JoVE Visualize What is visualize?
Stop Reading. Start Watching.
Advanced Search
Stop Reading. Start Watching.
Regular Search
Find video protocols related to scientific articles indexed in Pubmed.
WIPI2b and Atg16L1: setting the stage for autophagosome formation.
Biochem. Soc. Trans.
PUBLISHED: 09-19-2014
Show Abstract
Hide Abstract
The double-membraned autophagosome organelle is an integral part of autophagy, a process that recycles cellular components by non-selectively engulfing and delivering them to lysosomes where they are digested. Release of metabolites from this process is involved in cellular energy homoeostasis under basal conditions and during nutrient starvation. Selective engulfment of protein aggregates and dysfunctional organelles by autophagosomes also prevents disruption of cellular metabolism. Autophagosome formation in animals is crucially dependent on the unique conjugation of a group of ubiquitin-like proteins in the microtubule-associated proteins 1A/1B light chain 3 (LC3) family to the headgroup of phosphatidylethanolamine (PE) lipids. LC3 lipidation requires a cascade of ubiquitin-like ligase and conjugation enzymes. The present review describes recent progress and discovery of the direct interaction between the PtdIns3P effector WIPI2b and autophagy-related protein 16-like 1 (Atg16L1), a component of the LC3-conjugation complex. This interaction makes the link between endoplasmic reticulum (ER)-localized production of PtdIns3P, triggered by the autophagy regulatory network, and recruitment of the LC3-conjugation complex crucial for autophagosome formation.
Related JoVE Video
Endocytosis and autophagy: exploitation or cooperation?
Cold Spring Harb Perspect Biol
PUBLISHED: 05-03-2014
Show Abstract
Hide Abstract
Autophagy is a lysosome-mediated degradative system that is a highly conserved pathway present in all eukaryotes. In all cells, double-membrane autophagosomes form and engulf cytoplasmic components, delivering them to the lysosome for degradation. Autophagy is essential for cell health and can be activated to function as a recycling pathway in the absence of nutrients or as a quality-control pathway to eliminate damaged organelles or even to eliminate invading pathogens. Autophagy was first identified as a pathway in mammalian cells using morphological techniques, but the Atg (autophagy-related) genes required for autophagy were identified in yeast genetic screens. Despite tremendous advances in elucidating the function of individual Atg proteins, our knowledge of how autophagosomes form and subsequently interact with the endosomal pathway has lagged behind. Recent progress toward understanding where and how both the endocytotic and autophagic pathways overlap is reviewed here.
Related JoVE Video
WIPI2 links LC3 conjugation with PI3P, autophagosome formation, and pathogen clearance by recruiting Atg12-5-16L1.
Mol. Cell
PUBLISHED: 01-29-2014
Show Abstract
Hide Abstract
Mammalian cell homeostasis during starvation depends on initiation of autophagy by endoplasmic reticulum-localized phosphatidylinositol 3-phosphate (PtdIns(3)P) synthesis. Formation of double-membrane autophagosomes that engulf cytosolic components requires the LC3-conjugating Atg12-5-16L1 complex. The molecular mechanisms of Atg12-5-16L1 recruitment and significance of PtdIns(3)P synthesis at autophagosome formation sites are unknown. By identifying interacting partners of WIPIs, WD-repeat PtdIns(3)P effector proteins, we found that Atg16L1 directly binds WIPI2b. Mutation experiments and ectopic localization of WIPI2b to plasma membrane show that WIPI2b is a PtdIns(3)P effector upstream of Atg16L1 and is required for LC3 conjugation and starvation-induced autophagy through recruitment of the Atg12-5-16L1 complex. Atg16L1 mutants, which do not bind WIPI2b but bind FIP200, cannot rescue starvation-induced autophagy in Atg16L1-deficient MEFs. WIPI2b is also required for autophagic clearance of pathogenic bacteria. WIPI2b binds the membrane surrounding Salmonella and recruits the Atg12-5-16L1 complex, initiating LC3 conjugation, autophagosomal membrane formation, and engulfment of Salmonella.
Related JoVE Video
p38 signaling inhibits mTORC1-independent autophagy in senescent human CD8? T cells.
J. Clin. Invest.
PUBLISHED: 01-06-2014
Show Abstract
Hide Abstract
T cell senescence is thought to contribute to immune function decline, but the pathways that mediate senescence in these cells are not clear. Here, we evaluated T cell populations from healthy volunteers and determined that human CD8+ effector memory T cells that reexpress the naive T cell marker CD45RA have many characteristics of cellular senescence, including decreased proliferation, defective mitochondrial function, and elevated levels of both ROS and p38 MAPK. Despite their apparent senescent state, we determined that these cells secreted high levels of both TNF-? and IFN-? and showed potent cytotoxic activity. We found that the senescent CD45RA-expressing population engaged anaerobic glycolysis to generate energy for effector functions. Furthermore, inhibition of p38 MAPK signaling in senescent CD8+ T cells increased their proliferation, telomerase activity, mitochondrial biogenesis, and fitness; however, the extra energy required for these processes did not arise from increased glucose uptake or oxidative phosphorylation. Instead, p38 MAPK blockade in these senescent cells induced an increase in autophagy through enhanced interactions between p38 interacting protein (p38IP) and autophagy protein 9 (ATG9) in an mTOR-independent manner. Together, our findings describe fundamental metabolic requirements of senescent primary human CD8+ T cells and demonstrate that p38 MAPK blockade reverses senescence via an mTOR-independent pathway.
Related JoVE Video
HRES-1/Rab4 promotes the formation of LC3(+) autophagosomes and the accumulation of mitochondria during autophagy.
PLoS ONE
PUBLISHED: 01-01-2014
Show Abstract
Hide Abstract
HRES-1/Rab4 is a small GTPase that regulates endocytic recycling. It has been colocalized to mitochondria and the mechanistic target of rapamycin (mTOR), a suppressor of autophagy. Since the autophagosomal membrane component microtubule-associated protein light chain 3 (LC3) is derived from mitochondria, we investigated the impact of HRES-1/Rab4 on the formation of LC3(+) autophagosomes, their colocalization with HRES-1/Rab4 and mitochondria, and the retention of mitochondria during autophagy induced by starvation and rapamycin. HRES-1/Rab4 exhibited minimal baseline colocalization with LC3, which was enhanced 22-fold upon starvation or 6-fold upon rapamycin treatment. Colocalization of HRES-1/Rab4 with mitochondria was increased >2-fold by starvation or rapamycin. HRES-1/Rab4 overexpression promoted the colocalization of mitochondria with LC3 upon starvation or rapamycin treatment. A dominant-negative mutant, HRES-1/Rab4(S27N) had reduced colocalization with LC3 and mitochondria upon starvation but not rapamycin treatment. A constitutively active mutant, HRES-1/Rab4(Q72L) showed diminished colocalization with LC3 but promoted the partitioning of mitochondria with LC3 upon starvation or rapamycin treatment. Phosphorylation-resistant mutant HRES-1/Rab4(S204Q) showed diminished colocalization with LC3 but increased partitioning to mitochondria. A newly discovered C-terminally truncated native isoform, HRES-1/Rab4(1-121), showed enhanced localization to LC3 and mitochondria without starvation or rapamycin treatment. HRES-1/Rab4(1-121) increased the formation of LC3(+) autophagosomes in resting cells, while other isoforms promoted autophagosome formation upon starvation. HRES-1/Rab4, HRES-1/Rab4(1-121), HRES-1/Rab4(Q72L) and HRES-1/Rab4(S204Q) promoted the accumulation of mitochondria during starvation. The specificity of HRES-1/Rab4-mediated mitochondrial accumulation is indicated by its abrogation by dominant-negative HRES-1/Rab4(S27N) mutation. The formation of interconnected mitochondrial tubular networks was markedly enhanced by HRES-1/Rab4(Q72L) upon starvation, which may contribute to the retention of mitochondria during autophagy. The present study thus indicates that HRES-1/Rab4 regulates autophagy through promoting the formation of LC3(+) autophagosomes and the preservation of mitochondria.
Related JoVE Video
The autophagosome: origins unknown, biogenesis complex.
Nat. Rev. Mol. Cell Biol.
PUBLISHED: 11-09-2013
Show Abstract
Hide Abstract
Healthy cells use autophagy as a general housekeeping mechanism and to survive stress, including stress induced by nutrient deprivation. Autophagy is initiated at the isolation membrane (originally termed the phagophore), and the coordinated action of ATG (autophagy-related) proteins results in the expansion of this membrane to form the autophagosome. Although the biogenesis of the isolation membrane and the autophagosome is complex and incompletely understood, insight has been gained into the molecular processes involved in initiating the isolation membrane, the source from which this originates (for example, it was recently proposed that the isolation membrane forms from the mitochondria-associated endoplasmic reticulum (ER) membrane (MAM)) and the role of ATG proteins and the vesicular trafficking machinery in autophagosome formation.
Related JoVE Video
Pathogenic Parkinsons disease mutations across the functional domains of LRRK2 alter the autophagic/lysosomal response to starvation.
Biochem. Biophys. Res. Commun.
PUBLISHED: 10-10-2013
Show Abstract
Hide Abstract
LRRK2 is one of the most important genetic contributors to Parkinsons disease (PD). Point mutations in this gene cause an autosomal dominant form of PD, but to date no cellular phenotype has been consistently linked with mutations in each of the functional domains (ROC, COR and Kinase) of the protein product of this gene. In this study, primary fibroblasts from individuals carrying pathogenic mutations in the three central domains of LRRK2 were assessed for alterations in the autophagy/lysosomal pathway using a combination of biochemical and cellular approaches. Mutations in all three domains resulted in alterations in markers for autophagy/lysosomal function compared to wild type cells. These data highlight the autophagy and lysosomal pathways as read outs for pathogenic LRRK2 function and as a marker for disease, and provide insight into the mechanisms linking LRRK2 function and mutations.
Related JoVE Video
Current views on the source of the autophagosome membrane.
Essays Biochem.
PUBLISHED: 09-28-2013
Show Abstract
Hide Abstract
Autophagy was discovered in the late 1950s when scientists using the first electron microscopes saw membrane-bound structures in cells that contained cytoplasmic organelles, including mitochondria. Pursuant to further morphological characterization it was recognized that these vesicles, now called autophagosomes, are found in all eukaryotic cells and undergo changes in morphology from a double-membraned vesicle with recognizable content, i.e. sequestered organelles, to a uniformly dense core autolysosome. Genetic screens in the yeast Saccharomyces cerevisiae in the 1990s provided a molecule framework for the next era of discovery during which the interest in, and research into, autophagy has rapidly expanded into many areas of human biology and disease. A relatively small cohort of approximately 36 proteins, called Atgs (autophagy-related proteins), orchestrate the formation of the autophagosome, and these are now being studied and functionally characterized. Although the function of these proteins is being elucidated, the underlying molecular mechanisms of how autophagosomes form are still not completely understood. Recent advances have, however, provided a significant advance in both our understanding of the molecular control of the Atg proteins and the source of the membranes. A consensus view is emerging from these advances that the endoplasmic reticulum is the nucleation site for the autophagosome, and that contributions from other compartments (Golgi, endosomes and plasma membrane) are required. In the present chapter, I review the data from the pre-molecular decades, and discuss the most recent publications to give an overview of the current view of where, and how, autophagosomes form in mammalian cells.
