Molecular mechanism of autophagy in yeast, Saccharomyces cerevisiae

Bulk degradation of cytosol and organelles is important for cellular homeostasis under nutrient limitation, cell differentiation and development. This process occurs in a lytic compartment, and autophagy is the major route to the lysosome and/or vacuole. We found that yeast, Saccharomyces cerevisiae, induces autophagy under various starvation conditions. The whole process is essentially the same as macroautophagy in higher eukaryotic cells. However, little is known about the mechanism of autophagy at a molecular level. To elucidate the molecules involved, a genetic approach was carried out and a total of 16 autophagy-defective mutants (apg) were isolated. So far, 14 APG genes have been cloned. Among them we recently found a unique protein conjugation system essential for autophagy. The C-terminal glycine residue of a novel modifier protein Apg12p, a 186-amino-acid protein, is conjugated to a lysine residue of Apg5p, a 294-amino-acid protein, via an isopeptide bond. We also found that apg7 and apg10 mutants were unable to form an Apg12p-Apg5p conjugate. The conjugation reaction is mediated via Apg7p, E1-like activating enzyme and Apg10p, indicating that it is a ubiquitination-like system. These APG genes have mammalian homologues, suggesting that the Apg12 system is conserved from yeast to human. Further molecular and cell biological analyses of APG gene products will give us crucial clues to uncover the mechanism and regulation of autophagy.     

Role of the Apg12 conjugation system in mammalian autophagy

The Apg12 system is one of the ubiquitin-like protein conjugation systems conserved in eukaryotes. It was first discovered in yeast during systematic analyses of the apg mutants defective in autophagy, which is the intracellular bulk degradation system. Covalent attachment of Apg12-Apg5 is essential for autophagy. Enzymes catalyzing this conjugation reaction were also identified based on the apg mutant analyses. These are Apg7 and Apg10, corresponding to E1 and E2 enzymes, respectively. Studies using mammalian cells further revealed the function of the Apg12 system. The Apg12-Apg5 conjugate localizes to elongating autophagic isolation membranes. Apg12 conjugation of Apg5 is required for elongation of the isolation membrane to form a complete spherical autophagosome. Discovery of the Apg12 system has facilitated our understanding of the molecular mechanism of autophagosome formation.     

The human homolog of Saccharomyces cerevisiae Apg7p is a Protein-activating enzyme for multiple substrates including human Apg12p, GATE-16, GABARAP, and MAP-LC3

Autophagy is a process that involves the bulk degradation of cytoplasmic components by the lysosomal/vacuolar system. In the yeast, Saccharomyces cerevisiae, an autophagosome is formed in the cytosol. The outer membrane of the autophagosome is fused with the vacuole, releasing the inner membrane structure, an autophagic body, into the vacuole. The autophagic body is subsequently degraded by vacuolar hydrolases. Taking advantage of yeast genetics, apg (autophagy-defective) mutants were isolated that are defective in terms of formation of autophagic bodies under nutrient starvation conditions. One of the APG gene products, Apg12p, is covalently attached to Apg5p via the C-terminal Gly of Apg12p as in the case of ubiquitylation, and this conjugation is essential for autophagy. Apg7p is a novel E1 enzyme essential for the Apg12p-conjugation system. In mammalian cells, the human Apg12p homolog (hApg12p) also conjugates with the human Apg5p homolog. In this study, the unique characteristics of hApg7p are shown. A two-hybrid experiment indicated that hApg12p interacts with hApg7p. Site-directed mutagenesis revealed that Cys(572) of hApg7p is an authentic active site cysteine residue essential for the formation of the hApg7p.hApg12p intermediate. Overexpression of hApg7p enhances the formation of the hApg5p.hApg12p conjugate, indicating that hApg7p is an E1-like enzyme essential for the hApg12p conjugation system. Cross-linking experiments and glycerol-gradient centrifugation analysis showed that the mammalian Apg7p homolog forms a homodimer as in yeast Apg7p. Each of three human Apg8p counterparts, i.e. the Golgi-associated ATPase enhancer of 16 kDa, GABA(A) receptor-associated protein, and microtubule-associated protein light chain 3, coimmunoprecipitates with hApg7p and conjugates with mutant hApg7p(C572S) to form a stable intermediate via an ester bond. These results indicate that hApg7p is an authentic protein-activating enzyme for hApg12p and the three Apg8p homologs.     

