Atg9 Trafficking in Yeast Saccharomyces cerevisiae

Autophagy can be divided into selective and non-selective modes. This process is considered selective when a precise cargo is specifically and exclusively incorporated into autophagosomes, the double-membrane vesicles that are the hallmark of autophagy. In contrast, during nonselective, bulk autophagy, cytoplasmic components are randomly enwrapped into autophagosomes. To date, approximately 30 autophagy-related genes called ATG have been identified. Sixteen of them compose the general basic machinery catalyzing the formation of double-membrane vesicles in all eukaryotic cells. The rest of them are often not conserved between species and cooperate with the basic Atg proteins during either selective or nonselective autophagy. Atg9 is the only integral membrane component of the conserved Atg machinery and appears to be a crucial organizational element.5 Recent studies in the S. cerevisiae have shown that Atg9 transport is differentially regulated depending on the autophagy mode. In this addendum, we will review and discuss what has recently been unveiled about yeast S. cerevisiae Atg9 trafficking, its modulators and its potential role in double-membrane vesicle biogenesis.

Addendum to:

Atg9 Sorting from Mitochondria is Impaired in Early Secretion and VFT Complex Mutants in Saccharomyces cerevisiae

F. Reggiori and D.J. Klionsky

J Cell Sci 2006: 119:2903-11     

Atg9 trafficking in the yeast Saccharomyces cerevisiae

Autophagy can be divided into selective and nonselective modes. This process is considered selective when a precise cargo is specifically and exclusively incorporated into autophagosomes, the double-membrane vesicles that are the hallmark of autophagy. In contrast, during nonselective, bulk autophagy, cytoplasmic components are randomly enwrapped into autophagosomes. To date, approximately 30 autophagy-related genes called ATG have been identified. Sixteen of them compose the general basic machinery catalyzing the formation of double-membrane vesicles in all eukaryotic cells. The rest of them are often not conserved between species and cooperate with the basic Atg proteins during either selective or nonselective autophagy. Atg9 is the only integral membrane component of the conserved Atg machinery and appears to be a crucial organizational element. Recent studies in the S. cerevisiae have shown that Atg9 transport is differentially regulated depending on the autophagy mode. In this addendum, we will review and discuss what has recently been unveiled about yeast S. cerevisiae Atg9 trafficking, its modulators and its potential role in double-membrane vesicle biogenesis.     

Detection of Saccharomyces cerevisiae Atg13 by western blot

The proteins that comprise the Atg1 kinase complex constitute a key set of components that participate in macroautophagy (hereafter autophagy). Among these proteins, Atg13 plays a particularly important, although as yet undefined role, in that it is critical for the proper localization of Atg1 to the phagophore assembly site (PAS) and its efficient kinase activity. Atg13 is hyperphosphorylated in vegetative conditions when autophagy occurs at a basal level, and is largely dephosphorylated upon the induction of autophagy. Inhibitory phosphorylation of Atg13 reflects the activity of TOR complex 1 (TORC1) and protein kinase A. Accordingly, monitoring the phosphorylation state of Atg13 provides a convenient way to follow early steps of autophagy induction as well as the activity of some of the upstream nutrient-sensing kinases. However, the detection of Atg13 by western blot can be problematic. Here, we present a detailed protocol for sample preparation and detection of the Atg13 protein from yeast.     

Detection of Saccharomyces cerevisiae Atg13 by western blot

The proteins that comprise the Atg1 kinase complex constitute a key set of components that participate in macroautophagy (hereafter autophagy). Among these proteins, Atg13 plays a particularly important, although as yet undefined role, in that it is critical for the proper localization of Atg1 to the phagophore assembly site (PAS) and its efficient kinase activity. Atg13 is hyperphosphorylated in vegetative conditions when autophagy occurs at a basal level, and is largely dephosphorylated upon the induction of autophagy. Inhibitory phosphorylation of Atg13 reflects the activity of TOR complex 1 (TORC1) and protein kinase A. Accordingly, monitoring the phosphorylation state of Atg13 provides a convenient way to follow early steps of autophagy induction as well as the activity of some of the upstream nutrient-sensing kinases. However, the detection of Atg13 by western blot can be problematic. Here, we present a detailed protocol for sample preparation and detection of the Atg13 protein from yeast.     

