagy. This finding and the lack of Golgi traffic involvement pointed to the ER as one potential source of membranes for autophagy. In agreement, autophagosomes form in close association with ring-shaped omegasome-like ER structures resembling those described in mammalian cells.     

Starvation‐induced MTMR13 and RAB21 activity regulates VAMP8 to promote autophagosome–lysosome fusion

Autophagy, the process for recycling cytoplasm in the lysosome, depends on membrane trafficking. We previously identified Drosophila Sbf as a Rab21 guanine nucleotide exchange factor (GEF) that acts with Rab21 in endosomal trafficking. Here, we show that Sbf/MTMR13 and Rab21 have conserved functions required for starvation‐induced autophagy. Depletion of Sbf/MTMR13 or Rab21 blocked endolysosomal trafficking of VAMP8, a SNARE required for autophagosome–lysosome fusion. We show that starvation induces Sbf/MTMR13 GEF and RAB21 activity, as well as their induced binding to VAMP8 (or closest Drosophila homolog, Vamp7). MTMR13 is required for RAB21 activation, VAMP8 interaction and VAMP8 endolysosomal trafficking, defining a novel GEF‐Rab‐effector pathway. These results identify starvation‐responsive endosomal regulators and trafficking that tunes membrane demands with changing autophagy status.     

ZFYVE26/SPASTIZIN and SPG11/SPATACSIN mutations in hereditary spastic paraplegia types AR-SPG15 and AR-SPG11 have different effects on autophagy and endocytosis

ZFYVE26/Spastizin and SPG11/Spatacsin encode 2 large proteins that are mutated in hereditary autosomal-recessive spastic paraplegia/paraparesis (HSP) type 15 (AR-SPG15) and type 11 (AR-SPG11), respectively. We previously have reported that AR-SPG15-related ZFYVE26 mutations lead to autophagy defects with accumulation of immature autophagosomes. ZFYVE26 and SPG11 were found to be part of a complex including the AP5 (adaptor related protein complex 5) and to have a critical role in autophagic lysosomal reformation with identification of autophagic and lysosomal defects in cells with both AR-SPG15- and AR-SPG11-related mutations. In spite of these similarities between the 2 proteins, here we report that ZFYVE26 and SPG11 are differently involved in autophagy and endocytosis. We found that both ZFYVE26 and SPG11 interact with RAB5A and RAB11, 2 proteins regulating endosome trafficking and maturation, but only ZFYVE26 mutations affected RAB protein interactions and activation. ZFYVE26 mutations lead to defects in the fusion between autophagosomes and endosomes, while SPG11 mutations do not affect this step and lead to a milder autophagy defect. We thus demonstrate that ZFYVE26 and SPG11 affect the same cellular physiological processes, albeit at different levels: both proteins have a role in autophagic lysosome reformation, but only ZFYVE26 acts at the intersection between endocytosis and autophagy, thus representing a key player in these 2 processes. Indeed expression of the constitutively active form of RAB5A in cells with AR-SPG15-related mutations partially rescues the autophagy defect. Finally the model we propose demonstrates that autophagy and the endolysosomal pathway are central processes in the pathogenesis of these complicated forms of hereditary spastic paraparesis.

Abbreviations: ALR, autophagic lysosome reformation; AP5, adaptor related protein complex 5; AR, autosomal-recessive; HSP, hereditary spastic paraplegia/paraparesis; ATG14, autophagy related 14; BafA, bafilomycin A₁; BECN1, beclin 1; EBSS, Earle balanced salt solution; EEA1, early endosome antigen 1; EGF, epidermal growth factor; EGFR, epidermal growth factor receptor; GDP, guanosine diphosphate; GFP, green fluorescent protein; GTP, guanosine triphosphate; HSP, hereditary spastic paraplegias; LBPA, lysobisphosphatidic acid; MAP1LC3B/LC3B, microtubule associated protein 1 light chain 3 beta; MVBs, multivesicular bodies; PIK3C3, phosphatidylinositol 3-kinase, catalytic subunit type 3; PIK3R4, phosphoinositide-3-kinase regulatory subunit 4; PtdIns3P, phosphatidylinositol-3-phosphate; RFP, red fluorescent protein; RUBCN, RUN and cysteine rich domain containing beclin 1 interacting protein; shRNA, short hairpin RNA; SQSTM1/p62, sequestosome 1; TCC: thin corpus callosum; TF, transferrin; UVRAG, UV radiation resistance associated.     