Apg5p functions in the sequestration step in the cytoplasm-to-vacuole targeting and macroautophagy pathways

The cytoplasm-to-vacuole targeting (Cvt) pathway and macroautophagy are dynamic events involving the rearrangement of membrane to form a sequestering vesicle in the cytosol, which subsequently delivers its cargo to the vacuole. This process requires the concerted action of various proteins, including Apg5p. Recently, it was shown that another protein required for the import of aminopeptidase I (API) and autophagy, Apg12p, is covalently attached to Apg5p through the action of an E1-like enzyme, Apg7p. We have undertaken an analysis of Apg5p function to gain a better understanding of the role of this novel nonubiquitin conjugation reaction in these import pathways. We have generated the first temperature-sensitive mutant in the Cvt pathway, designated apg5(ts). Biochemical analysis of API import in the apg5(ts) strain confirmed that Apg5p is directly required for the import of API via the Cvt pathway. By analyzing the stage of API import that is blocked in the apg5(ts) mutant, we have determined that Apg5p is involved in the sequestration step and is required for vesicle formation and/or completion.     

Macroautophagy is dispensable for intracellular replication of Legionella pneumophila in Dictyostelium discoideum

The Gram-negative bacterium Legionella pneumophila is a facultative intracellular pathogen of free-living amoebae and mammalian phagocytes. L. pneumophila is engulfed in phagosomes that initially avoid fusion with lysosomes. The phagosome associates with endoplasmic reticulum (ER) and mitochondria and eventually resembles ER. The morphological similarity of the replication vacuole to autophagosomes, and enhanced bacterial replication in response to macroautophagy-inducing starvation, led to the hypothesis that L. pneumophila infection requires macroautophagy. As L. pneumophila replicates in Dictyostelium discoideum, and macroautophagy genes have been identified and mutated in D. discoideum, we have taken a genetic and cell biological approach to evaluate the relationship between host macroautophagy and intracellular replication of L. pneumophila. Mutation of the apg1, apg5, apg6, apg7 and apg8 genes produced typical macroautophagy defects, including reduced bulk protein degradation and cell viability during starvation. We show that L. pneumophila replicates normally in D. discoideum macroautophagy mutants and produces replication vacuoles that are morphologically indistinguishable from those in wild-type D. discoideum. Furthermore, a green fluorescent protein (GFP)-tagged marker of autophagosomes, Apg8, does not systematically co-localize with DsRed-labelled L. pneumophila. We conclude that macroautophagy is dispensable for L. pneumophila intracellular replication in D. discoideum.     

Ald6p is a preferred target for autophagy in yeast, Saccharomyces cerevisiae

Macroautophagy is the process of intracellular bulk protein degradation induced by nutrient starvation and is generally considered to be a nonselective degradation of cytosolic enzymes and organelles. However, it remains a possibility that some proteins may be preferentially degraded by autophagy. In this study, we have performed a systematic analysis on the substrate selectivity of autophagy in yeast, Saccharomyces cerevisiae, using two-dimensional PAGE. We performed a differential screen on wild-type and Deltaatg7/apg7 autophagy-deficient cells and found that cytosolic acetaldehyde dehydrogenase (Ald6p) decreased under nitrogen starvation. As assessed by immunoblot, Ald6p was reduced by greater than 82% after 24 h of nitrogen starvation. This reduction was dependent on Atg/Apg proteins and vacuolar proteases but was not dependent on the proteasome or the cytoplasm to vacuole targetting (Cvt) pathway. Using pulse-chase and subcellular fractionation, we have also demonstrated that Ald6p was preferentially transported to vacuoles via autophagosomes. Deltaatg7 Deltaald6 double mutant cells were able to maintain higher rates of viability than Deltaatg7 cells under nitrogen starvation, and Ald6p-overexpressing cells were not able to maintain high rates of viability. Furthermore, the Ald6p(C306S) mutant, which lacks enzymatic activity, had viability rates similar to Deltaald6 cells. Ald6p enzymatic activity may be disadvantageous for survival under nitrogen starvation; therefore, yeast cells may preferentially eliminate Ald6p via autophagy.     