Related JoVE Video
Listeria phospholipases subvert host autophagic defenses by stalling pre-autophagosomal structures.
EMBO J.
PUBLISHED: 08-22-2013
Show Abstract
Hide Abstract
Listeria can escape host autophagy defense pathways through mechanisms that remain poorly understood. We show here that in epithelial cells, Listeriolysin (LLO)-dependent cytosolic escape of Listeria triggered a transient amino-acid starvation host response characterized by GCN2 phosphorylation, ATF3 induction and mTOR inhibition, the latter favouring a pro-autophagic cellular environment. Surprisingly, rapid recovery of mTOR signalling was neither sufficient nor necessary for Listeria avoidance of autophagic targeting. Instead, we observed that Listeria phospholipases PlcA and PlcB reduced autophagic flux and phosphatidylinositol 3-phosphate (PI3P) levels, causing pre-autophagosomal structure stalling and preventing efficient targeting of cytosolic bacteria. In co-infection experiments, wild-type Listeria protected PlcA/B-deficient bacteria from autophagy-mediated clearance. Thus, our results uncover a critical role for Listeria phospholipases C in the inhibition of autophagic flux, favouring bacterial escape from host autophagic defense.
Related JoVE Video
Imaging endosomes and autophagosomes in whole mammalian cells using correlative cryo-fluorescence and cryo-soft X-ray microscopy (cryo-CLXM).
Ultramicroscopy
PUBLISHED: 06-28-2013
Show Abstract
Hide Abstract
Cryo-soft X-ray tomography (cryo-SXT) is a powerful imaging technique that can extract ultrastructural information from whole, unstained mammalian cells as close to the living state as possible. Subcellular organelles including the nucleus, the Golgi apparatus and mitochondria have been identified by morphology alone, due to the similarity in contrast to transmission electron micrographs. In this study, we used cryo-SXT to image endosomes and autophagosomes, organelles that are particularly susceptible to chemical fixation artefacts during sample preparation for electron microscopy. We used two approaches to identify these compartments. For early and recycling endosomes, which are accessible to externally-loaded markers, we used an anti-transferrin receptor antibody conjugated to 10nm gold particles. For autophagosomes, which are not accessible to externally-applied markers, we developed a correlative cryo-fluorescence and cryo-SXT workflow (cryo-CLXM) to localise GFP-LC3 and RFP-Atg9. We used a stand-alone cryo-fluorescence stage in the home laboratory to localise the cloned fluorophores, followed by cryo-soft X-ray tomography at the synchrotron to analyse cellular ultrastructure. We mapped the 3D ultrastructure of the endocytic and autophagic structures, and discovered clusters of omegasomes arising from hotspots on the ER. Thus, immunogold markers and cryo-CLXM can be used to analyse cellular processes that are inaccessible using other imaging modalities.
Related JoVE Video
Autophagosome formation--the role of ULK1 and Beclin1-PI3KC3 complexes in setting the stage.
Semin. Cancer Biol.
PUBLISHED: 03-27-2013
Show Abstract
Hide Abstract
Autophagy is a conserved and highly regulated degradative membrane trafficking pathway, maintaining energy homeostasis and protein synthesis during nutrient stress. Our understanding of how the autophagy machinery is regulated has expanded greatly over recent years. The ULK and Beclin1-PI3KC3 complexes are key signaling complexes required for autophagosome formation. The nutrient and energy sensors mTORC1 and AMPK signal directly to the ULK complex and affect its activity. Formation and activation of distinct Beclin1-PI3KC3 complexes produces PI3P, a signaling lipid required for the recruitment of autophagy effectors. In this review we discuss how the mammalian ULK1 and Beclin1 complexes are controlled by post-translational modifications and protein-protein interactions and we highlight data linking these complexes together.
Related JoVE Video
Identification of a candidate therapeutic autophagy-inducing peptide.
Nature
PUBLISHED: 01-30-2013
Show Abstract
Hide Abstract
The lysosomal degradation pathway of autophagy has a crucial role in defence against infection, neurodegenerative disorders, cancer and ageing. Accordingly, agents that induce autophagy may have broad therapeutic applications. One approach to developing such agents is to exploit autophagy manipulation strategies used by microbial virulence factors. Here we show that a peptide, Tat-beclin 1-derived from a region of the autophagy protein, beclin 1, which binds human immunodeficiency virus (HIV)-1 Nef-is a potent inducer of autophagy, and interacts with a newly identified negative regulator of autophagy, GAPR-1 (also called GLIPR2). Tat-beclin 1 decreases the accumulation of polyglutamine expansion protein aggregates and the replication of several pathogens (including HIV-1) in vitro, and reduces mortality in mice infected with chikungunya or West Nile virus. Thus, through the characterization of a domain of beclin 1 that interacts with HIV-1 Nef, we have developed an autophagy-inducing peptide that has potential efficacy in the treatment of human diseases.
Related JoVE Video
Rab3D is critical for secretory granule maturation in PC12 cells.
PLoS ONE
PUBLISHED: 01-21-2013
Show Abstract
Hide Abstract
Neuropeptide- and hormone-containing secretory granules (SGs) are synthesized at the trans-Golgi network (TGN) as immature secretory granules (ISGs) and complete their maturation in the F-actin-rich cell cortex. This maturation process is characterized by acidification-dependent processing of cargo proteins, condensation of the SG matrix and removal of membrane and proteins not destined to mature secretory granules (MSGs). Here we addressed a potential role of Rab3 isoforms in these maturation steps by expressing their nucleotide-binding deficient mutants in PC12 cells. Our data show that the presence of Rab3D(N135I) decreases the restriction of maturing SGs to the F-actin-rich cell cortex, blocks the removal of the endoprotease furin from SGs and impedes the processing of the luminal SG protein secretogranin II. This strongly suggests that Rab3D is implicated in the subcellular localization and maturation of ISGs.
Related JoVE Video
Inhibition of LRRK2 kinase activity stimulates macroautophagy.
Biochim. Biophys. Acta
PUBLISHED: 01-14-2013
Show Abstract
Hide Abstract
Leucine Rich Repeat Kinase 2 (LRRK2) is one of the most important genetic contributors to Parkinsons disease. LRRK2 has been implicated in a number of cellular processes, including macroautophagy. To test whether LRRK2 has a role in regulating autophagy, a specific inhibitor of the kinase activity of LRRK2 was applied to human neuroglioma cells and downstream readouts of autophagy examined. The resulting data demonstrate that inhibition of LRRK2 kinase activity stimulates macroautophagy in the absence of any alteration in the translational targets of mTORC1, suggesting that LRRK2 regulates autophagic vesicle formation independent of canonical mTORC1 signaling. This study represents the first pharmacological dissection of the role LRRK2 plays in the autophagy/lysosomal pathway, emphasizing the importance of this pathway as a marker for LRRK2 physiological function. Moreover it highlights the need to dissect autophagy and lysosomal activities in the context of LRRK2 related pathologies with the final aim of understanding their aetiology and identifying specific targets for disease modifying therapies in patients.
Related JoVE Video
Regulation of nutrient-sensitive autophagy by uncoordinated 51-like kinases 1 and 2.
Autophagy
PUBLISHED: 01-04-2013
Show Abstract
Hide Abstract
Macroautophagy, commonly referred to as autophagy, is a protein degradation pathway that occurs constitutively in cells, but can also be induced by stressors such as nutrient starvation or protein aggregation. Autophagy has been implicated in multiple disease mechanisms including neurodegeneration and cancer, with both tumor suppressive and oncogenic roles. Uncoordinated 51-like kinase 1 (ULK1) is a critical autophagy protein near the apex of the hierarchal regulatory pathway that receives signals from the master nutrient sensors MTOR and AMP-activated protein kinase (AMPK). In mammals, ULK1 has a close homolog, ULK2, although their functional distinctions have been unclear. Here, we show that ULK1 and ULK2 both function to support autophagy activation following nutrient starvation. Increased autophagy following amino acid or glucose starvation was disrupted only upon combined loss of ULK1 and ULK2 in mouse embryonic fibroblasts. Generation of PtdIns3P and recruitment of WIPI2 or ZFYVE1/DFCP1 to the phagophore following amino acid starvation was blocked by combined Ulk1/2 double knockout. Autophagy activation following glucose starvation did not involve recruitment of either WIPI1 or WIPI2 to forming autophagosomes. Consistent with a PtdIns3P-independent mechanism, glucose-dependent autophagy was resistant to wortmannin. Our findings support functional redundancy between ULK1 and ULK2 for nutrient-dependent activation of autophagy and furthermore highlight the differential pathways that respond to amino acid and glucose deprivation.
Related JoVE Video
ULK1 regulates melanin levels in MNT-1 cells independently of mTORC1.
PLoS ONE
PUBLISHED: 01-01-2013
Show Abstract
Hide Abstract
Melanosomes are lysosome-related organelles that serve as specialized sites of melanin synthesis and storage in melanocytes. The progression of melanosomes through the different stages of their formation requires trafficking of specific proteins and membrane constituents in a sequential manner, which is likely to deploy ubiquitous cellular machinery along with melanocyte-specific proteins. Recent evidence revealed a connection between melanogenesis and the autophagy machinery, suggesting a novel role for members of the latter in melanocytes. Here we focused on ULK1, a key autophagy protein which is negatively regulated by mTORC1, to assess its potential role in melanogenesis in MNT-1 cells. We found that ULK1 depletion causes an increase in melanin levels, suggesting an inhibitory function for this protein in melanogenesis. Furthermore, this increase was accompanied by increased transcription of MITF (microphthalmia-associated transcription factor) and tyrosinase and by elevated protein levels of tyrosinase, the rate-limiting factor in melanin biogenesis. We also provide evidence to show that ULK1 function in this context is independent of the canonical ULK1 autophagy partners, ATG13 and FIP200. Furthermore we show that regulation of melanogenesis by ULK1 is independent of mTORC1 inhibition. Our data thus provide intriguing insights regarding the involvement of the key regulatory autophagy machinery in melanogenesis.
Related JoVE Video
The puzzling origin of the autophagosomal membrane.
F1000 Biol Rep
PUBLISHED: 12-01-2011
Show Abstract
Hide Abstract
Autophagy is one of the newest and fastest emerging research areas in biomedical life sciences. Autophagosomes, large double-membrane vesicles enclosing cytoplasmic components targeted for degradation, are the hallmark of this catabolic pathway. The origin of the lipid bilayers composing these transport carriers has been the central enigma of the field since the discovery of autophagy. A series of recent studies has implicated several cellular organelles as the possible source of the autophagosomal membranes, if anything further clouding our view. In this compendium, we will discuss these apparently contradictory results and briefly emphasize the relevance of determining the lipid source used for autophagy for future translational research, for example in drug discovery programs.
