The C. elegans ATG101 homolog EPG-9 directly interacts with EPG-1/Atg13 and is essential for autophagy

Autophagy is an evolutionarily conserved catabolic process that involves the engulfment of cytoplasmic contents in a closed double-membrane structure, called the autophagosome, and their subsequent delivery to the vacuole/lysosomes for degradation. Genetic screens in Saccharomyces cerevisiae have identified more than 30 autophagy-related (Atg) genes that are essential for autophagosome formation. Here we isolated a novel autophagy gene, epg-9, whose loss of function causes defective autophagic degradation of a variety of protein aggregates during C. elegans embryogenesis. Mutations in epg-9 also reduce survival of animals under food depletion conditions. epg-9 mutants exhibit autophagy phenotypes characteristic of those associated with loss of function of unc-51/Atg1 and epg-1/Atg13. epg-9 encodes a protein with significant homology to mammalian ATG101. EPG-9 directly interacts with EPG-1/Atg13. Our study indicates that EPG-9 forms a complex with EPG-1 in the aggrephagy pathway in C. elegans.     

epg-1 functions in autophagy-regulated processes and may encode a highly divergent Atg13 homolog in C. elegans

Autophagy is an evolutionarily conserved intracellular catabolic system for degradation of long-lived proteins or damaged organelles. In this study, we have identified and characterized a new gene, epg-1, that plays a role in the autophagy pathway in C. elegans. Loss of function of epg-1 causes defects in various autophagy-regulated processes, including degradation of aggregate-prone proteins and optimal survival of animals during starvation. epg-1 encodes a novel protein that shows limited sequence similarity to the yeast autophagy protein Atg13. epg-1 displays a similar expression pattern to, and directly interacts with, the C. elegans Atg1 homolog UNC-51, suggesting that epg-1 encodes a divergent functional homolog of Atg13 in C. elegans.     

The two C. elegans ATG-16 homologs have partially redundant functions in the basal autophagy pathway

The presence of multiple homologs of the same yeast ATG genes endows an extra layer of complexity on the autophagic machinery in higher eukaryotes. The physiological function of individual homologs in the autophagy pathway remains poorly understood. Here we characterized the function of the two atg16 homologs, atg-16.1 and atg-16.2, in the autophagy pathway in C. elegans. We showed that atg-16.2 mutants exhibit a stronger autophagic defect than atg-16.1 mutants. atg-16.2; atg-16.1 double mutants display a much more severe defect than either single mutant. ATG-16.1 and ATG-16.2 interact with themselves and each other and also directly associate with ATG-5. atg-16.1 mutant embryos exhibit a wild-type expression and distribution pattern of LGG-1/Atg8, while LGG-1 puncta are markedly fewer in number and weaker in intensity in atg-16.2 mutants. In atg-16.2; atg-16.1 double mutants, the lipidated form of LGG-1 accumulates, but LGG-1 puncta are completely absent. ATG-16.2 ectopically expressed on the plasma membrane provides novel sites of LGG-1 puncta formation. We also demonstrated that the C-terminal WD repeats are dispensable for the role of atg-16.2 in aggrephagy (the degradation of protein aggregates by autophagy). Genetic epistasis analysis placed atg-16.2 upstream of atg-2, epg-6, and atg-18. Our study indicated that C. elegans ATG-16s are involved in specifying LGG-1 puncta formation and the two ATG-16 homologs have partially redundant yet distinct functions in the aggrephagy pathway.     

Autophagy Genes Protect Against Disease Caused by Polyglutamine Expansion Proteins in Caenorhabditis elegans

Expanded polyglutamine (polyQ) proteins aggregate intracellularly in Huntington’s disease and other neurodegenerative disorders. The lysosomal degradation pathway, autophagy, is known to promote clearance of polyQ protein aggregates in cultured cells. Moreover, basal autophagy in neuronal cells in mice prevents neurodegeneration by suppressing the accumulation of abnormal intracellular proteins. However, it is not yet known whether autophagy genes play a role in vivo in protecting against disease caused by mutant aggregate-prone, expanded polyQ proteins. To examine this question, we used two models of polyQ-induced toxicity in C. elegans, including the expression of polyQ40 aggregates in muscle and the expression of a human huntingtin disease fragment containing a polyQ tract of 150 residues (Htn-Q150) in ASH sensory neurons. Here, we show that genetic inactivation of autophagy genes accelerates the accumulation of polyQ40 aggregates in C. elegans muscle cells and exacerbates polyQ40-induced muscle dysfunction. Autophagy gene inactivation also increases the accumulation of Htn-Q150 aggregates in C. elegans ASH sensory neurons and results in enhanced neurodegeneration. These data provide in vivo genetic evidence that autophagy genes suppress the accumulation of polyQ aggregates and protect cells from disease caused by polyQ toxicity.     