Autophosphorylation Within the Atg1 Activation Loop Is Required for Both Kinase Activity and the Induction of Autophagy in Saccharomyces cerevisiae

Autophagy is an evolutionarily conserved degradative pathway that has been implicated in a number of physiological events important for human health. This process was originally identified as a response to nutrient deprivation and is thought to serve in a recycling capacity during periods of nutritional stress. Autophagy activity appears to be highly regulated and multiple signaling pathways are known to target a complex of proteins that contains the Atg1 protein kinase. The data here extend these observations and identify a particular phosphorylation event on Atg1 as a potential control point within the autophagy pathway in Saccharomyces cerevisiae. This phosphorylation occurs at a threonine residue, T226, within the Atg1 activation loop that is conserved in all Atg1 orthologs. Replacing this threonine with a nonphosphorylatable residue resulted in a loss of Atg1 protein kinase activity and a failure to induce autophagy. This phosphorylation required the presence of a functional Atg1 kinase domain and two known regulators of Atg1 activity, Atg13 and Atg17. Interestingly, the levels of this modification were found to increase dramatically upon exposure to conditions that induce autophagy. In addition, T226 phosphorylation was associated with an autophosphorylated form of Atg1 that was found specifically in cells undergoing the autophagy process. In all, these data suggest that autophosphorylation within the Atg1 activation loop may represent a point of regulatory control for this degradative process.MACROAUTOPHAGY (hereafter referred to as autophagy) is a highly conserved process of self-degradation that is essential for cell survival during periods of nutrient limitation (Tsukada and Ohsumi 1993). During autophagy, a double membrane grows out from a specific nucleation site, known as the pre-autophagosomal structure, or PAS, in Saccharomyces cerevisiae and the phagophore assembly site in mammals (Suzuki and Ohsumi 2007). This membrane encapsulates bulk protein and other constituents of the cytoplasm and ultimately targets this material to the vacuole/lysosome for degradation (Xie and Klionsky 2007). Recent studies have linked this pathway to a number of processes important for human health, including tumor suppression, innate immunity, and neurological disorders, like Huntington''s disease (Rubinsztein et al. 2007; Levine and Kroemer 2008). Determining how this pathway is regulated is therefore important for our understanding of these processes and our attempts to manipulate autophagy in clinically beneficial ways.Most of the molecular components of the autophagy pathway were initially characterized in the budding yeast, S. cerevisiae, but orthologs of many of these Atg proteins have since been found in other eukaryotes (Tsukada and Ohsumi 1993; Meijer et al. 2007). A complex of proteins that contains the Atg1 protein kinase is of special interest and appears to be a key point of regulatory control within this pathway (Kamada et al. 2000; Budovskaya et al. 2005; He and Klionsky 2009; Stephan et al. 2009). In S. cerevisiae, genetic and biochemical data indicate that this complex is targeted by at least three different signaling pathways. Two of these pathways, involving the Tor and cAMP-dependent protein kinases, inhibit this process, whereas the AMP-activated protein kinase is needed for the full induction of autophagy (Noda and Ohsumi 1998; Wang et al. 2001; Budovskaya et al. 2004; Stephan and Herman 2006; Kamada et al. 2010). The manner in which these signaling pathways regulate Atg1 activity and the precise role of this kinase in the autophagy process are presently matters of intense scrutiny.Although Atg1 kinase activity is required for the induction of autophagy, relatively little is known about how this enzyme is regulated in vivo. Two proteins associated with Atg1, Atg13 and Atg17, have been shown to be required for full Atg1 kinase activity both in vitro and in vivo (Kamada et al. 2000; Stephan et al. 2009). The roles of these proteins appear to be conserved through evolution as functional homologs of both have been identified in fruit flies and/or mammals (Hara et al. 2008; Chan et al. 2009; Chang and Neufeld 2009; Ganley et al. 2009; Hosokawa et al. 2009; Jung et al. 2009; Mercer et al. 2009). However, it is not yet clear precisely how these proteins stimulate Atg1 activity. In this study, we show that Atg1 is autophosphorylated within the activation loop and that this phosphorylation is required for both Atg1 kinase activity and the induction of autophagy. The activation loop is a structurally conserved element within the kinase domain and phosphorylation within this loop is often a necessary prerequisite for efficient substrate binding and/or phosphotransfer in the catalytic site (Johnson et al. 1996; Nolen et al. 2004). This loop generally corresponds to the sequence between two signature elements within the core kinase domain, the DFG and APE motifs (Hanks and Hunter 1995). Phosphorylation within this loop tends to result in a more ordered structure for this region and the proper positioning of key elements within the catalytic core of the kinase domain (Knighton et al. 1991; Johnson and O''reilly 1996; Huse and Kuriyan 2002). We found that Atg1 activation loop phosphorylation was correlated with the onset of autophagy and that replacing the site of phosphorylation with a phosphomimetic residue led to constitutive Atg1 autophosphorylation in vivo. In all, the data here suggest that Atg1 phosphorylation within its activation loop may be an important point of regulation within the autophagy pathway and models that discuss these data are presented.     

