Attila L. Kovács

Longevity pathways converge on autophagy genes to regulate life span in Caenorhabditis elegans

Aging is a multifactorial process with many mechanisms contributing to the decline. Mutations decreasing insulin/IGF-1 (insulin-like growth factor-1) or TOR (target of rapamycin) kinase-mediated signaling, mitochondrial activity and food intake each extend life span in divergent animal phyla. Understanding how these genetically distinct mechanisms interact to control longevity is a fundamental and fascinating problem in biology. Here we show that mutational inactivation of autophagy genes, which are involved in the degradation of aberrant, damaged cytoplasmic constituents accumulating in all aging cells, accelerates the rate at which the tissues age in the nematode Caenorhabditis elegans. According to our results Drosophila flies deficient in autophagy are also short-lived. We further demonstrate that reduced activity of autophagy genes suppresses life span extension in mutant nematodes with inherent dietary restriction, aberrant insulin/IGF-1 or TOR signaling, and lowered mitochondrial respiration. These findings suggest that the autophagy gene cascade functions downstream of and is inhibited by different longevity pathways in C. elegans, therefore, their effects converge on autophagy genes to slow down aging and lengthen life span. Thus, autophagy may act as a central regulatory mechanism of animal aging.

C. elegans Screen Identifies Autophagy Genes Specific to Multicellular Organisms

The molecular understanding of autophagy has originated almost exclusively from yeast genetic studies. Little is known about essential autophagy components specific to higher eukaryotes. Here we perform genetic screens in C. elegans and identify four metazoan-specific autophagy genes, named epg-2, -3, -4, and -5. Genetic analysis reveals that epg-2, -3, -4, and -5 define discrete genetic steps of the autophagy pathway. epg-2 encodes a coiled-coil protein that functions in specific autophagic cargo recognition. Mammalian homologs of EPG-3/VMP1, EPG-4/EI24, and EPG-5/mEPG5 are essential for starvation-induced autophagy. VMP1 regulates autophagosome formation by controlling the duration of omegasomes. EI24 and mEPG5 are required for formation of degradative autolysosomes. This study establishes C. elegans as a multicellular genetic model to delineate the autophagy pathway and provides mechanistic insights into the metazoan-specific autophagic process.

Inactivation of the Autophagy Gene bec-1 Triggers Apoptotic Cell Death in C. elegans

Programmed cell death (PCD) is an essential and highly orchestrated process that plays a major role in morphogenesis and tissue homeostasis during development. In humans, defects in regulation or execution of cell death lead to diabetes, neurodegenerative disorders, and cancer. Two major types of PCD have been distinguished: the caspase-mediated process of apoptosis and the caspase-independent process involving autophagy. Although apoptosis and autophagy are often activated together in response to stress, the molecular mechanisms underlying their interplay remain unclear. Here we show that BEC-1, the C. elegans ortholog of the yeast and mammalian autophagy proteins Atg6/Vps30 and Beclin 1, is essential for development. We demonstrate that BEC-1 is necessary for the function of the class III PI3 kinase LET-512/Vps34, an essential protein required for autophagy, membrane trafficking, and endocytosis. Furthermore, BEC-1 forms a complex with the antiapoptotic protein CED-9/Bcl-2, and its depletion triggers CED-3/Caspase-dependent PCD. Based on our results, we propose that bec-1 represents a link between autophagy and apoptosis, thus supporting the view that the two processes act in concerted manner in the cell death machinery.

Autophagosomal Syntaxin17-dependent lysosomal degradation maintains neuronal function in Drosophila.

Lysosomal degradation and recycling of sequestered autophagosome content is crucial to maintain proper functioning of the fly nervous system.

Seeing is believing: The impact of electron microscopy on autophagy research

Autophagy was first discovered by transmission electron microscopy more than 50 years ago. For decades, electron microscopy was the only way to reliably detect autophagic compartments in cells because no specific protein markers were known. In the 1970s, however, the introduction of biochemical methods enabled quantitative studies of autophagic-lysosomal degradation, and in the 1980s specific biochemical assays for autophagic sequestration became available. Since the identification of autophagy-related genes in the 1990s, combined fluorescence microscopy, biochemical and genetic methods have taken the leading role in autophagy research. However, electron microscopy is still needed to confirm and verify results obtained by other methods, and also to produce novel knowledge that would not be achievable by any other experimental approach. Confocal microscopy, with its ever-improving resolution, is probably the best-suited morphological approach to investigate the dynamic aspects of autophagy. However, for analyzing the ultrastructural details of the many novel organelles and mechanisms involved in specific subtypes of autophagy, the electron microscope is still indispensable. This review will summarize the impact that electron microscopy has had on autophagy research since the discovery of this self-degradation process in the mid-1950s. Astonishingly, some of the “novel” concepts and principles of autophagy, presented in the recent studies, were already proposed several decades ago by the pioneering, accurate and passionate work of virtuoso electron microscopists.