Autophagy genes promote apoptotic cell corpse clearance

Autophagy is a catabolic process through which damaged organelles and protein aggregates are delivered to lysosomes for degradation. Autophagy genes are reported to promote exposure of “eat me” signals on the surface of apoptotic cells, but whether they function in engulfing cells is not clear. Recently, we found that the autophagy mutants atg-18 and epg-5 are defective in removing apoptotic cells derived from the C. elegans Q neuroblast, a phenotype that can be fully rescued by expression of ATG-18 and EPG-5 in the engulfing cell. Loss of ATG-18 or EPG-5 does not affect cell corpse engulfment but causes defects in phagosomal recruitment of RAB-5 and RAB-7 and formation of phagolysosomes. EPG-5, ATG-18 and LGG-1 are sequentially recruited to phagosomes, suggesting that they function at different steps of phagosomal maturation. Our studies indicate that autophagy genes function sequentially to promote apoptotic cell corpse degradation in the engulfing cell.     

Autophagy is Required for Dietary Restriction-Mediated Life Span Extension in C. elegans

Dietary restriction extends life span in diverse species including Canorhabditis elegans. However, the downstream cellular targets regulated by dietary restriction are largely unknown. Autophagy, an evolutionary conserved lysosomal degradation pathway, is induced under starvation conditions and regulates life span in insulin signaling C. elegans mutants. We now report that two essential autophagy genes (bec-1 and Ce-atg7) are required for the longevity phenotype of the C. elegans dietary restriction mutant (eat-2ad1113) animals. Thus, we propose that autophagy mediates the effect, not only of insulin signaling, but also of dietary restriction on the regulation of C. elegans life span. Since autophagy and longevity control are highly conserved from C. elegans to mammals, a similar role for autophagy in dietary restriction-mediated life span extension may also exist in mammals.     

Autophagy protects against hypoxic injury in C. elegans

Macroautophagy has been implicated in a variety of pathological processes. Hypoxic/ischemic cellular injury is one such process in which autophagy has emerged as an important regulator. In general, autophagy is induced after an hypoxic/ischemic insult; however, whether the induction of autophagy promotes cell death or recovery is controversial and appears to be context dependent. We have developed C. elegans as a genetically tractable model for the study of hypoxic cell injury. Both necrosis and apoptosis are mechanisms of cell death following hypoxia in C. elegans. However, the role of autophagy in hypoxic injury in C. elegans has not been examined. Here, we found that RNAi knockdown of the C. elegans homologs of beclin 1/Atg6 (bec-1) and LC3/Atg8 (lgg-1, lgg-2), and mutation of Atg1 (unc-51) decreased animal survival after a severe hypoxic insult. Acute inhibition of autophagy by the type III phosphatidylinositol 3-kinase inhibitors, 3-methyladenine and Wortmannin, also sensitized animals to hypoxic death. Hypoxia-induced neuronal and myocyte injury as well as necrotic cellular morphology were increased by RNAi knockdown of BEC-1. Hypoxia increased the expression of a marker of autophagosomes in a bec-1-dependent manner. Finally, we found that the hypoxia hypersensitive phenotype of bec-1(RNAi) animals could be blocked by loss-of-function mutations in either the apoptosis or necrosis pathway. These results argue that inhibition of autophagy sensitizes C. elegans and its cells to hypoxic injury and that this sensitization is blocked or circumvented when either of the two major cell death mechanisms is inhibited.     

The scaffold protein EPG-7 links cargo–receptor complexes with the autophagic assembly machinery

The mechanism by which protein aggregates are selectively degraded by autophagy is poorly understood. Previous studies show that a family of Atg8-interacting proteins function as receptors linking specific cargoes to the autophagic machinery. Here we demonstrate that during Caenorhabditis elegans embryogenesis, epg-7 functions as a scaffold protein mediating autophagic degradation of several protein aggregates, including aggregates of the p62 homologue SQST-1, but has little effect on other autophagy-regulated processes. EPG-7 self-oligomerizes and is degraded by autophagy independently of SQST-1. SQST-1 directly interacts with EPG-7 and colocalizes with EPG-7 aggregates in autophagy mutants. Mutations in epg-7 impair association of SQST-1 aggregates with LGG-1/Atg8 puncta. EPG-7 interacts with multiple ATG proteins and colocalizes with ATG-9 puncta in various autophagy mutants. Unlike core autophagy genes, epg-7 is dispensable for starvation-induced autophagic degradation of substrate aggregates. Our results indicate that under physiological conditions a scaffold protein endows cargo specificity and also elevates degradation efficiency by linking the cargo–receptor complex with the autophagic machinery.     