Atg26 is not involved in autophagy-related pathways in Saccharomyces cerevisiae

Autophagy is a degradative pathway conserved among eukaryotes. It is a major route for degradation of long-lived proteins and entire organelles, such as peroxisomes. Atg26, a sterol glucosyltransferase, is specifically required for micro- and macropexophagy, but not for starvation-induced bulk autophagy in Pichia pastoris. Here we study the requirement of Saccharomyces cerevisiae Atg26 in the Cvt pathway, nonspecific autophagy and pexophagy. Our results show that the S. cerevisiae atg26Delta strain is not defective in prApe1 maturation, macroautophagy or peroxisome degradation, in contrast to the situation seen in Pichia pastoris. These studies highlight the importance of examining mutants in multiple organisms.     

Atg26 is Not Involved in Autophagy-Related Pathways in Saccharomyces cerevisiae

Autophagy is a degradative pathway conserved among eukaryotes. It is a major route for degradation of long-lived proteins and entire organelles, such as peroxisomes. Atg26, a sterol glucosyltransferase, is specifically required for micro- and macropexophagy, but not for starvation-induced bulk autophagy in Pichia pastoris. Here we study the requirement of Saccharomyces cerevisiae Atg26 in the Cvt pathway, nonspecific autophagy and pexophagy. Our results show that the S. cerevisiae atg26? strain is not defective in prApe1 maturation, macroautophagy or peroxisome degradation, in contrast to the situation seen in Pichia pastoris. These studies highlight the importance of examining mutants in multiple organisms.     

Atg15 in Saccharomyces cerevisiae consists of two functionally distinct domains

Autophagy is a cellular degradation system widely conserved among eukaryotes. During autophagy, cytoplasmic materials fated for degradation are compartmentalized in double membrane–bound organelles called autophagosomes. After fusing with the vacuole, their inner membrane–bound structures are released into the vacuolar lumen to become autophagic bodies and eventually degraded by vacuolar hydrolases. Atg15 is a lipase that is essential for disintegration of autophagic body membranes and has a transmembrane domain at the N-terminus and a lipase domain at the C-terminus. However, the roles of the two domains in vivo are not well understood. In this study, we found that the N-terminal domain alone can travel to the vacuole via the multivesicular body pathway, and that targeting of the C-terminal lipase domain to the vacuole is required for degradation of autophagic bodies. Moreover, we found that the C-terminal domain could disintegrate autophagic bodies when it was transported to the vacuole via the Pho8 pathway instead of the multivesicular body pathway. Finally, we identified H435 as one of the residues composing the putative catalytic triad and W466 as an important residue for degradation of autophagic bodies. This study may provide a clue to how the C-terminal lipase domain recognizes autophagic bodies to degrade them.     

Pex3-anchored Atg36 tags peroxisomes for degradation in Saccharomyces cerevisiae

Peroxisomes undergo rapid, selective autophagic degradation (pexophagy) when the metabolic pathways they contain are no longer required for cellular metabolism. Pex3 is central to the formation of peroxisomes and their segregation because it recruits factors specific for these functions. Here, we describe a novel Saccharomyces cerevisiae protein that interacts with Pex3 at the peroxisomal membrane. We name this protein Atg36 as its absence blocks pexophagy, and its overexpression induces pexophagy. We have isolated pex3 alleles blocked specifically in pexophagy that cannot recruit Atg36 to peroxisomes. Atg36 is recruited to mitochondria if Pex3 is redirected there, where it restores mitophagy in cells lacking the mitophagy receptor Atg32. Furthermore, Atg36 binds Atg8 and the adaptor Atg11 that links receptors for selective types of autophagy to the core autophagy machinery. Atg36 delivers peroxisomes to the preautophagosomal structure before being internalised into the vacuole with peroxisomes. We conclude that Pex3 recruits the pexophagy receptor Atg36. This reinforces the pivotal role played by Pex3 in coordinating the size of the peroxisome pool, and establishes its role in pexophagy in S. cerevisiae.     