Apg2p functions in autophagosome formation on the perivacuolar structure

Autophagy is a degradative process in which cytoplasmic components are non-selectively sequestered by double-membrane structures, termed autophagosomes, and transported to the vacuole. We have identified and characterized a novel protein Apg2p essential for autophagy in yeast. Biochemical and fluorescence microscopic analyses indicate that Apg2p functions at the step of autophagosome formation. Apg2p localizes to some membranous structure distinct from any known organelle. Using fluorescent protein-tagged Apg2p, we showed that Apg2p localizes to a dot structure close to the vacuole, where Apg8p also exists, but not on autophagosomes unlike Apg8p. This punctate localization of Apg2p depends on the function of Apg1p kinase, phosphatidylinositol 3-kinase complex and Apg9p. Apg2p(G83E), encoded by an apg2-2 allele, shows a severely reduced activity of autophagy and a dispersed localization in the cytoplasm. Overexpression of the mutant Apg2p lessens the defect in autophagy. These results suggest that the dot structure is physiologically important. Apg2p and Apg8p are independently recruited to the structure but coordinately function there to form the autophagosome.     

Apg7p/Cvt2p: A novel protein-activating enzyme essential for autophagy

In the yeast Saccharomyces cerevisiae, the Apg12p-Apg5p conjugating system is essential for autophagy. Apg7p is required for the conjugation reaction, because Apg12p is unable to form a conjugate with Apg5p in the apg7/cvt2 mutant. Apg7p shows a significant similarity to a ubiquitin-activating enzyme, Uba1p. In this article, we investigated the function of Apg7p as an Apg12p-activating enzyme. Hemagglutinin-tagged Apg12p was coimmunoprecipitated with c-myc-tagged Apg7p. A two-hybrid experiment confirmed the interaction. The coimmunoprecipitation was sensitive to a thiol-reducing reagent. Furthermore, a thioester conjugate of Apg7p was detected in a lysate of cells overexpressing both Apg7p and Apg12p. These results indicated that Apg12p interacts with Apg7p via a thioester bond. Mutational analyses of Apg7p suggested that Cys507 of Apg7p is an active site cysteine and that both the ATP-binding domain and the cysteine residue are essential for the conjugation of Apg7p with Apg12p to form the Apg12p-Apg5p conjugate. Cells expressing mutant Apg7ps, Apg7pG333A, or Apg7pC507A showed defects in autophagy and cytoplasm-to-vacuole targeting of aminopeptidase I. These results indicated that Apg7p functions as a novel protein-activating enzyme necessary for Apg12p-Apg5p conjugation.     

Antagonistic controls of autophagy and glycogen accumulation by Snf1p, the yeast homolog of AMP-activated protein kinase, and the cyclin-dependent kinase Pho85p