The WD40 repeat PtdIns(3)P-binding protein EPG-6 regulates progression of omegasomes to autophagosomes

PtdIns(3)P plays critical roles in the autophagy pathway. However, little is known about how PtdIns(3)P effectors act with autophagy proteins in autophagosome formation. Here we identified an essential autophagy gene in C.?elegans, epg-6, which encodes a WD40 repeat-containing protein with PtdIns(3)P-binding activity. EPG-6 directly interacts with ATG-2. epg-6 and atg-2 regulate progression of omegasomes to autophagosomes, and their loss of function?causes accumulation of enlarged early autophagic structures. Another WD40 repeat PtdIns(3)P effector, ATG-18, plays a distinct role in autophagosome formation. We also established the hierarchical relationship of autophagy genes in degradation of?protein aggregates and revealed that the UNC-51/Atg1 complex, EPG-8/Atg14, and binding of lipidated LGG-1 to protein aggregates are required for?omegasome formation. Our study demonstrates that autophagic PtdIns(3)P effectors play distinct roles in autophagosome formation and also provides?a framework for understanding the concerted action of autophagy genes in protein aggregate degradation.     

Autophagy Regulates Ageing in C. elegans

The role of autophagy in ageing regulation has been suggested based on studies in C. elegans, in which knockdown of the expression of bec-1 (ortholog of the yeast and mammalian autophagy genes ATG6/VPS30 and beclin 1, respectively) shortens the lifespan of the daf-2(e1370) mutant C. elegans. However, Beclin1/ATG6 is also known to be involved in other cellular functions in addition to autophagy. In the current study, we knocked down two other autophagy genes, atg-7 and atg-12, in C. elegans using RNAi. We showed that RNAi shortened the lifespan of both wild type and daf-2 mutant C. elegans, providing strong support for a role of autophagy in ageing regulation.     

Genome-Wide Analysis Reveals Novel Genes Essential for Heme Homeostasis in Caenorhabditis elegans

Heme is a cofactor in proteins that function in almost all sub-cellular compartments and in many diverse biological processes. Heme is produced by a conserved biosynthetic pathway that is highly regulated to prevent the accumulation of heme—a cytotoxic, hydrophobic tetrapyrrole. Caenorhabditis elegans and related parasitic nematodes do not synthesize heme, but instead require environmental heme to grow and develop. Heme homeostasis in these auxotrophs is, therefore, regulated in accordance with available dietary heme. We have capitalized on this auxotrophy in C. elegans to study gene expression changes associated with precisely controlled dietary heme concentrations. RNA was isolated from cultures containing 4, 20, or 500 µM heme; derived cDNA probes were hybridized to Affymetrix C. elegans expression arrays. We identified 288 heme-responsive genes (hrgs) that were differentially expressed under these conditions. Of these genes, 42% had putative homologs in humans, while genomes of medically relevant heme auxotrophs revealed homologs for 12% in both Trypanosoma and Leishmania and 24% in parasitic nematodes. Depletion of each of the 288 hrgs by RNA–mediated interference (RNAi) in a transgenic heme-sensor worm strain identified six genes that regulated heme homeostasis. In addition, seven membrane-spanning transporters involved in heme uptake were identified by RNAi knockdown studies using a toxic heme analog. Comparison of genes that were positive in both of the RNAi screens resulted in the identification of three genes in common that were vital for organismal heme homeostasis in C. elegans. Collectively, our results provide a catalog of genes that are essential for metazoan heme homeostasis and demonstrate the power of C. elegans as a genetic animal model to dissect the regulatory circuits which mediate heme trafficking in both vertebrate hosts and their parasites, which depend on environmental heme for survival.     

Selective endosomal microautophagy is starvation-inducible in Drosophila

Autophagy delivers cytosolic components to lysosomes for degradation and is thus essential for cellular homeostasis and to cope with different stressors. As such, autophagy counteracts various human diseases and its reduction leads to aging-like phenotypes. Macroautophagy (MA) can selectively degrade organelles or aggregated proteins, whereas selective degradation of single proteins has only been described for chaperone-mediated autophagy (CMA) and endosomal microautophagy (eMI). These 2 autophagic pathways are specific for proteins containing KFERQ-related targeting motifs. Using a KFERQ-tagged fluorescent biosensor, we have identified an eMI-like pathway in Drosophila melanogaster. We show that this biosensor localizes to late endosomes and lysosomes upon prolonged starvation in a KFERQ- and Hsc70-4- dependent manner. Furthermore, fly eMI requires endosomal multivesicular body formation mediated by ESCRT complex components. Importantly, induction of Drosophila eMI requires longer starvation than the induction of MA and is independent of the critical MA genes atg5, atg7, and atg12. Furthermore, inhibition of Tor signaling induces eMI in flies under nutrient rich conditions, and, as eMI in Drosophila also requires atg1 and atg13, our data suggest that these genes may have a novel, additional role in regulating eMI in flies. Overall, our data provide the first evidence for a novel, starvation-inducible, catabolic process resembling endosomal microautophagy in the Drosophila fat body.     