Interaction of the HOPS complex with Syntaxin 17 mediates autophagosome clearance in Drosophila

Interaction of the autophagosomal SNARE Syntaxin 17 (Syx17) with the homotypic fusion and vacuole protein–sorting (HOPS) tethering complex is necessary for the fusion of autophagosomes with lysosomes. HOPS, but not Syx17, is also required for endocytic degradation and biosynthetic transport to lysosomes and eye pigment granules.

O -GlcNAc-modification of SNAP-29 regulates autophagosome maturation

The mechanism by which nutrient status regulates the fusion of autophagosomes with endosomes/lysosomes is poorly understood. Here, we report that O-linked β-N-acetylglucosamine (O-GlcNAc) transferase (OGT) mediates O-GlcNAcylation of the SNARE protein SNAP-29 and regulates autophagy in a nutrient-dependent manner. In mammalian cells, OGT knockdown, or mutating the O-GlcNAc sites in SNAP-29, promotes the formation of a SNAP-29-containing SNARE complex, increases fusion between autophagosomes and endosomes/lysosomes, and promotes autophagic flux. In Caenorhabditis elegans, depletion of ogt-1 has a similar effect on autophagy; moreover, expression of an O-GlcNAc-defective SNAP-29 mutant facilitates autophagic degradation of protein aggregates. O-GlcNAcylated SNAP-29 levels are reduced during starvation in mammalian cells and in C. elegans. Our study reveals a mechanism by which O-GlcNAc-modification integrates nutrient status with autophagosome maturation.

Membrane transport in Caenorhabditis elegans: an essential role for VPS34 at the nuclear membrane

Here we present a detailed genetic analysis of let‐512/vps34 that encodes the Caenorhabditis elegans homologue of the yeast phosphatidylinositol 3‐kinase Vps34p. LET‐512/VPS34 has essential functions and is ubiquitously expressed in all tissues and developmental stages. It accumulates at a perinuclear region, and mutations in let‐512/vps34 result in an expansion of the outer nuclear membrane as well as in a mislocalization and subsequent complete lack of expression of LRP‐1, a C.elegans LDL receptor normally associated with the apical surface of hypodermal cells. Using a GFP::2xFYVE fusion protein we found that the phosphatidylinositol 3‐phosphate (PtdIns 3‐P) product of LET‐512/VPS34 is associated with a multitude of intracellular membranes and vesicles located at the periphery, including endocytic vesicles. We propose that LET‐512/VPS34 is required for membrane transport from the outer nuclear membrane towards the cell periphery. Thus, LET‐512/VPS34 may regulate the secretory pathway in a much broader range of compartments than was previously suggested for the yeast orthologue.

Wohlfahrtiimonas chitiniclastica gen. nov., sp. nov., a new gammaproteobacterium isolated from Wohlfahrtia magnifica (Diptera: Sarcophagidae)

New Gammaproteobacteria were isolated from 3rd stage fly larvae of the parasitic fly Wohlfahrtia magnifica. Phylogenetic analysis of the new isolates showed that these bacteria belong to a distinct lineage close to Ignatzschineria larvae, which was originally isolated from the same species of fly. The low similarity values in 16S rRNA gene sequences (93.8-94.8 %), and differences in fatty acid profiles, RiboPrint patterns, MALDI-TOF mass spectra of cell extracts, and physiological and biochemical characteristics differentiate the isolates from the type strain of Ignatzschineria larvae (DSM 13226T), and indicate that our isolates represent a new genus within the Gammaproteobacteria. The major isoprenoid quinone of the strains is Q8, the major fatty acids are C18 : 1 and C14 : 0, and the predominant polar lipids are phosphatidylglycerol, phosphatidylethanolamine and phosphatidylserine. The G+C content of the DNA of the type strain is 44.3 mol%. The name Wohlfahrtiimonas chitiniclastica gen. nov., sp. nov., is proposed for this novel genus and species. The type strain is S5T (=DSM 18708T=CCM 7401T).

Influence of autophagy genes on ion-channel-dependent neuronal degeneration in Caenorhabditis elegans.

Necrotic cell death is a common feature in numerous human neurodegenerative disorders. In the nematode Caenorhabditis elegans, gain-of-function mutations in genes that encode specific ion channel subunits such as the degenerins DEG-1 and MEC-4, and the acetylcholine receptor subunit DEG-3 lead to necrotic-like degeneration of a subset of neurons. Neuronal demise caused by ion channel hyperactivity is accompanied by intense degradation of cytoplasmic contents, dramatic membrane infolding and vacuole formation; however, the cellular pathways underlying such processes remain largely unknown. Here we show that the function of three autophagy genes, whose yeast and mammalian orthologs are implicated in cytoplasmic self-degradation, membrane trafficking and the cellular response to starvation, contributes to ion-channel-dependent neurotoxicity in C. elegans. Inactivation of unc-51, bec-1 and lgg-1, the worm counterparts of the yeast autophagy genes Atg1, Atg6 and Atg8 respectively, partially suppresses degeneration of neurons with toxic ion channel variants. We also demonstrate that the TOR-kinase-mediated signaling pathway, a nutrient sensing system that downregulates the autophagy gene cascade, protects neurons from undergoing necrotic cell death, whereas nutrient deprivation promotes necrosis. Our findings reveal a role for autophagy genes in neuronal cell loss in C. elegans.