Related JoVE Video
A comprehensive glossary of autophagy-related molecules and processes (2nd edition).
Autophagy
PUBLISHED: 11-01-2011
Show Abstract
Hide Abstract
The study of autophagy is rapidly expanding, and our knowledge of the molecular mechanism and its connections to a wide range of physiological processes has increased substantially in the past decade. The vocabulary associated with autophagy has grown concomitantly. In fact, it is difficult for readers--even those who work in the field--to keep up with the ever-expanding terminology associated with the various autophagy-related processes. Accordingly, we have developed a comprehensive glossary of autophagy-related terms that is meant to provide a quick reference for researchers who need a brief reminder of the regulatory effects of transcription factors and chemical agents that induce or inhibit autophagy, the function of the autophagy-related proteins, and the roles of accessory components and structures that are associated with autophagy.
Related JoVE Video
CERT depletion predicts chemotherapy benefit and mediates cytotoxic and polyploid-specific cancer cell death through autophagy induction.
J. Pathol.
PUBLISHED: 07-24-2011
Show Abstract
Hide Abstract
Chromosomal instability (CIN) has been implicated in multidrug resistance and the silencing of the ceramide transporter, CERT, promotes sensitization to diverse cytotoxics. An improved understanding of mechanisms governing multidrug sensitization might provide insight into pathways contributing to the death of CIN cancer cells. Using an integrative functional genomics approach, we find that CERT-specific multidrug sensitization is associated with enhanced autophagosome-lysosome flux, resulting from the expression of LAMP2 following CERT silencing in colorectal and HER2(+) breast cancer cell lines. Live cell microscopy analysis revealed that CERT depletion induces LAMP2-dependent death of polyploid cells following exit from mitosis in the presence of paclitaxel. We find that CERT is relatively over-expressed in HER2(+) breast cancer and CERT protein expression acts as an independent prognostic variable and predictor of outcome in adjuvant chemotherapy-treated patients with primary breast cancer. These data suggest that the induction of LAMP2-dependent autophagic flux through CERT targeting may provide a rational approach to enhance multidrug sensitization and potentiate the death of polyploid cells following paclitaxel exposure to limit the acquisition of CIN and intra-tumour heterogeneity.
Related JoVE Video
Autophagy proteins regulate the secretory component of osteoclastic bone resorption.
Dev. Cell
PUBLISHED: 07-01-2011
Show Abstract
Hide Abstract
Osteoclasts resorb bone via the ruffled border, whose complex folds are generated by secretory lysosome fusion with bone-apposed plasma membrane. Lysosomal fusion with the plasmalemma results in acidification of the resorptive microenvironment and release of CatK to digest the organic matrix of bone. The means by which secretory lysosomes are directed to fuse with the ruffled border are enigmatic. We show that proteins essential for autophagy, including Atg5, Atg7, Atg4B, and LC3, are important for generating the osteoclast ruffled border, the secretory function of osteoclasts, and bone resorption in vitro and in vivo. Further, Rab7, which is required for osteoclast function, localizes to the ruffled border in an Atg5-dependent manner. Thus, autophagy proteins participate in polarized secretion of lysosomal contents into the extracellular space by directing lysosomes to fuse with the plasma membrane. These findings are in keeping with a putative link between autophagy genes and human skeletal homeostasis.
Related JoVE Video
The origin of the autophagosomal membrane.
Nat. Cell Biol.
PUBLISHED: 09-03-2010
Show Abstract
Hide Abstract
Macroautophagy is initiated by the formation of the phagophore (also called the isolation membrane). This membrane can both selectively and non-selectively engulf cytosolic components, grow and close around the sequestered components and then deliver them to a degradative organelle, the lysosome. Where this membrane comes from and how it grows is not well understood. Since the discovery of autophagy in the 1950s the source of the membrane has been investigated, debated and re-investigated, with the consensus view oscillating between a de novo assembly mechanism or formation from the membranes of the endoplasmic reticulum (ER) or the Golgi. In recent months, new information has emerged that both the ER and mitochondria may provide a membrane source, enlightening some older findings and revealing how complex the initiation of autophagy may be in mammalian cells.
Related JoVE Video
Trafficking and signaling in mammalian autophagy.
IUBMB Life
PUBLISHED: 06-17-2010
Show Abstract
Hide Abstract
Macroautophagy, here called autophagy, is literally a "self-eating" catabolic process, which is evolutionarily conserved. Autophagy is initiated by cellular stress pathways, resulting in the sequestration or engulfment of cytosolic proteins, membranes, and organelles in a double membrane structure that fuses with endosomes and lysosomes, thus delivering the sequestered material for degradation. Autophagy is implicated in a number of human diseases, many of which can either be characterized by an imbalance in protein, organelle, or cellular homeostasis, ultimately resulting in an alteration of the autophagic response. Here, we will review the recent progress made in understanding the induction of autophagy, with emphasis on the contributions from our laboratory.
Related JoVE Video
Mammalian Atg18 (WIPI2) localizes to omegasome-anchored phagophores and positively regulates LC3 lipidation.
Autophagy
PUBLISHED: 05-16-2010
Show Abstract
Hide Abstract
Autophagosome formation is a complex process that begins with the nucleation of a pre-autophagosomal structure (PAS) that expands into a phagophore or isolation membrane, the precursor of the autophagosome. A key event in the formation of the phagophore is the production of PtdIns3P by the phosphatidylinsitol kinase Vps34. In yeast the two closely related proteins, Atg18 and Atg21, are the only known effectors of PtdIns3P that act in the autophagy pathway. The recruitment of Atg18 or Atg21 to the PAS is an essential step in the formation of the phagophore. Our bioinformatic analysis of the Atg18 and Atg21 orthologues in all eukaryotes shows that WIPI1 and WIPI2 are both mammalian orthologues of Atg18. We show that WIPI2 is a mammalian effector of PtdIns3P and is ubiquitously expressed in a variety of cell lines. WIPI2 is recruited to early autophagosomal structures along with Atg16L and ULK1 and is required for the formation of LC3-positive autophagosomes. Furthermore, when WIPI2 is depleted, we observe a remarkable accumulation of omegasomes, ER-localized PtdIns3P-containing structures labeled by DFCP1 (double FYVE domain-containing protein 1), which are thought to act as platforms for autophagosome formation. In view of our data we propose a role for WIPI2 in the progression of omegasomes into autophagosomes.
Related JoVE Video
A comprehensive glossary of autophagy-related molecules and processes.
Autophagy
PUBLISHED: 05-16-2010
Show Abstract
Hide Abstract
Autophagy is a rapidly expanding field in the sense that our knowledge about the molecular mechanism and its connections to a wide range of physiological processes has increased substantially in the past decade. Similarly, the vocabulary associated with autophagy has grown concomitantly. This fact makes it difficult for readers, even those who work in the field, to keep up with the ever-expanding terminology associated with the various autophagy-related processes. Accordingly, we have developed a comprehensive glossary of autophagy-related terms that is meant to provide a quick reference for researchers who need a brief reminder of the regulatory effects of transcription factors or chemical agents that induce or inhibit autophagy, the function of the autophagy-related proteins, or the role of accessory machinery or structures that are associated with autophagy.
Related JoVE Video
A novel syntaxin 6-interacting protein, SHIP164, regulates syntaxin 6-dependent sorting from early endosomes.
Traffic
PUBLISHED: 02-19-2010
Show Abstract
Hide Abstract
Membrane fusion is dependent on the function of SNAREs and their alpha-helical SNARE motifs that form SNARE complexes. The Habc domains at the N-termini of some SNAREs can interact with their associated SNARE motif, Sec1/Munc18 (SM) proteins, tethering proteins or adaptor proteins, suggesting that they play an important regulatory function. We screened for proteins that interact with the Habc domain of Syntaxin 6, and isolated an uncharacterized 164-kDa protein that we named SHIP164. SHIP164 is part of a large (approximately 700 kDa) complex, and interacts with components of the Golgi-associated retrograde protein (GARP) tethering complex. Depletion of GARP subunits or overexpression of Syntaxin 6 results in a redistribution of soluble SHIP164 to endosomal structures. Co-overexpression of Syntaxin 6 and SHIP164 produced excessive tubulation of endosomes, and perturbed the transport of cation-independent mannose-6-phosphate receptor (CI-MPR) and transferrin receptor. Thus,we propose that SHIP164 functions in trafficking through the early/recycling endosomal system.
Related JoVE Video
The role of membrane proteins in mammalian autophagy.
Semin. Cell Dev. Biol.
PUBLISHED: 02-06-2010
Show Abstract
Hide Abstract
Autophagy is an evolutionarily conserved degradative process that is initiated by autophagosomes, double-membrane structures that sequester cytoplasmic material and fuse with endosomes and lysosomes to become autolysosomes. Recent progress in the identification of proteins required for autophagy has led to a substantial understanding of the process involved in making an autophagosome. Mammalian Atg9, a multi-spanning transmembrane protein, is one of the possible keys to understanding how autophagosomes are formed. Current and future advances in understanding the function of mammalian Atg9 will provide a basis for further progress. In addition, the identification of so far uncharacterized transmembrane proteins which are involved in autophagy will also help to address the important questions of where, how, and why autophagosomes form.
Related JoVE Video
New insights into the function of Atg9.
FEBS Lett.
PUBLISHED: 01-08-2010
Show Abstract
Hide Abstract
Autophagy is a lysosomal degradation pathway that is essential for cellular homeostasis. Identification of more than 30 autophagy related proteins including a multi-spanning membrane protein, Atg9, has increased our understanding of the molecular mechanisms involved in autophagy. Atg9 is required for autophagy in several eukaryotic organisms although its function is unknown. Recently, we identified a novel interacting partner of mAtg9, p38 MAPK interacting protein, p38IP. We summarise recent data on the role of Atg9 trafficking in yeast and mammalian autophagy and discuss the role of p38IP and p38 MAPK in regulation of mAtg9 trafficking and autophagy.
Related JoVE Video
Membrane trafficking events that partake in autophagy.
Curr. Opin. Cell Biol.
PUBLISHED: 11-06-2009
Show Abstract
Hide Abstract
During autophagy, autophagosomes or autophagic vesicles (AVs) are formed and enclose portions of cytosol and/or entire organelles. Distinct from any other cellular vesicle, AVs have a double membrane, between which lies a very limited lumen. To obtain this peculiar topology, the early AV, the phagophore or isolation membrane (IM) must be either synthesised de novo or expanded by vesicle fusion. In support of the latter, recent work has implicated several different organelles as potential membrane sources during the initial stages of IM formation and expansion. Once closed, AVs use the microtubule network to meet and fuse with several different endocytic organelles on their way to becoming degradative AVs. Recent studies have shed light on the machinery required for both these early and late events to occur.
Related JoVE Video
Coordinated regulation of autophagy by p38alpha MAPK through mAtg9 and p38IP.
EMBO J.