In the yeast Saccharomyces cerevisiae, glycogen is accumulated as a carbohydrate reserve when cells are deprived of nutrients. Yeast mutated in SNF1, a gene encoding a protein kinase required for glucose derepression, has diminished glycogen accumulation and concomitant inactivation of glycogen synthase. Restoration of synthesis in an snf1 strain results only in transient glycogen accumulation, implying the existence of other SNF1-dependent controls of glycogen storage. A genetic screen revealed that two genes involved in autophagy, APG1 and APG13, may be regulated by SNF1. Increased autophagic activity was observed in wild-type cells entering the stationary phase, but this induction was impaired in an snf1 strain. Mutants defective for autophagy were able to synthesize glycogen upon approaching the stationary phase, but were unable to maintain their glycogen stores, because subsequent synthesis was impaired and degradation by phosphorylase, Gph1p, was enhanced. Thus, deletion of GPH1 partially reversed the loss of glycogen accumulation in autophagy mutants. Loss of the vacuolar glucosidase, SGA1, also protected glycogen stores, but only very late in the stationary phase. Gph1p and Sga1p may therefore degrade physically distinct pools of glycogen. Pho85p is a cyclin-dependent protein kinase that antagonizes SNF1 control of glycogen synthesis. Induction of autophagy in pho85 mutants entering the stationary phase was exaggerated compared to the level in wild-type cells, but was blocked in apg1 pho85 mutants. We propose that Snf1p and Pho85p are, respectively, positive and negative regulators of autophagy, probably via Apg1 and/or Apg13. Defective glycogen storage in snf1 cells can be attributed to both defective synthesis upon entry into stationary phase and impaired maintenance of glycogen levels caused by the lack of autophagy.     

Apg16p is required for the function of the Apg12p-Apg5p conjugate in the yeast autophagy pathway.

Autophagy is an intracellular bulk degradation system that is ubiquitous for eukaryotic cells. In this process, cytoplasmic components are enclosed in autophagosomes and delivered to lysosomes/vacuoles. We recently found that a protein conjugation system, in which Apg12p is covalently attached to Apg5p, is indispensable for autophagy in yeast. Here, we describe a novel coiled-coil protein, Apg16p, essential for autophagy. Apg16p interacts with Apg12p-conjugated Apg5p and less preferentially with unconjugated Apg5p. Moreover, the coiled-coil domain of Apg16p mediates self-multimerization that leads to cross-linking of Apg5p molecules and formation of a stable protein complex. Apg16p is not essential for the Apg12p-Apg5p conjugation reaction. These results suggest that the Apg12p-Apg5p conjugate requires Apg16p to accomplish its role in the autophagy pathway, and Apg16p is a key molecule as a linker to form the Apg12p-Apg5p-Apg16p multimer.     

The pre-autophagosomal structure organized by concerted functions of APG genes is essential for autophagosome formation.

Macroautophagy is a bulk degradation process induced by starvation in eukaryotic cells. In yeast, 15 Apg proteins coordinate the formation of autophagosomes. Several key reactions performed by these proteins have been described, but a comprehensive understanding of the overall network is still lacking. Based on Apg protein localization, we have identified a novel structure that functions in autophagosome formation. This pre-autophagosomal structure, containing at least five Apg proteins, i.e. Apg1p, Apg2p, Apg5p, Aut7p/Apg8p and Apg16p, is localized in the vicinity of the vacuole. Analysis of apg mutants revealed that the formation of both a phosphatidylethanolamine-conjugated Aut7p and an Apg12p- Apg5p conjugate is essential for the localization of Aut7p to the pre-autophagosomal structure. Vps30p/Apg6p and Apg14p, components of an autophagy- specific phosphatidylinositol 3-kinase complex, Apg9p and Apg16p are all required for the localization of Apg5p and Aut7p to the structure. The Apg1p protein kinase complex functions in the late stage of autophagosome formation. Here, we present the classification of Apg proteins into three groups that reflect each step of autophagosome formation.     

The mouse APG10 homologue,an E2-like enzyme for Apg12p conjugation,facilitates MAP-LC3 modification