Structure of Atg5.Atg16, a complex essential for autophagy

Atg5 is covalently modified with a ubiquitin-like modifier, Atg12, and the Atg12-Atg5 conjugate further forms a complex with the multimeric protein Atg16. The Atg12-Atg5.Atg16 multimeric complex plays an essential role in autophagy, the bulk degradation system conserved in all eukaryotes. We have reported here the crystal structure of Atg5 complexed with the N-terminal region of Atg16 at 1.97A resolution. Atg5 comprises two ubiquitin-like domains that flank a helix-rich domain. The N-terminal region of Atg16 has a helical structure and is bound to the groove formed by these three domains. In vitro analysis showed that Arg-35 and Phe-46 of Atg16 are crucial for the interaction. Atg16, with a mutation at these residues, failed to localize to the pre-autophagosomal structure and could not restore autophagy in Atg16-deficient yeast strains. Furthermore, these Atg16 mutants could not restore a severe reduction in the formation of the Atg8-phosphatidylethanolamine conjugate, another essential factor for autophagy, in Atg16-deficient strains under starvation conditions. These results taken together suggest that the direct interaction between Atg5 and Atg16 is crucial to the performance of their roles in autophagy.     

Cis1/Atg31 is required for autophagosome formation in Saccharomyces cerevisiae

Autophagy is the bulk degradation of cytosolic materials in lysosomes/vacuoles of eukaryotic cells. In the yeast Saccharomyces cerevisiae, 17 Atg proteins are known to be involved in autophagosome formation. Genome wide analyses have shown that Atg17 interacts with numerous proteins. Further studies on these interacting proteins may provide further insights into membrane dynamics during autophagy. Here, we identify Cis1/Atg31 as a protein that exhibits similar phenotypes to Atg17. ATG31 null cells were defective in autophagy and lost viability under starvation conditions. Localization of Atg31 to pre-autophagosomal structures (PAS) was dependent on Atg17. Coimmunoprecipitation experiments indicated that Atg31 interacts with Atg17. Together, Atg31 is a novel protein that, in concert with Atg17, is required for proper autophagosome formation.     

Dual role of Atg1 in regulation of autophagy-specific PAS assembly in Saccharomyces cerevisiae

Most autophagy-related (Atg) proteins are assembled at the phagophore assembly site or pre-autophagosomal structure (PAS), which is a potential site for vesicle formation during vegetative or starvation conditions. To understand the initial step of vesicle formation, it is important to know how Atg proteins are recruited to the PAS. Atg11 facilitates PAS assembly for the cytoplasm to vacuole targeting (Cvt) pathway in vegetative conditions. To examine autophagy-specific PAS formation, an ATG11 deletion mutant was used to eliminate the PAS formation that occurs in vegetative conditions. We found that Atg1, Atg13 and Atg17 play a similar role for PAS formation under autophagy-inducing conditions as seen for Atg11 during vegetative growth. In particular, Atg1 is proposed to have dual roles for autophagy-specific PAS recruitment. Atg1 plays a structural role for efficient recruitment of Atg proteins to the PAS, which is mediated by interaction with Atg13 and Atg17. In contrast, Atg1 kinase activity is needed for dissociation of Atg proteins from the PAS during autophagy inducing conditions, a function which is also critical for autophagy activity.

Addendum to: Cheong H, Nair U, Geng J Klionsky DK. The Atg1 kinase complex Is involved in the regulation of protein recruitment to initiate sequestering vesicle formation for nonspecific autophagy in Saccharomyces cerevisiae. Mol Biol Cell 2008; 19:668-81.     