PUBLISHED: 10-09-2009
Show Abstract
Hide Abstract
Autophagy, a lysosomal degradation pathway, is essential for homeostasis, development, neurological diseases, and cancer. Regulation of autophagy in human disease is not well understood. Atg9 is a transmembrane protein required for autophagy, and it has been proposed that trafficking of Atg9 may regulate autophagy. Mammalian Atg9 traffics between the TGN and endosomes in basal conditions, and newly formed autophagosomes in response to signals inducing autophagy. We identified p38IP as a new mAtg9 interactor and showed that this interaction is regulated by p38alpha MAPK. p38IP is required for starvation-induced mAtg9 trafficking and autophagosome formation. Manipulation of p38IP and p38alpha alters mAtg9 localization, suggesting p38alpha regulates, through p38IP, the starvation-induced mAtg9 trafficking to forming autophagosomes. Furthermore, we show that p38alpha is a negative regulator of both basal autophagy and starvation-induced autophagy, and suggest that this regulation may be through a direct competition with mAtg9 for binding to p38IP. Our results provide evidence for a link between the MAPK pathway and the control of autophagy through mAtg9 and p38IP.
Related JoVE Video
Coordination of membrane events during autophagy by multiple class III PI3-kinase complexes.
J. Cell Biol.
PUBLISHED: 10-03-2009
Show Abstract
Hide Abstract
Autophagy or "self-eating" is a highly conserved pathway that enables cells to degrade pieces of themselves in autolysosomes to enable their survival in times of stress, including nutrient deprivation. The formation of these degradative compartments requires cytosolic proteins, some of which are autophagy specific, as well as intracellular organelles, such as the ER and Golgi, and the endosome-lysosome system. Here we discuss the cross talk between autophagy and intracellular compartments, highlighting recent exciting data about the role and regulation of the Vps34 class III phosphatidylinositol (PI) 3-kinase in autophagy.
Related JoVE Video
Evolution of Atg1 function and regulation.
Autophagy
PUBLISHED: 08-09-2009
Show Abstract
Hide Abstract
The serine/threonine kinase Atg1 plays an essential role downstream of TOR for the regulation of autophagy. In yeast, where Atg1 was first identified, a complex regulatory mechanism has been described that includes at least seven other interacting proteins and a phosphorylation-dependent switch. Recent findings confirm that the mammalian Atg1 homologues ULK1 and 2 have autophagy regulatory roles. However, we and others have also demonstrated mechanistic differences with the yeast model and between these two Atg1 family members. Here, we elaborate on our growing understanding of Atg1 function, incorporating findings from yeast, C. elegans, D. melanogaster and mammalian cells. We propose that through evolution, Atg1 proteins have adopted additional cellular functions and regulatory mechanisms, which could involve multiple gene family isoforms working within multifunctional protein complexes. The gene family expansion observed in higher eukaryotes might reflect an increased functional diversity of Atg1 proteins in cell growth, differentiation and survival.
Related JoVE Video
The EmERgence of autophagosomes.
Dev. Cell
PUBLISHED: 08-03-2009
Show Abstract
Hide Abstract
Autophagosomes are large double-membrane vesicles that enclose cytoplasmic components targeting them for degradation. Two recent reports reveal that phagophores, the autophagosome precursors, are surrounded by and connected to rough endoplasmic reticulum (ER) membranes. These results shed light on how membranes may be supplied and reorganized for autophagosomal biogenesis.
Related JoVE Video
PIKfyve regulation of endosome-linked pathways.
Traffic
PUBLISHED: 07-08-2009
Show Abstract
Hide Abstract
The phosphoinositide 5-kinase (PIKfyve) is a critical enzyme for the synthesis of PtdIns(3,5)P2, that has been implicated in various trafficking events associated with the endocytic pathway. We have now directly compared the effects of siRNA-mediated knockdown of PIKfyve in HeLa cells with a specific pharmacological inhibitor of enzyme activity. Both approaches induce changes in the distribution of CI-M6PR and trans-Golgi network (TGN)-46 proteins, which cycles between endosomes and TGN, leading to their accumulation in dispersed punctae, whilst the TGN marker golgin-245 retains a perinuclear disposition. Trafficking of CD8-CI-M6PR (retromer-dependent) and CD8-Furin (retromer-independent) chimeras from the cell surface to the TGN is delayed following drug administration, as is the transport of the Shiga toxin B-subunit. siRNA knockdown of PIKfyve produced no defect in epidermal growth factor receptor (EGFR) degradation, unless combined with knockdown of its activator molecule Vac14, suggesting that a low threshold of PtdIns(3,5)P2 is necessary and sufficient for this pathway. Accordingly pharmacological inhibition of PIKfyve results in a profound block to the lysosomal degradation of activated epidermal growth factor (EGF) and Met receptors. Immunofluorescence revealed EGF receptors to be trapped in the interior of a swollen endosomal compartment. In cells starved of amino acids, PIKfyve inhibition leads to the accumulation of the lipidated form of GFP-LC3, a marker of autophagosomal structures, which can be visualized as fluorescent punctae. We suggest that PIKfyve inhibition may render the late endosome/lysosome compartment refractory to fusion with both autophagosomes and with EGFR-containing multivesicular bodies.
Related JoVE Video
In vitro reconstitution of fusion between immature autophagosomes and endosomes.
Autophagy
PUBLISHED: 07-06-2009
Show Abstract
Hide Abstract
Autophagy is a highly conserved degradative pathway whereby a double membrane engulfs cytoplasmic constituents to form an autophagic vacuole or autophagosome. An essential requirement for efficient autophagy is the acquisition of an adequate degradative capacity by the autophagosomes. To acquire this capacity the immature autophagic vacuoles (AVis) obtain lysosomal hydrolases by fusion with endosomes. The current models suggest that at least two types of endosomes, early and late, fuse with AVis to form mature, degradative AVds. This fusion and maturation requires proteins also involved in endosome maturation such as Rab7. However, it is not known if there are molecular requirements unique to AVi-endosome fusion. To identify and investigate the molecular requirements of this fusion we developed a cell-free fusion assay based on content mixing, which occurs after fusion of isolated AVis and different endosomal fractions. Our assay shows that isolated AVis can fuse to a similar extent in vitro with both early and late endosomes. Furthermore, fusion between autophagosomes and endosomes requires cytosolic and endosomal proteins, but does not show a nucleotide-dependence, and is partially N-ethylmaleimide sensitive. We also demonstrate that the lipidated form of the autophagosomal protein LC3 is dispensable for this fusion event.
Related JoVE Video
Early endosomes and endosomal coatomer are required for autophagy.
J. Cell Biol.
PUBLISHED: 04-13-2009
Show Abstract
Hide Abstract
Autophagy, an intracellular degradative pathway, maintains cell homeostasis under normal and stress conditions. Nascent double-membrane autophagosomes sequester and enclose cytosolic components and organelles, and subsequently fuse with the endosomal pathway allowing content degradation. Autophagy requires fusion of autophagosomes with late endosomes, but it is not known if fusion with early endosomes is essential. We show that fusion of AVs with functional early endosomes is required for autophagy. Inhibition of early endosome function by loss of COPI subunits (beta, beta, or alpha) results in accumulation of autophagosomes, but not an increased autophagic flux. COPI is required for ER-Golgi transport and early endosome maturation. Although loss of COPI results in the fragmentation of the Golgi, this does not induce the formation of autophagosomes. Loss of COPI causes defects in early endosome function, as both transferrin recycling and EGF internalization and degradation are impaired, and this loss of function causes an inhibition of autophagy, an accumulation of p62/SQSTM-1, and ubiquitinated proteins in autophagosomes.
Related JoVE Video
Correlative light and electron microscopy.
Meth. Enzymol.
PUBLISHED: 02-10-2009
Show Abstract
Hide Abstract
Autophagy is an intracellular degradative pathway that is essential for cellular homeostasis. Efficient autophagy ultimately relies on the ability of the cell to form autophagosomes, and the efficiency of lysosomal enzymes and lipid hydrolases contained within the autolysosome to degrade sequestered cytosolic material and organelles and recycle these nutrients back to the cytosol. Several assays and techniques to monitor autophagy are available, and these can be quantitative or qualitative, biochemical or morphological. Here we describe a method for monitoring the autophagic process that is based on morphology and the application of both light and electron microscopy, called correlative light and electron microscopy, or CLEM. CLEM provides an advance over either technique (light or electron microscopy) alone and can be performed on any cell or tissue sample, which can be grown or mounted on a gridded coverslip or support compatible with light microscopy. CLEM gives a broad low magnification overview of the cell, allowing an assessment of both spatial and temporal events, as well as providing high-resolution information about individual autophagosomes or single compartments.
Related JoVE Video
Kinase-inactivated ULK proteins inhibit autophagy via their conserved C-terminal domains using an Atg13-independent mechanism.
Mol. Cell. Biol.
PUBLISHED: 01-15-2009
Show Abstract
Hide Abstract
The yeast Atg1 serine/threonine protein kinase and its mammalian homologs ULK1 and ULK2 play critical roles during the activation of autophagy. Previous studies have demonstrated that the conserved C-terminal domain (CTD) of ULK1 controls the regulatory function and localization of the protein. Here, we explored the role of kinase activity and intramolecular interactions to further understand ULK function. We demonstrate that the dominant-negative activity of kinase-dead mutants requires a 7-residue motif within the CTD. Our data lead to a model in which the functions of ULK1 and ULK2 are controlled by autophosphorylation and conformational changes involving exposure of the CTD. Additional mapping indicates that the CTD contains other distinct regions that direct membrane association and interaction with the putative human homologue of Atg13, which we have here characterized. Atg13 is required for autophagy and Atg9 trafficking during autophagy. However, Atg13 does not bind the 7-residue dominant-negative motif in the CTD of ULK proteins nor is the inhibitory activity of the CTDs rescued by Atg13 ectopic expression, suggesting that in mammalian cells, the CTD may interact with additional autophagy proteins.
Related JoVE Video
A role for Rap2 in recycling the extended conformation of LFA-1 during T cell migration.
Biol Open
Show Abstract
Hide Abstract
T lymphocytes make use of their major integrin LFA-1 to migrate on surfaces that express ICAM-1 such as blood vessels and inflamed tissue sites. How the adhesions are turned over in order to supply traction for this migration has not been extensively investigated. By following the fate of biotinylated membrane LFA-1 on T lymphocytes, we show in this study that LFA-1 internalization and re-exposure on the plasma membrane are linked to migration. Previously we demonstrated the GTPase Rap2 to be a regulator of LFA-1-mediated migration. SiRNA knockdown of this GTPase inhibits both LFA-1 internalization and also its ability to be re-exposed, indicating that Rap2 participates in recycling of LFA-1 and influences its complete endocytosis-exocytosis cycle. Confocal microscopy images reveal that the intracellular distribution of Rap2 overlaps with endosomal recycling vesicles. Although the homologous GTPase Rap1 is also found on intracellular vesicles and associated with LFA-1 activation, these two homologous GTPases do not co-localize. Little is known about the conformation of the LFA-1 that is recycled. We show that the extended form of LFA-1 is internalized and in Rap2 siRNA-treated T lymphocytes the trafficking of this LFA-1 conformation is disrupted resulting in its intracellular accumulation. Thus LFA-1-mediated migration of T lymphocytes requires Rap2-expressing vesicles to recycle the extended form of LFA-1 that we have previously found to control migration at the leading edge.