Autophagy is a process for the bulk degradation of cytosolic compartments by lysosomes/vacuoles. The formation of autophagosomes involves a dynamic rearrangement of the membrane for which two ubiquitin-like modifications (the conjugation of Apg12p and the modification of a soluble form of MAP-LC3 to a membrane-bound form) are essential. In yeast, Apg10p is an E2-like enzyme essential for Apg12p conjugation. The isolated mouse APG10 gene product interacts with mammalian Apg12p dependent on mammalian Apg7p (E1-like enzyme), and facilitates Apg12p conjugation. The interaction of Apg10p with Apg12p is dependent on the carboxyl-terminal glycine of Apg12p. Mutational analysis of the predicted active site cysteine (Cys161) within mouse Apg10p shows that mutant Apg10pC161S, which can form a stable intermediate with Apg12p, inhibits Apg12p conjugation even in the presence of Apg7p, while overexpression of Apg7p facilitates formation of an Apg12p-Apg5p conjugate. Furthermore, the coexpression of Apg10p with Apg7p facilitates the modification of a soluble form of MAP-LC3 to a membrane-bound form, a second modification essential for autophagy. Mouse Apg10p interacts with MAP-LC3 in HEK293 cells, while no mutant Apg10pC161S forms any intermediate with MAP-LC3. Direct interaction between Apg10p and MAP-LC3 is also demonstrated by yeast two-hybrid analysis. The inability of mutant Apg10pC161S to form any intermediate with MAP-LC3 has ruled out the possibility that MAP-LC3 interacts with Apg10p as a substrate.     

Convergence of multiple autophagy and cytoplasm to vacuole targeting components to a perivacuolar membrane compartment prior to de novo vesicle formation.

Under starvation conditions, the majority of intracellular degradation occurs at the lysosome or vacuole by the autophagy pathway. The cytoplasmic substrates destined for degradation are packaged inside unique double-membrane transport vesicles called autophagosomes and are targeted to the lysosome/vacuole for subsequent breakdown and recycling. Genetic analyses of yeast autophagy mutants, apg and aut, have begun to identify the molecular machinery as well as indicate a substantial overlap with the biosynthetic cytoplasm to vacuole targeting (Cvt) pathway. Transport vesicle formation is a key regulatory step of both pathways. In this study, we characterize the putative compartment from which both autophagosomes and the analogous Cvt vesicles may originate. Microscopy analyses identified a perivacuolar membrane as the resident compartment for both the Apg1-Cvt9 signaling complex, which mediates the switching between autophagic and Cvt transport, and the autophagy/Cvt-specific phosphatidylinositol 3-kinase complex. Furthermore, the perivacuolar compartment designates the initial site of membrane binding by the Apg/Cvt vesicle component Aut7, the Cvt cargo receptor Cvt19, and the Apg conjugation machinery, which functions in the de novo formation of vesicles. Biochemical isolation of the vesicle component Aut7 and density gradient analyses recapitulate the microscopy findings although also supporting the paradigm that components required for vesicle formation and packaging concentrate at subdomains within the donor membrane compartment.     

Mouse Apg10 as an Apg12-conjugating enzyme: analysis by the conjugation-mediated yeast two-hybrid method

Autophagosome formation is a central event in macroautophagy. The Apg12-Apg5 conjugate, which is essential in this process, is generated by a ubiquitin-like protein conjugation system. In yeast, Apg12, following activation by the E1-like Apg7, forms a thioester with Apg10 (E2-like). Apg12 is finally conjugated to Apg5 via an isopeptide bond. The possible requirement of an E3-like protein for the conjugation, however, has not yet been confirmed. The Apg12 system is conserved among eukaryotes, although a mammalian counterpart of Apg10 has not yet been identified. Here, we report the identification and characterization of the mouse Apg10 ortholog. A yeast two-hybrid screen using the mouse Apg5 (mApg5) as bait identified a novel protein with 19% identity to yeast Apg10. We designated this protein mouse Apg10 (mApg10). We demonstrated by a modified yeast two-hybrid assay that mApg10 mediates the conjugation of mApg12 and mApg5. The in vivo interaction of mApg12 with mApg10 in HeLa cells suggests that mApg10 is an Apg12-conjugating enzyme, likely serving as an Apg5-recognition molecule in the Apg12 system. This novel two-hybrid method, which we have named 'conjugation-mediated yeast two-hybrid', proves to be a simple and useful technique with which to analyze protein-protein conjugation.     