The Autophagic and Endocytic Pathways Converge at the Nascent Autophagic Vacuoles

We used an improved cryosectioning technique in combination with immunogold cytochemistry and morphometric analysis to study the convergence of the autophagic and endocytic pathways in isolated rat hepatocytes. The endocytic pathway was traced by continuous uptake of gold tracer for various time periods, up to 45 min, while the cells were incubated in serum-free medium to induce autophagy. Endocytic structures involved in fusion with autophagic vacuoles (AV) were categorized into multivesicular endosomes (MVE) and vesicular endosomes (VE). Three types of AV—initial (AVi), intermediate (AVi/d), and degradative (AVd)—were defined by morphological criteria and immunogold labeling characteristics of marker enzymes.

The entry of tracer into AV, manifested as either tracer-containing AV profiles (AV⁺) or fusion profiles (FP⁺) between AV and tracer-positive endosomal vesicles/vacuoles, was detected as early as 10 min after endocytosis. The number of AV⁺ exhibited an exponential increase with time. FP⁺ between MVE or VE and all three types of AV were observed. Among the 112 FP⁺ scored, 36% involved VE. Of the AV types, AVi and AVi/d were found five to six times more likely to be involved in fusions than AVd. These fusion patterns did not significantly change during the period of endocytosis (15–45 min). We conclude that the autophagic and endocytic pathways converge in a multistage fashion starting within 10 min of endocytosis. The nascent AV is the most upstream and preferred fusion partner for endosomes.

     

Therapeutic strategies targeting AMPK-dependent autophagy in cancer cells

Macroautophagy is a health-modifying process of engulfing misfolded or aggregated proteins or damaged organelles, coating these proteins or organelles into vesicles, fusion of vesicles with lysosomes to form autophagic lysosomes, and degradation of the encapsulated contents. It is also a self-rescue strategy in response to harsh environments and plays an essential role in cancer cells. AMP-activated protein kinase (AMPK) is the central pathway that regulates autophagy initiation and autophagosome formation by phosphorylating targets such as mTORC1 and unc-51 like activating kinase 1 (ULK1). AMPK is an evolutionarily conserved serine/threonine protein kinase that acts as an energy sensor in cells and regulates various metabolic processes, including those involved in cancer. The regulatory network of AMPK is complicated and can be regulated by multiple upstream factors, such as LKB1, AKT, PPAR, SIRT1, or noncoding RNAs. Currently, AMPK is being investigated as a novel target for anticancer therapies based on its role in macroautophagy regulation. Herein, we review the effects of AMPK-dependent autophagy on tumor cell survival and treatment strategies targeting AMPK.     