Related JoVE Video
Endocytosis and autophagy: Shared machinery for degradation.
Bioessays
Show Abstract
Hide Abstract
Two key questions in the autophagy field are the mechanisms that underlie the signals for autophagy initiation and the source of membrane for expansion of the nascent membrane, the phagophore. In this review, we discuss recent findings highlighting the role of the classical endosomal pathway, from plasma membrane to lysosome, in the formation and expansion of the phagophore and subsequent degradation of the autophagosome contents. We also highlight the striking conservation of regulatory factors between the two pathways, including those regulating membrane budding and fusion, and the role of the lysosome in sensing the nutrient status of the cell, regulating mTORC1 activity, and ultimately the initiation of autophagy. Editors suggested further reading in BioEssays The evolution of dynamin to regulate clathrin-mediated endocytosis Abstract.
Related JoVE Video
Regulation of autophagosome formation by Rho kinase.
Cell. Signal.
Show Abstract
Hide Abstract
Macroautophagy, commonly referred to as autophagy, is a protein degradation pathway that functions at a constitutive level in cells, which may become further activated by stressors such as nutrient starvation or protein aggregation. Autophagy has multiple beneficial roles for maintaining normal cellular homeostasis and these roles are related to the implications of autophagy in disease mechanisms including neurodegeneration and cancer. We previously searched for novel autophagy regulators and identified Rho-kinase 1 (ROCK1) as a candidate. Here, we show that activated ROCK1 inhibits autophagy in human embryonic kidney 293 cells. Conversely, ROCK inhibitory compounds enhanced the autophagy response to amino acid starvation or rapamycin treatment. Inhibition of ROCK during the starvation period led to a more rapid response with the production of larger early autophagosomes that matured into enlarged late degradative autolysosomes. Despite the production of enlarged LC3-positive early autophagosomes, membrane precursors containing WD-repeat protein interacting with phosphoinositides 1 (WIPI1) and mammalian Atg9 were not affected by ROCK inhibition, suggesting that phagophore elongation had been unusually extended. However, the enlarged autophagosomes were enriched in ULK1 which was essential to allow progression of autophagy flux. Our results demonstrate a novel role for ROCK in the control of autophagosome size and degradative capacity.
Related JoVE Video
Guidelines for the use and interpretation of assays for monitoring autophagy.
Daniel J Klionsky, Fábio C Abdalla, Hagai Abeliovich, Robert T Abraham, Abraham Acevedo-Arozena, Khosrow Adeli, Lotta Agholme, Maria Agnello, Patrizia Agostinis, Julio A Aguirre-Ghiso, Hyung Jun Ahn, Ouardia Ait-Mohamed, Slimane Ait-Si-Ali, Takahiko Akematsu, Shizuo Akira, Hesham M Al-Younes, Munir A Al-Zeer, Matthew L Albert, Roger L Albin, Javier Alegre-Abarrategui, Maria Francesca Aleo, Mehrdad Alirezaei, Alexandru Almasan, Maylin Almonte-Becerril, Atsuo Amano, Ravi Amaravadi, Shoba Amarnath, Amal O Amer, Nathalie Andrieu-Abadie, Vellareddy Anantharam, David K Ann, Shailendra Anoopkumar-Dukie, Hiroshi Aoki, Nadezda Apostolova, Giuseppe Arancia, John P Aris, Katsuhiko Asanuma, Nana Y O Asare, Hisashi Ashida, Valerie Askanas, David S Askew, Patrick Auberger, Misuzu Baba, Steven K Backues, Eric H Baehrecke, Ben A Bahr, Xue-Yuan Bai, Yannick Bailly, Robert Baiocchi, Giulia Baldini, Walter Balduini, Andrea Ballabio, Bruce A Bamber, Edward T W Bampton, Gábor Bánhegyi, Clinton R Bartholomew, Diane C Bassham, Robert C Bast, Henri Batoko, Boon-Huat Bay, Isabelle Beau, Daniel M Béchet, Thomas J Begley, Christian Behl, Christian Behrends, Soumeya Bekri, Bryan Bellaire, Linda J Bendall, Luca Benetti, Laura Berliocchi, Henri Bernardi, Francesca Bernassola, Sébastien Besteiro, Ingrid Bhatia-Kiššová, Xiaoning Bi, Martine Biard-Piechaczyk, Janice S Blum, Lawrence H Boise, Paolo Bonaldo, David L Boone, Beat C Bornhauser, Karina R Bortoluci, Ioannis Bossis, Fréderic Bost, Jean-Pierre Bourquin, Patricia Boya, Michaël Boyer-Guittaut, Peter V Bozhkov, Nathan R Brady, Claudio Brancolini, Andreas Brech, Jay E Brenman, Ana Brennand, Emery H Bresnick, Patrick Brest, Dave Bridges, Molly L Bristol, Paul S Brookes, Eric J Brown, John H Brumell, Nicola Brunetti-Pierri, Ulf T Brunk, Dennis E Bulman, Scott J Bultman, Geert Bultynck, Lena F Burbulla, Wilfried Bursch, Jonathan P Butchar, Wanda Buzgariu, Sérgio P Bydlowski, Ken Cadwell, Monika Cahova, Dongsheng Cai, Jiyang Cai, Qian Cai, Bruno Calabretta, Javier Calvo-Garrido, Nadine Camougrand, Michelangelo Campanella, Jenny Campos-Salinas, Eleonora Candi, Lizhi Cao, Allan B Caplan, Simon R Carding, Sandra M Cardoso, Jennifer S Carew, Cathleen R Carlin, Virginie Carmignac, Leticia A M Carneiro, Serena Carra, Rosario A Caruso, Giorgio Casari, Caty Casas, Roberta Castino, Eduardo Cebollero, Francesco Cecconi, Jean Celli, Hassan Chaachouay, Han-Jung Chae, Chee-Yin Chai, David C Chan, Edmond Y Chan, Raymond Chuen-Chung Chang, Chi-Ming Che, Ching-Chow Chen, Guang-Chao Chen, Guo-Qiang Chen, Min Chen, Quan Chen, Steve S-L Chen, WenLi Chen, Xi Chen, Xiangmei Chen, Xiequn Chen, Ye-Guang Chen, Yingyu Chen, Yongqiang Chen, Yu-Jen Chen, Zhixiang Chen, Alan Cheng, Christopher H K Cheng, Yan Cheng, Heesun Cheong, Jae-Ho Cheong, Sara Cherry, Russ Chess-Williams, Zelda H Cheung, Eric Chevet, Hui-Ling Chiang, Roberto Chiarelli, Tomoki Chiba, Lih-Shen Chin, Shih-Hwa Chiou, Francis V Chisari, Chi Hin Cho, Dong-Hyung Cho, Augustine M K Choi, DooSeok Choi, Kyeong Sook Choi, Mary E Choi, Salem Chouaib, Divaker Choubey, Vinay Choubey, Charleen T Chu, Tsung-Hsien Chuang, Sheau-Huei Chueh, Taehoon Chun, Yong-Joon Chwae, Mee-Len Chye, Roberto Ciarcia, Maria R Ciriolo, Michael J Clague, Robert S B Clark, Peter G H Clarke, Robert Clarke, Patrice Codogno, Hilary A Coller, María I Colombo, Sergio Comincini, Maria Condello, Fabrizio Condorelli, Mark R Cookson, Graham H Coombs, Isabelle Coppens, Ramón Corbalán, Pascale Cossart, Paola Costelli, Safia Costes, Ana Coto-Montes, Eduardo Couve, Fraser P Coxon, James M Cregg, José L Crespo, Marianne J Cronjé, Ana Maria Cuervo, Joseph J Cullen, Mark J Czaja, Marcello D'Amelio, Arlette Darfeuille-Michaud, Lester M Davids, Faith E Davies, Massimo De Felici, John F de Groot, Cornelis A M de Haan, Luisa De Martino, Angelo De Milito, Vincenzo De Tata, Jayanta Debnath, Alexei Degterev, Benjamin Dehay, Lea M D Delbridge, Francesca Demarchi, Yi Zhen Deng, Jörn Dengjel, Paul Dent, Donna Denton, Vojo Deretic, Shyamal D Desai, Rodney J Devenish, Mario Di Gioacchino, Gilbert Di Paolo, Chiara Di Pietro, Guillermo Díaz-Araya, Inés Díaz-Laviada, Maria T Diaz-Meco, Javier Diaz-Nido, Ivan Dikic, Savithramma P Dinesh-Kumar, Wen-Xing Ding, Clark W Distelhorst, Abhinav Diwan, Mojgan Djavaheri-Mergny, Svetlana Dokudovskaya, Zheng Dong, Frank C Dorsey, Victor Dosenko, James J Dowling, Stephen Doxsey, Marlène Dreux, Mark E Drew, Qiuhong Duan, Michel A Duchosal, Karen Duff, Isabelle Dugail, Madeleine Durbeej, Michael Duszenko, Charles L Edelstein, Aimee L Edinger, Gustavo Egea, Ludwig Eichinger, N Tony Eissa, Suhendan Ekmekcioglu, Wafik S El-Deiry, Zvulun Elazar, Mohamed Elgendy, Lisa M Ellerby, Kai Er Eng, Anna-Mart Engelbrecht, Simone Engelender, Jekaterina Erenpreisa, Ricardo Escalante, Audrey Esclatine, Eeva-Liisa Eskelinen, Lucile Espert, Virginia Espina, Huizhou Fan, Jia Fan, Qi-Wen Fan, Zhen Fan, Shengyun Fang, Yongqi Fang, Manolis Fanto, Alessandro Fanzani, Thomas Farkas, Jean-Claude Farré, Mathias Faure, Marcus Fechheimer, Carl G Feng, Jian Feng, Qili Feng, Youji Feng, László Fésüs, Ralph Feuer, Maria E Figueiredo-Pereira, Gian Maria Fimia, Diane C Fingar, Steven Finkbeiner, Toren