C. elegans patched-3 is an essential gene implicated in osmoregulation and requiring an intact permease transporter domain

The nematode Caenorhabditis elegans has retained a rudimentary Hedgehog (Hh) signalling pathway; Hh and Smoothened (Smo) homologs are absent, but two highly related Patched gene homologs, ptc-1 and ptc-3, and 24 ptc-related (ptr) genes are present. We previously showed that ptc-1 is essential for germ line cytokinesis. Here, we report that ptc-3 is also an essential gene; the absence of ptc-3 results in a late embryonic lethality due to an apparent defect in osmoregulation. Rescue of a ptc-3 mutant with a ptc-3::gfp translational reporter reveals that ptc-3 is dynamically expressed in multiple tissues across development. Consistent with this pattern of expression, ptc-3(RNAi) reveals an additional postembryonic requirement for ptc-3 activity. Tissue-specific promoter studies indicate that hypodermal expression of ptc-3 is required for normal development. Missense changes in key residues of the sterol sensing domain (SSD) and the permease transporter domain GxxxD/E motif reveal that the transporter domain is essential for PTC-3 activity, whereas an intact SSD is dispensable. Taken together, our studies indicate that PTC proteins have retained essential roles in C. elegans that are independent of Smoothened (Smo). These observations reveal novel, and perhaps ancestral, roles for PTC proteins.     

An overview of C. Elegans trafficking mutants

It is almost 40 years since Sydney Brenner introduced Caenorhabditis elegans as a model genetic system. During that time mutants with defects in intracellular trafficking have been identified in a diverse range of screens for abnormalities. This should, of course, come as no surprise as it is hard to imagine any biological process in which the regulated movement of vesicles within the cells is not critical at some step. Almost all of these genes have mammalian homologs, and yet the role of many of these homologs has not been investigated. Perhaps the protein that regulates your favorite trafficking step has already been identified in C. elegans? Here I provide a brief overview of those trafficking mutants identified in C. elegans and where you can read more about them.     

The kinases male germ cell‐associated kinase and cell cycle‐related kinase regulate kinesin‐2 motility in Caenorhabditis elegans neuronal cilia

Kinesin‐2 motors power anterograde intraflagellar transport (IFT), a highly ordered process that assembles and maintains cilia. However, it remains elusive how kinesin‐2 motors are regulated in vivo. Here, we performed forward genetic screens to isolate suppressors that rescue the ciliary defects of OSM‐3‐kinesin (homolog of mammalian homodimeric kinesin‐2 KIF17) mutants in Caenorhabditis elegans. We identified the C. elegans dyf‐5 and dyf‐18, which encode the homologs of mammalian male germ cell‐associated kinase and cell cycle‐related kinase, respectively. Using time‐lapse fluorescence microscopy, we show that DYF‐5 and DYF‐18 are IFT cargo molecules and are enriched at the distal segments of sensory cilia. Mutations of dyf‐5 and dyf‐18 generate elongated cilia and ectopic localization of the heterotrimeric kinesin‐2 (kinesin‐II) at the ciliary distal segments. Genetic analyses reveal that dyf‐5 and dyf‐18 are important for stabilizing the interaction between IFT particles and OSM‐3‐kinesin. Our data suggest that DYF‐5 and DYF‐18 act in the same pathway to promote handover between kinesin‐II and OSM‐3 in sensory cilia.      

The tissue- and developmental stage-specific involvement of autophagy genes in aggrephagy

ABSTRACT

Genetic screens have identified two sets of genes that act at distinct steps of basal autophagy in higher eukaryotes: the pan-eukaryotic ATG genes and the metazoan-specific EPG genes. Very little is known about whether these core macroautophagy/autophagy genes are differentially employed during multicellular organism development. Here we analyzed the function of core autophagy genes in autophagic removal of SQST-1/SQSTM1 during C. elegans development. We found that loss of function of genes acting at distinct steps in the autophagy pathway causes different patterns of SQST-1 accumulation in different tissues and developmental stages. We also identified that the calpain protease clp-2 acts in a cell context-specific manner in SQST-1 degradation. clp-2 is required for degradation of SQST-1 in the hypodermis and neurons, but is dispensable in the body wall muscle and intestine. Our results indicate that autophagy genes are differentially employed in a tissue- and stage-specific manner during the development of multicellular organisms.

Abbreviations: ATG: autophagy related; CLP: calpain family; EPG: ectopic PGL granules; ER: endoplasmic reticulum; ESCRT: endosomal sorting complex required for transport; GFP: green fluorescent protein; LGG-1/LC3: LC3, GABARAP and GATE-16 family; MIT: microtubule interacting and transport; PGL: P granule abnormality protein; SQST-1: sequestosome-related; UPS: ubiquitin-proteasome system