PLEKHM1: Adapting to life at the lysosome

The endosomal system and autophagy are 2 intertwined pathways that share a number of common protein factors as well as a final destination, the lysosome. Identification of adaptor platforms that can link both pathways are of particular importance, as they serve as common nodes that can coordinate the different trafficking arms of the endolysosomal system. Using a mass spectrometry approach to identify interaction partners of active (GTP-bound) RAB7, the late endosome/lysosome GTPase, and yeast 2-hybrid screening to identify LC3/GABARAP interaction partners we discovered the multivalent adaptor protein PLEKHM1. We discovered a highly conserved LC3-interaction region (LIR) between 2 PH domains of PLEKHM1 that mediated direct binding to all LC3/GABARAP family members. Subsequent mass spectrometry analysis of PLEKHM1 precipitated from cells revealed the HOPS (homotypic fusion and protein sorting) complex as a prominent interaction partner. Functionally, depletion of PLEKHM1, HOPS, or RAB7 results in decreased autophagosome-lysosome fusion. In Plekhm1 knockout (KO) mouse embryonic fibroblasts (MEFs) we observed increased lipidated LC3B, decreased colocalization between LC3B and LAMP1 under amino acid starvation conditions and decreased autolysosome formation. Finally, PLEKHM1 binding to LC3-positive autophagosomes was also essential for selective autophagy pathways, as shown by clearance of puromycin-aggregates, in a PLEKHM1-LIR-dependent manner. Overall, we have identified PLEKHM1 as an endolysosomal adaptor platform that acts as a central hub to integrate endocytic and autophagic pathways at the lysosome.PLEKHM1 (pleckstrin homology domain containing, family M [with RUN domain] member 1) is a ubiquitously expressed protein involved in the regulation of osteoclast function and bone resorption. Recently, it was also described in the context of negatively regulating the endocytic pathway but not autophagy. However, in our recent studies, we show that PLEKHM1 positively regulates the terminal stages of both endocytic and autophagy pathways through direct interaction between PLEKHM1, RAB7, the HOPS complex, and mammalian Atg8 proteins (Fig. 1A). In addition, the PLEKHM1-RAB7-HOPS complex is a direct target for the Salmonella (Salmonella enterica Typhimurium) effector protein SifA (Salmonella-induced filament protein A) that together regulate the Salmonella-containing vacuole (Fig. 1B). Open in a separate windowFigure 1.Model of PLEKHM1 function in the endocytic and autophagic pathways. (A) Domain structure of PLEKHM1 and their interactions. RUN (RUNDC3A/RPIP8, UNC-14 and RUSC1/NESCA); PH1 and PH2 (Pleckstrin homology domain 1 and 2); C1/Zinc finger (C1); HOPS (homotypic fusion and protein sorting). (B) Proposed positioning of PLEKHM1 and its associated complexes in the autophagy and endocytic pathway. PLEKHM1 localizes to late endosomes and lysosomes in an RAB7-dependent manner. The interaction between PLEKHM1, RAB7, and HOPS on vesicles positions these vesicles for tethering and fusion with autophagosomes, through direct interaction with MAP1LC3/GABARAP proteins. The autophagosomes may also fuse with late endosomes/MVBs (multivesicular bodies) in a PLEKHM1-RAB7-HOPS-dependent manner to produce amphisomes, prior to fusion with the lysosome. PLEKHM1-RAB7-HOPS can also be subverted by the Salmonella effector SifA, for the proper maintenance of the Salmonella-containing vacuole (SCV) and Sif (Salmonella-induced filament) formation. mAtg8s, MAP1LC3/GABARAP proteins.Using a 2-pronged approach, we identified PLEKHM1 as an interaction partner of RAB7 in its GTP-bound active state, RAB7(GTP), and MAP1LC3/GABARAP proteins. PLEKHM1 interacts directly with all MAP1LC3/GABARAP proteins through a highly conserved LC3-interaction motif (LIR) located between the Pleckstrin homology domain 1 (PH1) and PH2 domains of PLEKHM1 (Fig. 1A). Endogenous PLEKHM1 colocalizes with LAMP1 at the cytosolic-facing membrane, but not the lumenal side, of LC3B-containing amphisomes/autolysosomes, indicating that PLEKHM1 is an autophagy adaptor protein rather than a selective cargo receptor.Using SILAC (stable isotope labeling of cells in culture)-labeled inducible PLEKHM1 cells, we identified the HOPS complex as a significant interaction partner. The hexameric HOPS complex is an essential component of the late endocytic fusion machinery and is required for autolysosome formation. PLEKHM1 interacts directly with the HOPS complex, mediated by the RUN domain of PLEKHM1 and the C terminus of VPS39 (Fig. 1A) Crucially, PLEKHM1 forms an endogenous complex with HOPS. In the context of vesicle fusion, the HOPS complex acts as a tether to anchor and position the vesicles prior to fusion that is driven by SNARE proteins. Multiple SNARE proteins, such as VAMP7, VAMP8, VTI1B, SNAP29, and STX17 have been described to be required for autophagosome-lysosome fusion. Upon autophagy induction, enhanced PLEKHM1 coprecipitation is detected with the HOPS complex and the autophagosome specific SNARE STX17, reinforcing a role for PLEKHM1 in autophagosome-lysosome fusion.Both RAB7 and the HOPS complex are integral components of the endocytic pathway and, as such, we wanted to test the effect of PLEKHM1 loss on EGFR (epidermal growth factor receptor) degradation. We used 2 epithelial cell lines, HeLa and Hke3. In both instances, loss of PLEKHM1 causes a marked decrease in the rate of EGFR degradation and increases retention in early endosomes. This is in stark contrast to previous reports that used A549 cells and showed that a lack of PLEKHM1 accelerates EGFR degradation. Clearly, cell lines and their background mutations will have to be considered for future studies.In addition to the endocytic pathway, RAB7 and the HOPS complex are essential for the autophagosome-to-autolysosome transition. Therefore, we also wanted to explore this facet of PLEKHM1 function. We generated Plekhm1 KO MEFs to analyze the effects of autophagy flux in the absence of PLEKHM1. Plekhm1 KO MEFs show a block in autophagy, with the accumulation of SQSTM1/p62 and LC3B-II and, using tandem-fluorescence-LC3B as a marker, a decrease in autolysosome formation. Taken together, these findings suggest that PLEKHM1 functions at the point of autophagosome-lysosome fusion (Fig. 1B).Finally, we were interested in testing the functional role of PLEKHM1, and in particular the LIR, during selective autophagy of protein aggregates. We treated control and PLEKHM1-depleted cells with puromycin and observed aggregate clearance over time after puromycin removal. Cells lacking PLEKHM1 and those reconstituted with a PLEKHM1-LIR mutant were unable to efficiently remove SQSTM1-ubiquitin-positive aggregates, compared to control or PLEKHM1-wild type reconstituted cells, indicating an important role for the final stages of endosome and autophagosome maturation (Fig. 1B).“No man is an island, entire of itself” seems of particular prudence when considering the intertwined nature of both autophagic and endocytic pathways. Indeed, it is interesting that there are multiple RAB7 effector proteins functioning at the late endocytic step that also contribute to autophagy, including FYCO1, KIAA0226/Rubicon, UVRAG and now PLEKHM1, where only PLEKHM1 and UVRAG have been shown to interact with the HOPS complex. All of which, when mutated or depleted, have effects on both the endocytic and autophagic pathways. Clearly the roles of these proteins in cell-type and tissue-specific settings have to be determined before we fully comprehend the complexities of how the endosomal and autophagic pathways integrate and communicate with each other.     