Finkel, Kim D Finley, Filomena Fiorito, Edward A Fisher, Paul B Fisher, Marc Flajolet, Maria L Florez-McClure, Salvatore Florio, Edward A Fon, Francesco Fornai, Franco Fortunato, Rati Fotedar, Daniel H Fowler, Howard S Fox, Rodrigo Franco, Lisa B Frankel, Marc Fransen, José M Fuentes, Juan Fueyo, Jun Fujii, Kozo Fujisaki, Eriko Fujita, Mitsunori Fukuda, Ruth H Furukawa, Matthias Gaestel, Philippe Gailly, Malgorzata Gajewska, Brigitte Galliot, Vincent Galy, Subramaniam Ganesh, Barry Ganetzky, Ian G Ganley, Fen-Biao Gao, George F Gao, Jinming Gao, Lorena Garcia, Guillermo Garcia-Manero, Mikel Garcia-Marcos, Marjan Garmyn, Andrei L Gartel, Evelina Gatti, Mathias Gautel, Thomas R Gawriluk, Matthew E Gegg, Jiefei Geng, Marc Germain, Jason E Gestwicki, David A Gewirtz, Saeid Ghavami, Pradipta Ghosh, Anna M Giammarioli, Alexandra N Giatromanolaki, Spencer B Gibson, Robert W Gilkerson, Michael L Ginger, Henry N Ginsberg, Jakub Golab, Michael S Goligorsky, Pierre Golstein, Candelaria Gomez-Manzano, Ebru Goncu, Céline Gongora, Claudio D Gonzalez, Ramon Gonzalez, Cristina González-Estévez, Rosa Ana González-Polo, Elena Gonzalez-Rey, Nikolai V Gorbunov, Sharon Gorski, Sandro Goruppi, Roberta A Gottlieb, Devrim Gozuacik, Giovanna Elvira Granato, Gary D Grant, Kim N Green, Aleš Gregorc, Frédéric Gros, Charles Grose, Thomas W Grunt, Philippe Gual, Jun-Lin Guan, Kun-Liang Guan, Sylvie M Guichard, Anna S Gukovskaya, Ilya Gukovsky, Jan Gunst, Asa B Gustafsson, Andrew J Halayko, Amber N Hale, Sandra K Halonen, Maho Hamasaki, Feng Han, Ting Han, Michael K Hancock, Malene Hansen, Hisashi Harada, Masaru Harada, Stefan E Hardt, J Wade Harper, Adrian L Harris, James Harris, Steven D Harris, Makoto Hashimoto, Jeffrey A Haspel, Shin-Ichiro Hayashi, Lori A Hazelhurst, Congcong He, You-Wen He, Marie-Josee Hebert, Kim A Heidenreich, Miep H Helfrich, Gudmundur V Helgason, Elizabeth P Henske, Brian Herman, Paul K Herman, Claudio Hetz, Sabine Hilfiker, Joseph A Hill, Lynne J Hocking, Paul Hofman, Thomas G Hofmann, Jörg Höhfeld, Tessa L Holyoake, Ming-Huang Hong, David A Hood, Gökhan S Hotamisligil, Ewout J Houwerzijl, Maria Høyer-Hansen, Bingren Hu, Chien-An A Hu, Hong-Ming Hu, Ya Hua, Canhua Huang, Ju Huang, Shengbing Huang, Wei-Pang Huang, Tobias B Huber, Won-Ki Huh, Tai-Ho Hung, Ted R Hupp, Gang Min Hur, James B Hurley, Sabah N A Hussain, Patrick J Hussey, Jung Jin Hwang, Seungmin Hwang, Atsuhiro Ichihara, Shirin Ilkhanizadeh, Ken Inoki, Takeshi Into, Valentina Iovane, Juan L Iovanna, Nancy Y Ip, Yoshitaka Isaka, Hiroyuki Ishida, Ciro Isidoro, Ken-Ichi Isobe, Akiko Iwasaki, Marta Izquierdo, Yotaro Izumi, Panu M Jaakkola, Marja Jäättelä, George R Jackson, William T Jackson, Bassam Janji, Marina Jendrach, Ju-Hong Jeon, Eui-Bae Jeung, Hong Jiang, Hongchi Jiang, Jean X Jiang, Ming Jiang, Qing Jiang, Xuejun Jiang, Alberto Jiménez, Meiyan Jin, Shengkan Jin, Cheol O Joe, Terje Johansen, Daniel E Johnson, Gail V W Johnson, Nicola L Jones, Bertrand Joseph, Suresh K Joseph, Annie M Joubert, Gábor Juhász, Lucienne Juillerat-Jeanneret, Chang Hwa Jung, Yong-Keun Jung, Kai Kaarniranta, Allen Kaasik, Tomohiro Kabuta, Motoni Kadowaki, Katarina Kågedal, Yoshiaki Kamada, Vitaliy O Kaminskyy, Harm H Kampinga, Hiromitsu Kanamori, Chanhee Kang, Khong Bee Kang, Kwang Il Kang, Rui Kang, Yoon-A Kang, Tomotake Kanki, Thirumala-Devi Kanneganti, Haruo Kanno, Anumantha G Kanthasamy, Arthi Kanthasamy, Vassiliki Karantza, Gur P Kaushal, Susmita Kaushik, Yoshinori Kawazoe, Po-Yuan Ke, John H Kehrl, Ameeta Kelekar, Claus Kerkhoff, David H Kessel, Hany Khalil, Jan A K W Kiel, Amy A Kiger, Akio Kihara, Deok Ryong Kim, Do-Hyung Kim, Dong-Hou Kim, Eun-Kyoung Kim, Hyung-Ryong Kim, Jae-Sung Kim, Jeong Hun Kim, Jin Cheon Kim, John K Kim, Peter K Kim, Seong Who Kim, Yong-Sun Kim, Yonghyun Kim, Adi Kimchi, Alec C Kimmelman, Jason S King, Timothy J Kinsella, Vladimir Kirkin, Lorrie A Kirshenbaum, Katsuhiko Kitamoto, Kaio Kitazato, Ludger Klein, Walter T Klimecki, Jochen Klucken, Erwin Knecht, Ben C B Ko, Jan C Koch, Hiroshi Koga, Jae-Young Koh, Young Ho Koh, Masato Koike, Masaaki Komatsu, Eiki Kominami, Hee Jeong Kong, Wei-jia Kong, Viktor I Korolchuk, Yaichiro Kotake, Michael I Koukourakis, Juan B Kouri Flores, Attila L Kovács, Claudine Kraft, Dimitri Krainc, Helmut Krämer, Carole Kretz-Remy, Anna M Krichevsky, Guido Kroemer, Rejko Krüger, Oleg Krut, Nicholas T Ktistakis, Chia-Yi Kuan, Róza Kucharczyk, Ashok Kumar, Raj Kumar, Sharad Kumar, Mondira Kundu, Hsing-Jien Kung, Tino Kurz, Ho Jeong Kwon, Albert R La Spada, Frank Lafont, Trond Lamark, Jacques Landry, Jon D Lane, Pierre Lapaquette, Jocelyn F Laporte, Lajos László, Sergio Lavandero, Josée N Lavoie, Robert Layfield, Pedro A Lazo, Weidong Le, Laurent Le Cam, Daniel J Ledbetter, Alvin J X Lee, Byung-Wan Lee, Gyun Min Lee, Jongdae Lee, Ju-Hyun Lee, Michael Lee, Myung-Shik Lee, Sug Hyung Lee, Christiaan Leeuwenburgh, Patrick Legembre, Renaud Legouis, Michael Lehmann, Huan-Yao Lei, Qun-Ying Lei, David A Leib, José Leiro, John J Lemasters, Antoinette Lemoine, Maciej S Lesniak, Dina Lev, Victor V Levenson, Beth Levine, Efrat Levy, Faqiang Li, Jun-lin Li, Lian Li, Sheng Li, Weijie Li, Xue-Jun Li, Yan-Bo Li, Yi-Ping Li, Chengyu Liang, Qiangrong Liang, Yung-Feng Liao, Pawel P Liberski, Andrew Lieberman, Hyunjung J Lim, Kah-Leong Lim, Kyu Lim, Chiou-Feng Lin, Fu-Cheng Lin, Jian Lin, Jiandie D Lin, Kui Lin, Wan-Wan Lin, Weei-Chin Lin, Yi-Ling Lin, Rafael Linden, Paul Lingor, Jennifer Lippincott-Schwartz, Michael P Lisanti, Paloma B Liton, Bo Liu, Chun-Feng Liu, Kaiyu Liu, Leyuan Liu, Qiong A Liu, Wei Liu, Young-Chau Liu, Yule Liu, Richard A Lockshin, Chun-Nam Lok, Sagar Lonial, Benjamin Loos, Gabriel Lopez-Berestein, Carlos Lopez-Otin, Laura Lossi, Michael T Lotze, Péter Low, Binfeng Lu, Bingwei Lu, Bo Lu, Zhen Lu, Fredéric Luciano, Nicholas W Lukacs, Anders H Lund, Melinda A Lynch-Day, Yong Ma, Fernando Macian, Jeff P MacKeigan, Kay F Macleod, Frank Madeo, Luigi Maiuri, Maria Chiara Maiuri, Davide Malagoli, May Christine V Malicdan, Walter Malorni, Na Man, Eva-Maria Mandelkow, Stéphen Manon, Irena Manov, Kai Mao, Xiang Mao, Zixu Mao, Philippe Marambaud, Daniela Marazziti, Yves L Marcel, Katie Marchbank, Piero Marchetti, Stefan J Marciniak, Mateus Marcondes, Mohsen Mardi, Gabriella Marfè, Guillermo Mariño, Maria Markaki, Mark R Marten, Seamus J Martin, Camille Martinand-Mari, Wim Martinet, Marta Martinez-Vicente, Matilde Masini, Paola Matarrese, Saburo Matsuo, Raffaele Matteoni, Andreas Mayer, Nathalie M Mazure, David J McConkey, Melanie J McConnell, Catherine McDermott, Christine McDonald, Gerald M McInerney, Sharon L McKenna, BethAnn McLaughlin, Pamela J McLean, Christopher R McMaster, G Angus McQuibban, Alfred J Meijer, Miriam H Meisler, Alicia Meléndez, Thomas J Melia, Gerry Melino, Maria A Mena, Javier A Menendez, Rubem F S Menna-Barreto, Manoj B Menon, Fiona M Menzies, Carol A Mercer, Adalberto Merighi, Diane E Merry, Stefania Meschini, Christian G Meyer, Thomas F Meyer, Chao-Yu Miao, Jun-Ying Miao, Paul A M Michels, Carine Michiels, Dalibor Mijaljica, Ana Milojkovic, Saverio Minucci, Clelia Miracco, Cindy K Miranti, Ioannis Mitroulis, Keisuke Miyazawa, Noboru Mizushima, Baharia Mograbi, Simin Mohseni, Xavier Molero, Bertrand Mollereau, Faustino Mollinedo, Takashi Momoi, Iryna Monastyrska, Martha M Monick, Mervyn J Monteiro, Michael N Moore, Rodrigo Mora, Kevin Moreau, Paula I Moreira, Yuji Moriyasu, Jorge Moscat, Serge Mostowy, Jeremy C Mottram, Tomasz Motyl, Charbel E-H Moussa, Sylke Müller, Sylviane Muller, Karl Münger, Christian Münz, Leon O Murphy, Maureen E Murphy, Antonio Musarò, Indira Mysorekar, Eiichiro Nagata, Kazuhiro Nagata, Aimable Nahimana, Usha Nair, Toshiyuki Nakagawa, Kiichi Nakahira, Hiroyasu Nakano, Hitoshi Nakatogawa, Meera Nanjundan, Naweed I Naqvi, Derek P Narendra, Masashi Narita, Miguel