Apg2 is a novel protein required for the cytoplasm to vacuole targeting, autophagy, and pexophagy pathways

To survive starvation conditions, eukaryotes have developed an evolutionarily conserved process, termed autophagy, by which the vacuole/lysosome mediates the turnover and recycling of non-essential intracellular material for re-use in critical biosynthetic reactions. Morphological and biochemical studies in Saccharomyces cerevisiae have elucidated the basic steps and mechanisms of the autophagy pathway. Although it is a degradative process, autophagy shows substantial overlap with the biosynthetic cytoplasm to vacuole targeting (Cvt) pathway that delivers resident hydrolases to the vacuole. Recent molecular genetics analyses of mutants defective in autophagy and the Cvt pathway, apg, aut, and cvt, have begun to identify the protein machinery and provide a molecular resolution of the sequestration and import mechanism that are characteristic of these pathways. In this study, we have identified a novel protein, termed Apg2, required for both the Cvt and autophagy pathways as well as the specific degradation of peroxisomes. Apg2 is required for the formation and/or completion of cytosolic sequestering vesicles that are needed for vacuolar import through both the Cvt pathway and autophagy. Biochemical studies revealed that Apg2 is a peripheral membrane protein. Apg2 localizes to the previously identified perivacuolar compartment that contains Apg9, the only characterized integral membrane protein that is required for autophagosome/Cvt vesicle formation.     

Apg7p/Cvt2p is required for the cytoplasm-to-vacuole targeting, macroautophagy, and peroxisome degradation pathways

Proper functioning of organelles necessitates efficient protein targeting to the appropriate subcellular locations. For example, degradation in the fungal vacuole relies on an array of targeting mechanisms for both resident hydrolases and their substrates. The particular processes that are used vary depending on the available nutrients. Under starvation conditions, macroautophagy is the primary method by which bulk cytosol is sequestered into autophagic vesicles (autophagosomes) destined for this organelle. Molecular genetic, morphological, and biochemical evidence indicates that macroautophagy shares much of the same cellular machinery as a biosynthetic pathway for the delivery of the vacuolar hydrolase, aminopeptidase I, via the cytoplasm-to-vacuole targeting (Cvt) pathway. The machinery required in both pathways includes a novel protein modification system involving the conjugation of two autophagy proteins, Apg12p and Apg5p. The conjugation reaction was demonstrated to be dependent on Apg7p, which shares homology with the E1 family of ubiquitin-activating enzymes. In this study, we demonstrate that Apg7p functions at the sequestration step in the formation of Cvt vesicles and autophagosomes. The subcellular localization of Apg7p fused to green fluorescent protein (GFP) indicates that a subpopulation of Apg7pGFP becomes membrane associated in an Apg12p-dependent manner. Subcellular fractionation experiments also indicate that a portion of the Apg7p pool is pelletable under starvation conditions. Finally, we demonstrate that the Pichia pastoris homologue Gsa7p that is required for peroxisome degradation is functionally similar to Apg7p, indicating that this novel conjugation system may represent a general nonclassical targeting mechanism that is conserved across species.     

Dictyostelium macroautophagy mutants vary in the severity of their developmental defects

Macroautophagy is the major mechanism that eukaryotes use to recycle cellular components during stressful conditions. We have shown previously that the Atg12-Atg5 conjugation system, required for autophagosome formation in yeast, is necessary for Dictyostelium development. A second conjugation reaction, Aut7/Atg8 lipidation with phosphatidylethanolamine, as well as a protein kinase complex and a phosphatidylinositol 3-kinase complex are also required for macroautophagy in yeast. In this study, we characterize mutations in the putative Dictyostelium discoideum orthologues of budding yeast genes that are involved in one of each of these functions, ATG1, ATG6, and ATG8. All three genes are required for macroautophagy in Dictyostelium. Mutant amoebae display reduced survival during nitrogen starvation and reduced protein degradation during development. Mutations in the three genes produce aberrant development with defects of varying severity. As with other Dictyostelium macroautophagy mutants, development of atg1-1, atg6(-), and atg8(-) is more aberrant in plaques on bacterial lawns than on nitrocellulose filters. The most severe defect is observed in the atg1-1 mutant, which does not aggregate on bacterial lawns and arrests as loose mounds on nitrocellulose filters. The atg6(-) and atg8(-) mutants display almost normal development on nitrocellulose filters, producing multi-tipped aggregates that mature into small fruiting bodies. The distribution of a green fluorescent protein fusion of the autophagosome marker, Atg8, is aberrant in both atg1-1 and atg6(-) mutants.     