Dual role of Atg1 in regulation of autophagy-specific PAS assembly in Saccharomyces cerevisiae

Most autophagy-related (Atg) proteins are assembled at the phagophore assembly site or pre-autophagosomal structure (PAS), which is a potential site for vesicle formation during vegetative or starvation conditions. To understand the initial step of vesicle formation, it is important to know how Atg proteins are recruited to the PAS. Atg11 facilitates PAS assembly for the cytoplasm to vacuole targeting (Cvt) pathway in vegetative conditions. To examine autophagy-specific PAS formation, an ATG11 deletion mutant was used to eliminate the PAS formation that occurs in vegetative conditions. We found that Atg1, Atg13 and Atg17 play a similar role for PAS formation under autophagy-inducing conditions as seen for Atg11 during vegetative growth. In particular, Atg1 is proposed to have dual roles for autophagy-specific PAS recruitment. Atg1 plays a structural role for efficient recruitment of Atg proteins to the PAS, which is mediated by interaction with Atg13 and Atg17. In contrast, Atg1 kinase activity is needed for dissociation of Atg proteins from the PAS during autophagy inducing conditions, a function which is also critical for autophagy activity.     

Functional studies of aldo-keto reductases in Saccharomyces cerevisiae

We utilized the budding yeast Saccharomyces cerevisiae as a model to systematically explore physiological roles for yeast and mammalian aldo-keto reductases. Six open reading frames encoding putative aldo-keto reductases were identified when the yeast genome was queried against the sequence for human aldose reductase, the prototypical mammalian aldo-keto reductase. Recombinant proteins produced from five of these yeast open reading frames demonstrated NADPH-dependent reductase activity with a variety of aldehyde and ketone substrates. A triple aldo-keto reductase null mutant strain demonstrated a glucose-dependent heat shock phenotype which could be rescued by ectopic expression of human aldose reductase. Catalytically-inactive mutants of human or yeast aldo-keto reductases failed to effect a rescue of the heat shock phenotype, suggesting that the phenotype results from either an accumulation of one or more unmetabolized aldo-keto reductase substrates or a synthetic deficiency of aldo-keto reductase products generated in response to heat shock stress. These results suggest that multiple aldo-keto reductases fulfill functionally redundant roles in the stress response in yeast.     

Functional analysis of gene duplications in Saccharomyces cerevisiae

Gene duplication can occur on two scales: whole-genome duplications (WGD) and smaller-scale duplications (SSD) involving individual genes or genomic segments. Duplication may result in functionally redundant genes or diverge in function through neofunctionalization or subfunctionalization. The effect of duplication scale on functional evolution has not yet been explored, probably due to the lack of global knowledge of protein function and different times of duplication events. To address this question, we used integrated Bayesian analysis of diverse functional genomic data to accurately evaluate the extent of functional similarity and divergence between paralogs on a global scale. We found that paralogs resulting from the whole-genome duplication are more likely to share interaction partners and biological functions than smaller-scale duplicates, independent of sequence similarity. In addition, WGD paralogs show lower frequency of essential genes and higher synthetic lethality rate, but instead diverge more in expression pattern and upstream regulatory region. Thus, our analysis demonstrates that WGD paralogs generally have similar compensatory functions but diverging expression patterns, suggesting a potential of distinct evolutionary scenarios for paralogs that arose through different duplication mechanisms. Furthermore, by identifying these functional disparities between the two types of duplicates, we reconcile previous disputes on the relationship between sequence divergence and expression divergence or essentiality.     

Differential Involvement of Atg16L1 in Crohn Disease and Canonical Autophagy: ANALYSIS OF THE ORGANIZATION OF THE Atg16L1 COMPLEX IN FIBROBLASTS*

A single nucleotide polymorphism in Atg16L1, an autophagy-related gene (ATG), is a risk factor for Crohn disease, a major form of chronic inflammatory bowel disease. However, it is still unknown how the Atg16L1 variant contributes to disease development. The Atg16L1 protein possesses a C-terminal WD repeat domain whose function is entirely unknown, and the Crohn disease-associated mutation (T300A) is within this domain. To elucidate the function of the WD repeat domain, we established an experimental system in which a WD repeat domain mutant of Atg16L1 is stably expressed in Atg16L1-deficient mouse embryonic fibroblasts. Using the system, we show that the Atg16L1 complex forms a dimeric complex and that the total Atg16L1 protein level is strictly maintained, possibly by the ubiquitin proteasome system. Furthermore, we show that an Atg16L1 WD repeat domain deletion and the T300A mutant have little impact on canonical autophagy and autophagy against Salmonella enterica serovar Typhimurium. Therefore, we propose that Atg16L1 T300A is differentially involved in Crohn disease and canonical autophagy.