To die or not to die: that is the autophagic question

Macroautophagy (commonly referred to as autophagy) is the process by which intact organelles and/or large portions of the cytoplasm are engulfed within double-membraned autophagic vacuoles for degradation. Whereas basal levels of autophagy ensure the physiological turnover of old and damaged organelles, the massive accumulation of autophagic vacuoles may represent either an alternative pathway of cell death or an ultimate attempt for cells to survive by adapting to stress. The activation of the autophagic pathway beyond a certain threshold may promote cell death directly, by causing the collapse of cellular functions as a result of cellular atrophy (autophagic, or type II, cell death). Alternatively, autophagy can lead to the execution of apoptotic (type I) or necrotic (type III) cell death programs, presumably via common regulators such as proteins from the Bcl-2 family. On the other hand, limited self-eating can provide cells with metabolic substrates to meet their energetic demands under stressful conditions, such as nutrient deprivation, or favor the selective elimination of damaged (and potentially dangerous) organelles. In these instances, autophagy operates as a pro-survival mechanism. The coordinate regulation of these opposite effects of autophagy relies upon a complex network of signal transducers, most of which also participate in non-autophagic signaling cascades. Thus, autophagy occupies a crucial position within the cell's metabolism, and its modulation may represent an alternative therapeutic strategy in several pathological settings including cancer and neurodegeneration. Here, we present a general outline of autophagy followed by a detailed analysis of organelle-specific autophagic pathways and of their intimate connections with cell death.