The carboxyl terminal 17 amino acids within Apg7 are essential for Apg8 lipidation,but not for Apg12 conjugation

In the yeast, Saccharomyces cerevisiae, two ubiquitin-like modifications, Apg12 conjugation with Apg5 and Apg8 lipidation with phosphatidylethanolamine, are essential for autophagy and the cytoplasm-to-vacuole transport of aminopeptidase I (Cvt pathway). As a unique E1-like enzyme, Apg7 activates two modifiers (Apg12 and Apg8) in an ATP-dependent manner and, for this activity, the carboxyl terminal 40 amino acids are essential. For a better understanding of the function of the carboxyl terminus of Apg7, we performed a sequential deletion of the region. A mutant expressing Apg7DeltaC17 protein, which lacks the carboxyl 17 amino acids of Apg7, showed defects in both the Cvt pathway and autophagy. Apg8 lipidation is inhibited in the mutant, while Apg12 conjugation occurs normally. A mutant expressing Apg7DeltaC13 protein showed a defect in the Cvt pathway, but not autophagy, suggesting that the activity of Apg7 for Apg8 lipidation is more essential for the Cvt pathway than for autophagy. Mutant Apg7DeltaC17 protein is still able to interact with Apg8, Apg12 and Apg3, and forms a homodimer, indicating that the deletion of the carboxyl terminal 17 amino acids has little effect on these interactions and Apg7 dimerization. These results suggest that the carboxyl terminal 17 amino acids of Apg7 play a specific role in Apg8 lipidation indispensable for the Cvt pathway and autophagy.     

The C-terminal region of an Apg7p/Cvt2p is required for homodimerization and is essential for its E1 activity and E1-E2 complex formation

Apg7p/Cvt2p, a protein-activating enzyme, is essential for both the Apg12p-Apg5p conjugation system and the Apg8p membrane targeting in autophagy and cytoplasm-to-vacuole targeting in the yeast Saccharomyces cerevisiae. Similar to the ubiquitin-conjugating system, both Apg12p and Apg8p are activated by Apg7p, an E1-like enzyme. Apg12p is then transferred to Apg10p, an E2-like enzyme, and conjugated with Apg5p, whereas Apg8p is transferred to Apg3p, another E2-like enzyme, followed by conjugation with phosphatidylethanolamine. Evidence is presented here that Apg7p forms a homodimer with two active-site cysteine residues via the C-terminal region. The dimerization of Apg7p is independent of the other Apg proteins and facilitated by overexpressed Apg12p. The C-terminal 123 amino acids of Apg7p (residues 508 to 630 out of 630 amino acids) are sufficient for its dimerization, where there is neither an ATP binding domain nor an active-site cysteine essential for its E1 activity. The deletion of its carboxyl 40 amino acids (residues 591-630 out of 630 amino acids) results in several defects of not only Apg7p dimerization but also interactions with two substrates, Apg12p and Apg8p and Apg12p-Apg5p conjugation, whereas the mutant Apg7p contains both an ATP binding domain and an active-site cysteine. Furthermore, the carboxyl 40 amino acids of Apg7p are also essential for the interaction of Apg7p with Apg3p to form the E1-E2 complex for Apg8p. These results suggest that Apg7p forms a homodimer via the C-terminal region and that the C-terminal region is essential for both the activity of the E1 enzyme for Apg12p and Apg8p as well as the formation of an E1-E2 complex for Apg8p.