Navarro, Steffan T Nawrocki, Taras Y Nazarko, Andriy Nemchenko, Mihai G Netea, Thomas P Neufeld, Paul A Ney, Ioannis P Nezis, Huu Phuc Nguyen, Daotai Nie, Ichizo Nishino, Corey Nislow, Ralph A Nixon, Takeshi Noda, Angelika A Noegel, Anna Nogalska, Satoru Noguchi, Lucia Notterpek, Ivana Novak, Tomoyoshi Nozaki, Nobuyuki Nukina, Thorsten Nürnberger, Beat Nyfeler, Keisuke Obara, Terry D Oberley, Salvatore Oddo, Michinaga Ogawa, Toya Ohashi, Koji Okamoto, Nancy L Oleinick, F Javier Oliver, Laura J Olsen, Stefan Olsson, Onya Opota, Timothy F Osborne, Gary K Ostrander, Kinya Otsu, Jing-hsiung James Ou, Mireille Ouimet, Michael Overholtzer, Bulent Ozpolat, Paolo Paganetti, Ugo Pagnini, Nicolas Pallet, Glen E Palmer, Camilla Palumbo, Tianhong Pan, Theocharis Panaretakis, Udai Bhan Pandey, Zuzana Papackova, Issidora Papassideri, Irmgard Paris, Junsoo Park, Ohkmae K Park, Jan B Parys, Katherine R Parzych, Susann Patschan, Cam Patterson, Sophie Pattingre, John M Pawelek, Jianxin Peng, David H Perlmutter, Ida Perrotta, George Perry, Shazib Pervaiz, Matthias Peter, Godefridus J Peters, Morten Petersen, Goran Petrovski, James M Phang, Mauro Piacentini, Philippe Pierre, Valérie Pierrefite-Carle, Gérard Pierron, Ronit Pinkas-Kramarski, Antonio Piras, Natik Piri, Leonidas C Platanias, Stefanie Pöggeler, Marc Poirot, Angelo Poletti, Christian Poüs, Mercedes Pozuelo-Rubio, Mette Prætorius-Ibba, Anil Prasad, Mark Prescott, Muriel Priault, Nathalie Produit-Zengaffinen, Ann Progulske-Fox, Tassula Proikas-Cezanne, Serge Przedborski, Karin Przyklenk, Rosa Puertollano, Julien Puyal, Shu-Bing Qian, Liang Qin, Zheng-Hong Qin, Susan E Quaggin, Nina Raben, Hannah Rabinowich, Simon W Rabkin, Irfan Rahman, Abdelhaq Rami, Georg Ramm, Glenn Randall, Felix Randow, V Ashutosh Rao, Jeffrey C Rathmell, Brinda Ravikumar, Swapan K Ray, Bruce H Reed, John C Reed, Fulvio Reggiori, Anne Regnier-Vigouroux, Andreas S Reichert, John J Reiners, Russel J Reiter, Jun Ren, Jose L Revuelta, Christopher J Rhodes, Konstantinos Ritis, Elizete Rizzo, Jeffrey Robbins, Michel Roberge, Hernan Roca, Maria C Roccheri, Stéphane Rocchi, H Peter Rodemann, Santiago Rodríguez de Córdoba, Bärbel Rohrer, Igor B Roninson, Kirill Rosen, Magdalena M Rost-Roszkowska, Mustapha Rouis, Kasper M A Rouschop, Francesca Rovetta, Brian P Rubin, David C Rubinsztein, Klaus Ruckdeschel, Edmund B Rucker, Assaf Rudich, Emil Rudolf, Nelson Ruiz-Opazo, Rossella Russo, Tor Erik Rusten, Kevin M Ryan, Stefan W Ryter, David M Sabatini, Junichi Sadoshima, Tapas Saha, Tatsuya Saitoh, Hiroshi Sakagami, Yasuyoshi Sakai, Ghasem Hoseini Salekdeh, Paolo Salomoni, Paul M Salvaterra, Guy Salvesen, Rosa Salvioli, Anthony M J Sanchez, José A Sánchez-Alcázar, Ricardo Sánchez-Prieto, Marco Sandri, Uma Sankar, Poonam Sansanwal, Laura Santambrogio, Shweta Saran, Sovan Sarkar, Minnie Sarwal, Chihiro Sasakawa, Ausra Sasnauskiene, Miklós Sass, Ken Sato, Miyuki Sato, Anthony H V Schapira, Michael Scharl, Hermann M Schätzl, Wiep Scheper, Stefano Schiaffino, Claudio Schneider, Marion E Schneider, Regine Schneider-Stock, Patricia V Schoenlein, Daniel F Schorderet, Christoph Schüller, Gary K Schwartz, Luca Scorrano, Linda Sealy, Per O Seglen, Juan Segura-Aguilar, Iban Seiliez, Oleksandr Seleverstov, Christian Sell, Jong Bok Seo, Duska Separovic, Vijayasaradhi Setaluri, Takao Setoguchi, Carmine Settembre, John J Shacka, Mala Shanmugam, Irving M Shapiro, Eitan Shaulian, Reuben J Shaw, James H Shelhamer, Han-Ming Shen, Wei-Chiang Shen, Zu-Hang Sheng, Yang Shi, Kenichi Shibuya, Yoshihiro Shidoji, Jeng-Jer Shieh, Chwen-Ming Shih, Yohta Shimada, Shigeomi Shimizu, Takahiro Shintani, Orian S Shirihai, Gordon C Shore, Andriy A Sibirny, Stan B Sidhu, Beata Sikorska, Elaine C M Silva-Zacarin, Alison Simmons, Anna Katharina Simon, Hans-Uwe Simon, Cristiano Simone, Anne Simonsen, David A Sinclair, Rajat Singh, Debasish Sinha, Frank A Sinicrope, Agnieszka Sirko, Parco M Siu, Efthimios Sivridis, Vojtech Skop, Vladimir P Skulachev, Ruth S Slack, Soraya S Smaili, Duncan R Smith, María S Soengas, Thierry Soldati, Xueqin Song, Anil K Sood, Tuck Wah Soong, Federica Sotgia, Stephen A Spector, Claudia D Spies, Wolfdieter Springer, Srinivasa M Srinivasula, Leonidas Stefanis, Joan S Steffan, Ruediger Stendel, Harald Stenmark, Anastasis Stephanou, Stephan T Stern, Cinthya Sternberg, Björn Stork, Peter Stralfors, Carlos S Subauste, Xinbing Sui, David Sulzer, Jiaren Sun, Shi-Yong Sun, Zhi-Jun Sun, Joseph J Y Sung, Kuninori Suzuki, Toshihiko Suzuki, Michele S Swanson, Charles Swanton, Sean T Sweeney, Lai-King Sy, Gyorgy Szabadkai, Ira Tabas, Heinrich Taegtmeyer, Marco Tafani, Krisztina Takács-Vellai, Yoshitaka Takano, Kaoru Takegawa, Genzou Takemura, Fumihiko Takeshita, Nicholas J Talbot, Kevin S W Tan, Keiji Tanaka, Kozo Tanaka, Daolin Tang, Dingzhong Tang, Isei Tanida, Bakhos A Tannous, Nektarios Tavernarakis, Graham S Taylor, Gregory A Taylor, J Paul Taylor, Lance S Terada, Alexei Terman, Gianluca Tettamanti, Karin Thevissen, Craig B Thompson, Andrew Thorburn, Michael Thumm, Fengfeng Tian, Yuan Tian, Glauco Tocchini-Valentini, Aviva M Tolkovsky, Yasuhiko Tomino, Lars Tönges, Sharon A Tooze, Cathy Tournier, John Tower, Roberto Towns, Vladimir Trajkovic, Leonardo H Travassos, Ting-Fen Tsai, Mario P Tschan, Takeshi Tsubata, Allan Tsung, Boris Turk, Lorianne S Turner, Suresh C Tyagi, Yasuo Uchiyama, Takashi Ueno, Midori Umekawa, Rika Umemiya-Shirafuji, Vivek K Unni, Maria I Vaccaro, Enza Maria Valente, Greet Van den Berghe, Ida J van der Klei, Wouter van Doorn, Linda F van Dyk, Marjolein van Egmond, Leo A van Grunsven, Peter Vandenabeele, Wim P Vandenberghe, Ilse Vanhorebeek, Eva C Vaquero, Guillermo Velasco, Tibor Vellai, Jose Miguel Vicencio, Richard D Vierstra, Miquel Vila, Cécile Vindis, Giampietro Viola, Maria Teresa Viscomi, Olga V Voitsekhovskaja, Clarissa von Haefen, Marcela Votruba, Keiji Wada, Richard Wade-Martins, Cheryl L Walker, Craig M Walsh, Jochen Walter, Xiang-Bo Wan, Aimin Wang, Chenguang Wang, Dawei Wang, Fan Wang, Fen Wang, Guanghui Wang, Haichao Wang, Hong-Gang Wang, Horng-Dar Wang, Jin Wang, Ke Wang, Mei Wang, Richard C Wang, Xinglong Wang, Xuejun Wang, Ying-Jan Wang, Yipeng Wang, Zhen Wang, Zhigang Charles Wang, Zhinong Wang, Derick G Wansink, Diane M Ward, Hirotaka Watada, Sarah L Waters, Paul Webster, Lixin Wei, Conrad C Weihl, William A Weiss, Scott M Welford, Long-Ping Wen, Caroline A Whitehouse, J Lindsay Whitton, Alexander J Whitworth, Tom Wileman, John W Wiley, Simon Wilkinson, Dieter Willbold, Roger L Williams, Peter R Williamson, Bradly G Wouters, Chenghan Wu, Dao-Cheng Wu, William K K Wu, Andreas Wyttenbach, Ramnik J Xavier, Zhijun Xi, Pu Xia, Gengfu Xiao, Zhiping Xie, Zhonglin Xie, Da-zhi Xu, Jianzhen Xu, Liang Xu, Xiaolei Xu, Ai Yamamoto, Akitsugu Yamamoto, Shunhei Yamashina, Michiaki Yamashita, Xianghua Yan, Mitsuhiro Yanagida, Dun-Sheng Yang, Elizabeth Yang, Jin-Ming Yang, Shi Yu Yang, Wannian Yang, Wei Yuan Yang, Zhifen Yang, Meng-Chao Yao, Tso-Pang Yao, Behzad Yeganeh, Wei-Lien Yen, Jia-Jing Yin, Xiao-Ming Yin, Ook-Joon Yoo, Gyesoon Yoon, Seung-Yong Yoon, Tomohiro Yorimitsu, Yuko Yoshikawa, Tamotsu Yoshimori, Kohki Yoshimoto, Ho Jin You, Richard J Youle, Anas Younes, Li Yu, Long Yu, Seong-Woon Yu, Wai Haung Yu, Zhi-Min Yuan, Zhenyu Yue, Cheol-Heui Yun, Michisuke Yuzaki, Olga Zabirnyk, Elaine Silva-Zacarin, David Zacks, Eldad Zacksenhaus, Nadia Zaffaroni, Zahra Zakeri, Herbert J Zeh, Scott O Zeitlin, Hong Zhang, Hui-Ling Zhang, Jianhua Zhang, Jing-Pu Zhang, Lin Zhang, Long Zhang, Ming-Yong Zhang, Xu Dong Zhang, Mantong Zhao, Yi-Fang Zhao, Ying Zhao, Zhizhuang J Zhao, Xiaoxiang Zheng, Boris Zhivotovsky, Qing Zhong, Cong-Zhao Zhou, Changlian Zhu, Wei-Guo Zhu, Xiao-feng Zhu, Xiongwei Zhu, Yuangang Zhu, Teresa Zoladek, Wei-Xing Zong, Antonio Zorzano, Jürgen Zschocke, Brian Zuckerbraun.
Autophagy
Show Abstract
Hide Abstract
In 2008 we published the first set of guidelines for standardizing research in autophagy. Since then, research on this topic has continued to accelerate, and many new scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Accordingly, it is important to update these guidelines for monitoring autophagy in different organisms. Various reviews have described the range of assays that have been used for this purpose. Nevertheless, there continues to be confusion regarding acceptable methods to measure autophagy, especially in multicellular eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers or volume of autophagic elements (e.g., autophagosomes or autolysosomes) at any stage of the autophagic process vs. those that measure flux through the autophagy pathway (i.e., the complete process); thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from stimuli that result in increased autophagic activity, defined as increased autophagy induction coupled with increased delivery to, and degradation within, lysosomes (in most higher eukaryotes and some protists such as Dictyostelium) or the vacuole (in plants and fungi). In other words, it is especially important that investigators new to the field understand that the appearance of more autophagosomes does not necessarily equate with more autophagy. In fact, in many cases, autophagosomes accumulate because of a block in trafficking to lysosomes without a concomitant change in autophagosome biogenesis, whereas an increase in autolysosomes may reflect a reduction in degradative activity. Here, we present a set of guidelines for the selection and interpretation of methods for use by investigators who aim to examine macroautophagy and related processes, as well as for reviewers who need to provide realistic and reasonable critiques of papers that are focused on these processes. These guidelines are not meant to be a formulaic set of rules, because the appropriate assays depend in part on the question being asked and the system being used. In addition, we emphasize that no individual assay is guaranteed to be the most appropriate one in every situation, and we strongly recommend the use of multiple assays to monitor autophagy. In these guidelines, we consider these various methods of assessing autophagy and what information can, or cannot, be obtained from them. Finally, by discussing the merits and limits of particular autophagy assays, we hope to encourage technical innovation in the field.
Related JoVE Video
Binding of the Atg1/ULK1 kinase to the ubiquitin-like protein Atg8 regulates autophagy.
EMBO J.
Show Abstract
Hide Abstract
Autophagy is an intracellular trafficking pathway sequestering cytoplasm and delivering excess and damaged cargo to the vacuole for degradation. The Atg1/ULK1 kinase is an essential component of the core autophagy machinery possibly activated by binding to Atg13 upon starvation. Indeed, we found that Atg13 directly binds Atg1, and specific Atg13 mutations abolishing this interaction interfere with Atg1 function in vivo. Surprisingly, Atg13 binding to Atg1 is constitutive and not altered by nutrient conditions or treatment with the Target of rapamycin complex 1 (TORC1)-inhibitor rapamycin. We identify Atg8 as a novel regulator of Atg1/ULK1, which directly binds Atg1/ULK1 in a LC3-interaction region (LIR)-dependent manner. Molecular analysis revealed that Atg13 and Atg8 cooperate at different steps to regulate Atg1 function. Atg8 targets Atg1/ULK1 to autophagosomes, where it may promote autophagosome maturation and/or fusion with vacuoles/lysosomes. Moreover, Atg8 binding triggers vacuolar degradation of the Atg1-Atg13 complex in yeast, thereby coupling Atg1 activity to autophagic flux. Together, these findings define a conserved step in autophagy regulation in yeast and mammals and expand the known functions of LIR-dependent Atg8 targets to include spatial regulation of the Atg1/ULK1 kinase.
Related JoVE Video
Recycling endosomes contribute to autophagosome formation.
Autophagy
Show Abstract
Hide Abstract
Autophagosome formation is a complex cellular process, which requires major membrane rearrangements leading to the creation of a relatively large double-membrane vesicle that directs its contents to the lysosome for degradation. Although various membrane compartments have been identified as sources for autophagosomal membranes, the molecular mechanism underlying these membrane trafficking steps remains elusive. To address this question we performed a systematic analysis testing all known Tre-2/Bub2/Cdc16 (TBC) domain-containing proteins for their ability to inhibit autophagosome formation by disrupting a specific membrane trafficking step. TBC proteins are thought to act as inhibitors of Rab GTPases, which regulate membrane trafficking events. Up to 11 TBC proteins inhibit autophagy when overexpressed and one of these, TBC1D14, acts at an early stage during autophagosome formation and is involved in regulating recycling endosomal traffic. We found that the early acting autophagy proteins ATG9 and ULK1 localize to transferrin receptor (TFR)-positive recycling endosomes (RE), which are tubulated by excess TBC1D14 leading to an inhibition of autophagosome formation. Finally, transferrin (TF)-containing recycling endosomal membranes can be incorporated into newly forming autophagosomes, although it is likely that most of the autophagosome membrane is subsequently acquired from other sources.
Related JoVE Video
Autophagy regulation through Atg9 traffic.
J. Cell Biol.
Show Abstract
Hide Abstract
Rapid membrane expansion is the key to autophagosome formation during nutrient starvation. In this issue, Yamamoto et al. (2012. J. Cell Biol. http://dx.doi.org/10.1083/jcb.201202061) now provide a mechanism for vesicle-mediated initiation of autophagosome biogenesis. They show that Atg9 vesicles, produced de novo during starvation, are ?30-60 nm in size and contain ?30 molecules of Atg9. These vesicles assemble to form an autophagosome, and subsequently, the Atg9 embedded in the outer membrane is recycled to avoid degradation.
Related JoVE Video
Coiling up with SCOC and WAC: two new regulators of starvation-induced autophagy.
Autophagy
Show Abstract
Hide Abstract
Autophagy is a conserved and highly regulated catabolic pathway, transferring cytoplasmic components in autophagosomes to lysosomes for degradation and providing amino acids during starvation. In multicellular organisms autophagy plays an important role for tissue homeostasis, and deregulation of autophagy has been implicated in a broad range of diseases, including cancer and neurodegenerative disorders. In mammals, many aspects of autophagy still need to be fully elucidated: what is the exact hierarchy and relationship between ATG proteins and other factors that lead to the formation and expansion of phagophores? Where does the membrane source for autophagosome formation originate? Which signaling events trigger amino acid starvation-induced autophagy? How are the activities of ULK1/2 and the class III PtdIns3K regulated and linked to each other? To develop therapeutic strategies to manipulate autophagy in human disease, a comprehensive understanding of the molecular protein machinery mediating and regulating autophagy is required.
Related JoVE Video
TBC1D14 regulates autophagosome formation via Rab11- and ULK1-positive recycling endosomes.
J. Cell Biol.
Show Abstract
Hide Abstract
Autophagy is a bulk degradation process characterized by the formation of double membrane vesicles called autophagosomes. The exact molecular mechanism of autophagosome formation and the origin of the autophagosomal membrane remain unclear. We screened 38 human Tre-2/Bub2/Cdc16 domain-containing Rab guanosine triphosphatase-activating proteins (GAPs) and identified 11 negative regulators of starvation-induced autophagy. One of these putative RabGAPs, TBC1D14, colocalizes and interacts with the autophagy kinase ULK1. Overexpressed TBC1D14 tubulates ULK1-positive recycling endosomes (REs), impairing their function and inhibiting autophagosome formation. TBC1D14 binds activated Rab11 but is not a GAP for Rab11, and loss of Rab11 prevents TBC1D14-induced tubulation of REs. Furthermore, Rab11 is required for autophagosome formation. ULK1 and Atg9 are found on Rab11- and transferrin (Tfn) receptor (TfnR)-positive recycling endosomes. Amino acid starvation causes TBC1D14 to relocalize from REs to the Golgi complex, whereas TfnR and Tfn localize to forming autophagosomes, which are ULK1 and LC3 positive. Thus, TBC1D14- and Rab11-dependent vesicular transport from REs contributes to and regulates starvation-induced autophagy.
Related JoVE Video
Genome-wide siRNA screen reveals amino acid starvation-induced autophagy requires SCOC and WAC.
EMBO J.
Show Abstract
Hide Abstract
Autophagy is a catabolic process by which cytoplasmic components are sequestered and transported by autophagosomes to lysosomes for degradation, enabling recycling of these components and providing cells with amino acids during starvation. It is a highly regulated process and its deregulation contributes to multiple diseases. Despite its importance in cell homeostasis, autophagy is not fully understood. To find new proteins that modulate starvation-induced autophagy, we performed a genome-wide siRNA screen in a stable human cell line expressing GFP-LC3, the marker-protein for autophagosomes. Using stringent validation criteria, our screen identified nine novel autophagy regulators. Among the hits required for autophagosome formation are SCOC (short coiled-coil protein), a Golgi protein, which interacts with fasciculation and elongation protein zeta 1 (FEZ1), an ULK1-binding protein. SCOC forms a starvation-sensitive trimeric complex with UVRAG (UV radiation resistance associated gene) and FEZ1 and may regulate ULK1 and Beclin 1 complex activities. A second candidate WAC is required for starvation-induced autophagy but also acts as a potential negative regulator of the ubiquitin-proteasome system. The identification of these novel regulatory proteins with diverse functions in autophagy contributes towards a fuller understanding of autophagosome formation.
Related JoVE Video
Tales of the autophagy crusaders.
EMBO Rep.
Show Abstract
Hide Abstract
The second EMBO Conference Series meeting on Autophagy in Health and Disease took place in November 2011 in Israel. It brought together researchers from around the globe to cover the biogenesis of the autophagosome, as well as related topics including the regulation of autophagy, selective autophagy and the role of autophagy in disease and cell death.
Related JoVE Video

What is Visualize?

JoVE Visualize is a tool created to match the last 5 years of PubMed publications to methods in JoVE's video library.

How does it work?

We use abstracts found on PubMed and match them to JoVE videos to create a list of 10 to 30 related methods videos.

Video X seems to be unrelated to Abstract Y...

In developing our video relationships, we compare around 5 million PubMed articles to our library of over 4,500 methods videos. In some cases the language used in the PubMed abstracts makes matching that content to a JoVE video difficult. In other cases, there happens not to be any content in our video library that is relevant to the topic of a given abstract. In these cases, our algorithms are trying their best to display videos with relevant content, which can sometimes result in matched videos with only a slight relation.